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30 June 2009 Generic Revision of the Dioptinae (Lepidoptera: Noctuoidea: Notodontidae) Part 1: Dioptini
James S Miller
Author Affiliations +
Abstract

The moth subfamily Dioptinae is almost entirely neotropical. One species—Phryganidia californica—occurs on the west coast of the US, while the remaining taxa are found from Mexico south to northern Argentina and Uruguay. None is known from the Old World. Most dioptines are diurnal as adults, and many exhibit aposematic coloration. A few taxa are nocturnal. Their larval hosts include the families Passifloraceae, Violaceae and Poaceae, plants famous for their use by important butterfly groups.

In this paper, a revised generic classification for the Dioptinae is presented. Nearly 17,000 specimens, assembled from 38 private and institutional collections worldwide, form the basis for the first comprehensive analysis of adult morphology in the subfamily. A subset of 115 exemplar species, chosen to represent structural diversity across the Dioptinae, is subjected to detailed morphological study and cladistic analysis. The resulting matrix includes 305 characters delineated by 938 character states. Cladistic analyses produced a single most parsimonious tree, rooted using three species from the Nystaleinae—the sister-subfamily to the Dioptinae. This phylogenetic hypothesis provides the framework for a revised classification.

The 456 species are assigned to 43 genera in two tribes; 10 species are treated as incertae sedis. Twelve genera are synonymized, and seven—Argentala, Chrysoglossa, Nebulosa, Notascea, Pikroprion, Proutiella, and Sagittala—are described as new. The 36 remaining genera are redescribed. Sixteen genera are further subdivided into species groups. All 574 species-group names of previous authors are addressed; in nearly all cases, primary type material was examined. Forty-seven species are newly synonymized, while 31 names are revived from synonymy. The revised classification includes 118 new combinations. Sixty-four species belonging in 30 different genera are newly described from Brazil, Colombia, Costa Rica, Ecuador, French Guiana, Guyana, Mexico, Panama, Peru, and Venezuela.

An illustrated overview of dioptine morphology is presented, demonstrating remarkable variation in a wide range of structures. Dichotomous keys utilizing external adult anatomy are provided to the tribes, genera, species groups and species. The salient features of each genus are figured and described. Heads, labial palpi, antennae, metathoracic tympani, wing scales, wing venation, and male and female terminalia are shown through line drawings, photographs, and scanning electron micrographs. Each species is diagnosed, its habitus is illustrated in color, type material is notated, and a summary of its known geographical distribution is presented.

General themes, as exemplified by the Dioptinae, are discussed. These include: Estimating species diversity in neotropical Lepidoptera; the evolution of aposematic coloration and mimicry; patterns of host-plant use; and the potential utility of characters from immature stages and DNA for further refining our understanding of dioptine evolution.

DEDICATION

PhotoThis paper is dedicated to the memory of John G. Franclemont (born April 15, 1912, the day the Titanic sank; died May 26, 2004). It was John Franclemont who inspired me to become a Lepidoptera systematist. He taught me valuable lessons in Lepidoptera and in life from the day we met, when I attended his lecture in Insect Systematics at Cornell University in 1980. He continued to inspire me even on visits during his final days. During the intervening 24 years, I hounded him constantly for information and ideas; rarely did a month go by where I didn't “go to the source”. I will forever be grateful for the kindness with which he graced my endless requests.

Photo

John G. Franclemont at his home with Belle and Angie, spring 1992 (photo by M. Hartill).

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Dr. Franclemont, a native of Buffalo NY, received both his B.S. and his Ph.D. from Cornell as a student of W.T.M. Forbes. After serving in World War II as a medical entomologist, followed by six years at the USNM (1947–1953), he taught in the Cornell Department of Entomology until his official retirement in June 1977. As a testament to his teaching commitment, he continued to offer a graduate course in Lepidoptera Systematics there until 1995. His association with Cornell thus encompassed over 60 years.

John Franclemont's influence on me personally was vast, but his reach extends far into the scientific community. Because of the incredible breadth of his knowledge, as well as the obvious depth of his love for entomology and natural history studies, he became a magnet for an entire generation of North American insect systematists. Dr. Franclemont was an astoundingly gifted teacher—his innate ability to incite curiosity in his students was beyond compare. His graduate students went on to become some of the most influential systematists in the history of the field; their papers are cited throughout the current work.

My interest in the Dioptinae can be directly credited to Franclemont. While I was a graduate student at Cornell University in 1983, working under his tutelage, two fellow graduate students—Jim Carpenter and Debbie Smith—had returned with insects collected in Suriname. I was encouraged by Dr. Franclemont to sort the Lepidoptera. This was my first exposure to the neotropical fauna. Among their material was a delicate, clear-winged moth bearing incredible resemblance to an ithomiine butterfly. I was fascinated. Franclemont urged me to identify the specimen (knowing full well that it belonged in the difficult genus Dioptis), and so my journey began. His influence on this project started that day and continued for over 20 years. It took those full 20 years, by the way, before I was able to positively identify the CUIC specimen (shown on plate 18) as Dioptis fatima Möschler. If nothing else, Dr. Franclemont would have been proud of my persistence.

INTRODUCTION

For over 20 years I have claimed the title of “world's expert” on the Dioptinae. To put that statement in perspective, the sad truth is that I am the first systematist to study these moths in nearly 100 years, and I am the only specialist active today. The research described in the current paper is the first comprehensive study of the Dioptinae since Hering's (1925) contribution to Volume 6 of Seitz's Macrolepidoptera of the World. The only other overview of dioptine classification was published earlier by Prout (1918), a taxonomist at the Tring Museum (later incorporated into the Natural History Museum, London) best known for his work on Geometridae. Both Hering and Prout provided essential references on the Dioptinae, but the two authors were hampered by severe limitations, one of the most significant that monophyly was not a philosophical concern during their time. The genera I was confronted with at the outset of this research were loosely defined assemblages, some without a single supporting character state.

A new classification for the Dioptinae is proposed here, based on cladistic analyses of characters from adult skeletal anatomy. A species sample, chosen to reflect morphological variation across the subfamily, serves to provide a character matrix. Parsimony analyses of these data generated an hypothesis of phylogenetic relationships, which is then used to delineate generic boundaries. The 43 genera employed in this revised classification are supported by synapomorphies, though rarely are these uniquely derived. All but 10 dioptine species were satisfactorily given generic assignment; these were placed as incertae sedis. Wherever informative morphological variation presented itself within a genus, species groups are defined. Keys are provided for all levels of the dioptine classification to enable collectors and museum workers the means to identify each of the 456 currently recognized species. It is hoped that this paper will provide a solid basis for future specialists in advancing our knowledge of dioptine systematics and biology.

An important goal here is to enlighten others regarding the scientific potential of the Dioptinae. In reading this publication, I hope it becomes clear that the group encompasses an incredible wealth of issues concerning natural history and biodiversity. The subfamily deserves intense future exploration on a multitude of disciplinary fronts.

Phylogenetic Position of the Dioptinae

The Dioptinae belong to the largest superfamily of the Lepidoptera, the Noctuoidea, which is estimated to contain 43,000 described species (Heppner, 1991; Minet, 1991; Solis and Pogue, 1999). The group's precise position within the superfamily has long been contentious. Packard (1895) was among the first to explore the phylogenetic position of the “Dioptidae”, though his conclusions were based entirely on study of the California Oakworm, Phryganidia californica, the only dioptid occurring north of the Mexican border (Franclemont, 1970). He placed the Dioptidae, Cyllopodidae (now Geometridae: Sterrhinae) and Geometridae together in a single evolutionary line, but few agreed with his interpretation. Forbes (1923), in the earliest proposed phylogeny for the superfamily Noctuoidea to treat all major family-level groups, placed the Dioptinae (as Dioptidae) at the base of the entire tree. However, various workers had noted characteristics shared by dioptids and the Notodontidae (Bodine, 1896; Prout, 1910), especially apparent in features of the immature stages (Fracker, 1915; Mosher, 1916). Because the adults bear little superficial resemblance to notodontids (Jordan, 1923b), the Dioptidae was nevertheless retained as a separate family by early taxonomists. As the years passed, accumulating morphological evidence highlighted a close affinity between the Dioptidae and Notodontidae (Köhler, 1930; Franclemont, 1970; Brock, 1971) until finally Minet (1983) relegated the group to tribal status, the Dioptini, subsumed within the subfamily Notodontinae. All of these authors observed that dioptine larvae possess reduced anal prolegs, a derived characteristic exhibited by most notodontids.

Spurred largely by the “Dioptidae/Dioptini” controversy, Miller (1991) published a reassessment of the higher classification of the world Notodontidae. An attempt was made to define monophyletic subfamilies and tribes using a cladistic analysis of larval, adult, and later (Miller, 1992b) pupal characters. Nine subfamilies of the Notodontidae were recognized—one being the Dioptinae—and, notwithstanding certain refinements proposed by Nakamura (2007), that classification has remained largely intact until the present time (Kitching and Rawlins, 1999; Fibiger and Lafontaine, 2005). Miller (1991, 1992b) regarded the Dioptinae to be in a derived position on the family phylogeny (fig. 1).

Figure 1

Position of the Dioptinae among major clades of the Notodontidae (from Miller, 1991).

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Dioptine adults, characteristically light bodied and of small to moderate size, span a diversity of wing patterns rivaled by few lepidopteran clades. Early authors were doubtful that dioptines formed a natural grouping (e.g., Seitz, 1925; Köhler, 1930), but no one had examined their morphology in detail. Miller (1991) found strong evidence that the Dioptinae are monophyletic, identifying 19 synapomorphies (more than for any other notodontid subfamily)—seven from larvae and 12 from adults. The current study has done nothing to shed doubt on this hypothesis; evidence for monophyly of the Dioptinae is overwhelming. Miller (1991) also described five synapomorphies suggesting that the neotropical subfamily Nystaleinae is the sister group to the Dioptinae. Three of these are from larval morphology, the most unambiguous being the position of seta L2 on abdominal segment 8 (Character 153 in Miller, 1991). The Dioptinae and Nystaleinae are unique among notodontids in that L2 on segment A8 is located anterior to the spiracle, on a line horizontal with it. The L2 seta on A8 is located directly below the spiracle in other Notodontidae.

From a taxonomic standpoint, the Dioptinae are thus poised to become one of the best-understood neotropical moth subfamilies: Monophyly has been confirmed; the clade's position has been established within the context of a higher classification; and a sister group has been identified. The most significant obstacle prior to revisionary species-level work, definition of monophyletic genera, provided the impetus for this paper.

Taxonomic History

The Dioptinae claim an intriguing, if tortuous, taxonomic history. It was Hering's (1925) opinion that no other group of Lepidoptera so thoroughly confounded the early specialists. The vast majority of species were originally described in the geometrid subfamily Cyllopodinae (now Sterrhinae), but during the course of nearly 200 years of descriptive work, dioptines have also been assigned to the Arctiidae, Pyralidae, Zygaenidae, and even the Psychidae (Hering, 1925; Miller, 1987a). Prout repeatedly encountered dioptines incorrectly identified as Geometridae during his taxonomic research. Realizing that these species needed proper placement, Prout (1918) decided to remedy the situation, uniting them in a single group, the Dioptidae, and presenting what he called a “provisional system of classification”.

The family name Dioptidae, first used by Walker in 1862 (Speidel and Naumann, 2005), has been applied throughout the group's history. Josiidae (Piepers and Snellen, 1900) is the only other available family-group name. Based on structure of the metathoracic hearing organ, Kiriakoff (1950) divided the Dioptidae into the Dioptinae and Josiinae, the latter exhibiting a unique kettledrum tympanum and the former showing a range of tympanal types (see also Sick, 1940). This division was later formalized as the tribes Dioptini and Josiini (Miller and Otero, 1994).

Prout (1918) and Hering (1925) relied on a small set of superficial adult traits for taxonomic assessments—notably wing venation, wing pattern, antennal structure, and labial palpus shape—most of which can be evaluated without the aid of a microscope. Considering this fact, the accuracy and insight reflected in their classifications is astounding. Bryk (1930), the most recent taxonomic arrangement for the Dioptinae and the only existing catalogue, made few modifications from Prout and Hering. By 1930, 40 genera and 396 valid species were recognized.

In the years between 1930 and the present, taxonomic contributions on the Dioptinae have been scarce. Hering (1930, 1943) described two additional species and Schaus (1933) described one. Kiriakoff (1950) erected the genus Euforbesia for a single species (unimacula Warren), and Beutelspacher (1986) described Tithraustes watsoni from Mexico; both of these taxa are synonymized in the present work. My own research to date has not focused on dioptine taxonomy, but rather on building our knowledge of the group's morphology and biology (Miller, 1988, 1996; Miller and Otero, 1994). In previous papers I described only four species and one genus (Miller, 1987a, 1989). In a fascinating discovery, Sattler and Wojtusiak (2000) described the first known brachypterous notodontid, a dioptine in the genus Xenomigia. Finally, Rawlins and Miller (2008) described two new dioptine species from the Dominican Republic, each in its own new genus. This paragraph is a complete summary of taxonomic literature on the Dioptinae over the past 80 years.

Prior to the research here, 574 species-group names had been published for the Dioptinae (421 Dioptini, 153 Josiini). The bulk of those are attributable to relatively few taxonomists. Table 1 shows the name totals for all authors who described more than one taxon. These authors comprise a familiar list of historically important players, several of whom are notorious for their extremely brief, often obtuse, species descriptions. Such work has caused relentless headaches for modern students of Lepidoptera taxonomy. It is an understatement to say that some of the taxonomists working near the turn of the 20th century were describing species at a furious pace—William Schaus of the USNM is said to have described roughly 5000 species of Lepidoptera, while Francis Walker at the BMNH described over 10,000 (V. Becker, personal commun.). For the Dioptinae, Warren, Hering, and Druce lead the pack with over 90 names attributable to each (table 1).

Table 1

Number of dioptine species-group names attributable to authors who described more than one taxon (years during which the names were described are in parentheses) Single taxa were described by seven additional authors.

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The history of dioptine taxonomy has a positive aspect, however. Six authors—William Warren, Martin Hering, Herbert Druce, Paul Dognin, Louis Prout, and Francis Walker—account for 462 species group names in the Dioptinae, over 80% of the total. An obvious ramification of the limited number of authors is that the vast majority of dioptine type material can be found at one of three museums (table 2): Hering's types are at the ZMH; those of Dognin (and Schaus) are at the USNM; and the huge remainder—the types of Warren, Druce, Prout, and Walker, well over half of those for the subfamily—are housed at the BMNH. Needless to say, I frequented the halls of those museums during the course of this research.

Table 2

Holdings of adult Dioptinae in the world's major collections The number of primary types listed includes those resulting from the current work.

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Acknowledgments

The groundwork for this project was laid during my years as an AMNH curator (1987–1999). The most intensive phase, which involved writing the text and completing the illustrations, was undertaken there as well (2004–2008). It is a pleasure to acknowledge the curators, as well as the entire staff of the AMNH Division of Invertebrate Zoology, who, throughout that time, provided an incredibly stimulating working environment. In particular, it is an honor to acknowledge Dave Grimaldi, Lee Herman, and Toby Schuh. Without their encouragement, this project would not have been completed. During the years 2000–2003, Jim Liebherr and Rick Hoebeke of the Department of Entomology at Cornell University kindly provided work space, as well as access to the Cornell insect collections. For logistical support during my return to New York City in 2004, I will forever be grateful to Lee Herman, Valerie Giles, and Andrew Valelly. Between 1991 and 1996, the research was supported by a National Science Foundation grant (BSR-9106517) to JSM. Expeditions to Ecuador (2004, 2006, 2009) were supported by NSF grants DEB-0717173 and DEB-0849361 to Lee Dyer, and by the University of Nevada, Reno. Robert G. Goelet, chairman emeritus and current trustee of the AMNH graciously funded the years 2006 and 2007.

Special thanks must be extended to Steve Thurston (AMNH), whose remarkable expertise and tireless efforts were crucial during the production phase of this paper. He generated digital renderings of the illustrations and produced the final figures and color plates, suffering through innumerable changes and last-minute modifications. It is no exaggeration to say that without Steve's help, the paper would not have been completed; I feel considerable guilt for not making him a coauthor.

Amy Trabka, formerly associated with Cornell University, executed many of the genitalia illustrations (1993–1996), and Sally Goodman (formerly AMNH) inked a series of adult heads (1996). Becky Rudolph and Emily Griffiths of the AMNH Microscopy and Imaging Facility assisted with scanning electron microscopy. Dave Grimaldi kindly provided access to his Microptics-USA system for photographing adult moths and genitalia slides. Tam Nguyen assisted with setup and troubleshooting. On a visit to the Natural History Museum in London (March 2005), Quentin Wheeler made his Microptics system available for photographing BMNH types. Claudia Aragón (Herédia, Costa Rica) rendered the cover for Part 1, and Steve Thurston (AMNH) painted the cover for Part 2.

It is with extreme gratitude that I thank the scientists who reviewed this paper—Vitor Becker (Serra Bonita, Brazil), Andy Brower (Middle Tennessee State University, Murfreesboro), Phil DeVries (University of New Orleans, LA), Ian Kitching (Natural History Museum, London), Don Lafontaine (Canadian National Collections, Ottawa), Carla Penz (University of New Orleans, LA) and Keith Willmott (McGuire Center, Gainesville, FL). Each offered unique insights, drawing on their vast expertise in neotropical Lepidoptera. The submitted version was greatly improved as a result of their remarkable efforts. Special thanks also go to Rob Voss, Lee Herman and Lorenzo Prendini of the AMNH Publications Committee, whose oversight in guiding the manuscript from submission to publication made the process painless. I am especially grateful to Mary Knight, editor of AMNH publications. Her extremely thorough review greatly improved the paper's readability. Furthermore, her extensive knowledge of Latin, Greek, and English grammar proved to be invaluable.

Throughout the years, I have frequently consulted Gerardo Lamas (Museo de Historia Natural, Lima, Peru), whose remarkable knowledge of 19th-century Lepidoptera collectors and their collecting localities was indispensable. He also aided in finding certain extremely rare, usually ancient, literary citations, frequently providing copies from his immense personal collection.

This study would not have been possible without the generosity of the world museum community. It is especially important to acknowledge Martin Honey of the Natural History Museum, London, and Wolfram Mey of the Zoologisches Museum für Naturkunde, Humboldt-Universität, Berlin. Over the years, I have come to count on their amazing knowledge of their respective collections. In addition to facilitating loans, they fielded innumerable questions regarding type specimens and obscure literature citations. I am deeply indebted to both. Dave Furth, collection manager at the United States National Museum, spearheaded the arrangements necessary for a long-term loan of the entire USNM Dioptinae holdings, including types. Daily access to that material was pivotal for understanding the group's systematics.

I am particularly indebted to the numerous private collectors who loaned, or often donated, valuable Dioptinae for this research. I would especially like to thank Vitor Becker (Serra Bonita, Brazil), Bernard Hermier (Cayenne, French Guiana), Francisco Piñas (Quito, Ecuador), J. Bolling Sullivan (Beaufort, North Carolina), Paul Thiaucourt (Paris, France) and Rafael Turrent (Mexico City, Mexico), whose collections were the source of species newly described here.

The following individuals and institutions kindly loaned material for study. Without their generous assistance in providing access to the collections in their care, it would have been impossible to investigate dioptine biodiversity. The abbreviations listed below are utilized throughout this work:

AMNH

American Museum of Natural History, New York, NY, USA

ARTC

Alonso and Rafael Turrent Collection, Mexico City, Mexico (Rafael Turrent)

BHC

Bernard Hermier Collection, Cayenne, French Guiana (Bernard Hermier)

BMNH

The Natural History Museum, London, Great Britain (Martin Honey, Malcolm Scoble)

CAS

California Academy of Sciences, San Francisco, CA, USA (Paul Arnaud)

CCC

Charles Covell Collection, University of Kentucky, KY, USA (Charles Covell)

CMNH

Carnegie Museum of Natural History, Pittsburgh, PA, USA (John E. Rawlins)

CNC

Canadian National Collections, Ottawa, Canada (Don Lafontaine)

CUIC

Cornell University Insect Collections, Ithaca, NY, USA (Jim Liebherr and Rick Hoebeke)

EMEC

Essig Museum of Entomology Collection, Berkeley, CA, USA (Kip Will)

FML

Fundación Miguel Lillo, Tucumán, Argentina (Robert Eisele)

FNHM

Florida Natural History Museum, Gainesville, FL, USA (Paul Goldstein and Andre Sourakov)

FPC

Francisco Piñas Collection, Quito, Ecuador (Francisco Piñas)

INBio

Instituto Nacional de Biodiversidad, Santo Domingo de Heredia, Costa Rica (Bernardo Espinoza and Isidro Chacón)

IZA

Instituto de Zoología Agrícola, Maracay, Venezuela (John Lattke and Jorge Gonzalez)

JBSC

J. Bolling Sullivan Collection, Beaufort, NC, USA (Bo Sullivan)

JCC

J. Cerda Collection, Kaw, French Guiana (J. Cerda)

LACM

Natural History Museum of Los Angeles County, Los Angeles, CA, USA (Brian Brown and Julian Donahue)

MCZ

Museum of Comparative Zoology, Harvard University, Boston, MA, USA (P. Perkins and Michael Kelley)

MNHN

Museum National d'Histoire Naturelle, Paris, France (Joel Minet)

MPM

Milwaukee Public Museum, Milwaukee, WI, USA (Allen Young and Susan Borkin)

MUSM

Museo de Historia Natural, Universidad Nacional Mayor de San Marcos, Lima, Peru (Gerardo Lamas and Juan Grados)

NHMB

Naturhistorisches Museum, Basel, Switzerland (D. Burckhardt)

NMW

Naturhistorisches Museum Wien, Austria (Martin Lödl and Sabine Gaal-Haszler)

NYSM

New York State Museum, Albany, NY, USA (Tim McCabe)

OUMNH

Oxford University Museum of Natural History, Oxford, Great Britain (Zoë Simmons)

PMNH

Peabody Museum of Natural History, New Haven, CT, USA (Raymond Pupedis)

PTC

Paul Thiaucourt Collection, Paris, France (Paul Thiaucourt)

PUCE

Pontificía Universidad Católica del Ecuador, Quito (Giovanni Onore)

SDNH

San Diego Natural History Museum, San Diego, CA, USA (David Faulkner)

SMNS

Staatliches Museum für Naturkunde, Stuttgart, Germany (Gunnar Brehm)

STRI

Smithsonian Tropical Research Institute, Balboa, Panama (Annette Aiello)

UNAM

Colección Entomológica, Instituto de Biología, Universidad Nacional Autónoma de Mexico, Mexico City, Mexico (Carlos Beutelspacher)

USNM

United States National Museum, Washington, DC, USA (Michael Pogue and David Furth)

USUC

Utah State University Insect Collection, Logan, UT, USA

VOB

Vitor Osmar Becker Collection, Serra Bonita Reserve, Camacan, Bahia, Brazil (Vitor Becker)

ZMC

Zoologisk Museum of Copenhagan, Denmark (Nicholaj Scharff and Ole Karsholt)

ZMH

Zoologisches Museum für Naturkunde der Humboldt-Universität, Berlin, Germany (Wolfram Mey)

ZMJU

Zoological Museum, Jagiellonian University, Kraków, Poland (Janusz Wojtusiak)

Fieldwork forms the backbone of this project. The following people provided valuable aid, either by accompanying me on expeditions in search of Dioptinae, or by collecting dioptines on their own: from the USA, Lee Herman, Cal Snyder, Andy Brower, Suzanne Rab Green, and Valery Giles; in Costa Rica, Jorge Corrales, Bernardo Espinosa, Isidro Chacón, and Antonio Azofeifa (INBio); in Ecuador, Giovanni Onore, Elicio Tapia, and Mario Tapia; in French Guiana, Bernard Hermier and Frederic Beneluz; in Panama, Annette Aiello and Don Windsor (STRI); in Peru, Gerardo Lamas, Juan Grados, Juan José Ramírez, and Angel Asenjo (MUSM); in Venezuela, Daniel Otero (Universidad de Los Andes). For tireless efforts documenting the natural history of neotropical Lepidoptera, and for generously sharing their findings on the Dioptinae, I would like to thank the following: Dan Janzen, Winnie Hallwachs, and their remarkable field teams at Area de Conservación de Guanacaste (Costa Rica); Harold Greeney, Lee Dyer, Grant Gentry, and the group at Yanayacu Biological Station (Ecuador); Annette Aiello (STRI, Panama); Daniel Otero and Andres Orellana (Mérida, Venezuela). I also gratefully acknowledge the following individuals who donated Dioptinae, collected during their own expeditions, to the AMNH for study: Phil DeVries (University of New Orleans); Dave Wagner (University of Connecticut, Storrs); Tim McCabe (NY State Museum); Gunnar Brehm (Institut für Spezielle Zoologie und Evolutionsbiologie, Friedrich-Schiller-Universität Jena); and Bob Robbins (Smithsonian Institution).

The following agencies issued collecting and export permits, allowing me to collect Dioptinae in their countries: In Panama, STRI and the Instituto de Recursos Naturales Renovables; in Venezuela, the Instituto Nacional de Parques; in Costa Rica, the Instituto Nacional de Biodiversidad and the Ministerio del Ambiente y Energía; in Quito Ecuador, the Ministerio del Ambiente and the Museo Ecuatoriano de Ciencias Naturales; in Lima Peru, the Museo de Historia Natural Universidad Nacional Mayor de San Marcos and the Instituto de Recursos Naturales.

Kurt Picket (University of Vermont), Kip Will (University of California, Berkeley) and Jim Carpenter (AMNH) assisted with cladistic analyses. Andy Brower (Middle Tennessee State University) was instrumental in providing analytical expertise throughout this project, and kindly calculated Bremer support values. For general discussions concerning character coding and phylogenetic methodology, I thank Lee Herman, Kurt Picket, Jim Liebherr, Toby Schuh, and Dave Grimaldi. I thank Andy Warren for providing references on the corethrogyne in skippers, and for facilitating a loan of material from the Alonso and Rafael Turrent Collection in Mexico City.

Methods

The form of this publication takes its inspiration from the landmark monograph by Pedro Wygodzinsky (1966) on the subfamily Emesinae (Hemiptera: Reduviidae), in which he reclassified the world fauna. My project pales in comparison with his; Wygodzinsky monographed nearly 1000 species in 92 genera, twice the size of the fauna treated here. Nevertheless, our goals were the same: to revise the genera and provide species-level taxonomic coverage for a large insect clade, along with identification keys, comprehensive documentation of adult morphology, and geographical distributions.

Pinned adult specimens, assembled through museum loans and from my own fieldwork, provided the raw materials for this study. These were the source for morphological character data, which were then utilized in phylogenetic analyses. A cladistic analysis of all species in the Dioptinae would not have been practical. I instead chose the exemplar approach, a method that has delivered positive results in the past (e.g., Miller, 1987b, 1991, 1996; Miller, Brower, and DeSalle, 1997). The rationale for utilizing a species subset was driven largely by the inordinate rarity of certain taxa. Many are known solely from the type. Likewise, some genera, especially monobasic ones, have been described either from a tiny series of specimens, or from a single specimen. Often, females are unknown. These cases presented two problems. First, when two or fewer specimens represent the sum of our knowledge of a taxon, I was loath to sacrifice one of those by performing a whole-body dissection, necessary for scoring all traits. Secondly, females provide important characters for these analyses; if female specimens were unavailable, that taxon was not included as an exemplar in my cladistic analyses.

In order for the exemplar approach to be successful, it was crucial that the species chosen reflect all or most of the morphological variation that occurs across the subfamily. My approach was to familiarize myself, as completely as possible, with species-level taxonomy and morphology for the entire Dioptinae. In conjunction with this goal, I attempted to examine type material for each of the 574 previously published species-group names. During the course of visits to the museums in London, Berlin, and Washington, I photographed and examined nearly all extant types for the Dioptinae.

Once this groundwork of knowledge had been established, I was able to select exemplar species from a position of strength. My search for characters from skeletal anatomy was exhaustive. Cladistic hypotheses can always be improved upon through the addition of novel characters and more taxa, but given the data set at hand, I place considerable confidence in the results described in these pages. The new generic classification, while not perfect, is a vast improvement over what existed before.

Museums

Dioptinae are poorly represented in collections worldwide (table 2). I was able to locate only 14 collections that contained more than 150 specimens. Interestingly, relatively recent biodiversity sampling programs, such as those at INBio, the LACM, and the CMNH, have produced dramatic results, placing those institutions near the forefront of tropical Lepidoptera collections. Growth of Dioptinae holdings at the AMNH reflects nearly 20 years of focused collecting. When I first arrived there in 1987, the AMNH housed approximately 1000 specimens, whereas it now ranks first in the world, with roughly 3700 specimens. In contrast, the holdings at the BMNH are large, but have grown little over the past 100 years.

The initial phase of this research was carried out during a Smithsonian postdoctoral fellowship in 1986. During that year, I visited major museums, borrowing representative specimens of Dioptinae. Collections studied included those of the AMNH, BMNH, CMNH, CUIC, ZMH, and of course the USNM, the site of my postdoctoral research. Whole-body and genital dissections (males and females) provided an initial morphological survey, and served to highlight problem areas in the generic classification.

A seven-year curatorial fellowship (1987–1994) at the AMNH followed. I continued amassing pinned specimens through loans, and began my own fieldwork on the Dioptinae. During the course of field trips, I studied the following collections: BHC, FPC, INBio, IZA, JCC, MUSM, PUCE, and STRI. Additional museum visits were made to: the CNC, EMEC, MCZ, MNHN, PTC, and the PMNH.

Another phase of loans further increased species representation in my study sample. The following graciously sent me all or most of the Dioptinae in their holdings: ARTC, CAS, CCC, CMNH, EMEC, FML, FNHM, JBSC, LACM, MPM, NMW, SDNH, VOB, and the ZMC.

In an incredibly gracious and helpful gesture, the USNM loaned the entirety of their substantial dioptine holdings, including 92 types, on a long-term basis. This provided daily access to the remarkable historical collections of Dognin and Schaus.

Fieldwork

Dioptines are extremely difficult to collect. They are usually rare, and are always elusive. Members of a few genera, such as Xenomigia, Scotura, and Monocreaga, can be captured at light traps. These taxa thus appear more frequently in museum collections. However, the vast majority of dioptine species are largely or completely diurnal. Many seem to show two active periods each day, flying in late morning, and then again between 4 p.m. and 6 p.m. before sunset. Understory and cloud forest species are active in brief bursts throughout the day. Nevertheless, I have walked particular trails, where dioptines were known to occur, for days without seeing a single individual. A few taxa are locally common. For example, Dolophrosyne coniades (Druce) and Nebulosa yanayacu, sp. nov., fly in abundance at Yanayacu Biological Station in eastern Ecuador. Nonetheless, these two taxa rarely appear in museum or private collections, apparently because butterfly and moth collectors have consistently overlooked them in the field.

My quest to learn more about the biology of these fascinating moths, and to accumulate a strong representation of dioptine specimens for study, has taken me to some of the most beautiful locations on earth. During the course of this project, I made 20 field trips to six different Central and South American countries, searching for dioptine adults and immatures. These expeditions were aimed at visiting areas of high species diversity, based on examination of pre-existing specimen label data. I learned to undertake each trip with a minimum of expectations, and although I was frequently dismayed at the difficulty of finding target taxa, every expedition produced remarkable surprises. These collecting efforts helped to more than triple the number of dioptine specimens housed at the AMNH (table 2), providing a strong species sample for comparative morphological study.

Exemplars

After nearly two decades of accumulated insight regarding dioptine morphology and taxonomy, 115 exemplar species (table 3) were chosen for detailed study—in the species treatments, exemplars are designated by “[EX]” following their name. Cladistic analysis of relationships among this species subset provides the framework for a revised classification of the subfamily. At the outset, I was relatively confident concerning the monophyly of certain pre-existing genera. For example, Erbessa shows a suite of clear-cut morphological apomorphies, obvious even to the early taxonomists. For genera such as this, relatively few exemplars were chosen. On the other hand, my morphological survey suggested that Tithraustes was polyphyletic. In such cases, a much broader sample of representatives was included in the cladistic analyses. Overall, I am confident that the list of exemplar species represents a comprehensive picture of morphological diversity for the Dioptinae.

Table 3

Exemplar species used in the cladistic analyses For previously described species, generic assignments follow earlier classifications (Bryk, 1930; Kiriakoff, 1950; Miller, 1989). Provenance refers to the specimen from which the whole-body dissection was made.

i0003-0090-321-1-1-t03.gif

Preparation of specimens for morphological study follows previously described methods (e.g., Miller, 1996). Male and female genital dissections, stained with chlorazol black and mounted in Canada balsam, were made for as many species as possible. In most cases, specimens from more than one locality were dissected. Each slide preparation was given a “JSM” slide number, and these are cited in the individual species treatments. For each exemplar taxon, a whole-body dissection was made by removing the wings and dissolving the body in 10% KOH. Wings were retained with the pin and labels, whereas the bodies were placed in individual vials of 70% ethanol. In certain cases, the right fore- and hind wings, as well as appendages, were stained using eosin Y and mounted in balsam. Altogether, more than 2000 preparations were made during the course of this study—over 1800 genitalia and wing slides, as well as approximately 200 bodies in alcohol.

Morphology

Completion of this study would not have been possible were it not for the fact that adult Dioptinae provide a rich source of morphological characters. Use of pinned museum material allowed for study across the taxonomic spectrum, even for species that had been captured well before the turn of the 20th century but have not been seen since. Interestingly, the Dioptinae seem to offer a broader range of structural variation than most other Lepidoptera groups with which I am familiar. Comparatively speaking, many subfamilies of similar size are morphologically homogeneous. It is not clear why dioptines exhibit such remarkable structural diversity. Perhaps the evolution of a lifestyle novel for the Notodontidae has in turn given rise to a rapid burst of anatomical specializations. Whatever the underlying reason, I am thankful for small favors.

Larval morphology has played an important role throughout the history of notodontid classification, starting with Packard (1895). In previous family-level studies on the Notodontidae, caterpillars have been shown to hold more deep-level phylogenetic information than adults (Miller, 1991). However, I relied exclusively on adult morphology for the cladistic analyses described here. This was of necessity. Tables 4 and 6 summarize our current knowledge of dioptine immatures and host plant relationships. To date, immature stages are known for only 17% of the fauna, and the larvae of certain crucial taxa may never be discovered. However, earlier comparisons showed that adult characters alone are extremely effective for unraveling phylogeny within the Dioptinae (Miller, 1996; Miller, Brower, and DeSalle, 1997).

Table 4

Known host plants of the Dioptini Genera are assigned to plant families according to Soltis et al. (2005) and the Missouri Botanical Garden's angiosperm phylogeny website (Stevens, 2006). For a host-plant database of world Lepidoptera, visit  http://www.nhm.ac.uk/entomology/hostplants/ (Robinson et al., 2007).

i0003-0090-321-1-1-t04.gif

My search for informative adult morphological traits was exhaustive. Appendix 1 lists virtually every skeletal character that showed structural variation for the Dioptinae. The 305 characters are described by a total of 938 character states. Difficult character complexes, such as those where character state assignments were somewhat ambiguous, were nevertheless incorporated into the analysis. My rationale was that even these potentially provide useful information regarding common ancestry.

Along with standard references on Lepidoptera morphology (e.g., Common, 1990; Nielsen and Common, 1991; Scoble, 1992; Kristensen, 2003), the important papers of Ehrlich (1958a, 1958b) and Oseto and Helms (1976) proved useful. The latter was especially insightful for understanding sclerites of the head and thorax. Additional discussions focusing on dioptine morphology can be found in my own published work (Miller, 1987a, 1988, 1989, 1992b, 1996; Miller and Otero, 1994). Terminology for microsculpture follows Eady (1968).

Cladistic Analyses

The data matrix (appendix 3) comprises 115 ingroup species and three outgroup species, each scored for 305 morphological characters. Of these characters, 118 are binary while 187 are described by three or more states. Multistates were treated as either unordered (91 characters) or ordered (96 characters); following each character description in appendix 1, these are noted as either [−] for unordered, or [+] for ordered. More complex multistate treatments, for example using character state tree coding, were not employed.

Throughout its construction and development, the matrix was edited using WinClada, Version 1.00.08 (Nixon, 2002). Phylogenetic analyses were performed with a single, straightforward goal in mind—a search for the shortest tree—since this best summarizes available data (e.g., see Wenzel, 1997). Parsimony analyses employed Tree Analysis Using New Technology, Version 1.0, or TNT (Goloboff, Farris and Nixon, 2006). This software combination afforded flexibility for manipulating the large data matrix, and offered powerful tree-searching capabilities. To root the dioptine cladogram, three notodontid species were selected from the Nystaelinae, the sister group of the Dioptinae (Miller, 1991), and scored for all characters. Experimentation utilizing up to five nystaleine taxa produced the same ingroup tree topology, as well as identical character state optimizations.

For tree searches using TNT, the following were specified: First, the settings were modified to allow 100,000 trees to be retained in memory, and General RAM was increased to 100 MB. For the analyses themselves, Random Seed was set to 0; 200 random addition sequences were employed; and the algorithms Sectorial Search, The Ratchet, and Drift and Tree Fusing were utilized simultaneously. Characters were equally weighted. The full analysis took 3 minutes and 2 seconds, and examined over 2.6 billion tree rearrangements. A single shortest tree was found, with a length of 3077 steps, a consistency index of 0.19, and a retention index of 0.71. This tree (fig. 2) forms the basis for the new classification of the Dioptinae (appendix 2). Bremer support (BS) values (Bremer, 1988; Bremer, 1994) were chosen to estimate the robustness of clade support. These were estimated by heuristic anticonstraint searches with 10 random addition sequences (see Brower, 2006). Figure 2 shows BS values for all branches of the dioptine cladogram. Figures 3 and 283 summarize generic assignments for the exemplar species, while the implied cladogram of relationships among dioptine genera is shown in Figure 7.

Descriptive Taxonomy

The primary focus here is to present a revised, and—it is hoped—stable, dioptine classification. However, during the course of these studies, numerous undescribed species were encountered. Sixty-four species of Dioptinae are described here as new. This is a relatively small percentage of the undescribed material residing in collections, and it is only a fraction of the new taxa that will ultimately be recognized. In some genera, such as Xenomigia and Nebulosa, I argue that the described species represent less than a third of those that occur in nature (see Discussion: Biodiversity).

The species described were selected using somewhat arbitrary criteria. A few exhibit novel morphology. The majority were chosen because a sizeable series, usually recently collected, was available for study. Two countries, Ecuador and Costa Rica, are particularly well represented in the list of newly described taxa. Modern collectors have traveled to those nations frequently over the past two decades, and I have visited them on numerous occasions myself. The high number of species described from these two, relatively small neotropical countries, is illustrative. Thorough collecting in larger, ecologically and topologically complex Central and South American countries, such as Guatemala, Nicaragua, Venezuela, Colombia and Peru, will undoubtedly reveal an incredible wealth of undiscovered biodiversity for the Dioptinae (see Discussion: Biodiversity). Choices of species epithets were aided by referring to Brown (1956), with subsequent input from Mary Knight (AMNH). Generic names were checked for availability by searching the online version of Neave (1939) and by searching Google ( http://www.google.com).

Maps showing geographical distributions are provided only for newly described species. Ultimately, it will be important to delimit distributions throughout the Dioptinae. Species distributions for Costa Rica, Ecuador, and Peru are shown using detailed relief maps (figs. 4Figure 56), while those for species described from other countries are illustrated with simple line maps.

Figure 4

Costa Rica, showing major cities.

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Figure 5

Ecuador, showing major cities and river systems.

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Figure 6

Peru, showing major cities and river systems.

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Figures

Another important focus of this paper is to thoroughly document dioptine morphological diversity. Representative heads, wings, and genitalia are figured for each genus, and usually for each species group where those are defined. When deemed important, variation in particular structures—such as thoracic sclerites, antennae, and legs—is shown. Traditional line drawings are combined with digital photography and scanning electron microscopy (SEM).

Genitalia photographs were taken using a Microptics-USA photomicrographic apparatus, equipped with Infinity K2 optics and a Nikon D1X digital camera. One of three Infinity Photo Optical lenses (CF-1, CF-2, CF-3), each of different magnification, was selected based on the size of the moth's genitalia. Specimens for SEM were sputter coated with gold-palladium and photographed using a Hitachi S-4700 scanning electron microscope.

Figures follow certain conventions throughout. The method for preparing genitalia mounts was to make a slit along the abdomen's left side. Genitalia were then removed and the remaining abdomen was mounted flat, resulting in a dorsal view of Tg8 and a ventral view of St8; whenever these are illustrated, the distal margin is always positioned at the top. In all genital drawings and photographs, the male is shown in posterior view, whereas female genitalia and the aedeagus are illustrated in lateral view. Additional structures, such as heads and thoraces, are also shown in lateral view. Whenever lateral views are shown, anterior is always at the left.

A crucial aspect of Hering's (1925) paper was that he presented renderings for the adults of 271 dioptine species on four, full-color plates. Those illustrations are relatively accurate, and provide important aids for species identification; I have relied on them heavily over the years. However, my goal was to take Hering's contribution a step further. Therefore, color plates depicting an adult specimen representing every described species in the Dioptinae, are included in this paper (pls. 1–35). Locality data for each adult figured are listed in appendix 5. Adult specimens were photographed using the same Microptics system employed for genitalia photographs, except that in this case the lens was a Nikon 60 mm AF Micro Nikkor.

COMPARATIVE ADULT MORPHOLOGY

The major structural features of adults, crucial for understanding phylogenetic relationships in the Dioptinae, are outlined below. Morphological details can be gleaned from the character list (appendix 1), from the generic and species keys, and from the associated figures. The following abbreviations are used throughout this publication:

A1–A8

abdominal segments 1–8

1A–3A

anal veins 1–3

AA

anterior apophyses

BO

Barth organ

C

costal vein

CB

corpus bursae

CuA

cubito-anal vein

DB

ductus bursae

DC

discal cell

DS

ductus seminalis

FW

forewing

HW

hind wing

LDC

lower discocellular vein

Lp

labial palpus segment

M

medial vein

MDC

middle discocellular vein

PA

papillae anales

PP

posterior apophysis

PVP

postvaginal plate

R

radial vein

Rs

radial sector

St

sternum

Tg

tergum

UDC

upper discocellular vein

Head

Labial palpi have been used as diagnostic features almost since the beginning of Lepidoptera classification (see Kristensen, 2003). Their early usage in systematics is probably due to the fact that they can be studied at low magnification, sometimes even without the aid of a microscope. Palpus development is highly variable in the Notodontidae; for nearly 200 years, differences and similarities have been providing notodontid taxonomists with useful characters at the subfamilial, tribal, and generic levels (e.g., Stephens, 1829; Packard 1895; Marumo, 1920; Forbes, 1948; Weller, 1992). As in most other Lepidoptera, three segments are typical for notodontids, a notable exception being some members of the subfamily Notodontinae, which exhibit derived reduction to two (Miller, 1991). An analogous situation occurs within the Zygaenoidea, most of whose taxa exhibit three labial palpus segments while a few possess only two (Epstein, 1996). All Dioptinae exhibit three visible segments, but otherwise the diversity of palpus morphology almost matches that observed across the entire Notodontidae. These structures figure heavily in descriptive taxonomy for the Dioptinae (e.g., Warren, 1897), and played a prominent role in the early generic classifications (Prout, 1918; Hering, 1925). Labial palpus morphology provides an extremely useful source of diagnostic characters for dioptine genera.

After considerable trial and error, labial palpus morphology is described using 11 characters (totaling 38 states). These treat overall length, relative length and shape of each palpus segment, vestiture specializations, and scale color. Erbessa, Phaeochlaena, and some Polypoetes exhibit the most striking palpus configurations (figs. 35; 36A; 70A, B; 89B, E; 90A, D; 92C; 94C, D). Here, the extremely long palpi are folded elbowlike over the front. There is an unusual hinged joint between Lp1 and Lp2, with the palpi extending up to the antennal bases, and often well beyond. In these, a portion of Lp2 is usually denuded of scales on its mesal surface (figs. 36C, D; 71B; 82E; 93A; 94D). Among notodontids, this structural type is unique to the Dioptinae, but according to the phylogenetic results described here, it has apparently evolved at least three times within the subfamily. Two clades in the tribe Dioptini exhibit such palpi—one containing Erbessa and Oricia (fig. 31A, E), and the other including Phaeochlaena, Argentala (fig. 84A, D), Pikroprion (fig. 79A, E), and most Polypoetes. Additionally, elongate elbowed palpi appear as a derived trait within the Josiini; those of Phintia (fig. 328A, D) are as long as the ones found in Dioptini. There is sexual dimorphism in length for elbowed-palpus taxa, with palpi of males noticeably longer. The longest palpi of any dioptine occur in Erbessa leechi (Prout) (fig. 35A, D).

When the labial palpus segments are examined separately, Lp1 shows the fewest shape differences, whereas Lp2 exhibits great variation in length, thickness, and degree of curvature. The third segment is frequently short with an acute apex, but morphological differences among groups are extensive. In some species, Lp3 is extremely short (e.g., Cacolyces plagifera; fig. 135B), while in others, such as Tithraustes (fig. 268A, E) and Isostyla (fig. 276A, D), it is greatly elongate. Nystaleinae typically exhibit bullet-shaped or elongate Lp3 types (Miller, 1991; Weller, 1992).

The organ of vom Rath is a sensory pore found at the terminus of Lp3 (vom Rath, 1887; Scoble, 1992). The pore encloses elongate sensilla, which are sensitive to CO2 levels (Bogner et al., 1986) and various odors (Lee et al., 1985). However, precise answers concerning the organ's biological function have eluded discovery. The organ of vom Rath is a putative autapomorphy for the Lepidoptera (Kristensen, 1984; Kristensen and Skalski, 1999; Kristensen, 2003; Kristensen et al., 2007). In Dioptinae, it is either located apically (e.g., Phanoptis; fig. 64E, G) or on the anterior surface of Lp3 (e.g., Polypoetes nubilosa; fig. 90A). The pore also varies in size and depth; it is shallow and barely visible in Phelina Group species of Dioptis, as well as in D. candelaria (fig. 187G).

A character found in some Dioptinae, and unique to the group as far as I can determine, is the presence of robust spinules located near the labial palpus apex (Character 10). These structures, apparently modified scales, are usually yellowish brown in color, contrasting with the other palpus scales. Presence of palpus spinules in Phaeochlaena, Argentala, Pikroprion, and Polypoetes is one of the synapomorphies uniting these four genera (Clade 6; fig. 7). The spinules occur exclusively on Lp3 in some groups (e.g., Rubribasis Group of Polypoetes; figs. 91D–F), while in others, such as Pikroprion (figs. 79A, 83C–F) and Argentala (fig. 82E, F) they occur distally on Lp2, as well as on Lp3. These structures can be observed with the aid of a dissecting microscope, under the apical scales in pinned specimens, but are most readily seen in material that has been cleared with KOH. The palpus spinules of Argentala subcoerulea are long and thin (figs. 83A, B), whereas those of Polypoetes nubilosa are short and thick (figs. 94E, 94F, 95A). The apex of Lp3 in Erbessa species is thornlike (figs. 35B–E, 36C, 36D), a synapomorphy for that genus. As with most morphological specializations of the Dioptinae, none of these structures have a known function.

Figure 7

Summary cladogram showing relationships among dioptine genera implied from the analysis of 115 exemplar species (figs. 2, 3, 283).

i0003-0090-321-1-1-f007.gif

Scale color on the labial palpus provides characters useful for separating species (Miller, 1989), and has proved useful at higher taxonomic levels as well. In many Dioptinae, Lp1 and the base of Lp2 are yellow. Less commonly these are white. Such differences are utilized extensively for the species descriptions in the present paper. Presence of yellow or white scales is a derived trait, the plesiomorphic condition being completely dark palpi. This character is useful for defining clades above the genus level. Differences in the distribution of light-colored scales on Lp1 and Lp2 can be used to separate closely related species.

Most Josiini do not possess scale tufts on the apex of the labial palpus, but in some genera of the Dioptini tufts are highly developed. The scale tufts of Dioptini do not compare with the spectacular palpal androconia found in herminiine Noctuidae (Smith, 1895; Forbes, 1954), but the structures are similar in that they are associated with males. Within Dioptini, the most elaborate tufts on the labial palpus can be seen in males of the Frigida Group of Euchontha, where the terminus of Lp2 bears a wide, fanlike tuft of elongate scales that obscures Lp1 (Miller, 1989). Interestingly, a single josiine—Getta unicolor (fig. 289A)—exhibits analogous conspicuous tufts on its palpi. This modification is strangely absent in other Getta species.

Members of the suborder Glossata, which includes the vast majority of Lepidoptera (Kristensen, 1984), exhibit the haustellate condition in which the paired galeae of the maxilla form an elongate sucking tube, or proboscis. Structure and function of the proboscis are outlined in Scoble (1992) and Kristensen (2003). Our basic understanding of this remarkable organ was laid down in important earlier papers (Börner, 1939; Eastham and Eassa, 1955), and Krenn (1990) detailed its functional morphology.

Proboscis development varies widely in the Notodontidae. Across subfamilies, it can be long, short, or even absent (Miller, 1991; Weller, 1992). Nearly all Dioptinae possess a long tongue, the sole exception being a species in the rare and obscure genus Xenormicola (pl. 22); the proboscis of X. extensa is short (fig. 232B). In the only other described member of the genus, X. prouti, the tongue is long.

Proboscis coloration, a trait easily observed in pinned specimens, provided useful phylogenetic information. In most dioptine genera, and in the outgroup taxa employed for this study, the proboscis is dark brown to blackish brown. On the other hand, some dioptines exhibit a golden-yellow proboscis (Character 14). Proboscis coloration seems to be consistent within genera, but the derived color, a yellow tongue, is found in groups scattered across the dioptine phylogeny, including Oricia, Scotura, Phanoptis, and Xenomigia. In addition, six species formerly placed in Tithraustes are here referred to the new genus Chrysoglossa, so-called because they possess a yellow proboscis. In many Geometridae, the tongue is bright lemon yellow (personal obs.), thus providing a useful field character for separating day flying members of that family from most Dioptinae.

Study of the lepidopteran proboscis using scanning electron microscopy has revealed a range of fascinating characters, many of which provide useful phylogenetic information (e.g., Kitching, 1987, 1988; Ryabov, 1988; Krenn and Kristensen, 2000). Speidel et al. (1996a) recognized two distinct regions of the proboscis: in the proximal part, chaetiform sensilla are present, whereas the distal part is densely covered with styloconic sensilla. These authors found considerable diversity in proboscis surface structure within the Noctuidae for both regions, especially among species of the subfamily Catocalinae. Speidel et al. (1996a) characterized six surface structure types, and showed that some of these define monophyletic entities within the Noctuidae. Miller (1991) documented the utility of similar characters for the Notodontidae. Dioptinae exhibit Type II surface sculpturing: each ring of the proboscis bears a series of longitudinal ridges, so aligned that they alternate with the ridges of adjacent rings in an interlocking configuration (figs. 91B, 91C, 312B). Type II proboscis sculpturing has been found in only two other notodontid subfamilies—the Nystaleinae and Heterocampinae (Miller, 1991).

In Lepidoptera, the distal portion of the proboscis bears a set of large sensilla styloconica (fig. 312B). Typically, each sensillum is columnar, with five or six lateral flutes and a terminal peg (figs. 92F, 216B, 312C). In a remarkable early paper, Guyénot (1912) discussed these proboscis sensilla in detail. Using 70 species representing a dozen moth and butterfly families, he detailed fascinating structural variation among the groups. It is now clear that fluted proboscis sensilla are found almost universally in the Lepidoptera (e.g., see MacIndoo, 1917, 1929; Börner, 1939; Ikeuchi, 1962; Goldware and Barnes, 1973; Städler et al., 1974; Sellier, 1975; Dey et al., 1999; Hallberg et al., 2003). For the Noctuoidea, they have been documented in the Arctiidae (Altner and Altner, 1986), Notodontidae (Miller, 1991), and Noctuidae (Callahan, 1969; Flower and Helson, 1971; Blaney and Simmonds, 1988).

Proboscis sensilla have been a subject of taxonomic interest because morphological differences reflect phylogenetic history in certain groups (Scoble, 1992). Speidel and Naumann (1995) emphasized the utility of proboscis ultrastructure as a source of characters for phylogenetic classification of the Noctuidae. They further summarized the types of sensilla styloconica found across noctuid subfamilies, and provided scanning electron micrographs of representative taxa (Speidel and Naumann, 1995; Speidel et al., 1996a). Of particular evolutionary interest in the Noctuidae are the remarkable modifications of the sensilla and proboscis tip in fruit-piercing and blood-feeding taxa (Darwin, 1876; Wu and Chou, 1985; Bänziger, 1989; Scoble, 1992; Büttiker et al., 1996; Kitching and Rawlins, 1999; Kristensen, 2003).

The sensilla styloconica of the proboscis show a great deal of morphological variation across clades of the Notodontidae (Miller, 1991). Fluted sensilla are the most widely distributed type, but in tear-drinking species (Bänziger, 1988) belonging to the subfamily Dudusinae, the sensilla are cylindrical and smooth (Miller, 1991). Similar smooth sensilla characterize the nymphalid tribe Argynnini (Guyénot, 1912). For this paper, I performed a brief survey of dioptine proboscis sensilla searching for differences, but all the species examined exhibit the typical fluted type; no variation was found.

Other mouthpart structures show minimal variation in the Dioptinae. Pilifers, brushlike lobes arising laterally from the labrum, occur throughout the Heteroneura (Krenn and Kristensen, 2000). They are thought to function in registering the position of the proboscis during feeding (Kristensen, 2003). These structures are absent in some notodontids with a reduced proboscis (Miller, 1991), but are present in all Dioptinae. The pilifers are especially long and narrow in Oricia and some Scotura species (Character 12; figs. 10E, 31A, 31B, 31D). The maxillary palpi of ditrysian Lepidoptera are usually small (Scoble, 1992). For Dioptinae, I scored relatively subtle differences in size and shape (Character 13).

The configuration of the frontal scales provides important phylogenetic information for the Noctuidae (Fibiger and Lafontaine, 2005). Both Prout (1918) and Hering (1925) noted differences in frontal scaling in their generic diagnoses for the Dioptinae. I expanded their interpretations, using three characters (Characters 15–17) with a total of 10 states to describe this variation. Scale configurations range from the downwardly oriented scales of many Josiini (fig. 312A), also typical of Nystaleinae, to the more horizontal arrangement of Dioptis (fig. 188A). In Euchontha and others (Miller, 1989), the frontal scales form an unusual bowl-like structure. In a great many taxa within the Dioptini, such as members of Polypoetes, Nebulosa, and Phaeochlaena, the scales on the lateral regions of the front point upward, forming two elongate tufts that converge near the antennal bases (figs. 91A, 92D, 160B). Color patterns of the front were not used in this study because, though diagnostic for species, they are too variable to enable characterization of genera. On the other hand, the distribution of yellow scales on the vertex and ventral region of the head (Characters 18, 19) provided useful generic traits.

Eye size is apparently correlated with diurnal versus nocturnal behavior in Lepidoptera (Bourgogne, 1951; Powell, 1973), with smaller eyes being typical of day-flying species. Considerable variation in size can occur within clades, as has been shown for the Arctiidae (Ferguson, 1985) and Palaephatidae (Davis, 1986). Day-flying has evolved by convergence many times in the Noctuidae; concordant reduction of the eye has been noted in subclades of the Catocalinae (Speidel and Naumann, 1995), Plusiinae (Kitching, 1987) and Heliothinae (Hardwick, 1970; Matthews, 1987, 1991). Eye size shows considerable variation across subfamilies of the Notodontidae (Miller, 1991; Weller, 1992).

Although various eye-size indices have been developed for Lepidoptera (Powell, 1973; Ferguson, 1985; Davis, 1998b; Kristensen, 2003), I employed a single character with three simple states (Character 20), based on relative width of the postgena, to describe this feature. Variation in eye size within the Dioptinae has been noted in previous works on the group (Prout, 1918; Miller, 1989, 1996). In dioptines where the eye is small, a scaleless, densely spiculate band completely surrounds it (fig. 160A). Based on outgroup comparison, the plesiomorphic state for Dioptinae is large eyes, but reduction has apparently occurred numerous times within the group. The smallest eyes (State 2) are found in Dolophrosyne (fig. 221A–D) and Scoturopsis (fig. 227A, B), as well as certain species of Nebulosa (fig. 159E), Dioptis (187B, E), and Scea. Altogether, these taxa are widely scattered across the dioptine cladogram (fig. 7), suggesting multiple origin of small eyes. Eyes of moderate size (State 1) are observed in numerous groups. Interestingly, certain genera, such as Polypoetes, exhibit variation in eye size, ranging from small eyes in the Rubribasis Group (figs. 89A, C) to large bulging eyes in the Haruspex and Etearchus groups (figs. 89B, 89D, 90A–F). Even closely related species can sometimes vary, as is exemplified by the different eye sizes of Polypoetes approximans and P. subcandidata.

One feature of eye morphology, so-called “hairy eyes”, has been utilized almost throughout the history of noctuoid systematics. For example, present of hairy eyes has been used to define the controversial group Pantheinae (Forbes, 1954; see also Fibiger and Lafontaine, 2005; Mitchell et al., 2005). In Dioptinae, many genera exhibit short microsetae (Character 21), sparsely interspersed among the eye facets (figs. 92E, 188B). This character was difficult to score because the setae are often difficult to see with a dissecting microscope. They are fairly prominent in species belonging to the Rubribasis Group of Polypoetes. Interfacetal setae occur widely across the Dioptini, but appear to be absent in Josiini.

The presence of paired ocelli in adults, located behind the antennae, is apparently part of the lepidopteran groundplan, but they have been lost numerous times within the order (Kristensen, 2003). Presence or absence has been used widely in reference to higher-level relationships among Lepidoptera. For example, it is used to separate subfamilies in the Drepanoidea and Geometroidea (Minet and Scoble, 1999), and figures in the classification of the Zygaenidae (Yen et al., 2005a). Within Noctuoidea, absence of ocelli has been used to define the subfamily Lithosiinae (Arctiidae). However, careful examination shows that they can be present, but extremely small within this group (Kitching and Rawlins, 1999). Ocelli are relatively uncommon in adult Notodontidae, and are absent in all Dioptinae (Miller, 1991).

For nomenclature describing sclerites of the head, I follow Matsuda (1965) and Oseto and Helms (1976). The latter, which provides a detailed morphological analysis for adults of Loxagrotis albicosta (Smith) (Noctuidae), is an extremely useful general reference. Two regions of the head show clear-cut intergeneric differences in the Dioptinae. The gena, a sclerite below the eye, can have a smooth ventral margin or it can be flanged, as in Erbessa and others (Character 22; figs. 35A, 36B). In some genera there is an anterior notch in the gena (Character 23). The submentum in Lepidoptera is the ventral plate of the head to which the labial palpi attach (Snodgrass, 1935). Along its posterior margin, the submentum curves upward to form a secondary sclerite, called the hypostomal bridge (Oseto and Helms, 1976) or gula (Bourgogne, 1951; Matsuda, 1965). The hypostomal bridge, best seen in posterior view, thus forms a sclerotized band along the ventral margin of the occipital foramen. Dioptinae show considerable variation in the size and width of the hypostomal bridge (Character 23). For example, in Xenomigia (fig. 235D) and Brachyglene (143F) it forms a narrow band, while in Erbessa (fig. 35G) and Polypoetes (fig. 90C, 90F) it is wide and robust. Width of the hypostomal bridge may be correlated with labial palpus length; the species with a robust sclerite are roughly the same ones exhibiting long, elbowed palpi (Characters 4 and 5).

Antennae are the primary sensory structures of Lepidoptera (Schneider, 1984), and accordingly they are covered with numerous types of sensilla along their ventral surface. Three morphological regions of the antenna are commonly recognized—the scape, the pedicel, and the flagellum—the latter composed of numerous annulations or flagellomeres (Bourgogne, 1951; Scoble, 1992). Jordan (1898) detailed the comparative antennal morphology of Lepidoptera in a remarkable early paper, and their structure has played a pivotal role in the group's systematics since that time (e.g., Hampson, 1898). Considering that antennal function must be universal, the amount of structural variation observable within certain clades is remarkable.

Scanning electron micrographs of dioptine antennae (Miller, 1987a, 1989, 1996) reveal not only a complexity of sensillum types and distribution, but also vast differences in overall shape. Bipectinate antennae are the most common type (e.g., figs. 82C, 82D, 144A, 144B), but the antennae of Dioptis (fig. 188C–F), Euchontha, and Xenomigia are quadripectinate. The ventral surface of each ramus bears two types of sensilla (fig. 151B)—flattened sensilla auricillica (fig. 151C) and basketlike sensilla coeloconica (fig. 151D). These structures, found throughout the Lepidoptera (Hallberg et al., 2003), were not used as characters in these analyses. In Scotura, Erbessa, and Pseudoricia the antennae are ciliate (figs. 11B, 11C, 36E, 36F, 37B, 37C, 256A), with no rami. Certain clades, such as Argentala (fig. 82A, B), Monocreaga (fig. 216C, D), and the Rubribasis Group of Polypoetes (fig. 92A), are characterized by antennae showing short, transverse flanges where the rami would typically occur. Such antennae are termed subserrate.

Characterizing dioptine genera on the basis of antennal morphology is often problematic; in certain cases, intrageneric differences are remarkable. For example, within the Truncata Group of Oricia, both ciliate and pectinate male antennae occur. The diversity of antennal structure found among Dioptinae easily matches that observed across the entire remainder of the Notodontidae, comprising approximately 2500 species (Gaede, 1934). The five character states used here to describe antennal pectination types (Character 28) are meant to reflect structural similarity above the generic level; they obscure a great deal of variation within genera.

At least among moths, female antennae exhibit less morphological diversity than those of males. The usual explanation for this is that males require more elaborate antennal sensilla with increased surface area so they can actively follow a pheromone trail to the stationary female. In butterflies both sexes are highly mobile. Typically, males actively search for females (e.g., see Silberglied, 1984), and females can travel large distances to find appropriate host plants for oviposition (Chew and Robbins, 1984). Antennae are important in both activities, and butterflies thus show less sexual dimorphism in antennal structure (Jordan, 1898; Chapman, 1899). There has been no research on mating systems in Dioptinae, but one might predict contrasting sensory needs in diurnal and nocturnal species. Interestingly, for most dioptine species in which the males possess pectinate antennae, those of females are pectinate as well (Characters 35, 37). Invariably, the rami are shorter in females (compare figs. 93C, D and 93E), but they are nonetheless present; in some Dioptis species (figs. 188E, F) and in Chrysoglossa phaethon, the female rami are nearly as long as those of males. It will be interesting to explore whether presence of pectinate female antennae is correlated with behavioral specializations.

Numerous, single-species scanning electron microscope studies in Lepidoptera have documented the remarkable diversity of antennal sensillum types (e.g., Faucheux, 1989, 1990, 1997). Particular attention has been paid to crop pests (e.g., Lin and Chow, 1972; Cornford et al., 1973; Cook et al., 1980; Lavoie-Dornik and McNeil, 1987). Flower and Helson (1974) were among the first to develop a system of sensillum nomenclature for the Lepidoptera. Comparative SEM studies among closely related species (e.g., Jefferson et al., 1970; Cuperus et al., 1983; Cuperus, 1985; Faucheux, 1993) reveal a rich source of character information. Such data can also provide important phylogenetic information at higher taxonomic levels, as has recently been shown for the Neopseustidae (Faucheux et al., 2006). As another example, the remarkable ascoid sensilla of Opostegidae and Nepticulidae—primitive members of the clade Heteroneura (Kristensen et al., 2007)—are an important synapomorphy uniting those families (Davis, 1989; Davis, 1998b; Davis and Stonis, 2007).

At least six different sensillum types are found ubiquitously in adult Lepidoptera (Hallberg et al., 2003). Perhaps the most conspicuous of these is the single, large sensillum styloconicum, typically located at the apex of each flagellomere (Fauchaux, 1990). This sensillum has been shown to respond to temperature and humidity (Hallberg et al., 2003). Cursory SEM study of antennae in the Dioptinae reveals interspecific differences in the size, shape and precise location of the sensillum styloconicum (see figs. 11D, 36E, 36F, 37A–D, 82D, 92A, 92B, 189A, 216E, 256B, 313A), variation that could potentially offer fascinating phylogenetic information for the group. However, while a comprehensive study of antennal sensilla in Dioptinae might yield a wealth of characters, such research for a species sample of the size employed here would be a huge undertaking—a study unto itself.

Other than pectination arrangements, I employed relatively few characters to describe differences in antennal structure. These involve traits such as bristle configuration (Characters 29, 38), and the presence of ventral ridges on the flagellomeres (Character 30). All can be observed with the aid of a dissecting microscope. A synapomorphy for the Josiini is presence of an unusual, hingelike junction occurring at the point where each ramus joins the antennal flagellomere (Character 33; fig. 312E, F). In many notodontid subfamilies, the pectinations are abruptly shortened before the antennal apex, with the terminal flagellomeres either simple or with short pectinations (Miller, 1991). This also occurs in several clades within the Josiini (Character 32; fig. 312D). The newly described genus Nebulosa is characterized by bipectinate antennae with long flagellomeres (Character 34), a condition that produces widely spaced pectinations (fig. 160C–E).

Three characters of the occipital region provide character information. One of these, presence of a narrow postocciput (Character 39), occurs in Tithraustes only (fig. 268A–C). Second, in all species examined the occipital condyles meet at the back of the head to form a small notch. The shape of this notch varies among genera (Character 40). For example, it is particularly deep in Chrysoglossa maxima (fig. 150C). Third, some Josiini, such as Ephialtias (fig. 311A, B) and Notascea (fig. 331A–C), possess tiny cuticular projections on the occiput, behind the antennal bases (Characters 41, 42).

The Lepidoptera tentorium, an internal supporting structure of the head joining the anterior and posterior tentorial pits (Snodgrass, 1935), serves as an attachment site for the cibarial and antennal muscles (Oseto and Helms, 1976). Ehrlich (1958a, 1958b), in his pioneering morphological works, showed the utility of tentorium morphology in butterfly phylogeny, and the character has subsequently proved useful in other Lepidoptera groups (e.g., Miller, 1987b, 1991, 1996). Tentorium shape varies in Dioptinae, with some species showing a marked swelling near the midpoint (e.g., Erbessa lindigii; fig. 35E), and others having a narrow, parallel-sided configuration (e.g., Momonipta onorei; fig. 211A). In addition, carinae can occur (e.g., Xenorma cytheris; fig. 53A), sometimes more than one for a given taxon. I used three characters of the tentorium (Characters 43–45) in an attempt to isolate homologous differences. The various carinae, identified based on their location, are often extremely thin, and in small taxa, are difficult to see. Although their utility is not practical from a taxonomic standpoint, for certain genera the tentorium provides excellent diagnostic traits.

Thorax

Considering their complexity and number, the thoracic sclerites of Lepidoptera seem to provide relatively few useful characters. This holds true for the Dioptinae. It might be judged that these structures are conservative from an evolutionary standpoint (Brock, 1971; Kristensen, 1984). General treatments of thoracic morphology include Weber (1924), a beautifully illustrated work, as well as Snodgrass (1935), Matsuda (1970), and Scoble (1992). My analyses show that the thoracic appendages (tegulae, legs, and wings) provide more character information for Dioptinae than the sclerites themselves. Internal structures, such as the furca and discrimen, are particularly complex (Scoble, 1992). Numerous authors have examined these hoping to find information for solving difficult phylogenetic questions in the Lepidoptera. The metafurca, in particular, has been heavily employed in higher-level studies (Ehrlich, 1958b; Brock, 1971; Kristensen, 1984; Davis, 1989). For the Dioptinae, characters of the internal skeleton can be found on all three thoracic segments (Characters 48, 49, 54, 64–66). These differences, almost all involving shape, are difficult to categorize into discrete character states. It is equally difficult to determine state assignments for certain taxa. Nevertheless, I employed these traits as best I could.

Lepidoptera hearing organs were apparently first discovered in the Uraniidae in 1889 (Eltringham, 1923). They show remarkable structural diversity in Lepidoptera, having evolved at least eight times within the order (Grimaldi and Engel, 2005). Presence of a metathoracic hearing organ in Noctuoidea, the largest and most complex superfamily in the order (Wagner, 2001; Mitchell et al., 2005), is often regarded as providing unequivocal evidence for the group's monophyly (Kitching and Rawlins, 1999; Fibiger and Lafontaine, 2005). Over the years, an army of entomologists has studied the morphology, physiology, and taxonomic significance of this structure. Among the earliest papers are those of Forbes (1916) and Eggers (1919). The relatively simple tympanum of Notodontidae, once viewed as a primitive precursor to the more complex organ found in other Noctuoidea (Richards, 1932), is now regarded as a derived specialization (Miller, 1991; Speidel and Naumann, 1995; Speidel et al., 1996b; Minet and Surlykke, 2003). Even in morphologically complex examples, the noctuoid tympanum can be viewed simply as a depression near the dorsal margin of the metepimeron. An auditory cell, or scoloparium, is attached to the surface of the tympanal membrane (Minet and Surlykke, 2003), which spans the upper margin of this depression. Additional structures, such as sound-reflecting cavities on A1 (the “counter-tympanal hood”) are associated with the hearing organ, and these are elaborated to varying degrees across the superfamily (Kitching and Rawlins, 1999).

The metathoracic tympanum has played an illustrious role in the history of dioptine systematics. In one of the first attempts to summarize the phylogeny of the Noctuoidea, absence of a tympanum in Dioptis led Forbes (1916, 1923) to regard the “Dioptidae” as the most primitive noctuoid group (see Character Evolution, under Discussion). Richards (1932) undertook a complex analysis of tympanal morphology to elucidate evolutionary relationships within the Noctuidae. He also looked at the tympana of Erbessa, Josia, and Cyanotricha ( =  Scea), as he assessed structure across additional noctuoid groups. It was he who first noted the unique tympanum in Josiini. Interestingly, Richards followed Forbes' early assessment that the “Dioptidae” were the stem group of the entire Noctuoidea.

Sick (1935) was a proponent of using tympanal morphology in Lepidoptera systematics. Later, it was he who, in a monumental study, first documented extensive variation in tympanum morphology across the Dioptinae (Sick, 1940). He examined the metathorax of 255 dioptine species, dividing these taxa into five groups based on differences in tympanal structure. However, Sick did not formalize his ideas in a revised classification. Using the five groups as terminal taxa, he did however produce a cladogram outlining his hypothesis of tympanum evolution. These theories were later modified by Kiriakoff, who considered the tympanum the most important character, not only for dioptine classification (Kiriakoff, 1950), but for understanding the phylogeny of the entire Noctuoidea (Kiriakoff, 1963). In retrospect, the concepts of Sick (1940) make considerable sense in terms of a modern dioptine classification, whereas Kiriakoff's theories can be largely ignored.

Here, five characters of the metathoracic tympanum are employed (Characters 56–60). Not only does size of the tympanal cavity vary widely, but there are also differences in size and orientation of the membrane itself. The remarkable kettledrum tympanum in Josiini has been the subject of considerable discussion (Richards, 1932; Sick, 1940; Miller and Otero, 1994; Miller, 1996), and needs little further elaboration. On the other hand, the research described here provides novel information regarding tympanum evolution in the Dioptini. For example, my cladistic results (fig. 3) support a broader concept of Dioptis than that of previous authors. According to this new information, the tympanum among Dioptis species shows a complete transformation series, ranging from presence of a well-developed tympanum in Dioptis longipennis to various stages of reduction, with complete loss restricted to one subclade within the genus (Dioptis trailii and relatives).

In other Notodontidae, all of which are nocturnal, the tympanum is thought to function as a system for detecting the echolocation signals of predatory bats (Fenton and Fullard, 1981; Fullard, 1984). Two papers have examined its function in Dioptinae (Fullard et al., 1997; Fullard et al., 2000), which theoretically would not be exposed to bats. The resulting picture is complex. These authors discovered that, while some dioptines possess auditory thresholds typical of Notodontidae, others show reduced hearing at bat-specific frequencies, and still others are completely bat-deaf (Fullard et al., 1997). This range in auditory response occurs in conjunction with a spectrum of flight-activity patterns (Fullard et al., 2000). Rather than being strictly “diurnal”, as they are often characterized, some dioptine taxa fly with considerable frequency at night as well as during the day. Others are indeed restricted to a day-flying habit, where the ears more likely function in intraspecific communication. In many tympanate moth groups where sound receptors originally served to detect bats, such as the Arctiidae, the hearing organs now also function in courtship (Krasnoff and Roelofs, 1990; Conner, 1999; Sanderford, 2009). A fascinating story, involving behavioral evolution in the Dioptinae and possible co-opting of the metathoracic tympanum for novel functions, remains to be told.

The metascutal bulla, a swelling located above the tympanum (figs. 12G, 326B), is found in almost all Notodontidae (Holloway, 1983; Common, 1990; Nielsen and Common, 1991). Brock (1971) considered it to be a diagnostic feature for the family. Miller (1991) highlighted variation in size and development of the metascutal bulla within Dioptinae, following Sick (1940) and Kiriakoff (1950). Four character states (Character 55) are used here to define these differences.

Three additional characters of the metathoracic sclerites were employed: The first (Character 61), probably unique to Notodontidae, is the presence of a sclerotized flange on the ventral portion of the metepisternum (Miller, 1991). This flange is poorly developed in most notodontid species, but can usually be seen upon careful inspection. In Dioptinae, the flange is absent in a few genera (e.g., Phanoptis), but is present in most. Its highest degree of development occurs in the Josiini (Miller, 1991; see fig. 326B). This structure has the general appearance of a sound-producing organ, a phenomenon that has not yet been reported in Josiini. Other Dioptinae are known to make sounds using specialized organs on the forewing (discussed below), but such behavior is probably not related to the metathoracic flange. The second trait (Character 62) occurs only in Josiini. Here, there is a broad, scaleless region immediately behind the tympanal opening (fig. 313B, C). The third character involves the shape of the metameron. This sclerite, usually a broad triangle, is dorsoventrally elongate in Dioptis, as well as in Tithraustes and some species of the closely related genera Isostyla and Stenoplastis (Character 63; fig. 187I).

The remaining thoracic characters I studied involve the various appendages. At the base of each forewing in Lepidoptera there is a moveable sclerite called the tegula. Among other functions, it may assist in wing coupling (Hering, 1958; Scoble, 1992) or to reinforce wing articulation (Matsuda, 1970). There has been historical confusion regarding the name of this structure. Some early lepidopterists called it the patagium (e.g., Schaus, 1894; Hampson 1898), but true patagia are membranous outgrowths of the prothorax (Ehrlich, 1958a; Kristensen, 1984). The tegula is usually large and is almost always covered with long scales, making it highly conspicuous in pinned specimens. A transverse sulcus divides the tegula into two parts, which I term the dorsal arm and the ventral angle. I characterized structural variation of the tegula using three discrete characters (Characters 50–52). Dioptinae exhibit a wide range of tegula size, from large, as occurs in Erbessa (fig. 38C, D, H) and Josiini (fig. 326B), to highly reduced, as in Dioptis trailii (fig. 187I). Intermediate sizes are found in less derived Dioptis species and in Monocreaga (fig. 215E). The tegula is universally large in Nystaleinae. A feature found in many Dioptinae (Character 53) is the presence of contrasting, orange-yellow scales at the tegula base (e.g., Momonipta onorei; pl. 21). This trait is often useful for field recognition, and was noted by many early authors in their species descriptions (e.g., Dognin, 1902; Druce, 1899, 1900; Schaus, 1912, 1913).

The epiphysis on the foreleg tibia, thought to be serially homologous with tibial spurs on the meso- and metathoracic legs (Michener, 1952; Kuznetsov, 1967), is a synapomorphy for the Lepidoptera (Kristensen, 1984; Kristensen and Skalski, 1999). Experiments and field observations confirm that the epiphysis functions as an antennal-cleaning device (Callahan and Carlysle, 1971; ODell et al., 1982; Robbins, 1989). Its surface is covered with spatulate processes (fig. 313D, E). The epiphysis is often smaller in females than in males, concordant with shorter pectinations in female antennae. The structure varies in shape and size throughout the Notodontidae, and provides a valuable taxonomic character for generic diagnoses (Marumo, 1920). It is absent in females of some notodontid genera (Miller, 1991). There is important variation within the Dioptinae (Characters 67, 68). For example, in Erbessa and Oricia the epiphysis is short and teardrop shaped (figs. 37F, 38G), much shorter than the foretibia, while in other taxa it is longer and lanceolate (e.g., figs. 189D, 189E), sometimes extending beyond the tibial apex. This difference might be correlated with antennal development; Erbessa and Oricia have ciliate antennae, and the smaller epiphysis may clean this type more effectively.

The meso- and metathoracic tibial spurs of all Dioptinae occur in the 2–4 configuration typical of Nystaleinae and most other Notodontidae (Miller, 1991), so spur number is not taxonomically informative. However, dioptines do show considerable variation in spur length (Character 69). Tibial spur length was stressed as an important character in understanding phylogeny of the Noctuidae (Speidel et al., 1996b). The sclerotized apex of each tibial spur is serrate in most Notodontidae (Janse, 1920; Jordan, 1923b; Miller, 1991; Weller, 1992), and all Dioptinae (figs. 189F, 301F, 313F).

Wings

Wing venation has been one of the most important character systems in the history of Lepidoptera classification. A possible explanation for this emphasis is that wing veins show a tremendous amount of easily accessible variation, requiring little or no dissection and preparation for study. Herrich-Schäffer (1843–1856) first stressed the utility of wing venation (Scoble, 1992), and devised a standardized system of numbers for each vein. His scheme was adopted by most early taxonomists (e.g., Hampson, 1898). Herrich-Schäffer's pioneering work greatly influenced the use of wing veins as characters, and has been incorporated into modern theories of Lepidoptera classification at the superfamily and family levels. Comstock's (1918) remarkably insightful analysis of insect wing veins has been more influential than any other work on the subject. The sytem developed by Comstock and Needham (in Comstock, 1918) was modified slightly by Kristensen (2003) in the Handbüch der Zoology, the most significant change involving the terms applied to the FW radial sector. The nomenclature of Kristensen (2003) is employed here.

Wing venation has been by far the most heavily utilized character system in development of the dioptine generic classification. Prout (1918) provided characterizations of all genera using wing vein traits, and based his generic key on them. Subsequent additions and changes to the dioptine classification (Hering, 1925; Bryk, 1930) relied on wing veins as well. Unfortunately, these specialists employed different wing-vein terminology. Hering (1925) largely followed Comstock and Needham, but Prout adopted a system of nomenclature different from the others in common usage at that time. Because of the historical complexity of wing-vein nomenclature and the usage of different systems by various authors, the study of dioptine taxonomy, especially interpretation of the early literature, requires an ability to convert from one system to another. Köhler (1930) provided the first illustrations of dioptine wings, showing wing venation for species in three genera. Lima (1950) later figured the wing venation of Erbessa pyraloides in his treatment of the Brazilian fauna.

Many of the wing-vein differences in Dioptinae involve the forewing radial system. As in other Lepidoptera, dioptines exhibit five FW radials, comprising R1 and four branches of the radial sector: Rs1–Rs4 (e.g., fig. 8). Throughout the subfamily, vein R1 invariably arises from a point well out on the discal cell. The veins of the radial sector, on the other hand, vary widely in their branching patterns. Vein Rs1 is typically conjoined with Rs2–Rs4 (Character 70). In Erbessa (fig. 38A, B, E, F) and Phaeochlaena (fig. 70F), on the other hand, Rs1 arises from the DC, the placement found throughout the outgroup. Overall, the most common radial vein arrangement in the Dioptinae is exemplified by the forewings of Xenorma (fig. 53F), Phryganidia (fig. 60C), and most Josia (fig. 336F, H). Here, Rs1 is stalked with Rs2–Rs4, and the latter are in the pattern [2+3]+4 (Character 72, State 1). This configuration is not found elsewhere in the Notodontidae (Miller, 1991), but occurs in roughly 70% of dioptine species (Miller, 1987a). Other branching patterns (Character 72, States 2 and 3) are less common, but can provide important diagnostic features for particular dioptine genera, or for subclades within genera. In members of two closely related genera—Dolophrosyne (fig. 221F) and Xenormicola (fig. 232C)—the radial sector is comprised of only three veins (Character 71).

The discocellular veins close the distal margin of the DC. Within Dioptis there is considerable variation in the length of the UDC and MDC relative the length of the LDC (Characters 73, 74; fig. 190D–G). These differences do not occur elsewhere in the Dioptinae. Another apomorphic feature of the FW venation restricted to Dioptis is the presence of a strongly curved radial sector (Character 76).

The FW medial system shows less variation than the radials, but nevertheless offers several important characters. Vein M1 can arise from near the anterolateral angle of the discal cell (e.g., Nebulosa; fig. 158A, 158C–F), separate from the radials, or it can be stalked with the radials (Character 75), arising well out from the DC (e.g., Proutiella; fig. 284C). This character state is found in many Josiini and provides a useful key character for identifying genera. A unique, and easily recognizable, diagnostic feature for a great many species of Dioptinae is fusion of FW veins M3 with CuA1 (Character 85; e.g., figs. 12A–D, 84F, 255F, 306B). This, one of the most useful field traits for distinguishing dioptines from other moths of similar habitus, occurs in 30 genera comprising roughly 75% of the species. Based on outgroup comparison, the plesiomorphic state is where M3 is approximate to, but not fused with, CuA1 (e.g., Cleptophasia; fig. 8F). Dioptines in which M3 is separate from CuA1 have often been accorded generic status by previous authors on that basis alone. For example, Prout (1918) erected both Xenorma (fig. 53F) and Phanoptis (fig. 64K) for having M3 and CuA1 “widely separate” in the FW. Other FW veins are of limited value; the position of FW vein M2 does not vary, nor does the configuration of the cubital or anal veins.

Nijhout and his colleagues (e.g., Nijhout, 1991, 2003; Nijhout and Wray, 1986, 1988) are largely responsible for spearheading what can only be termed a renaissance in the use of lepidopteran wing patterns for systematic studies. In a recent example, Willmott's (2003) phylogenetic analysis of species in the nymphalid butterfly genus Adelpha employed 114 morphological characters, of which 83 were derived from detailed study of wing pattern. The incredible variety of wing patterns among Dioptinae elicited amazement from early authors (e.g., Köhler, 1930), and the more I learn about the group the more amazed I become. Dramatically different patterns and colors can occur in closely related species, an example being the genus Erbessa, where skeletal morphology is remarkably uniform but wing patterns vary tremendously. As in other diurnal Lepidoptera, the evolution of mimetic resemblance seems to be the driving force behind this phenomenon (Seitz, 1925). One of the examples Bates (1862) used in formulating his theory of mimicry was the near perfect resemblance of some Dioptis species to ithomiine butterflies.

Both day-flying and nocturnal habits occur in the Dioptinae (Fullard et al., 2000), and although experimental work remains to be done, my own observations suggest that wing coloration tracks this trend to some extent. Bold patterns and bright colors tend to occur in the wings of diurnally active species, examples being the yellow transverse bands of Phaeochlaena costaricensis (pl. 9), or the striking orange stripes of some Josiini (e.g., pl. 32), moths collected frequently in the day but almost never at lights. On the other hand, the subdued, intricate patterns of Chrysoglossa (pl. 15) and Xenomigia (pl. 23) seem to indicate nocturnal habits; these taxa are commonly attracted to lights.

In this paper, my goal was to search for generality in wing-pattern characters, rather than focus on the numerous differences. I looked for homologous pattern elements (sensu Nijhout, 1991) using position relative to particular wing veins as a guide. Previous research had shown this to be a successful methodology. For example, superficially identical longitudinal forewing stripes have evolved at least twice by convergence in the Josiini (Miller, 1996). Upon careful inspection, the two pattern types can be distinguished by their position relative to the radial and cubital veins (see Character 82). A similar approach was applied throughout. At first glance, forewing spots seem to occur in an almost limitless number of ways. However, in searching for generalizations, I identified three types of subapical spots on the forewing (Characters 83, 84), using position relative to the radial and M1 veins in assigning character states. My analysis of dioptine pattern characters is rudimentary. A more fine-tuned study using species-level phylogenies to elucidate transformation hypotheses would be a fascinating endeavor. In my opinion, the Dioptinae provide one of the most intriguing cases of pattern evolution to be found in the Lepidoptera.

An important wing-pattern trait, unique to Dioptinae among notodontids, characterizes a great many species in several genera. Here, the scales along the forewing veins are more lightly colored than the wing ground color (Character 87). Often, as in Brachyglene (pls. 14, 15), Nebulosa (pls. 16, 17), and Xenomigia (pl. 23), the scales along the veins are light brown whereas the ground color is a darker brown. In a large number of Polypoetes species (pls. 10–14), this trend produces striking patterns, where the forewing veins are outlined in orange or yellow scales, while the remaining ground color is blackish brown or black.

The fine structure and taxonomic value of Lepidoptera wing scales have been well documented over the years (e.g., Kellogg, 1894; Mayer, 1896; Kristensen, 1970; Ghiradella, 1984; Scoble, 1992; Simonsen, 2001). A typical wing scale is broad and flat (fig. 290E), with a narrow pedicel at its base that fits into a socket in the wing (fig. 290F). The scale's distal margin is often broadly dentate. Downey and Allyn (1975) devised categories of scale shape, and developed a comprehensive nomenclature to describe scale morphology. Most importantly, they documented the vast array of wing-scale types that occur in the Lepidoptera. These types can provide important phylogenetic information when surveyed across a group. Yen et al. (2005a) provided a particularly elegant use of wing-scale morphology to aid in understanding phylogenetic relationships within the Chalcosiinae (Zygaenidae). In the current study, I limited my focus to wing scales occurring in specialized regions of the wing. For example, some Josiini, such as Polyptychia, possess complex alar androconial systems (figs. 299–301), with associated specializations in wing venation (fig. 298E).

Wing transparency has evolved multiple times in the Lepidoptera (Punnet, 1915; Kristensen and Simonsen, 2003), often by more than one means within any given monophyletic group. Kristensen (1974) documented such an example in the Sesiidae. Within that family the clear-winged trait has evolved via two pathways: In some species, the pharate adult emerges with a full complement of pigmented scales that fall off during the first wing movements. In other sesiids, the wings are covered with scales that are themselves transparent, giving a clear appearance. Similarly, wing transparency in Sphingidae is obtained by two means (Kitching, 2003): Hemaris and Cephonodes exhibit the scale-shedding mechanism, whereas in the Cocytius Group, hind-wing transparency is achieved through narrow, depigmented scales that expose the wing membrane.

The Dioptinae showcase a third means for producing hyaline wings, exemplified by Phanoptis (fig. 65), Dioptis (fig. 191), and Monocreaga (fig. 217). Here, the wings are covered with extremely thin, gently curved scales (figs. 65A, 65B, 191B, 217B, 217C). Furthermore, these are reduced in number and are spaced widely apart. In contrast, the wing veins themselves are lined with broad scales (figs. 65A, 191A, 217A, 217B). This means of achieving hyaline wings occurs throughout the Dioptinae, but appears to have evolved a number of times within the subfamily (see Discussion: Wing Pattern). An intermediate arrangement can also be found whereby the wing surface is covered by long, thin scales intermixed with more typical flat scales, thus producing semitransparent or translucent wings. In all dioptine genera in which transparent wings occur, there are no discernable morphological differences in the specialized scales.

Within the Dioptinae, hyaline wings are found universally in Dioptis (pls. 17–21) and Monocreaga (pl. 21), whereas translucent wings occur in some species belonging to Dolophrosyne and Xenomigia (pls. 21–23). Phanoptis (pls. 8, 9) and Hadesina (pl. 14) are unusual in containing species with clear wings, as well as ones where the wings are fully scaled. In Tithraustes and Isostyla (pls. 24, 25), the wings can be either hyaline or translucent. I employed two derived character states to describe these features in the Dioptinae (Character 94). In one, the covering includes both thin and broad scales, resulting in translucent wings. The second state, which gives rise to hyaline wings, is characterized by the presence of long, thin scales only. The hind wings were used to score this character since, as in Sesiidae (Kristensen, 1974; Edwards et al., 1999), transparency is more pronounced there.

The number of bristles in the female frenulum, part of the wing-coupling mechanism, varies in Lepidoptera (Marshall, 1922; Braun, 1924). These differences hold phylogenetic information for Notodontidae, useful at the subfamily level (Miller, 1991). The basic dichotomy in Dioptinae is presence of two frenular bristles, the plesiomorphic condition, or more than two (Character 100). Only two bristles occur in Nystaleinae, Josiini, and Scotura. Species with the multiple condition, which includes the vast majority of Dioptinae, usually have approximately 10 bristles in the female frenulum. Three unrelated taxa—Euchontha, Scotura transversa, and Phavaraea dilatata—are unusual in possessing three bristles.

Among Notodontidae, the presence of a stridulatory organ in the male forewing (Characters 77–79) is unique to the Dioptinae. In taxa where this structure occurs, veins M1 and M2 are swollen in the region immediately beyond the discal cell (e.g., figs. 145F, 162A, 162C–F, 255F), protruding from the wing's ventral surface (figs. 144C, 161C, 256E). The structure was noted by early dioptine taxonomists, and was first discussed in detail by Forbes (1922, 1931, 1939a). Later, Miller (1989) described it using SEM. At that time I suggested two possible functions for this organ—one being that it is androconial in nature since it is found only in males and the associated wing scales are unusual in shape, and the second being that it is used to produce sounds. Careful subsequent reading of Forbes' writings revealed that, during an expedition to Peru, he had witnessed stridulation in the dioptine Euchontha frigida (Forbes, 1922: 72). More recent field observations for Euchontha in Ecuador (J.S. Miller and E. Tapia, personal obs.; F. Sperling, personal commun.) confirm that these moths are capable of producing clicking sounds, undoubtedly using the forewing organ. The clicking sounds in Arctiidae, generated by a metathoracic tymbal organ (Forbes and Franclemont, 1957; Conner, 1999; Kitching and Rawlins, 1999), are a form of auditory aposematism (Conner et al., 2009). Arctiid clicks advertise toxicity, and thus confer protection from nocturnal bat predators (Watson, 1975; Fenton and Fullard, 1981; Dunning and Krüger, 1995, 1996). Sounds in Dioptinae, on the other hand, are most likely used for intraspecific communication, since in all observed cases they are produced during diurnal flight.

Altogether, nearly 180 dioptine species in 22 genera posses a FW stridulatory organ (see Discussion: Character Evolution). This organ thus represents a case analogous to the male forewing organ found in two separate subfamilies of the Noctuidae—the Heliothinae (Matthews, 1987, 1991; Mitter et al., 1993) and Agaristinae (Bailey, 1978; Common, 1990; Rawlins, 1992; Talianchich et al., 2003). In both groups, males stridulate during diurnal, premating, and territorial behaviors.

The dioptine forewing organ varies in its level of morphological complexity. In its simplest form (e.g., Cleptophasia scissa and Xenomigia), the discal cell is not short, but veins M1 and M2 are slightly swollen (figs. 8F, 235G, H). In taxa such as Pseudoricia (255F), Euchontha (fig. 249C), and Hadesina (fig. 137F), the stridulatory organ is highly complex, involving several distinctive structural modifications. Here, the forewing discal cell is extremely short—less than one-fourth the FW length; veins M1 and M2 protrude markedly from the wing ventral surface; there is a well-developed secondary fold between M1 and M2 (fig. 256E, 257C); and the area beyond the discal cell is semitransparent, forming a fascia. In addition, the wing surface of this region is distinctly corrugated (fig. 257C, D). Derived members of Dioptis are unusual in that veins M1 and M2 are not swollen, the wing surface shows no signs of corrugation, a fascia is not present beyond the discal cell, but the discal cell is short (fig. 190E, F); more basal members of the genus, such as D. subalbata (fig. 190D), show a typical stridulatory organ. My phylogenetic analyses suggest that this is a case of derived loss of the stridulatory organ. It is interesting that there are Dioptis species in which the membrane of the metathoracic tympanum is completely absent (fig. 189B, C), a situation rare in the Noctuoidea and unique to Dioptis among Dioptinae. Loss of the tympanal hearing organ and the forewing sound-producing structure in the same genus may reflect correlated function. Whether these moths can make sounds is unknown.

Most species of Polypoetes possess a small forewing fascia beyond the discal cell (Character 80). The fascia is covered with thin scales, making it translucent, or, as in P. forficata and relatives, almost clear (pl. 12). My cladistic results suggest that the fascia in Polypoetes is not homologous with the one occurring in species possessing a stridulatory organ. There are morphological differences between these forewing structures; the discal cell is never short in Polypoetes, and veins M1 and M2 are never swollen. The functional significance, if any, of the forewing fascia in Polypoetes is not known. It almost always co-occurs with an analogous hyaline area on the hind wing (Character 93, below).

The vast majority of Lepidoptera exhibit heteroneuran wing venation, in which the system of hind-wing veins is reduced compared to that of the forewings (Common, 1990; Scoble, 1992). Concordantly, the hind wing shows less variability in venation. In Dioptinae, the most important hind-wing vein character is whether M3 and CuA1 are fused or separate (Character 89). Fusion (e.g., Scotura; fig. 12A–D) is derived, and as in the analogous FW character (Character 85), this provides one of the most useful diagnostic field traits for Dioptinae; it is found widely across the subfamily. The only other useful hind-wing venation characters appear in males of some Josiini, where there is fusion of Rs and M1 in Getta and relatives (Character 99). In these same taxa, hind-wing shape is modified due to the presence of specialized androconial patches (Miller, 1996; and see below).

A diagnostic feature for some subclades within Polypoetes, such as the Rufipuncta Group, is the presence of a hind-wing fascia (Character 93) located immediately beyond the DC (fig. 95B). The fascia varies in size and shape across species, and is usually visible in pinned specimens. SEM reveals that the scales of this HW fascia are small and somewhat concave (fig. 95C–F), and widely spaced on both the upper and lower wing surfaces. Since this trait occurs in both females and males and lacks associated modifications, it probably does not serve a stridulatory or androconial function.

Androconia, specialized scales in adult males usually involved in the dissemination of close-range scents (Birch et al., 1990; Schneider et al., 1992), are widespread in Lepidoptera (Scoble, 1992). They are especially prevalent among butterflies (e.g., see Scudder, 1877; Eltringham, 1913, 1915; Vane-Wright, 1972; Boppré, 1984; Vane-Wright and Boppré, 1993). Androconia can occur on a wide range of body parts. For example, in Riodinidae they are found on various locations of the wings and abdomen, as well as on the legs and genitalia (Hall and Harvey, 2002). Androconia also show considerable diversity in many moth groups (e.g., Grant, 1971, 1978). The noctuid subfamily Herminiinae is a prime example; there they show dramatic development on the labial palpi and forelegs (Smith, 1895; Kitching, 1984a; Owada, 1987). The spectacular abdominal coremata of male Arctiidae, located between the sterna of segments 7 and 8 and bearing long, hairlike androconia, have been described and figured in numerous publications (e.g., Boppré and Schneider, 1989), and their involvement in courtship has been thoroughly documented (see Weller et al., 1999). In the Notodontidae, elaborate androconia occur on the forelegs of some Nystaleinae (Weller, 1992). Scent scales on the valvae of the male genitalia are found in most notodontid species (Miller, 1991), including the majority of Dioptinae (see discussion of Barth organ, below).

Perhaps the most conspicuous androconial organs in Lepidoptera are those on the wings. Alar androconia have been discussed and figured in considerable detail for certain butterfly groups, such as the pipevine swallowtails (Papilionidae: Troidini) (Zeuner, 1943; Miller, 1987b; Racheli and Pariset, 1992; Racheli and Olmisani, 1998), milkweed butterflies (Nymphalidae: Danainae) (Eltringham, 1913, 1915; Ackery and Vane-Wright, 1984; Boppré‚ and Vane-Wright, 1989), and Riodinidae (Hall and Harvey, 2002). Usually the wing scales within the androconial patch are highly modified, and species-specific differences in shape have been reported (Ackery and Vane-Wright, 1984; Miller, 1987b; Racheli and Olmisani, 1998).

In Dioptinae, alar androconia occur in a single lineage of the Josiini (Clade 19; fig. 7) comprising three genera—Getta, Polyptychia, and Phavaraea—and totaling 12 described species. However, a surprising variety of androconial configurations is exhibited by the members of this small clade (Characters 90, 92, 101). For example, in Getta there are two areas of specialized scales: one on the dorsal surface of the hind-wing anterior margin, and the other on the ventral surface of the forewing posterior margin (fig. 289H). These two patches apparently overlap during flight. Remarkably similar overlap-type alar androconia occur in certain genera of the Arctiidae (Watson, 1975). The closely related josiine genus Phavaraea possesses different alar androconia. Here, the anal margin of the hind wing is expanded into a rolled, dorsal pouch (fig. 306A, B) enclosing short, cream-colored scales and long, bristlelike scales. Superficially at least, this organ is similar to the hind wing androconia of Battus butterflies (Papilionidae: Troidini) (Miller, 1987b). Polyptychia has an androconial fold along the hind-wing anal margin similar to that of Phavaraea, but also exhibits a second pouch located between hind-wing veins M2 and CuA1+M3 (fig. 298E).

Alar androconia in these dioptines are often associated with specialized scales on other body regions. In Phavaraea dilatata the hind-wing anal margin is greatly expanded (fig. 306B), enclosing woolly, deciduous androconia. There is, in addition, a set of robust, black bristlelike scales on the pleuron of A4–A7, as well as a patch of elongate scales on the dorsum of A5–A8. Polyptychia is unique in exhibiting a tuft of long, white hairlike scales on each tibia (pl. 27), in addition to the alar organs (figs. 299–301). In Phavaraea rejecta and P. poliana (pls. 27, 28) the entire venter of the abdomen is covered with a layer of short, iridescent scales, possibly androconial in nature. For at least some of these dioptine species, the nonalar scales may interact physically and chemically with the ones on the wings. Such a situation has been documented for the Queen Butterfly, Danaus gillipus, in which mechanical contact between abdominal hairpencils and hind-wing pockets is required for proper biosynthesis of the male pheromone, danaidone (Boppré et al., 1978).

In summary, Clade 21 of the Josiini has evolved a diversity of androconial morphology that nearly encompasses that observed across the entire Papilionoidea. The biological reason for this phenomenon is unclear. It is curious to note that the caterpillars of these same josiines are the only ones associated with the primitive Passiflora subgenus Astrophea (Miller, 1996; table 6). Further research on this remarkable system might provide insights into the evolution of androconia in Lepidoptera.

Abdomen

(both sexes, A1–A6)

Several specialized features of the notodontid abdomen, such as the sclerotized cup surrounding the spiracle on A1 (Jordan, 1923b; Fullard, 1984; Kitching and Rawlins, 1999) and the cteniophore on sternum 4 (Jordan, 1923a; Weller, 1992; Miller, Janzen, and Franclemont, 1997), are absent in Dioptinae (Miller, 1991). However, an obscure synapomorphy for the subfamily is the presence of a small patch of microsetae, set on a lightly sclerotized transverse bar in the pleuron of A1, anterodorsal to the spiracle. This structure, figured and discussed in Miller (1991), is of unknown function, but seems to occur throughout the Dioptinae (Character 106).

The A1 sternum is highly reduced in primitive Lepidoptera and absent in Heteroneura (Scoble, 1992; Kristensen and Skalski, 1999). Character 102 details various types of “windows”, or fovea, found on the anterior portion of sternum 2, using four states. These are presumably derived modifications of the fully sclerotized condition, but the character shows considerable homoplasy and is somewhat difficult to interpret. Sternum 2 typically bears apodemes on its anterodorsal corners, a feature found throughout the Ditrysia (Kyrki, 1983). Within the Dioptinae, these vary in thickness and shape (Characters 103, 104). The anterior apodemes on sternum 3 are similarly variable (Character 107). Tergum 1 is membranous, but on tergum 2 the anterolateral apodemes vary in their thickness and degree of curvature (Character 105).

Abdominal color patterns provide important characters, especially in the Josiini (Forbes, 1931). For example, presence of a band of orange scales across the dorsum of A1 (Character 108) defines a small subclade of Lyces that includes L. annulata and L. minuta, the latter formerly placed in its own genus—Leptactea. Lateral stripes and dorsal spots occur in Ephialtias (Characters 109, 110), and the pattern on the abdominal venter (Character 111) is an important synapomorphy for the new genus Proutiella.

The final character from the abdomen, other than features of the terminalia, is the shape of the A2–A6 sterna (Character 112), which are trapezoidal and wider at their posterior margin in a clade of high Andean genera that includes Scoturopsis, Dolophrosyne, and Xenormicola.

Terminalia

(A7–A10)

The male and female genitalia of Dioptinae show tremendous structural variation. This is reflected by the large number of genital characters utilized for the phylogenetic analyses in this study; from a total of 305 adult morphological characters, 193 of them, approximately 63%, are genital. Rather than describe the innumerable differences in genitalia morphology across the Dioptinae, below I outline major trends. A more detailed survey can be inferred from the character list (appendix 1), the generic diagnoses, the species descriptions, and the figures shown in this paper. Throughout the history of Lepidoptera systematics, female genitalia have been less frequently utilized than those of males. They provided fewer characters in the present study (68 female, 124 male). Nevertheless, many of the most reliable traits for diagnosing genera and species can be found in the female external genitalia. As is well known to Lepidopterists, while the basic elements of genital morphology can usually be identified with certainty, homology assessments for the myriad of specializations can be extremely problematic (Epstein, 1996). Here, similarity of location (Remane, 1952; Hennig, 1966) was the guiding rule. Regardless, certain areas were difficult to homologize.

Females

To most students of Lepidoptera, the term “female genitalia” is applied exclusively to modifications of segments A8–A10. Dioptinae are unusual in that many species show specializations on A7 (Characters 92–103) that are clearly related to copulation and oviposition. In this paper, the term female terminalia is therefore broadly applied to encompass variation in all traits of the external reproductive system occurring on segments A7–A10.

Most of the female characters I utilized have been discussed for other groups by previous Lepidopterists. Typically, they show extensive variation within the Dioptinae, and I therefore coded a high proportion of them as multistate characters. For example, I describe signum shape using nine character states and signum location with four (see characters 164, 165). Certain traits, such as position of the ductus seminalis (Character 155), consistently define monophyletic groups, whereas others (e.g., width of the ductus bursae, Character 148) are variable even within narrowly defined clades. Characterization of highly variable, shape-related traits, such as the innumerable configurations of the region surrounding the ostium (Characters 141–146), was difficult. For some of these, it seemed as if generalizations do not apply. Nevertheless, informative characters from the female genitalia far outnumber ambiguous ones.

Basic differences in the shape and relative sizes of tergum 7 and sternum 7 (discussed below) are useful across the Dioptinae. In certain genera, female segment 7 shows an unusual modification associated with oviposition. In these, the broadly membranous tergum is covered with a dense layer of elongate, deciduous scales, here termed a corethrogyne. Analogous structures, known from many groups of Lepidoptera, have been termed anal wool or an anal tuft. A corethrogyne is known to occur in some lower clades of the Ditrysia, such as the subfamily Harmacloninae of the Tineidae (Davis, 1998a), and it has been well documented in Hesperiidae (Larsen, 2005; de Jong, 2006), with Evans (1937) first noting its presence in certain Old World genera. According to Warren et al. (2009), the corethrogyne serves as a synapomorphy for the hesperiid tribe Tagiadini, where it consists of a large mass of long, deciduous scales, tightly packed onto A8. The structure is also found in groups scattered across the Noctuoidea. A corethrogyne is found in some genera of the Lymantriidae and Noctuidae (Masoodi, 1991; Kitching and Rawlins, 1999), in members of the small Australian family Oenosandridae (Miller, 1991), and throughout the Old World notodontid subfamily Thaumetopoeinae (Common, 1990; Miller, 1991; Weller, 1992; Floater, 1998). In Noctuoidea, the structure occurs on A7, and sometimes, as in Dioptinae (below), on A8 as well. Nevertheless, the organs in these distantly related groups are functionally similar.

After eggs are laid, the long deciduous scales become pasted to the chorion surface. Females in Tagiades (Hesperiidae) rub the tip of their abdomen over each egg, spending approximately 30 seconds per egg covering it with long, drooping deciduous scales (Basacombe et al., 1999). In the Thaumetopoeinae, where clutches of up to 500 eggs are laid, the egg group is covered with a deep layer of flat scales and filamentous, barbed scales (Floater, 1998). These together provide a physical barrier impermeable to water, and capable of reducing desiccation. The most important role for the scales transferred onto the eggs from the corethrogyne is thought to be protection from predators and parasitoids (Floater, 1998; Basacombe et al., 1999).

In the Dioptinae, a corethrogyne (Character 119) occurs in two clades. First, it is present in females belonging to a clade comprising three closely related genera—Stenoplastis, Isostyla, and Tithraustes (Clade 17; fig. 7). In these, long, threadlike deciduous scales are densely packed onto the dorsum of A7 and A8 (fig. 263A, B, C). Even longer, hairlike scales are sparsely scattered among the dense pack of threadlike ones (fig. 263D). The tips of these scales appear to be covered with a sticky substance (fig. 263E, F), perhaps fascilitating adhesion to the eggs. Pseudoricia, the probable sister group to Clade 17 (fig. 7), shows a much less elaborate structure. Here, the female abdomen is broad and bears a dense layer of deciduous scales, but its configuration is not nearly so specialized. A corethrogyne is found in a fifth dioptine genus, Pareuchontha (Miller, 1989). These findings suggest that the corethrogyne arose in the common ancestor of Clade 15 (fig. 7), but was subsequently lost in Euchontha.

Sternum 7 shows greater shape variation than tergum 7. One of the most striking modifications involves the position of the ostium relative to the anterior margin of St7 (Character 123). In most moths the ostium, the external opening of the ductus bursae, is located posterior to the trailing margin of sternum 7. In many dioptines, however, the ostium has apparently shifted anteriorly, so that the posterior margin of St7 is deeply excavated. This can be seen, for example, in many species of Brachyglene, Polypoetes (e.g., figs. 97G, 98C), and Nebulosa (figs. 164G, 177G, 181G). The situation shows a range of development within Dioptis. In basal members of the genus, such as the Chloris Group, the posterior margin of female St7 is barely excavated at all (figs. 192F, 193F), whereas in more derived species, such as D. trailii of the Cyma Group, the ostium has shifted so far forward that it is located near the posterior margin of sternum 6 (fig. 210B). In a separate occurrence, the new genus Argentala is characterized by an ostium that is located near the anterior margin of St6 (fig. 85K). In both instances, a longitudinal sclerotized band runs posteriorly from behind the ostium to a position approximately even with tergum 8. Dissection of female genitalia for these taxa requires great care since the boundaries of the sclerites are so unusual, and because the sulci are difficult to locate.

There are interesting modifications on the lateral margins of sternum 7 (Characters 124, 125). In members of a clade that includes Brachyglene, Chrysoglossa, and Nebulosa, sternum 7 wraps upward so that its lateral margins touch tergum 7 (figs. 149E, 164F, 164G, 177E, 177G, 181F, 181G), with the pleuron of segment 7 apparently obliterated. Females in Phaeochlaena possess lateral lobes on St7, and in many Polypoetes species, large, dentate processes occur in the lateral and posterior margins (e.g., figs. 98C, 100G, 108G). Ventrally, sternum 7 can be scaleless and covered with setae or spicules (e.g., Polypoetes forficata; fig. 105G,), it can be heavily sclerotized with a wrinkled or crenulate appearance (e.g., Hadesina goeleti; fig. 141E), it can have a crest or protuberance near the anterior margin (e.g., Polypoetes tinalandia; fig. 117G), or it can have various combinations of these traits (Characters 126–128). The configuration of female St7 shows promise as a means for separating closely related species. For example, within the taxonomically challenging Cyma Group of Dioptis, the configuration of female St7, visible in intact, pinned specimens, shows shape differences useful for separating species with seemingly identical wing patterns and body coloration.

Another trait on female St7 that can be observed in pinned specimens is the presence of a transverse groove (Character 129). It can be shallow (fig. 141E), or deep and well defined. The groove shows a homoplasious distribution, occurring in Phanoptis (Clade 5; fig. 7), as well as in Clade 10 (fig. 7), comprising Hadesina and Brachyglene.

Much of the variation in segment 8 involves the degree of sclerotization of the tergum (Character 131), as well as the presence or absence of various types of ornamentation along its posterior margins (Characters 132–136). In the basal genus of the Josiini—Proutiella—Tg8 is sclerotized (fig. 285E), whereas in the rest of the tribe it is completely membranous (e.g., Phintia broweri; fig. 329D). Determining the boundary between Tg8 and the A8 pleuron can be difficult. In most dioptines and in the outgroup the pleuron is mostly or entirely membranous. In derived forms, the pleuron is partially or completely sclerotized (Character 137), or densely rugulose (Character 139). Many Polypoetes females (e.g., P. copiosa; fig. 94A, B; P. corneola; fig. 102D) are characterized by the presence of large, bladelike processes along the posterior margins of the A8 pleuron (Character 138). Anterior apophyses, located on the anterior margin of pleuron 8, are found throughout the Lepidoptera. Within the Dioptinae, these show differences in length and width (Character 140).

The postvaginal plate (PVP), located immediately behind the ostium, varies greatly in shape and size across the Dioptinae, but this variation proved difficult to categorize into discrete characters and character states. I employed five characters with a total of 19 states to describe morphological variation in the PVP (Characters 141–145), especially involving the shape of its posterior margin. Nevertheless, my system could ultimately benefit from a better understanding of homology in this difficult region. The surface of the PVP is often densely shagreened, or is less commonly striate (Character 143). Shape of the ostium itself provides an important character for defining species groups within Polypoetes (Character 146); in the Rufipuncta Group the ostium is small and its surface is shagreened (fig. 122E), whereas in the Haruspex Group it is large and funnel shaped, its surface is smooth, and its posterior margins are often strongly dentate (e.g., fig. 98A).

The ductus bursae (DB; see fig. 9E), defined as the region between the ostium and the corpus bursae (Klots, 1970), is usually a moderately narrow tube, but differences among taxa are dramatic. It is similar to the PVP in being highly variable in form, yet difficult to translate into character information. Nevertheless, previous work on dioptine taxonomy has shown this structure to be rich in useful traits (e.g., Miller, 1996), and considerable effort therefore went into its analysis here. My strategy was to treat length/width and flat/cylindrical as separate traits (Characters 147, 148). Other specializations are described using six additional characters (Characters 149–154). These include the presence of spines in the DB (e.g., Notascea obliquaria; fig. 334E), and the presence of various appendices (e.g., Oricia homalochroa; fig. 34E).

The ductus seminalis (DS), a small duct—easy to overlook during dissection—provides a connection between the genitalia, where the sperm is deposited, dorsally to the common oviduct, allowing the eggs to be fertilized as they pass to the ovipositor lobes (Dugdale, 1974). Its position relative to the ductus bursae and corpus bursae, as well as its shape, provides useful phylogenetic information in Lepidoptera (Mitter, 1988). This character has proved effective in previous work on higher classification of the Notodontidae (Miller, 1991), and is significant within the Dioptinae as well. I describe DS position using six character states (Character 155). In some josiines the ductus seminalis arises on the body of the CB (e.g., fig. 347D), whereas in other taxa, such as Tithraustes, it is located near the ostium (figs. 271E, 274E). More typically, the DS arises at a point nearly midway along the DB (e.g., fig. 237E). The shape of the ductus seminalis base is important as well (Character 156).

The corpus bursae (CB; characters 157–163) offers the greatest amount of character information of any structure in the female genitalia. Functionally it is simple, comprising a large sac into which the male spermatophore is placed. However, the sac varies dramatically in size and shape, and a startling array of specialized sclerotizations can occur. Under the category of CB shapes, I include the unusual appendices found in Phanoptis and Momonipta (Character 157; figs. 67D, 68D, 213E), and the basal constrictions of Dioptis, Phaeochlaena, and others (Character 163; e.g., fig. 207E). In most dioptine taxa, the CB bears one or more types of sclerotized features, such as internal spinose areas (Character 159; e.g., fig. 104E), longitudinal sclerites (Character 161; e.g., fig. 285E) or complex sclerotized folds (Characters 160, 162; e.g., fig. 352E). Most Dioptis species are exceptional in that the sac is entirely membranous (e.g., fig. 194D).

The signum, a sclerite in the membrane of the corpus bursae, is found almost universally in ditrysian Lepidoptera. It does not occur in the most primitive moth families, such as the Micropterigidae (Kristensen and Skalski, 1999), but is present in some non-Ditrysia of the lower Heteroneura (Busck, 1931), such as the yucca moths (Incurvarioidea: Prodoxidae) (Davis et al., 1992). Surprisingly, even though the signum is such a basic component of the female genitalia in Lepidoptera, its function has been controversial. Some have speculated that the signum, which is usually covered internally with spicules or spines, serves to hold the male's spermatophore in place (Busck, 1931; Callahan, 1958). Recent experiments (Galicia et al., 2008) support an alternative hypothesis, that the signum functions to break the envelope of the spermatophore after the latter has been deposited within the corpus bursae. In many lepidopteran groups, differences in signum shape are useful for separating closely related species (e.g., Pierce, 1909; Pierce and Beirne, 1941; Penz, 1999; Rubinoff and Powell, 1999).

Within the Dioptinae, signum shape is extremely variable. I employed nine character states for shape alone (Character 164). In its most typical form, the dioptine signum is an oval- or figure-eight–shaped sclerite covered with fine spicules (e.g., figs. 21E, 44E). There is usually a defined seam along its midline. The signum is completely absent in a few taxa (e.g., Cacolyces plagifera; fig. 136E), but is present in one form or another in the vast majority of species. In addition to signum shape, I scored three traits (Characters 165–167), totaling 11 states, related to signum position, spicule development, and the presence or absence of a protruding knob, found only within the Josiini (e.g., fig. 335E).

Other than the signum, there are additional sclerites of the CB, and although determining homology among them is sometimes difficult, they provide useful taxonomic information. For example, the base of the corpus is broadly sclerotized throughout the outgroup (Miller, 1991). In Erbessa, presence of a sclerotized region on each side of the corpus midline (e.g., fig. 39E) is diagnostic for the genus (Character 158, State 1). Similarly, the Flavicapilla Group of Scotura is defined by the presence of sclerotized, ridgelike folds in the membrane of the corpus bursae (Character 162, State 1; e.g., figs. 24E, 25E). Perhaps the most spectacular development occurs among Josiini. In Scea, for example, the entire base of the corpus is covered by a complex series of sclerotized folds (Character 160, State 1), and the precise configuration of these differs among species (compare figs. 347D, 348E). In many Dioptinae, the inner surface of the corpus bears spines (Character 170). These can occur in diffuse patches, or on well-defined sclerites, the latter having the appearance of “secondary” signa (Character 171; e.g., fig. 220E). Members of a subclade within Polypoetes possess a region of long villae (Character 159) in the corpus membrane, sometimes located in paired pockets (e.g., fig. 102D).

The membrane between segments A8 and A9 in females can be variously modified. From a phylogenetic standpoint, the most interesting character of the A8/A9 membrane is found in some members of Polypoetes (Character 172). Here, the membrane between the ostium and the ovipositor lobes is sclerotized and heavily spiculate. The region is deeply infolded to form a large internal pocket (figs. 120E, 121D). This trait serves to divide Polypoetes, the largest genus in the Dioptinae with 63 described species, into two major clades.

The final structure of the female terminalia to be discussed is the papillae anales, or ovipositor lobes. The ovipositor lobes are moved by means of protractor/retractor muscles attached to the posterior apophyses (Kristensen, 1984; Scoble, 1992). In some Lepidoptera, such as the chalcosiine Zygaenidae, these apophyses are extremely long and thin, modified to move a greatly extensible ovipositor (Yen et al., 2005a). Modifications within the Dioptinae, where the ovipositor is barely extended, are much less dramatic. Here, the apophyses show moderate variation in length, width, and curvature (Characters 173–175). In Brachyglene, the bases of the papillae anales are broadly sclerotized at the point of attachment of each apophysis (fig. 147E).

Typically, the papillae anales are covered with short spicules and scattered, hairlike setae, but specialized setae are found on the ovipositors of some Lepidoptera. Examples are the hook-shaped setae in troidine swallowtails (Miller, 1987b) and the row of stiff spines in Tortricodes (Tortricidae), used for scraping dirt over the eggs (Scoble, 1992). The Dioptinae show few modifications; in Scotura and some Josiini there is a set of robust, elongate setae near the dorsal margin of each lobe (Character 178), and in some Polypoetes the surface of the papillae anales is covered with a dense mat of dark spicules (Character 179). A subset of Polypoetes species in the Haruspex Group exhibits a spiculate dorsal lobe at the bases of the papillae anales (fig. 94A, B).

The papillae anales themselves can be highly modified in some Lepidoptera, such as in Prodoxidae (Davis et al., 1992) and Incurvariidae (Scoble, 1992) (both Incurvarioidea), where the sclerotized, serrate lobes form a cutting ovipositor, used to insert each egg into plant tissue (Thompson, 1987). The papillae anales of Dioptine are usually membranous and relatively simple, although females in a few clades show sclerotized modifications (Character 177; fig. 322E). The lobes exhibit few differences in relative size, but are particularly large in Phanoptis fatidica and Isostyla species (Character 181; e.g., fig. 279E). Specialized shapes also occur, such as the thumblike dorsal process on the lobes in some Josiini (Character 180; e.g., fig. 335E), and the triangular lobes of Brachyglene (Character 176; fig. 146D).

Males

Not surprisingly, male terminalia provided the majority of characters for these analyses. Their utility in Lepidoptera systematics is legendary (Scoble, 1992). In a situation analogous to that described above for females, I use the term terminalia to refer to segment A8 plus the genitalia proper—the latter homologous with A9 and A10. In Dioptinae, as in other notodontids, segment 8 of the male shows a high degree of modification, presumably associated with its use as a grasping structure during copulation (Miller, 1988). It has been found in other Notodontidae that differences in configuration of the eighth terga and sterna can be used to separate species. They are particularly useful in Nystaleinae (see Franclemont, 1946; Todd, 1973; Weller, 1990, 1991, 1992).

Conspicuous terminal scale tufts, arising from male tergum 8, are widespread in the Notodontidae (e.g., Holloway, 1983; Miller, 1991). In some genera of the Nystaleinae, they comprise long, spatulate scales. Terminal scale tufts are absent in Dioptinae males (Character 183).

Altogether, 21 characters are delineated relating to modifications of male segment 8 in the Dioptinae (Characters 184–204), most involving the anterior and posterior margins on the tergum and sternum, as well as the relative lengths and widths of these sclerites. The various anterior apodemes on Tg8 and St8 are most likely associated with muscles used either for helping clasp the female, or for manipulating the male genitalia themselves. Sclerotizations on the posterior margins, including notches, processes, and complex folds, may provide purchase while gripping the female genitalia during copulation. Such variation is highly specific, and can be useful for species identification (see Miller, 1996; and species descriptions in this paper). In some genera, such as Phaeochlaena (e.g., fig. 75B, E) and Polypoetes (e.g., fig. 128C, D), the eighth sternum and tergum together form a large, powerful-looking, jawlike structure (Character 193).

In all Notodontidae except Thaumetopoeinae, the male intersegmental membrane between A8 and A9 is extremely long (Miller, 1991). This is associated with an unusual copulatory mechanism whereby, during copulation, the male grasps the female's seventh segment and draws her into his abdomen (Miller, 1988; 1991). A long A8/A9 membrane is plesiomorphic for Dioptinae, but in certain genera, such as members of the clade that includes Pseudoricia, Isostyla, and Tithraustes, it is secondarily reduced (Character 205).

In male Lepidoptera, the uncus/socii complex, with its associated muscles, applies dorsoventral pressure on the female genitalia during copulation (Forbes, 1939b; Miller, 1988). In Dioptinae, the configuration at the attachment of the uncus/socii complex to the dorsal portion of the tegumen arms varies (Character 206). The junction can be narrow (e.g., Scotura; figs. 22A, 23A) or wide (e.g., Polypoetes; figs. 100A, 102A). In some taxa, such as Tithraustes (e.g., figs. 273A, 274A), the entire uncus/socii complex is fused together and bends downward in a hingelike structure (Character 207).

Shape and length of the uncus itself varies greatly (Characters 208–210). Although differences can be used to separate dioptine species, similarities in shape effectively define clades. The uncus apex can be acute (the typical form), spatulate, bifid, or trifurcate (Character 211). There is a trend toward uncus reduction in the genus Dioptis; in certain members of the genus it is apparently lost altogether (e.g., fig. 209A). The dorsum of the uncus can exhibit various secondary processes and carinae (Characters 212, 213). Presence of these processes often provides evidence useful for defining subclades within particular genera, such as in the Auriceps Group of Scotura (e.g., fig. 16A). Two traits (Characters 214, 215) address the microstructure of the uncus ventral surface.

Across the Noctuoidea, socii are present in Notodontidae, Doidae, and the Australian Oenosandridae (Miller, 1991). These are regarded as plesiomorphic families within the superfamily (Fibiger and Lafontaine, 2005). The occurrence of socii in quadrifid Noctuoidea has been debated ( Kitching and Rawlins, 1999). They are absent in Noctuidae (Speidel et al., 1996b) and Arctiidae (Jacobsen and Weller, 2002), but socii-like structures occur in some Lymantriidae (Ferguson, 1978). Socii occur throughout the Dioptinae, where they show incredible variation in structure. I used eight characters totaling 29 states to describe these differences (Characters 216–222, 224). Extremes range from species such as Oricia hillmani (fig. 32A) with small socii, to taxa such as Hadesina goeleti (fig. 141A) with greatly elongate ones. In Phanoptis fatidica (fig. 66A), these structures are huge. Throughout the Josiini the socii are narrow, roughly cylindrical and appressed to the uncus (e.g., fig. 329A), but they can also be laterally compressed and paddle shaped, as in certain Polypoetes (e.g., fig. 123A). In most species, they curve gradually upward, but they can also be strongly upcurved, porrect, or curved slightly downward. The junction of the socii to the uncus is variable in its width and degree of sclerotization. In some cases it is firmly fused, while in others there is a clearly defined transverse suture. Both the uncus and socii of Dioptinae are covered with fine, hairlike setae. Specializations (Character 223) include the presence of thickened, robust setae on the uncus in the Rubribasis Group of Polypoetes (e.g., fig. 132A).

The so-called “ring” of the male genitalia in Lepidoptera is composed of the tegumen, homologous with Tg9, and the vinculum, the homologue of St9 (Kristensen and Skalski, 1999). The tegumen varies greatly in width, as well as in its height relative to that of the vinculum (Characters 225, 226, 229). In some species, the tegumen is wider dorsally than ventrally, while in others the reverse is true. In Dioptis vacuata the tegumen is hugely expanded (fig. 196F), while in some members of the Cyma Group, such as Dioptis fratelloi (fig. 206A), there are long dorsal projections arising from the tegumen on either side of the uncus/socii complex (Character 228, State 2). These unusual processes can often be seen in pinned specimens. They are long enough, and in the appropriate position to assist in clasping the female. Other modifications of the tegumen appear in some Nebulosa (e.g., N. elicioi; fig. 167A), where the dorsolateral portion is swollen outward. Other apomorphic conditions include the formation of a large elbow at the tegumen/vinculum junction in Tithraustes (Character 230; e.g., fig. 271A). In Clade 16 (fig. 7)—a more inclusive group that includes Tithraustes and three additional genera—a condition occurs wherein the tegumen, when seen in lateral view, arches strongly backward rather than being upright (Character 227).

Like the tegumen, the vinculum can be wide or narrow (Character 231). The most important structural variation occurs in the ventral region. Here, there is frequently an envelope, formed from the ventral margins of the arms of the vinculum where they join at the midline (Character 233). This envelope is folded upward, and in Erbessa it is so large that it encloses the bases of the valvae (e.g., figs. 39A, 41A). In most outgroup species, a narrow sclerite occupies this same position between the valval bases. Absence of a ventral envelope is taken to be a derived state within Dioptinae. The saccus, a large, anteriorly directed process formed at the ventral midline of the tegulum arms, is found throughout the Lepidoptera but is absent in most Notodontidae (Mehta, 1933; Miller, 1988). A saccuslike structure occurs in a few Dioptinae (e.g., Pareuchontha; fig. 245A), while in others (e.g., Scotura bugabensis; fig. 21A) there is a medial excavation in this region (Character 232).

The male valva exhibits by far the greatest amount of morphological variation of any region in the genitalia. Its most conspicuous elements include the costa, usually present as a well-defined sclerite along the dorsal margin of the valva, and the sacculus. Both of these structures are obscured in those Dioptinae where the valva is completely sclerotized (fig. 271A), a derived condition (Character 238). In some Oricia species, and in Cacolyces, the valva is tightly held to the ring and does not expand (Character 239; fig. 136A). I also used one character with three states to describe general valva shape (Character 240). The inner surface is characterized by the presence of a setose process in Isostyla (Character 241; fig. 277A), and by a set of thick setae in some Dioptis (Character 242; fig. 199A).

The costa varies in width among genera, and various processes can be found along its margin (Characters 234, 236–238). The valva apex is highly variable in shape (Characters 237, 246–248). It can be membranous or sclerotized, and spinelike processes (e.g., fig. 307A), regarded here as extensions of the costa, often occur. Perhaps the most interesting modification of the valva apex is a membranous, balloonlike sac (Character 249), found in Erbessa. In some species, the sac is almost free from the valva itself, being connected only by a thin, threadlike duct (fig. 47A). The function of this structure, perhaps secretory in nature, is unknown.

Androconial organs associated with the male genitalia can be found throughout the Lepidoptera (e.g., Hampson, 1898). The large, membranous sacculus of the valva, with expandable, accordionlike pleats, is a modification unique to Notodontidae, but one that is widely distributed in the family (Miller, 1991). This spectacular structure, named the “Barth valve” by Weller (1992) after its discoverer (Barth, 1955), is one of the most notable features of notodontid morphology. In this paper, the modification is called the Barth organ (BO). Barth (1955) detailed its morphology using Hemiceras as his example. When hemolymph is supplied to the valvae, the pleats of the Barth organ unfold to form a pair of huge sacs, thus exposing long, hairlike androconia. Nonhomologous male coremata in Zygaena, enclosed within dorsal pouches in the membrane between Tg8 and the genitalia, have been shown to produce pheromones, integral to successful copulation (Fänger and Naumann, 1998). These authors have documented the complete sequence of precopulatory behaviors in Zygaena, as well as the important role the coremata play during courtship. While copulatory behavior has never been observed in the Dioptinae, their Barth organs undoubtedly serve a crucial function.

The Barth organ is found in almost all Nystaleinae (Weller, 1992), including the three nystaleine species used as an outgroup for these analyses. Within the Dioptinae, the BO varies greatly in size (Character 251). It is large and membranous in most Erbessa, for example (e.g., fig. 49A), but is small and sclerotized in Cacolyces (fig. 136A). The largest BO occurs in males of Proutiella (e.g., fig. 286A), a newly described genus in the Josiini. Loss of the BO has apparently occurred numerous times within the subfamily, and many genera exhibit sclerotized valvae with no sign of the organ at all (e.g., Dolophrosyne mirax; fig. 223A). In some taxa, the dorsal margin of the BO is heavily sclerotized (Character 253). In many dioptines, I observed a small straplike sclerite that extends from near the valva apex to the dorsum of the BO (Character 254). This sclerite, apparently restricted to the Dioptini (e.g., fig. 147A), may somehow be involved in opening and closing the sacculus pleats during mating. A short, internal apodeme located at the BO midpoint (Character 255), previously detailed for the Josiini (Miller, 1996), might also assist in this function. Other characters associated with the BO include the presence of a wrinkled, membranous sac located immediately above the organ (Character 250), and the presence of an elongate concave sclerite enclosing the dorsum of the BO pleats (Character 252). In Nystaleinae and many Dioptinae, the lateral margin of the BO is strongly curled (Character 256), while in most Josiini this curl is absent.

Within the Josiini, additional valval androconia, not located on the BO, can occur. These are somewhat difficult to document because they seem to be extremely fragile, and are easily lost during dissection. Such scales can be long or short and balloonlike (fig. 316A). One scale group (Character 260) is located on the valva's mesal surface at the lower angle near the juxta (fig. 318A), and characterizes the Abrupta Group of Ephialtias. Additional phylogenetic information could ultimately be acquired through detailed study of the diversity of valval androconia in the Josiini.

I found three other characters of the valva itself: a finely crenulate area at the base in some Scotura species (Character 257; fig. 24A); coarse setae along the valva's ventral margin in Pseudoricia and Euchontha (Character 258; e.g., fig. 260A); and various modifications of the basal sclerite (Character 259). In the outgroup and in some Dioptinae, this basal sclerite is broad, with parallel sides. Variation includes the presence of a narrow sclerite (fig. 22A), and one that is wide (e.g., fig. 107A). In certain Josiini, there is a knoblike process arising from the sclerite itself (fig. 350A).

The membranous expanse of the genitalia (in posterior view), circumscribed by the uncus/tegumen above and the valvae/vinculum below, is termed the annellus (Klots, 1970) or diaphragm (Kristensen, 2003). The aedeagus passes through it. Important sclerites that support the aedeagus are found in the diaphragm, including the transtilla and juxta (both discussed below). The anal tube, located in the dorsal part of the membrane below the socii/uncus complex, varies in length (Character 261), being particularly elongate in some Scotura species (e.g., fig. 25A). In the Rubribasis Group of Polypoetes, there is a small striate sclerite in the diaphragm (e.g., fig. 125A), located immediately above the transtilla (Character 263, State 1). In this same location, a spiculate, often heart-shaped patch can occur (Character 263, State 2). This patch is prominent in some Josiini, such as Lyces (fig. 323A, 323F; Miller, 1996).

The transtilla is a sclerite of variable width, arising from the base of each valval costa. Typically, the transtillar arms meet medially above the aedeagus to form a strengthening or supportive structure. A synapomorphy for the Nystaleinae (Character 264), sister subfamily of the Dioptinae, is the presence of “costulae” on the transtillar arms (Weller, 1990, 1992; Miller, 1991). Within Dioptinae, the transtilla shows remarkable variation in shape. I identified 10 informative characters (Characters 265–274) totaling 29 states. These traits describe differences in the orientation of the transtillar arms, variation in transtilla width and shape, as well as numerous types of secondary processes and sclerites arising from the transtilla dorsal margin. In one of the more generalized apomorphies involving the transtilla, the arms arch sharply upward on each side of the body midline (Character 268). Arching transtillar arms (e.g., figs. 138A, 139A) occur in at least four genera—Brachyglene, Hadesina, Chrysoglossa, and Nebulosa—but within each of these, they are not universally distributed. Sagittala (fig. 59A) and the Albitumida Group of Nebulosa (figs. 183A, 184A) exhibit an additional apomorphy, the presence of a long, dorsal process arising from each transtillar arm. In most Dioptinae, a plate is formed where the arms of the transtilla meet above the aedeagus. Differences in the shape of this plate (Character 270) are described by seven character states. When seen in lateral view, the transtillar arms usually bend slightly anteriad at their medial junction. In taxa such as Phryganidia (fig. 62B) and Dolophrosyne (fig. 222A), they form a strut that extends a considerable distance along the dorsum of the aedeagus toward its base (Character 271).

The area of the anellus immediately above and below the aedeagus has been given a separate name, the manica (Klots, 1970; Nichols, 1989). Within Clade 17 (fig. 7), comprising Stenoplastis, Isostyla, and Tithraustes, the region immediately above the aedeagus is sclerotized to varying degrees (Character 275). Sclerites in the manica, perhaps homologous with those of the Tithraustes clade, provide apomorphies useful for defining subclades within Dioptis. A character state series describes the development of these (Character 276).

The juxta, found ventrally in the manica below the aedeagus, may be of considerable functional significance, since it occurs almost universally in Lepidoptera (Klots, 1970; Kristensen and Skalski, 1999). In Dioptinae, the juxta can be small and heart shaped, tall and narrow, or absent altogether (Character 277). A second transformation series describes the development of a deep, cup-shaped juxta (Character 278). Its upper margin usually exhibits a small medial excavation, but the juxta of some species has a deep excavation (Character 279), and in Dioptis longipennis and others the notch is so deep that the juxta appears to be divided into two halves (fig. 195A).

The Lepidoptera phallus comprises three components—the sclerotized aedeagus proper, the membranous ductus ejaculatorius at the proximal end, and the eversible vesica distally (Scoble, 1992). Although rather simple in its basic form, the phallus provides a rich source of morphological variation; in the Dioptinae, I identified 26 characters involving the aedeagus, ductus ejaculatorius, and vesica. For the aedeagus, relative length and width vary greatly (Character 280). The proximal end shows a variety of shapes (Character 283), ranging from the bulbous base (e.g., fig. 335C), a synapomorphy for most Josiini (Miller, 1996), to the wide, bell-shaped configuration typical of Polypoetes (e.g., fig. 110D). I characterize the basal region of the aedeagus using seven character states, a testament to the large amount of shape variation. In Nystaleinae, the base of the aedeagus forms a callosum (Character 281; Weller, 1990, 1992), purportedly a synapomorphy for that subfamily (Miller, 1991; Kitching and Rawlins, 1999). The delicate membrane arising from the base of the aedeagus is termed the ductus ejaculatorius simplex (Callahan, 1958; Mitter, 1988; Scoble, 1992) or bulbous ejaculatorius (Speidel et al., 1996a). The DES is purportedly involved in shaping the spermatophore before it is introduced into the female corpus bursae (Callahan, 1958). This structure is extremely long in higher Noctuoidea (Speidel et al., 1996a), but is relatively short in most Notodontidae and in Dioptinae. Because of its fragile nature the DES is difficult to study, but I employed one trait (Character 282) involving orientation of the opening.

The distal end of the aedeagus shows less shape variation than is found at the anterior end. Usually, the apex narrows gradually and bears a small ventral tooth (e.g., figs. 32D, 33C), but additional modifications occur. I here describe a structure, which I term the opercular sclerite (Character 288), not discussed by previous authors as far as I am aware. In most taxa this sclerite is contiguous with the aedeagus, extending dorsally onto the vesica (e.g., fig. 24C), but in some species it appears as to be completely separate from the aedeagus. When the vesica is not everted, the opercular sclerite forms a valvalike closure at the apex of the aedeagus. Within the Dioptinae it shows varying degrees of development, from large to absent. Its most elaborate configuration (fig. 21D) is exemplified by species in the Annulata Group of Scotura (formerly the genus Zunacetha). A narrow sclerite, located laterally at the apex of the aedeagus, occurs in Argentala (fig. 86B) and some Polypoetes. Because its location differs, I do not consider this lateral sclerite (Character 289) to be homologous with the opercular sclerite.

Other characters of the aedeagus apex describe various small processes (Characters 290, 293), as well as general shape (Character 287). Almost all species exhibit some form of apical tooth on the aedeagus, variations of which I characterize using four states (Character 291). One of the most unusual specializations consists of a complex appendix, covered with minute folds and spicules (Character 296). This structure, separate from the vesica (discussed below) and located anterior to it, is found in only three dioptine genera—Xenomigia (e.g., fig. 236C), Momonipta (figs. 212B, 213C), and Monocreaga (figs. 218C, 219E, 220C). Based on details of shape, the dorsal appendices in the latter two genera are almost certainly homologous, whereas the appendix of Xenomigia may represent a separate derivation.

The male vesica, enclosed within the aedeagus at rest, is everted within the female corpus bursae during copulation (Miller, 1988; Galicia et al., 2008). Callahan (1958) postulated that eversion is brought about by aerostatic pressure combined with muscle action. An alternative explanation is that they are inflated with haemolymph. At least for Dioptinae, size and shape of the vesica appear to be constant within a species, while differences in shape are among the most useful traits for separating closely related species (Miller, 1996). Such variation was of limited use in this generic-level study, so the vesica characters utilized here were limited to orientation of the distal opening (Character 294), as well as general length and shape (Character 295).

Cornuti, the sclerotized, usually spinelike structures on the surface of the vesica, occur throughout the Lepidoptera (Klots, 1970; Scoble, 1992). Nevertheless, as taxonomically widespread as these structures are, theories concerning their function are vague. They are thought either to be important in placing and holding the male spermatophore within the female corpus bursae (Callahan, 1958; Callahan and Chapin, 1960), or to provide a grip for the vesica within the corpus (Scoble, 1992). Differences in cornuti number, size, and shape are extensive in Dioptinae; I identified eight characters involving the cornuti (Characters 297–304), but these only partially describe the tremendous amount of variation involved. For example, sizes range from the extremely long thin cornuti of Cacolyces (fig. 136C) to the tiny, thornlike ones found in many Polypoetes (e.g., fig. 102C). Cornuti also vary in number; usually they are numerous (e.g., fig. 149C), but in some dioptines, such as the Fulvipalpis Group of Nebulosa, only a single cornutus occurs (e.g., fig. 180C). In some Dioptis species, as well as in Momonipta and Monocreaga (e.g., figs. 213C, 220C), cornuti are absent altogether.

One of the most remarkable characteristics of notodontid morphology is the presence of deciduous “stellate” or “caltrop” cornuti on the vesica. The term caltrop, from Middle English, has historically been used in reference to star thistles (the plant family Zygophyllaceae), or to a four-pointed metal device—employed during the Middle Ages—that was placed on the ground to pierce the hooves of horses. Application of the term to these specialized cornuti in Lepidoptera can be attributed to J.G. Franclemont (personal commun.). Caltrop cornuti have been reported in only two moth families—the Sphingidae and Notodontidae. In Sphingidae, they are found in three macroglossine genera—Theretra, Centroctena, and Cechenena; the caltrop cornuti of Theretra (Rothschild and Jordan, 1903; pl. 58, figs. 4–7) are superficially indistinguishable from those of Notodontidae. Apparently, the occurrence of caltrop cornuti represents three separate derivations in Sphingidae (I. Kitching, personal commun.). These structures show an extremely broad taxonomic distribution in Notodontidae (Forbes, 1939a; Franclemont, 1946; Holloway, 1983; Miller, 1991; Kitching and Rawlins, 1999). The caltrop cornuti become detached during copulation and remain lodged in the female corpus bursae after the male vesica is withdrawn (Pierce and Beirne, 1941; Torre and Alayo, 1959; Miller, 1991). In many groups of Microlepidoptera, a similar phenomenon occurs (Busck, 1931). There, the deciduous cornuti are flattened and sharply pointed rather than stellate, but they similarly remain in the bursa following copulation. Busck (1931), who gave such cornuti the colorful name “lovethorns”, speculated that they break up the male spermatophore, thus more effectively releasing spermatozoa.

Based on outgroup comparison, the presence of caltrop cornuti is plesiomorphic for the Dioptinae (Character 299). However, the character shows multiple cases of evolutionary loss and gain within the subfamily. Deciduous caltrop cornuti occur in many dioptine genera, such as Scotura, Erbessa, Oricia, Brachyglene, Chrysoglossa, and Xenorma, but their presence does not define a monophyletic group (see Discussion: Character Evolution). Deciduous caltrop cornuti are absent in several large genera, such as Dioptis, and they are absent in Josiini, except for their occurrence in the newly described genus Notascea (figs. 334C, 335C), a small clade comprising species formerly placed in Scea. Similarly, deciduous caltrop cornuti are absent in Polypoetes (63 species), but appear in a small subclade of the Rufipuncta Group (fig. 120E). The deciduous cornuti show species-specific shape differences among hapigiine notodontids (Miller, Janzen, and Franclemont, 1997). Some dioptines show similar shape specificity—in Scotura transversa one spine of the caltrop is extremely long (Character 300); in certain taxa within the Flavicapilla Group of Scotura (fig. 25B, C), a single, pinecone-shaped deciduous cornutus, located distally on the vesica, is much larger than the others (Character 304).

SYSTEMATICS

DIOPTINAE WALKER, 1862

Type genus: Dioptis Hübner, 1818: 9.

Dioptidae Walker, 1862: 70.

Dioptinae Kiriakoff, 1950: 81.

Monophyly of the Dioptinae has been firmly established and is now widely accepted; supporting characters come from all life stages. Its hypothetical sister group, the subfamily Nystaleinae (Miller, 1991), currently contains approximately 300 described species (Gaede, 1934; Weller, 1992; Kitching and Rawlins, 1999). Together, the Dioptinae + Nystaleinae thus comprise roughly 800 species, all exclusively neotropical. When the taxonomy of these two subfamilies is finally resolved, I estimate that the clade will total well over 1200 species.

Dioptine adults are most frequently confused with Geometridae or Arctiidae. However, they can be separated from geometrids by their metathoracic, rather than abdominal, tympanum. Arctiidae show quadrifid forewing venation, a tymbal organ on the metathorax, and a countertympanal hood on A1, none of which occur in the Dioptinae. Presence of an unmodified A1, relatively simple metathoracic tympanum, and trifid wing venation establishes membership in the Notodontidae. From there, it becomes relatively simple to identify most Dioptinae to subfamily. A key to notodontid subfamilies is presented in Miller (1991).

Redescription (Adults)

Small, delicate, slender-bodied Notodontidae; wing pattern highly variable, frequently brightly colored; male antenna bipectinate, quadripectinate, or ciliate; female antenna usually ciliate, sometimes (e.g., Brachyglene, Chrysoglossa, Nebulosa) bipectinate; eye variable in size, ranging from small and surrounded by a scaleless band, to large, bulging, and completely surrounded by scales; labial palpus porrect or curved upward over front, sometimes extremely long (Erbessa, Phaeochlaena, Polypoetes); veins M3 and CuA1 stalked in FW and HW (70% of species), occasionally separate in FW, rarely separate in HW; metathoracic tympanum present, variable in size and orientation, rarely absent (some Dioptis); legs elongate; tibial spurs in formula 0-2-4; pleural membrane surrounding A1 spiracle not sclerotized; a small, lightly sclerotized, setose patch in pleuron above A1 spiracle (Miller, 1991); male abdomen usually elongate; female abdomen truncate, sometimes bearing a corethrogyne (Pareuchontha and Clade 17; fig. 7); female St7 often setose (Dioptini); postvaginal plate of female usually simple, variable in size, ranging from small or absent (e.g., Erbessa) to extremely large and wide (e.g., Tithraustes); ostium frequently located anteriorly (e.g., Argentala, Dioptis), St7 then deeply invaginated along posterior margin; male genitalia with transtilla present, comprising two sclerotized bands in manica, joined medially above aedeagus, sometimes highly modified; BO of valva present or absent; vesica of aedeagus variable in size, almost always bearing spinelike cornuti, frequently also bearing deciduous caltrop cornuti.

Immatures

Larvae (final instar). Head taller than T1; head surface finely rugose (Dioptini; fig. 357A–E) or smooth and shiny (Josiini; fig. 358A, B); body integument densely shagreened (fig. 359C); thoracic SV setae in the formula 2-1-1; MD proprioceptor setae unisetose on A1; abdominal spiracles small; seta L2 on A8 located anterior to spiracle, on a line horizontal with it (Miller, 1991); abdominal dorsum lacking distinct tubercles; A8 often with a dorsal hump or false head; anal proleg small and cylindrical (fig. 359A, B), sometimes stemapodiform (e.g., fig. 358C–E; pls. 36, 37); A10 crochets present but reduced in number.

Pupae. Attached by cremaster in an exposed manner, often butterflylike (e.g., Nebulosa erymas, pl. 38J); coloring either uniformly reddish brown (Josiini; pl. 39I), or contrastingly marked (Dioptini; e.g., Tithraustes, pl. 39B, F); abdominal dorsum often bearing large, straight or curled setae (figs. 360B, 361), in addition to those on cremaster (fig. 360C–F).

Discussion

Early authors (Bodine, 1896; Fracker, 1915; Mosher, 1916; Prout, 1918; Forbes, 1922; Hering, 1925) considered the group to be a separate family in the Noctuoidea. It was later suggested that the group should be accorded tribal status within the Notodontidae (Minet, 1983, 1986; Weller, 1989). Franclemont (1970) argued for recognizing the subfamily Dioptinae, and his hypothesis has been followed by subsequent authors (Miller, 1991; Kitching and Rawlins, 1999; Fibiger and Lafontaine, 2005). According to Miller's (1991) findings, monophyly of the Dioptinae is strongly supported; seven unambiguous synapomorphies were described from larval morphology and 12 from adults.

In this paper, the Dioptinae is divided into two tribes—the Josiini and Dioptini—following Miller and Otero (1994). The Josiini (103 species, 11 genera) is a tight assemblage (Miller, 1996); adult and larval morphology, relatively uniform across the group, provides unequivocal support for its monophyly. The Dioptini (353 species, 32 genera), on the other hand, shows extreme morphological diversity. In adults, this variability applies to wing pattern, wing venation, labial palpus shape, antennal shape, tympanal structure, and genital morphology. Larvae of the Dioptini are equally diverse, both in coloration and shape (pls. 36–38). Future research on dioptine evolution should focus on establishing a more informative tribal classification, one that accurately reflects generic interrelationships within what is now recognized as the Dioptini. Most likely, character information from immature stages and DNA will be required. Preserved larvae are currently unavailable from pivotal dioptine genera. In the meantime, I have chosen to retain the Dioptini as a single large, diverse tribe.

KEY TO THE TRIBES OF DIOPTINAE

1. Internal cavity of metathoracic tympanum extremely large, kettledrum shaped (fig. 326B), external opening small (fig. 313B, C), tympanal membrane large, facing ventrally; male antenna with pectinations joined to shaft by a hinged joint (fig. 312E, F); DC usually longer than one-half FW length (e.g., figs. 284C), male stridulatory organ absent; FW ground color usually black or brownish black (pls. 26–35), with a single, orange or yellow transverse band or longitudinal stripe, ground color sometimes iridescent blue; larval head smooth and shiny (fig. 358A, B); four larval instars (Miller and Otero, 1994); pupa without hook-shaped dorsal setae (fig. 360C) Josiini

2. Tympanal cavity moderate in size, deeply invaginated (fig. 11E, F) shallow (fig. 160F), rarely absent (Dioptis; fig. 187I, 189B, 189C), never kettledrum shaped, membrane variable in size, almost always facing posteroventrally; male antenna variable, pectinate (e.g., fig. 93C, D) or ciliate (e.g., figs. 11B, C), when pectinate, pectinations broadly joined to shaft (e.g., fig. 160D, E); male DC frequently shorter than one-half FW length (e.g., figs. 12A–D, 137F), forming a stridulatory organ; FW pattern highly variable, sometimes hyaline (e.g., pls. 9, 18–21), often with a light-colored transverse band (e.g., pls. 16, 17), never with a longitudinal stripe; larval head surface minutely pebbled (fig. 357A–E); five or six larval instars; pupa with spinelike or hook-shaped dorsal setae (figs. 360E, 360F, 361)Dioptini

DIOPTINI

Type genus: Dioptis Hübner (1918).

Dioptini Minet, 1983: 368.

Diagnosing the Dioptini is difficult. For adults, no single character defines the tribe. Instead, certain derived traits can be used to recognize large portions of the group. For example, greatly elongate, sickle-shaped labial palpi (e.g., fig. 35A–E) diagnose 125 species in five genera (Argentala, Erbessa, Phaeochlaena, Polypoetes, and Pikroprion). Altogether, these do not form a monophyletic group (fig. 7). Similarly, the male FW stridulatory organ (e.g., figs. 162A, 162C–F) occurs in approximately 180 species of Dioptini from 22 different genera. Again, these do not form a single clade; the structure appears in clades 1 and 8 (fig. 7). Perhaps important synapomorphies for the Dioptini will be revealed through the study of immature stages. One of the most promising candidates is the presence of curled or curved setae on the abdominal dorsum in pupae (figs. 360B, 361). While such observations are tantalizing, they also point out the dire need for preserved immature stages. At present, life histories remain unknown for genera pivotal to furthering our understanding of dioptine evolution, such as Eremonidia, Argentala, and Monocreaga in the Dioptini, as well as Proutiella, Phintia, and Notascea in the Josiini.

Redescription (Adults)

Labial palpus variable in length and shape, ranging from extremely short and porrect (e.g., fig. 227A, B), to greatly elongate, these arching upward beyond antennal bases (e.g., fig. 35A); eye variable in size, ranging from small (e.g., fig. 221A, D) to large and bulging (e.g., fig. 276A, F); male antenna usually bipectinate (e.g., fig. 93C, D), rami shorter in females (fig. 93E); antenna frequently ciliate (e.g., fig. 36E, F) or subserrate, sometimes quadripectinate (fig. 188C–F); tegula variable in size, usually large (e.g., fig. 38H), sometimes small (e.g., Dioptis; fig. 187I); wing pattern highly variable, sometimes aposematic (e.g., pls. 4, 5) or hyaline (e.g., pls. 18–21), occasionally cryptic (e.g., pl. 22); FW stridulatory organ often present in males (e.g., fig. 137F), DC then shorter than one-half wing length; branching pattern of FW and HW veins M3 and CuA1 variable, usually stalked (e.g., fig. 12A–D), less frequently approximate (fig. 135D) or widely separate (fig. 64K); metathoracic tympanum usually shallow (e.g., fig. 160F), membrane moderate in size, never forming an enclosed kettledrum; female St7 frequently large, scaleless, and setose (e.g., figs. 105G, 265F), its posterior margin excavated (Polypoetes), sometimes extremely so, ostium then located anteriorly (Argentala and Dioptis; figs. 85K, 210B); male terminal segments often sclerotized, highly modified; Tg8 and St8 sometimes forming a large, jawlike structure to aid in clasping female; all features of male genitalia highly variable; transtilla sometimes dentate (fig. 206A), or bearing long dorsal arms (figs. 59A, 184A); Barth organ large (e.g., fig. 47A), small (e.g., fig. 46A) or absent (e.g., fig. 29A); aedeagus highly variable in shape, never globose at base; vesica highly variable in size and shape; deciduous caltrop cornuti present or absent.

Immatures

Larvae (final instar). Head surface minutely pebbled (fig. 357A–E), frequently yellowish brown with small black spots; thorax and abdomen variously colored, often with yellow longitudinal stripes and pinkish or purplish dorsal spots; A8 with a prominent hump, occasionally (Dioptis, Isostyla, Tithraustes) forming a “false head” (pls. 38M; 39A, D); A10 proleg small, held aloft, sometimes stemapodiform (Erbessa, Phaeochlaena, Phanoptis; pl. 36D, F, I; pl. 37A, B, D, G); A10 crochets present, but reduced in size and number; five or six instars; caterpillars feeding on a range of plants (table 4), including Violaceae (Oricia, Phanoptis, Pseudoricia, Scotura), Melastomataceae (Erbessa and Nebulosa), Arecaceae (Dioptis, Isostyla, Stenoplastis, Tithraustes) and Poaceae (Dolophrosyne, Scoturopsis, Xenomigia).

Pupae. Not forming a cocoon, exposed on substrate; anchored by cremaster, aided by hooklike abdominal setae on dorsum (fig. 361A, C, D); body frequently patterned with dark markings, sometimes seemingly aposematic (e.g., pls. 36H, 38J).

Although an attempt was made to create a key that functions using specimens of either sex, it performs best when both sexes are available. Important characters are taken from male antennae and male wing specializations. Less frequently, female structures are crucial for identification. Many of the traits utilized, especially those involving wing venation, were employed by Prout (1918) in his key to the dioptine genera. For Scotura and Xenormicola, the somewhat anomalous taxa—S. nigricaput and X. extensa—key out separately from the remaining members of their respective genera.

KEY TO THE GENERA OF DIOPTINI

1. Forewing with a full compliment of radials present (R1, Rs1–Rs4) 3

FW with only four radials present (figs. 221F, 232C) 2

2. Forewing vein Rs1 arising from radial sector (fig. 221F); FW uniformly gray to gray-brown (pl. 21), or FW gray-brown with a large white triangle along anal margin (pl. 22); FW length  =  9.0–12.0 mmDolophrosyne Prout

FW vein Rs1 arsing from anterolateral angle of DC (fig. 232C); FW light brown with a faint, cream-colored dash along anal margin (pl. 22); FW length  =  11.0–12.9 mmXenormicola extensa (Hering)

3. Forewing vein Rs1 stalked with Rs2–Rs4; FW pattern variable, sometimes cryptically colored5

FW vein Rs1 arising from anterolateral angle of DC (figs. 38A, 70F), widely separate from Rs2–Rs4; FW brightly colored4

4. Male antenna bipectinate; abdomen relatively short, truncate (pls. 9, 10); HW veins M3 and CuA1 widely separate (fig. 70F)Phaeochlaena Hübner

Male antenna ciliate (fig. 36E, 37B), long and threadlike; abdomen long and slender (pls. 2–7); HW veins M3 and CuA1 stalked (fig. 38A, B, E, F), rarely approximateErbessa Walker

5. Male antenna quadripectinate (fig. 188C, D)6

Male antenna ciliate, subserrate, or bipectinate (e.g., figs. 11B, 92A, 93C)8

6. Antenna with distal pair of rami slightly offset (fig. 188D); FW and HW with hyaline areas at base and beyond DC (pls. 17–21), these areas usually extensive; female antenna quadripectinate (ciliate in Chloris Group), pectinations long (fig. 188E) or short Dioptis Hübner

Male antenna with distal pair of pectinations arising opposite one another, not offset; FW and HW without extensive hyaline areas; female antenna ciliate7

7. Forewing and HW veins M3 and CuA1 stalked; DC of FW less than one-third wing length (fig. 249C); FW boldly patterned (pl. 23)Euchontha Walker

FW and HW veins M3 and CuA1 separate (fig. 235G, H); FW DC longer than one-half wing length; FW cryptically patterned (pls. 22, 23)Xenomigia Warren

8. Male with bases of FW veins M1 and M2 swollen on ventral surface immediately beyond DC, forming a stridulatory organ (e.g., figs. 12A–D, 28B)9

FW veins M1 and M2 not swollen at their bases, stridulatory organ absent24

9. Forewing DC longer than one-half wing length10

FW DC shorter than one-half wing length12

10. Forewing veins Rs2–Rs4 in the arrangement [2+3]+4; FW olive brown (pl. 2), veins lined with yellow; a large, yellow wedge arising from costa; HW central area yellowCleptophasia Prout

FW veins Rs2–Rs4 in the arrangement 2+[3+4]; FW not olive brown, without yellow markings; HW central area hyaline, or uniformly gray11

11. Forewing hyaline (pl. 21), with a large white subapical area, veins lined with dark brown to blackish brown scales; HW veins M3 and CuA1 long stalked (fig. 215F); metathoracic tympanum exposed, cavity shallow (fig. 216F); FW length  =  15.0–24.0 mm (South America)Monocreaga C. and R. Felder

FW silvery white (pl. 2), no markings, veins concolorous; HW veins M3 and CuA1 approximate, barely stalked (fig. 28B); metathoracic tympanum eclosed, cavity deep; FW length  =  12.0–12.5 mm (Dominican Republic)Eremonidia Rawlins and Miller

12. Vertex yellow.13

Vertex variable in color, never yellow14

13. Tympanal membrane large, deeply enclosed (fig. 11E, F), facing nearly horizontally; HW central area blackish gray, gray, or white (pls. 1, 2), never yellow; labial palpus relatively wide (figs. 10A–D, 11A)Scotura Walker

Tympanal membrane moderate in size, not deeply enclosed, facing posterolaterally; HW central area yellow to orange-yellow, outer margin dark gray-brown (pl. 23); labial palpus thin (fig. 255A)Pseudoricia Prout

14. Proboscis brown or blackish brown17

Proboscis golden yellow15

15. Forewing DC less than one-half wing length but greater than one-third (e.g., fig. 150F); eye large and bulging, gena absent (e.g., fig. 150A–D); tympanal membrane large, cavity deep, membrane oriented almost horizontally16

FW DC less than one-third wing length (fig. 137F); eye relatively small (fig. 137A–E), not bulging, gena present; tympanal membrane small, cavity shallow, membrane oriented lateroposteriorlyHadesina Warren

16. Male antenna bipectinate, rami long; female antenna bipectinate, rami short; tegula base orange-yellow;FW length  =  13.5–26.0 mm (Central America)Chrysoglossa, gen. nov.

Male and female antenna ciliate; tegula gray, concolorous with rest of body; FW length  =  11.5–15.0 mm (Amazonian Brazil)Scotura nigricaput Dognin

17. Labial palpius long and thin (fig. 268A, D, E; fig. 276A, D, F), sickle shaped, curving strongly upward, Lp3 greatly elongate; wing translucent (pls. 24, 25)18

Labial palpus wide, curving gently upward, Lp3 not elongate; wing densely scaled19

18. Forewing veins Rs2–Rs4 in the arrangement [2+3]+4 (fig. 268G); male Tg8 much longer than St8 (e.g., fig. 269C, E), posterior margin bearing complex, folded processes; male genitalia with uncus present (e.g., fig. 269A); female PVP extremely large, wide (e.g., fig. 269D)Tithraustes Druce

FW veins Rs2–Rs4 in the arrangement 2+[3+4] (fig. 276G); male Tg8 short, approximately equal in length to St8, posterior margin with a deep U-shaped mesal excavation and long, hornlike, sclerotized processes (e.g., fig. 277C, D); male genitalia with uncus absent (e.g., fig. 277A); female with region of PVP membranous (e.g., fig. 277E)Isostyla Prout

19. Hind wing veins M3 and CuA1 stalked; FW without yellow spots, or with a single yellow fascia beyond DC, no spot present between M3 and CuA2; wings broad, short to moderate in length, FW length  =  10.0–20.0 mm20

HW veins M3 and CuA1 separate (fig. 135D); FW with a pair of large, ovoid, light yellow spots, the posterior one located between M3 and CuA2 (pl. 14); wings elongate and long, FW length  =  21.0–25.0 mmCacolyces Warren

20. Male and female antenna bipectinate (male rami long, female rami short)21

Male antenna subserrate, female antenna ciliate22

21. Antennal flagellomeres elongate (fig. 160C–E), rami spaced widely apart; FW and HW variously patterned with brown and white (pls. 16, 17), no yellow markingsNebulosa, gen. nov.

Antennal flagellomeres short, rami thus close together (fig. 144A, B); FW and HW dark brown to olive brown with yellow markings (pls. 14, 15), never whiteBrachyglene Herrich-Schäffer

22. Eye large and bulging, gena absent (fig. 211A–D); labial palpus moderate in length, Lp2 slightly longer than Lp1 (fig. 211A); female without a corethrogyne; wings relatively long (pl. 21), FW length  =  17.0–20.0 mmMomonipta Warren

Eye small, gena broad (fig. 215A, B; fig. 262A–E); labial palpus extremely short, Lp2 shorter than Lp1; female abdomen bearing a corethrogyne on dorsum of A7–A8 (fig. 263B, C); wings short to moderate in length23

23. Area surrounding tympanal membrane heavily sclerotized, protruding laterally, membrane oriented horizontally (Miller, 1989); FW elongate (pl. 23), moderate in length, FW length  =  12.5–19.0 mmPareuchontha Miller

Area surrounding tympanal membrane moderately sclerotized, not protruding, membrane oriented lateroposteriorly; FW triangular (pl. 23), relatively short, FW length  =  11.0–15.0 mmStenoplastis C. and R. Felder

24 (8). Forewing and HW veins M3 and CuA1 stalked or approximate, arising together near lateroposterior angle of DC; wings never hyaline, length variable25

FW and HW veins M3 and CuA1 widely separated, CuA1 arising basal to lateroposterior angle of DC (fig. 64K); wings large (FW length  =  20.0–30.0 mm), often hyaline (pls. 8, 9)Phanoptis C. and R. Felder

25. Male Tg8 much longer than St8 (e.g., fig. 97B, C), with a deep furrow along midline (visible in intact specimens); female St7 wide, heavily sclerotized, scaleless, densely covered with setae (e.g., fig. 98B, C); FW and HW often with an ovoid, hyaline, or semihyaline fascia beyond DC (fig. 95B–F; pls. 10–14); labial palpus usually elongate (e.g., figs. 89B, 90A, 90D, 92C), occasionally short (figs. 89A, 89C, 91D)Polypoetes Druce

Male Tg8 not longer than St8, without a furrow along midline; female St7 not wide, not covered with setae; wings without a fascia beyond DC26

26. Metathoracic tympanum enclosed in a deep cavity, membrane large, oriented horizontally; wings elongate (pl. 2); male abdomen elongate; male antenna ciliate and threadlike, or rarely (O. homalochroa) bipectinateOricia Walker

Metathoracic tympanum located in a shallow cavity, membrane variable in size, oriented lateroposteriorly; wings broad; male abdomen not elongate; male antenna variable, never threadlike27

27. Labial palpus greatly elongate (fig. 79A, E; fig. 84A, D), Lp2 over twice as long as Lp1, palpus apex reaching antennal base or beyond; palpus bearing distal spinules (fig. 83A–F)28

Labial palpus not elongate, Lp2 equal in length to, or shorter than Lp1, without spinules29

28. Male and female antenna subserrate (fig. 82A, B); HW ventral surface silvery white along anal margin from base to beyond DC (pl. 10); female PVP extremely long (figs. 85F, 86C, 88E), forming an elongate band along midline of St7, extending anteriorly almost to St6; pleuron of female Tg8 simpleArgentala, gen. nov.

Male and female antenna pectinate (fig. 82C, D); HW (both surfaces) white with a dark brown outer margin (pl. 10); female St7 broadly sclerotized, not deeply excavated (fig. 80F); posterior margin of female pleuron 8 dentatePikroprion, gen. nov.

29. Male and female antenna bipectinate31

Male and female antenna coarsely ciliate30

30. Head with a prominent frontal bulge (fig. 227A, B); FW ground color brown to dark brown, with contrasting light yellow to yellow-orange markings, usually with a basal dash and an ovoid fascia beyond DC (pl. 22); FW length  =  10.0–13.5 mmScoturopsis Hering

Head without a frontal bulge (fig. 232A, B); FW ground color brown (pl. 22); FW with a long, faint basal dash, and a tiny whitish fascia beyond DC; FW length  =  11.0–17.0 mmXenormicola Hering

31. Forewing vein M1 stalked with radial sector (fig. 58E); FW elongate and narrow, apex acute (pl. 8); wing short; FW length  =  11.0–13.0 mmSagittala, gen. nov.

FW vein M1 arising from DC, not stalked with radial sector; FW broad, triangular, apex not acute; wings moderate in length32

32. Veins M3 and CuA1 separate in FW, stalked in HW (fig. 53F)33

Veins M3 and CuA1 stalked in FW and HW (fig. 60C)Phryganidia Packard

33. Forewing ground color dark brown to blackish brown with a purple iridescence (pl. 25); FW with a reddish orange transverse band crossing from subcosta to near tornus; FW without a subapical spot; HW uniformly purplish brownAnticoreura Prout

FW ground color light olive brown to blackish brown (pl. 8), without purple iridescence; FW with a light yellow fascia distally of DC and a light yellow or semihyaline transverse, subapical spot; HW dark brown with a light yellow central areaXenorma Prout

CLEPTOPHASIA PROUT, 1918

Figures 8, 9; plate 2

Cleptophasia Prout, 1918: 397, 405. Type species: Oricia scissa Warren, 1909 (by original designation).

Figure 8

Cleptophasia scissa ♂. A, head in lateral view; B, head in frontal view; C, head in posterior view; D, tegula; E, head in lateral view; F, wings (illustration by J.S. Miller). Symbols are listed under Comparative Adult Morphology (pp. 23–24).

i0003-0090-321-1-1-f008.gif

Figure 9

Genitalia of Cleptophasia scissa (♂ JSM-161, ♀ JSM-205). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A.’Trabka).

i0003-0090-321-1-1-f009.gif

Diagnosis

Cleptophasia scissa (pl. 2), the only species in Cleptophasia, has the same general appearance as some members of its sister genus, Scotura, being particularly similar to S. transversa (pl. 1) in FW pattern and color. The head of C. scissa is yellow, a characteristic of most Scotura, and the labial palpi are roughly similar in size and shape (compare fig. 8A, 8E and fig. 10A–D). The most reliable means for distinguishing C. scissa from members of Scotura is the length of the DC; in C. scissa it is over one-half the FW length (fig. 8F), whereas in Scotura the DC is less than one-half (figs. 12A–D), with that of S. transversa males less than one-third the FW length (fig. 12A). Diagnostic features for C. scissa include the wedge-shaped yellow transverse FW bar, as well as the mostly yellow HW with yellow extending almost to the wing's outer margin in the area between veins M3 and 2A. Scotura transversa shows a broad yellow transverse FW band extending across the entire wing, and the HW is yellow only along the anterior margin near the apex. Other features of Cleptophasia scissa, such as ciliate antennae in males and females and the presence of a large, deeply enclosed tympanum, are shared with Scotura.

Redescription

Male. FW length  =  14.4–15.0 mm. Head (figs. 8A–C, E): Labial palpus relatively long, narrow, curving upward to middle of front; Lp1 short, slightly curved, with a low, wedge-shaped ventral ridge of scales; Lp2 approximately twice as long as Lp1, curving upward, laterally compressed, tightly scaled with a short ridge of scales along ventral margin; Lp3 extremely short; proboscis yellowish brown; scales of front short, pointing ventromedially from below antennal base, then medially in lower half of front; eye extremely large, bulging strongly outward, completely surrounded by scales; postgena narrow; scales of vertex short, pointing anteriorly, apressed; antennae completely lacking pectinations, ventral surface densely ciliate, each annulation bearing cilia in two transverse rows.

Thorax: Epiphysis short, approximately one-half tibia length, wide at base, apically acute, falling well short of tibia apex; tegula long (fig. 8D), almost two-thirds length of mesoscutum, distal portion narrow, rounded at apex, ventral portion acute, transverse sulcus strong; metathoracic tympanum large, cavity deep with acute margins, membrane large, round, enclosed, oriented horizontally.

Forewing (fig. 8F, pl. 2): Elongate, apical angle acute; vein Rs1 arising from radial sector below Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from near anterolateral angle of DC, close to, but separate from base of Rs1–Rs4, UDC short; stridulatory organ present, but not elaborate, veins M1 and M2 swollen at bases, protruding slightly from wing surface below, no fascia present, no ventral fold between vein bases; DC longer than one-half FW length; veins M3 and CuA1 arising from posterolateral angle of DC, approximate but not stalked; ground color gray-brown, with a large, yellow inverted triangle straddling outer margin of DC, its base resting on costa, its peak extending to anal fold.

Hind wing (fig. 8F, pl. 2): Somewhat narrow, angle at apex acute; M3 and CuA1 arising together from posterolateral angle of DC, touching at their bases but not stalked; a broadly yellow-orange central area from anterior margin, becoming narrower posteriorly between veins M3 and 2A, yellow extending almost to outer margin; apex, edge of wing between M3 and 2A, and anal region blackish gray; anal margin yellow-orange.

Abdomen: Moderately long, narrow, acute distally; dorsum gray-brown, venter creamy white to buff colored, a wide yellow stripe along pleuron.

Terminalia (fig. 9A–D): Tg8 roughly ovoid, shorter than St8, lateral margins slightly convex, anterior margin with a pair of short, narrow apodemes located relatively close together near midline, posterior margin simple, lightly sclerotized, gently convex; St8 much longer than Tg8, wide at anterior margin, then abruptly narrowed distally, anterior margin bearing a long, broad mesal apophysis, posterior margin tapered, almost to a point, apex lightly sclerotized; socii/uncus complex moderately large, narrowly attached to tegumen; uncus short and wide, constricted near middle, apex bifid with a digitate ventral process; each socius wide at base, then abruptly narrowed, curving upward, bearing a brush of short, coarse setae at its apex; anal tube long and narrow, extending far above uncus; tegumen moderately wide, sides roughly parallel, taller than vinculum; vinculum similar in width to tegumen, but becoming thin at ventral margin of genitalia; saccus comprising a small, roughly triangular sclerite, turned upward between valva bases; valvae large, upright, mostly membranous, apices extending well above socii/uncus complex; BO large, occupying over two-thirds of valva, bearing extremely long, hairlike androconia, dorsal sclerite of BO thin, straplike; costa of valva sclerotized, wide, sinuate along upper margin near apex; costa expanded at apex of valva, lateral area immediately below apex membranous, a wide, lightly sclerotized band extending along lateral margin of valva from below apex to upper margin of BO; arms of transtilla narrow, straplike, curving downward from valva base, meeting at midline above aedeagus to form a transverse, conical sclerite; aedeagus long, wide, and straight, narrower at base; apex of aedeagus gradually narrowing to form a scoop-shaped ventral process, opercular sclerite narrow, lightly sclerotized; vesica long, but shorter than aedeagus, wide at base then gradually narrowing distally, oriented at a 90° angle to aedeagus; vesica bearing a dense, wide band of short, spinelike cornuti around its widest part, as well as numerous small, deciduous caltrop cornuti beyond those.

Female. FW length  =  15.5–17.0 mm. Head, thorax, and wings similar to males, except: ventral surface of antennae less densely ciliate; Lp2 shorter and thinner; wings longer and broader; stridulatory organ absent, bases of M1 and M2 not swollen; M3 and CuA1 of FW more widely separated at base; frenulum comprising two bristles.

Abdomen: Shorter and wider than in males, tapered distally.

Terminalia (fig. 9E): Tg7 longer than Tg6, slightly narrower posteriorly, anterior and posterior margins simple; St7 slightly shorter than Tg7, anterior margin simple, posterior margin with a shallow, wide mesal excavation; Tg8 sclerotized, short and simple, somewhat wide, with a shallow depression along midline; anterior apophyses short and straight, tapered anteriorly; A8 pleuron membranous, with a narrow sclerotized band along anterior margin; posterior apophyses long, narrow, curving slightly downward; membrane between Tg8 and papillae anales finely spiculate; papillae anales small, roughly ovoid, with a set of elongate dorsal setae; postvaginal plate flat, sclerotized, surface finely spiculate with several longitudinal costae, ostium sclerotized, wide, funnel shaped, dorsoventrally compressed; ductus bursae extremely short, membranous; corpus bursae wide and long, roughly ovoid, narrowing toward base, surface membranous, scabrous; CB with broad, lightly sclerotized areas above and below, a slightly concave, longitudinal sclerite along dorsal midline near base, its internal surface finely spiculate; signum comprising a transverse, wedge-shaped sclerite, its internal surface coarsely dentate; ductus seminalis with a wide, elongate section from base, arising on dorsal midline of CB at approximately halfway point.

Distribution

Cleptophasia scissa is restricted to lowland forests of South America, from southern Venezuela east across the Guiana Shield and south into Amazonian Brazil. The majority of specimens in museum collections were captured during the early 1900s by Anton Fassl at São Paulo de Olivença, a town on the Rio Solimões of far western Brazil, near its border with Peru and Colombia.

Biology

Nothing is known about the biology of Cleptophasia. However, one could predict, based on the recorded hosts of Scotura (table 4), that the larvae of C. scissa are associated with plants in the Violaceae, possibly either Rinorea or Hybanthus.

Discussion

Prout (1918) described Cleptophasia to include a single species, scissa Warren, and the genus has remained monobasic ever since (Bryk, 1930). Prout's rationale for creating the genus was based on wing venation; Cleptophasia scissa is unusual in having M3 and CuA1 approximate, not stalked or widely separate, in the FW and HW (fig. 8D). This configuration also occurs in Cacolyces (fig. 135D), certain members of Oricia (e.g., O. truncata; fig. 31G), and some Scotura species (the Annulata Group, formerly Zunacetha).

Cleptophasia scissa belongs in a clade with three additional genera (Clade 1; fig. 7)—Scotura, Oricia, and Erbessa. It also appears to be closely related to the Hispaniolan endemic Eremonidia (see fig. 30A, B). In all of these, the antennae are ciliate in males as well as in females. My cladistic analyses suggest that Cleptophasia is the sister group to Scotura, essentially differing only in wing venation. An argument could be made for subsuming it within that genus. However, the phylogenetic status of C. scissa may change when additional characters, such as from immature stages or DNA, become available. In the meantime, I follow previous authors in retaining Cleptophasia.

SPECIES INCLUDED AND MATERIAL EXAMINED

Cleptophasia scissa (Warren)

Figures 8, 9; plate 2 [EX]

Oricia scissa Warren, 1909: 72.

Type Locality

Brazil, Fonte Boa, Upper Amazon.

Type

Syntype ♂/♀, leg. Klages, May–Jun 1906 (BMNH).

Discussion

As occurs with certain species in Erbessa, males of Cleptophasia scissa are extremely rare in collections compared to females. For example, the USNM holdings contain 19 females, all collected at São Paulo de Olivença, but not a single male. Means for recognizing this species are presented in the generic diagnosis above. Cleptophasia scissa was illustrated by Hering (1925: fig. 68i).

Distribution

Brazil (BMNH, CMNH, USNM); French Guiana (AMNH, BHC); Venezuela (AMNH).

Dissected

♂, French Guiana, Patawa, 27 Mar 1992, leg. J.A. Cerda, AMNH (genitalia slide no. JSM-795); ♂, Brazil, Amazonas, Rio Madeira, BMNH (genitalia slide no. JSM-161, wing slide no. JSM-188); ♀, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, USNM (genitalia slide no. JSM-796); ♀, Brazil, Tefé, upper Rio Amazonas, Aug 1935, leg. A.M. Moss, BMNH (genitalia slide no. JSM-205, wing slide no. JSM-167).

SCOTURA WALKER, 1854

Figures 10Figure 11Figure 12Figure 13Figure 14Figure 15Figure 16Figure 17Figure 18Figure 19Figure 20Figure 21Figure 22Figure 23Figure 24Figure 25Figure 2627; plates 1, 2, 36A, 36B

Figure 10

Scotura heads (♂♂). A, S. nervosa, lateral view; B, S. flavicapilla, lateral view; C, S. transversa, lateral view; D, S. venata, labial palpus in lateral view; E, S. transversa, frontal view; F, S. transversa, posterior view (illustrations by J.S. Miller, except A by S. Goodman).

i0003-0090-321-1-1-f010.gif

Figure 11

Scanning electron micrographs of Scotura nervosa ♂. A, head in lateral view; B, antenna in ventral view; C, a single flagellomere (ventral view); D, large sensillum styloconicum, located on distal margin of flagellomere in C; E, opening of metathoracic tympanum; F, close-up of tympanal opening.

i0003-0090-321-1-1-f011.gif

Figure 12

Morphology of Scotura. A, S. transversa ♂ wings; B, S. nervosa ♂ wings; C, S. nervosa ♀ wings; D, S. fulviceps ♀ wings; E, S. flavicapilla tegula; F, S. longigutta tegula; G, head, thorax, and A1 of S. annulata, lateral view (illustration by J.S. Miller).

i0003-0090-321-1-1-f012.gif

Figure 13

Male genitalia of Scotura atelozona (JSM-1128). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f013.gif

Figure 14

Male genitalia of Scotura auriceps (JSM-691). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f014.gif

Figure 15

Genitalia of Scotura longigutta (♂ JSM-693, ♀ JSM-694). A, ♂ genitalia; B, ♂ Tg8; C, ♀ genitalia; D, ♂ St8; E, aedeagus.

i0003-0090-321-1-1-f015.gif

Figure 16

Genitalia of Scotura nigricaput (♂ JSM-1137, ♀ JSM-1136) A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f016.gif

Figure 17

Genitalia of Scotura transversa (JSM-220, 221) A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka)

i0003-0090-321-1-1-f017.gif

Figure 18

Genitalia of Scotura vestigiata (♂ JSM-1615, ♀ JSM-1616) A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia.

i0003-0090-321-1-1-f018.gif

Figure 19

Genitalia of Scotura aeroptera (♂ JSM-1479, ♀ JSM-1480) A, ♂ genitalia; B, ♂ St8; C, ♀ genitalia; D, ♂ Tg8; E, aedeagus; F, ♀ Tg7 (left) and St7 (right)

i0003-0090-321-1-1-f019.gif

Figure 20

Costa Rica, showing the known distributions of Scotura aeroptera, sp. nov., and an undescribed species (nr. aeroptera)

i0003-0090-321-1-1-f020.gif

Figure 21

Genitalia of Scotura bugabensis (JSM-1159, 1160) A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, aedeagus; E, ♀ genitalia (illustration by A. Trabka)

i0003-0090-321-1-1-f021.gif

Figure 22

Genitalia of Scotura flavicapilla (♂ JSM-807, ♀ JSM-808) A, ♂ genitalia; B, ♂ St8; C, ♀ genitalia; D, ♂ Tg8; E, aedeagus.

i0003-0090-321-1-1-f022.gif

Figure 23

Male genitalia of Scotura fulviceps (JSM-1148) and S. quadripuncta, sp. nov., (Holotype, JSM-1151) A, S. fulviceps genitalia; B, S. fulviceps St8; C, S. fulviceps aedeagus; D, S. fulviceps Tg8; E, S. quadripuncta genitalia; F, S. quadripuncta Tg8; G, S. quadripuncta St8; H, S. quadripuncta aedeagus.

i0003-0090-321-1-1-f023.gif

Figure 24

Genitalia of Scotura leucophleps (JSM-445, 446) A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka)

i0003-0090-321-1-1-f024.gif

Figure 25

Genitalia of Scotura nervosa (JSM-769, 1530) A, ♂ genitalia; B, aedeagus; C, ♀ genitalia (illustration by J.S. Miller)

i0003-0090-321-1-1-f025.gif

Figure 26

Genitalia of Scotura occidentalis, sp. nov. (♂ JSM-1647, ♀ JSM-1650) A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f026.gif

Figure 27

Ecuador, showing the known distributions of Scotura occidentalis, sp. nov., and Oricia hillmani, sp. nov.

i0003-0090-321-1-1-f027.gif

Scotura Walker, 1854: 524. Type species: Scotura pyraloides Walker, 1854 (by monotypy); S. pyraloides is a junior subjective synonym of Atolmis flavicapilla Hübner (Watson et al., 1980).

Cymopsis C. and R. Felder, 1874: pl. 105, fig. 23. Type species: Cymopsis fulviceps C. and R. Felder, 1874 (by monotypy).

Zunacetha Walker, 1863: 133. Type species: Zunacetha bipartita Walker, 1863 (by monotypy). New synonymy.

Diagnosis

Characterizing Scotura is somewhat difficult. The genus shows fairly wide variation in wing pattern (pls. 1, 2) and genital morphology (figs. 13–19, 21Figure 22Figure 23Figure 24Figure 2526). The labial palpi of Scotura are fairly long (fig. 10A–D; fig. 11A), but not nearly as long as those of its close relatives Oricia (fig. 31A, D, E) and Erbessa (figs. 35A–E, 36A). The vast majority of Scotura species can be properly assigned based on the presence of gray to brownish gray forewings and a yellow or yellow-orange vertex of the head (pls. 1, 2), but exceptions exist. For example, the vertex in Scotura fusciceps and S. nigricaput is gray, concolorous with the rest of the head and thorax. In a few species, such as S. venata and S. delineata, the head is a less contrasting light yellow. In addition, there are Dioptinae outside Scotura showing a yellow vertex, examples being Cleptophasia scissa (pl. 2), Eremonidia (pl. 2), Cacolyces plagifera (pl. 14) and Pseudoricia (pl. 23). However, these always lack one or more of the traits listed below.

The most important features for distinguishing Scotura species, when used in combination, are the following: vertex yellow (except S. fusciceps and S. nigricaput); eye extremely large and rounded (fig. 10A–C, E, F), no scaleless area below; metathoracic tympanum large and deep, membrane enclosed (fig.11E, F; fig. 12G), oriented horizontally; veins M3 and CuA1 stalked in both the FW and HW (figs. 12A–D), except for the Annulata Group where these veins are touching but not stalked; labial palpus moderately long (figs. 10A–D; fig. 11A), never with an elbowlike joint at Lp1 and Lp2; FW DC much less than one-half the wing length (fig. 12A–D), stridulatory organ well developed; male antenna densely ciliate below (fig. 11B, C), completely lacking pectinations or transverse flanges. Although the FW pattern is variable, the HW is less so, with most Scotura species exhibiting a white central area in the HW with a wide, dark gray outer margin. Exceptions are flavicapilla, delineata, nigricaput, and aeroptera, where the HW is entirely gray.

Redescription

Male. FW length  =  11.5–16.5 mm. Head (figs. 10, 11A–D): Labial palpus variable in length, ranging from short (e.g., S. quadripuncta) to long (e.g., S. delineata, S. nigricaput), usually held close to front; Lp1 short, curved, with a loose fringe of long scales below; Lp2 much longer than Lp1, sometimes (e.g., Annulata Group) with an acute terminal tuft of long scales; Lp3 either short (e.g., S. transversa, S. flavicapilla) or moderately elongate (e.g., S. annulata, S. leucophleps); proboscis reddish brown to yellowish brown; clypeus scaleless; scales of front pointing downward below antennal bases, then oriented horizontally above clypeus; frontal scales in Annulata Group pointing dorsomedially, forming large lateral crests; eye extremely large, bulging, completely surrounded by scales; antenna without pectinations, ventral surface densely covered with fine cilia, or rarely (e.g., S. transversa) each annulation with a pair of extremely short pectinations in lower half, these bearing long cilia.

Thorax (fig. 12G): Epiphysis short, falling well short of tibia apex, wide at base, apically acute; tegula short to moderately long, ventral angle acute, transverse sulcus absent; metathoracic tympanum large, cavity deep with acute margins, membrane large, round, enclosed, oriented horizontally.

Forewing (figs. 12A–D): Elongate in most species, more rounded in some (e.g., S. auriceps, S. transversa); vein Rs1 long stalked with Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC near base of Rs1–Rs4, UDC short, obliquely angled; stridulatory organ present, M1 and M2 swollen at bases with a diffuse fascia present, a prominent, scaleless fold between swellings on ventral surface; DC much shorter than one-half FW length, sometimes (e.g., S. auriceps, S. transversa) less than one-fourth; veins M3 and CuA1 long stalked, or touching but not stalked (Annulata Group); wing pattern variable, usually gray with veins lighter (e.g., S. leucophleps), sometimes with white or yellow cross bands (e.g., S. auriceps), or gray with from one to four small white spots (e.g., S. quadripuncta); FW pattern in Annulata Group reticulate.

Hind wing (figs. 12A–D): Narrow, angle at apex acute; M3 and CuA1 long stalked, or touching at their bases but not stalked (Annulata Group); central area of HW white, outer margin broadly banded in dark gray (except HW uniformly gray in S. flavicapilla and S. aeroptera); transversa with a yellow, teardrop-shaped spot near apex. Abdomen: Usually elongate, apically acute, shorter in S. transversa and S. auriceps; uniformly gray, sometimes (e.g., S. fulviceps) with a faint, thin white line along pleuron.

Terminalia (figs. 139, 21Figure 22Figure 23Figure 24Figure 2526): Tg8 short, somewhat quadrate, sides roughly parallel or occasionally slightly narrower posteriorly; anterior margin of Tg8 with a pair of small, narrow apodemes located relatively close together near midline; posterior margin of Tg8 with a wide, poorly defined, quadrate or U-shaped mesal excavation; excavation rarely absent (e.g., S. contracta and S. nigricaput), posterior margin instead broadly tapered; posterior margin sometimes simple (e.g., S. auriceps, S. transversa); St8 usually longer and wider than Tg8; St8 widest at anterior margin, tapered toward distal margin, sometimes (e.g., S. contracta) greatly so; anterior margin of St8 with a long, wide mesal apodeme, tapered to a blunt point, apodeme sometimes short (e.g., S. atelozona); posterior margin of St8 with a deep, V-shaped mesal notch, margin sometimes (e.g., Annulata Group) finely sclerotized; socii/uncus complex highly variable, either large and robust (Auriceps and Annulata groups), or small and delicate (Flavicapilla Group); uncus shape highly variable, never long, sometimes with a digitate (S. bugabensis) or bifid (S. nigricaput) dorsal process; socii extremely variable, either large (Auriceps and Annulata groups), or small, delicate, and apressed (Flavicapilla Group); anal tube usually extending far above uncus; tegumen narrow, taller than vinculum, rarely wide (e.g., nigricaput); vinculum wide, concave; saccus large and wide, extending upward to cover valva base; dorsal margin of saccus forming a large triangle, ventral margin frequently with a mesal excavation; valva variable, moderately long, usually wide and membranous, sometimes narrow; BO variable in size, usually extremely large and membranous (Flavicapilla Group), sometimes occupying approximately one-third of valva (Annulata Group), rarely small (e.g., S. auriceps); costa of valva heavily sclerotized, narrow; apex of valva almost always forming an ear-shaped structure that is often quadrate (Flavicapilla Group); arms of transtilla narrow, straplike, oriented horizontally, meeting at midline to form a small, transverse sclerite; aedeagus long and narrow, occasionally (e.g., Annulata Group) wide; apex of aedeagus forming a narrow, digitate ventral process; vesica moderately large, approximately one-half length of aedeagus, angled sharply upward; vesica bearing a large group of deciduous caltrop cornuti, almost always with a small set of nondecidous spinelike cornuti below those; some Flavicapilla Group species (e.g., S. nervosa, S. fusciceps) with one or two deciduous cornuti much larger than others, these pinecone shaped, heavily spinose.

Female. FW length  =  12.0–19.0 mm. Head: Similar to males, except labial palpus slightly shorter and thinner; ventral surface of antenna covered with short, fine cilia.

Thorax: Similar to males.

Forewing: Longer and broad than in males; stridulatory organ absent; DC slightly less than one-half wing length.

Hind wing: Longer and broader than males; frenulum comprising only two bristles.

Abdomen: Shorter and much wider than males, not tapered toward apex.

Terminalia (figs. 15Figure 16Figure 17Figure 1819, 21Figure 22Figure 23Figure 24Figure 2526): Tg7 long, wide, frequently tapered distally (e.g., nervosa), sometimes markedly so (e.g., nigricaput); St7 extremely wide, wider than Tg7, posterolateral margins sometimes with shallow, sclerotized pockets (Annulata Group); anterior and posterior margins of St7 simple; Tg8 sclerotized, short and wide, arching upward at midline, posterior margin simple; AA usually long and thin, rarely short (e.g., longigutta), sometimes sinuate; A8 pleuron mostly membranous, with a narrow straplike sclerite along anterior margin; PP straight, thin; papillae anales small, covered with long setae and short spicules, posterior margins simple; PVP sclerotized, short and wide, slightly concave, surface spiculate; DB short, sclerotized, dorsoventrally compressed; CB large, membranous, an elongate oval, always with longitudinal folds; a broadly sclerotized region dorsally near base, this sometimes with elongate striae; internal surface of basal CB plate often densely spinose; signum variable, internal surface always dentate, shape ranging from a small figure eight (e.g., S. delineata) to an elongate oval (S. bugabensis); signum in most Auriceps Group species transverse; DS arising from a triangular appendix on dorsum of CB near base.

Distribution

Scotura shows its highest diversity in lowland forests. As far as I am aware, none has been collected at elevations above 1000 meters; the vast majority of material is recorded from well below 500 meters. Four species of Scotura live in Central America, but most of them are endemic to the Amazon Basin. A single species—occidentalis, newly described here—occurs in lowland forests on the western side of the Andes.

Biology

Host plants for six Scotura species are known (table 4)—two in the Annulata Group and four in the Flavicapilla Group. Hosts have not yet been discovered for any species of the Auriceps Group. According to the data gathered so far, Scotura shows a strong association with the violaceous genera Rinorea (pl. 47C) and Hybanthus. The habitats in which most Scotura species occur undoubtedly mirror the distribution of their hosts, which are common plants in the forest understory throughout the lowland tropics (Gentry, 1993).

Although Flavicapilla Group species are restricted to Rinorea and Hybanthus, diets in the Annulata Group are broader. Caterpillars of Scotura annulata (pl. 36B) most commonly feed on Hybanthus, but occasionally reach outbreak levels, at which time their host breadth expands greatly (Wolda and Foster, 1978; Harrison, 1987; L.D. Otero, personal commun.); S. annulata larvae have been recorded from a huge variety of plant families, including the Arecaceae, Euphorbiaceae, Sabiaceae, and Rubiaceae. A newly described species in the Annulata Group, S. aeroptera from Costa Rica, is apparently restricted to Genipa americana (table 4), a member of the Rubiaceae. It is interesting that this plant family appears in the host list of both Annulata Group species.

Discussion

Walker's (1854) description of Scotura was brief, and of the characters he listed, none were particularly informative. Some, such as “wings rather narrow, of moderate length” (p. 525), can be broadly applied across the Dioptinae. Others, such as “antennae slender, setaceous, pubescent”, provide slightly more information, but again leave an unsatisfactory hole. The only species Walker included in Scotura was pyraloides (a junior synonym of flavicapilla Hübner), so he was understandably hampered. The bright yellow head, so prominent in flavicapilla, was not mentioned as a generic character. By the time Prout (1918) unified the dioptine classification, Scotura contained 13 species. Dognin (1923) then described three more, and Hering (1925) two more after that, bringing the total number of Scotura species to 18 (Bryk, 1930).

Walker (1863) established Zunacetha in the Phycitidae, now Pyralidae, with Zunacetha bipartita Walker, a junior synonym of Lithosia annulata Guérin-Méneville, as its type species. The genus was placed in the Dioptidae by Prout (1918). Previous authors have noted numerous characters shared by Scotura and Zunacetha. Prout (1918: 407) wrote that Zunacetha “could be made a section of Scotura”. My cladistic analyses support Prout's contention; Scotura is paraphyletic with respect to Zunacetha (fig. 3), and I here place the latter in synonymy as the Annulata Group. With the synonymy of Zunacetha, three more names become added to the Scotura species list, and three species are described here as new (appendix 2). In contrast to many other dioptine genera, the composition of Scotura in the current work does not differ dramatically from that proposed by Prout (1918).

Scotura belongs in Clade 1 (fig. 7) along with its sister genus, Cleptophasia, as well as another pair of sister genera, Oricia + Erbessa. This lineage shows strong Bremer support (fig. 2), as does Scotura itself. Altogether, Clade 1 comprises 88 species and could potentially be designated as a separate tribe of the Dioptinae. However, I defer this proposal until a more comprehensive intergeneric analysis, which would include characters from DNA and immature stages, has been done.

Scotura is here divided into three species groups. Based on my analysis of representative species (fig. 2), the monophyly of each is strongly supported, although membership in the Auriceps Group may ultimately require adjustment. Each group exhibits noteworthy morphological attributes. For example, in the Auriceps Group the male genitalia are structurally diverse. Some species have sclerotized valvae lacking a BO (e.g., fig. 13A). In others, the dorsum of the uncus bears a pair of processes (figs. 16A, 17A) seen nowhere else in the Dioptinae. In contrast, genitalia in the Flavicapilla Group are remarkably uniform (e.g., figs. 2326); the BO is universally huge and heavily pleated, and the uncus is simple.

However, the Flavicapilla Group shows numerous synapomorphies of its own. For example, in taxa such as N. nervosa (fig. 25B, C) and N. fusciceps, one deciduous cornutus of the vesica is pinecone-shaped and greatly enlarged. This trait seems to be unique for the Notodontidae. Differences in cornutus shape could potentially prove useful for separating closely related species within the Flavicapilla Group.

The Annulata Group (pl. 1) shows an apomorphic wing pattern. The wings of most Scotura species are typical for the Dioptinae; the veins themselves are lighter, contrasting with the FW ground color (e.g., S. transversa). On the other hand, in the Annulata Group the dark lines fall between the wing veins (Character 88), and the veins are concolorous with the rest of the FW. This character state does not occur elsewhere in the Dioptinae.

KEY TO SCOTURA SPECIES GROUPS

1. Forewing pattern reticulate in basal half (pl. 1); a conspicuous white triangle outlined in black along FW anal margin halfway out; areas between veins in distal half of FW with thin, contrasting black lines; male vesica with deciduous cornuti only (figs. 19E, 21D); female signum an extremely large, elongate oval (figs. 19C, 21E)Annulata Group

FW pattern various, never reticulate in basal half, without a white triangle along anal margin (pls. 1, 2); areas between FW veins never with black lines, veins frequently contrasting, lighter than ground color; male vesica with spinelike as well as deciduous caltrop cornuti (e.g., fig. 17C); female signum relatively small (e.g., figs. 16D, 24E)2

2. Uncus wide at base, junction with tegumen transverse (e.g., figs. 14A, 16A); socii heavily sclerotized, wide at bases then abruptly narrowed toward apices; vesica with a dense brush of spinelike cornuti at base (e.g., fig. 17C); signum of female CB transverse (e.g., fig. 17E); FW often with a white or yellow transverse band (pl. 1)Auriceps Group

Uncus narrow at base, narrowly joined to tegumen (e.g., fig. 22A); socii small, membranous, setose, gradually tapered toward apices (e.g., fig. 23A); vesica with a small group of spinelike cornuti at base (e.g., figs. 22E, 24C); female CB with an ovoid or figure-eight–shaped signum (e.g., figs. 24E); FW without a transverse band (pls. 1, 2)Flavicapilla Group

SPECIES INCLUDED AND MATERIAL EXAMINED

1. AURICEPS GROUP

The Auriceps Group (pl. 1) contains nine taxa whose genital structure differs markedly from those of the Annulata and Flavicapilla groups. These latter groups are almost certainly monophyletic. However, character variability among species in the Auriceps Group sheds doubt on its monophyly. Resolution of this issue will require a species-level revision. The Auriceps Group is exclusively South American, with the majority of taxa being found in the Amazon Basin.

KEY TO AURICEPS GROUP SPECIES

1. FW uniformly gray or mottled gray-brown (pl. 1)5

FW with a contrasting transverse band (pl. 1)2

2. Transverse band of FW yellow3

Transverse band of FW white4

3. Hind wing uniformly dark charcoal gray; Lp2 mostly yellow, dorsum and a thin lateral stripe gray-browncontracta Dognin

HW charcoal gray with a yellow, wedge-shaped spot along anterior margin near apex; Lp2 entirely yellowtransversa (Warren)

4. Hind wing uniformly dark charcoal gray; Lp1 yellow with gray-brown scales on dorsum, Lp2 gray-brown with a yellow lateral stripe, Lp3 gray-brownauriceps Butler

HW with an oblong white central area, falling well short of posterior margin, white narrower posteriorly; labial palpus uniformly yellowatelozona Prout

5. Vertex yellow to yellow-orange, rest of body gray or gray-brown; wing span variable (FW length  =  12.0–17.0 mm)6

Vertex gray, concolorous with rest of body; wings relatively short (FW length  =  13.0–14.5 mm); FW uneven gray-brown, HW graynigricaput Dognin

6. FW uniformly gray, veins lighter, HW central area white; labial palpus moderate in length, ascending upward to middle of front or below7

FW glossy light gray-brown with a mottled pattern consisting of three wavy, darker brown transverse lines; HW evenly gray-brown; labial palpus elongate, extending well beyond antennal basedelineata Dognin

7. HW with a well defined white central area; FW ventral surface with a small white area beyond DC; FW length  =  15.0–17.0 mm; apices of socii not digitate8

HW with a diffuse whitish central area, gray scales mixed in; FW ventral surface without a white area; FW length  =  12.0 mm; apices of socii narrowly tapered, digitatenigrata Warren

8. White central area of HW large, extending from base to well beyond fork of M3+CuA1; outer margin of white area gently rounded; aedeagus extremely large and wide (fig. 18C)vestigiata Prout

White central area of HW small, extending from outer half of DC to base of M3+CuA1, wing base and HW anal margin gray; outer margin of white area obliquely angled posteriorly; aedeagus narrow (fig. 15E)longigutta Warren

SPECIES INCLUDED AND MATERIAL EXAMINED

Scotura atelozona Prout

Figure 13, plate 1

Scotura atelozona Prout, 1918: 407.

Type Locality

Brazil, Fonte Boa, Upper Amazon.

Type

Holotype ♀, leg. S.M. Klages, Aug 1907 (BMNH).

Discussion

The transverse FW band of S. atelozona might suggest that this moth is related to S. auriceps and S. transversa (pl. 1). However, male genital similarities suggest that S. longigutta, a moth without a transverse FW band, is the sister species of S. atelozona; the two have essentially identical genital morphology (compare figs. 13, 15). An additional hint of a relationship between these taxa is provided by the shape of the white HW central area. Furthermore, atelozona and longigutta share the same type locality—Fonte Boa, Brazil. Future study may reveal that these are color forms of a single species. If true, this would be the first case in the Dioptinae where presence or absence of a transverse FW band is not indicative of species status.

Scotura atelozona is rare in collections. In addition to the male dissected (pl. 1), the BMNH contains two males and the female holotype, there is one male at the ZMH—illustrated by Hering (1925: fig. 68l)—and a male at the AMNH. The JBSC male of S. atelozona (JSM-1128), as well as two males at the BMNH, show a wing pattern differing slightly from that of the female type. In these the white FW band reaches the anal margin, whereas in the type the FW band falls short of the anal margin.

Distribution

Brazil (AMNH, BMNH, JBSC, ZMH).

Dissected

♂, Brazil, Amazonas, Faz. Porto Alegre, Manaus, BR-175, km 64, 2°22′S, 59°56′W, 10 Dec 1993, leg. Roger W. Hutchings & J. Bolling Sullivan, light trap, JBSC (genitalia slide no. JSM-1128).

Scotura auriceps Butler

Figure 14, plate 1

Scotura auriceps Butler, 1878: 60.

Type Locality

Brazil, Amazonas, Tefé.

Type

Syntype ♀, “in the forest”, 19 Oct 1874 (BMNH).

Discussion

Morphology of the male and female genitalia suggests that Scotura auriceps, endemic to Brazil, is the sister species of S. transversa, from the Guyana Shield (compare figs. 14, 17). Among other features, the two share a highly unusual configuration of the socii/uncus complex, with paired dorsal processes on the uncus. The valvae in both species are narrow with a highly reduced BO, the tegumen is wide, and St8/Tg8 exhibit similar shapes. The two species differ in that the FW cross band is white in auriceps but yellow in transversa. The latter also bears a small spot near the HW apex, not shown by auriceps.

Distribution

Brazil (AMNH, BMNH, CMNH, JBSC, NMW, ZMH).

Dissected

♂, Brazil, Pará, leg. A.M. Moss, BMNH (genitalia slide no. JSM-691); ♀, Brazil, Pará, [“Santinga”?], 14 Dec 1939, “flying”, Miles Moss Collection, BMNH (genitalia slide no. JSM-692).

Scotura contracta Dognin

Plate 1

Scotura contracta Dognin, 1923: 29.

Type Locality

Brazil, Amazonas, São Paulo de Olivença.

Type

Holotype ♂, leg. Fassl, Nov–Dec (USNM type no. 33122).

Discussion

I know this species from the holotype male and from three females—one at the USNM (São Paulo de Olivença), one at the AMNH (French Guiana), and one in the Bernard Hermier Collection (French Guiana). Scotura contracta exhibits a yellow transverse FW band similar to that of S. transversa, but the two can be separated by a large suite of characters: the labial palpus is yellow with dark scales dorsally along all three segments in contracta, whereas it is completely yellow except for a dark Lp3 apex in transversa (see Warren, 1906: 413). The most obvious difference is in the HW: there is a teardrop-shaped yellow spot along the costal margin in transversa, but this region is completely dark in contracta. Male and female genital morphology differs dramatically between the two.

The male genitalia of S. contracta, showing a large BO and an unusually shaped socii/uncus complex, create doubt as to whether this species is properly placed in the Auriceps Group. I was unable to identify a more appropriate species group within Scotura, and so have provisionally placed contracta here.

Distribution

Brazil (USNM); French Guiana (AMNH, BHC).

Dissected

Holotype ♂ (genitalia slide no. JSM-1130); ♀, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, USNM (genitalia slide no. JSM-1131).

Scotura delineata Dognin

Plate 1

Scotura delineata Dognin, 1923: 30.

Type Locality

Brazil, Amazonas, São Paulo de Olivença.

Type

Syntype ♂, leg. Fassl, Nov–Dec (USNM type no. 33121).

Discussion

The name “Scotura delineata Dognin” does not appear in the body of the text in Bryk (1930)—the only catalogue for the Dioptinae—but was referred to (as an addendum) on page 65 in the index of that work. The species was discussed by Hering (1925: 511), but not figured. Numerous characters confirm its placement in Scotura. For example, the well-developed FW stridulatory organ and yellow head, as well as several features of the male and female genitalia, are consistent with membership in Scotura. However, the moth exhibits some unusual features. For example: The labial palpus in males is exceptionally long for the genus; the broad, convex male valva apex with an apical point is highly unusual; and the scoop-shaped socii are unique. The mottled forewings of S. delineata are somewhat suggestive of the reticulate pattern found in Annulata Group species. Understanding the taxonomic affinities of this taxon within Scotura will require additional research.

Anton Fassl collected all the known material of S. delineata (2♂♂, 4♀♀) near the turn of the 20th century at São Paulo de Olivença, Brazil, at which time he also captured several specimens of S. contracta, including the type.

Distribution

Brazil (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1134); ♂, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1132); ♀, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1133).

Scotura longigutta Warren

Figure 15, plate 1 [EX]

Scotura longigutta Warren, 1909: 74.

Type Locality

Brazil, Amazonas, Fonte Boa.

Type

Syntype ♂/♀, leg. S.M. Klages, May–Jul 1906 (BMNH).

Discussion

As is noted in the discussion for S. atelozona above, genital synapomorphies suggest that that species (fig. 13) is sister to S. longigutta (fig. 15). Scotura longigutta lacks the white transverse FW band of S. atelozona, but in both taxa the white central area of the HW has a downturned shape (pl. 1), distinctive within Scotura. Type material for the two taxa was collected by S.M. Klages a year apart, but at precisely the same Amazonian locality. The FW of longigutta shows a short, faint white transverse band on its ventral surface, and the male FW DC is extremely short. These two might, in fact, be color forms of the same species.

My search of collections worldwide located specimens of S. longigutta at only two institutions—the Natural History Museum in London, and the Naturhistorisches Museum in Vienna. The BMNH holdings contain four males (including the type) and three females, captured on the Upper Amazon during the years 1906 and 1907; six of these were collected at Fonte Boa and one downriver at Teffé. The NMW contains a beautiful series of seven males, all captured by Zerny in 1927 at Taperinha, near Santarem on the Lower Amazon. Based on this information, it appears that the species occurs along the length of the river.

Distribution

Brazil (BMNH, NMW).

Dissected

♂, Brazil, Amazonas, Teffé, Sep 1907, leg. M. de Mathan, BMNH (genitalia slide no. JSM-693); ♀, Brazil, Fonte Boa, Upper Amazons, Jun 1906, leg. S.M. Klages, BMNH (genitalia slide no. JSM-694).

Scotura nigrata Warren, revised status

Plate 1

Scotura nigrata Warren, 1906: 412.

Type Locality

French Guiana, St. Jean, Maroni River.

Type

Syntype ♂, leg. Mar 1904 (USNM type no. 9171).

Discussion

When Warren (1906: 412) described Scotura nigrata he treated it as a species, but Prout (1918) and all subsequent authors (Hering, 1925; Bryk, 1930) placed it in synonymy with nervosa Schaus (pl. 1). My dissection of the USNM male syntype shows not only that S. nigrata is markedly distinct from nervosa, but also that—judging from its male genitalia—it belongs in a different Scotura species group; I have placed nigrata in the Auriceps Group (appendix 2), whereas nervosa belongs in the Flavicapilla Group. The narrow male valva of S. nigrata (lacking a BO), with a conspicuous flange along its lateral margin, suggests a close relationship with two Auriceps members—atelozona and longigutta (figs. 13, 15).

The problem, however, is to distinguish S. nigrata from S. nervosa and S. intermedia (pl. 1), both in the Flavicapilla Group, without relying on their obvious genital differences. Useful features on the rest of the body are obscure. The only trait I was able to find for separating S. nigrata from the two Flavicapilla Group taxa involves the color of the occiput—the region immediately behind the eye. In all three species the front and labial palpi are yellow-orange. However, in S. nervosa and S. intermedia the occiput is gray-brown to steely gray, concolorous with the thorax. In S. nigrata, on the other hand, the occiput is yellow-orange, concolorous with the labial palpi and front.

After searching the world's major collections, S. nigrata is apparently rare. Only a handful of specimens were located at a scattering of museums. However, since the species is difficult to identify, careful study of material from French Guiana, especially in private collections, will undoubtedly yield additional specimens. In addition to the male syntype dissected (JSM-1154), the USNM contains a syntype female, captured at Rockstone, Essequibo, Guyana.

Distribution

French Guiana (BHC, BMNH, NMW, USNM); Guyana (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1154).

Scotura nigricaput Dognin

Figure 16; plate 1

Scotura nigricaput Dognin, 1923: 30.

Type Locality

Brazil, Amazonas, São Paulo de Olivença.

Type

Syntype ♂, leg. Fassl, Nov–Dec (USNM type no. 30968).

Scotura soror Hering, 1925: 510. New synonymy.

Type Locality

Brazil, Amazonas, São Paulo de Olivença.

Type

Holotype ♀ (ZMH).

Discussion

Dognin (1923) named Scotura nigracaput because its head is gray, concolorous with rest of the body, rather than being yellow or yellow-orange as in most Scotura species. The only other member of the genus with a gray head is S. fusciceps, in the Flavicapilla Group (below). The male and female genitalia of nigricaput (fig. 16) clearly support placement in the Auriceps Group. The moth with which S. nigricaput might most easily be confused based on size and wing pattern is S. venata (Butler) (pl. 2). However, these are easily separated because S. venata shows a conspicuous yellow head.

The USNM collection contains the following material of Scotura nigricaput, all of which was collected by Fassl: A male syntype (separated in the type holdings); a male lacking its abdomen; and two females—one labeled “type” and another labeled “co-type”. The only other examples of S. nigricaput of which I am aware are the type of soror at the ZMH (see below), as well as two males and a female at the Naturhistorisches Museum in Vienna. Except for a single specimen from Taperinha (NMW), the species is known exclusively from São Paulo de Olivença, on the Upper Amazon.

Scotura soror was described by Hering (1925) as similar to flavicapilla, but with a unicolored gray head. The types of S. soror and S. nigricaput are identical, and both were collected at the same locality. Under his summary for nigricaput, Hering (1925: 510) noted that soror might merely be a light form of nigricaput. Even though I have not dissected Hering's type, my studies support that hypothesis. Thus, soror becomes a new synonym of nigricaput.

Distribution

Brazil (NMW, USNM, ZMH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1136); Syntype ♀, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, USNM (genitalia slide no. JSM-1137); “Co-type” ♀, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, USNM (genitalia slide no. JSM-1138).

Scotura transversa (Warren)

Figures 10C, 10E, 10F, 12A, 17; plate 1 [EX]

Stenoplastis transversa Warren, 1906: 413.

Type Locality

French Guiana, St. Jean, Maroni River.

Type

Holotype ♂, leg. Jul 1904 (USNM type no. 9172).

Discussion

Scotura transversa, a highly distinctive species, is relatively common in collections. Although most specimens were collected in French Guiana, the moth occurs across the Guiana Shield. The species is distinguished by its yellow FW cross band (of somewhat variable width and shape) and its yellow, comma-shaped spot at the HW apex. The wing veins are lined with contrasting light yellowish brown scales. Male and female genital similarities (figs. 14, 17) suggest a close relationship between S. transversa and the Brazilian S. auriceps (pl. 1).

Distribution

French Guiana (AMNH, BHC, BMNH, CUIC, MHNH, USNM); Suriname (CMNH, BMNH, CUIC); Guyana (BMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1129); ♂, French Guiana, St. Jean de Maroni, Received from E. Le Moult, BMNH (wing slide no. JSM-189, genitalia slide no. JSM-220); ♀, Aroewarwa Creek, Maroewym Valley, Suriname, Mar 1905, leg. S.M. Klages, BMNH (genitalia slide no. JSM-221).

Scotura vestigiata Prout

Figure 18, plate 1

Scotura vestigiata Prout, 1918: 408.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♂, leg. C. Buckley (BMNH).

Discussion

Even though S. vestigiata is extremely similar to S. nervosa in wing pattern (pl. 1), it is otherwise markedly distinct. Morphological differences between the two suggest placement in separate species groups within Scoturavestigiata in the Auriceps Group, and nervosa in the Flavicapilla Group (see appendix 2). For example, the FW DC of S. vestigiata is extremely short, much less than one-third the wing length, whereas it is slightly less than one-half in nervosa (fig. 12B, C). Comparison of wing, head, and genital traits suggests that S. vestigiata is a close relative of S. longigutta and S. atelozona. All three exhibit male valvae lacking a BO (figs. 13A, 15A, 18A), and in all the ventral portion of the male genitalia forms a large, tight envelope around the valva bases. Additional traits, including features of the female genitalia (figs. 15C, 18E), support this relationship.

Historically, the vast number of Scotura specimens in collections in which the FW is uniformly gray and the HW shows a large white central area, has simply been identified as “nervosa”. In reality, this material can include as many as six Scotura species, including S. vestigiata.

Distribution

Ecuador (BMNH, CMNH).

Dissected

♂, Ecuador, Napo, Parque Nacional Yasuní, at PUCE station on Río Tiputini, 450 m, 25 Nov 1995, leg. Jan Hillman, CMNH (genitalia slide no. JSM-1615); ♀, Ecuador, Napo, Parque Nacional Yasuní, 35 km SE PUCE station toward Bogi, 450 m, 27 Nov 1995, leg. Jan Hillman, dry forest, CMNH (genitalia slide no. JSM-1616).

2. ANNULATA GROUP

The Annulata Group (pl. 1) includes the two species formerly placed in Zunacetha and a third taxon newly described here. My cladistic analyses show that these species form a clade arising within Scotura (fig. 3), as sister to the Flavicapilla Group. Monophyly of the Annulata Group is indisputable; its Bremer support value is 21 (fig. 2). Synapomorphies include: outer half of FW with longitudinal streaks in cells between veins; FW with a large, whitish, wedge-shaped maculation at midpoint of anal margin; aedeagus with a large, elbowed, straplike, dorsolateral sclerite in right side at apex (figs. 19E, 21D); vesica lacking spinelike cornuti, bearing caltrop cornuti only; female St7 expanded at posterolateral margins, with a pair of shallow, sclerotized pockets (fig. 19F); base of CB with a large, sclerotized region (figs. 19C, 21E), its internal surface densely spinose.

The Annulata Group is well represented in Central America, unlike the other two Scotura species groups, one of which (the Auriceps Group) is strictly South American, and the other of which (the Flavicapilla Group) is South American except for a single species (S. leucophleps) from Central America.

KEY TO ANNULATA GROUP SPECIES

1. Forewing ground color white or light gray (pl. 1), HW mostly white, with a light gray to light gray-brown margin; labial palpus entirely yellow to orange-yellow; uncus with a long, secondary dorsal process (fig. 21A); CB with a long spinose sclerite from base (fig. 21E) greater than one-half CB length2

FW ground color with a coppery cast (p. 1); HW uniformly charcoal gray; labial palpus yellow with a small, black lateral spot near distal margin of Lp1; uncus without a secondary dorsal process (fig. 19A); spiny area at base of CB relatively small (fig. 19C), much less than one-half CB length (Costa Rica)aeroptera, sp. nov.

2. Forewing mostly white, with reticulate black lines in basal half, distal half with contrasting black longitudinal lines between veins; areas behind FW costa in basal third and at apex of DC yellow-orange; HW mostly white, a light gray-brown area at margin near apex; socii membranous, apex of valva strongly concave; CB sclerotized in basal three-fourths, this area with strong longitudinal folds and long internal spines (Mexico S to Argentina)annulata (Guérin-Méneville)

Distal third of FW grayish white, with darker lines between veins, basal two-thirds whitish gray, a conspicuous white triangle along FW anal margin at halfway point, yellow-orange areas absent; HW white with a wide, gray to gray-brown marginal band; socii sclerotized (fig. 21A), valva apex not concave; CB broadly sclerotized in basal two-thirds (fig. 21E), this area densely spinose, without folds (Costa Rica S to Brazil and Peru)bugabensis (Druce)

SPECIES INCLUDED AND MATERIAL EXAMINED

Scotura aeroptera, new species

Figures 19, 20; plate 1

Diagnosis

Among the described species of Scotura, S. aeroptera is unmistakable. It exhibits the reticulate FW pattern characteristic of the Annulata Group, but differs from other members in its darker pigmentation, and in the bronze-colored cast in its FW; the FW ground color of the other described species is white or whitish gray. Scotura aeroptera also differs in having black patagia, as opposed to these being white with a thin, transverse black line along the posterior margin. One more trait unique to S. aeroptera is the presence of a small, contrasting, black lateral spot against a brilliant orange-yellow ground color on Lp1. The male and female genitalia of aeroptera (fig. 19) are distinct from those of either annulata or bugabensis (fig. 21), particularly in the configuration of the male socii/uncus complex, as well as the shape of the basal sclerite on the female corpus bursae.

Description

Male. (pl. 1). Forewing length  =  12.5–13.0 mm. Head: Labial palpus elongate, extending upward to middle of front; Lp1 short, with a loose fringe of long scales below, lateral surface and fringe orange, light orange-yellow on dorsal surface, a small black spot on lateral surface near distal margin of segment; Lp2 greatly elongate, wide, curved sharply upward near apex, covered with orange scales, a bristly fringe below; apex of Lp2 with an acute tuft of long, creamy orange scales, obscuring Lp3; front with short, creamy orange, upwardly pointing scales in central region, lateral margins with a pair of long, orange, ridgelike crests, these forming short tufts between each antennal base; occiput trimmed with long, dusky gray scales, darker immediately behind eye; eye large, bulging outward, gena absent; vertex covered with long, erect, brilliant orange scales; ventral surface of antenna evenly covered with cilia; antennal scape creamy orange on lateral surface, orange on mesal surface; dorsum of antennal shaft tightly covered with glossy, bronzy-gray scales.

Thorax: Legs dusky gray on outer surfaces, light gray on inner ones; pleuron covered with long, hairlike, light gray to dusky gray scales; patagium covered with long, erect, blackish brown scales, anterior margin sparsely trimmed with light, gray-brown scales; tegula covered with hairlike, creamy bronze scales, dark brown at ventral angle; dorsum creamy gray with a blackish brown, midsagittal stripe; metathoracic tympanum large and deep, internal surface scaleless, shiny, margins acute; tympanal membrane large, enclosed, ovoid, oriented horizontally.

Forewing: (Dorsal) Ground color creamy bronze in basal half, bronzy gray in outer half; a large, black, irregular oval near base, oval touching radius anteriorly, extending to anal margin posteriorly, its lateral margin slightly concave; area behind costa, anterior to oval, forming a thin, orange streak, with a few scattered blackish gray scales distally; a bold, black transverse line dividing basal and distal halves of wing, line interrupted as it crosses stridulatory organ by a small orange spot located immediately beyond DC; a large, creamy bronze triangle formed approximately midway along anal margin between outer margin of oval and posterior portion of transverse line, its apex touching orange spot at stridulatory organ; cells between veins in outer half with long, bold, blackish streaks, extending from transverse line to outer margin, streaks acute basally, wider distally; costa gray; anal margin thinly lined with long, dark gray scales. (Ventral) Ground color glossy gray with a coppery tinge; a long, diffuse, creamy gray triangle along anal margin from base to fork of M3 and CuA1, its anterior margin touching cubitus.

Hind wing: (Dorsal) Ground color glossy charcoal gray; basal half somewhat sparsely scaled; anal margin fringed with gray hairlike scales; fringe itself a mix of gray and cream colored scales. (Ventral) Ground color glossy gray, slightly lighter than FW ventral surface; central area glossy whitish gray.

Abdomen: Dark gray on dorsum, dusky gray below.

Terminalia (fig. 19A, B, D, E): Tg8 moderately long, sides parallel, anterior margin with a wide, deep, U-shaped mesal excavation, posterior margin weakly sclerotized, with a short, quadrate excavation; St8 roughly ovoid, longer than Tg8, lateral margins gently concave at midpoint, anterior margin with a wide, broadly rounded mesal process, posterior margin transverse, posterolateral angles sclerotized; uncus/socii complex fairly large, narrowly attached to tegumen; uncus wide at base, apex acute, without a middorsal process (present in all other Annulata Group species); socii sclerotized, wide at base, apices digitate, slightly flattened; tegumen moderately wide, approximately equal in height to vinculum; vinculum wide; ventral margin of genitalia with a large mesal excavation, saccus large, upper margin covering valva bases, with a low mesal ridge; valvae long, mostly membranous; BO small, occupying less than one-third of valva; costa sclerotized, narrow, expanded at valva apex to form a triangular, ear-shaped structure; transtilla thin, oriented horizontally; aedeagus wide, narrowing slightly at base, apex with a small, straight process; an angled, straplike sclerite on right side at apex of aedeagus, its surface coarsely dentate; vesica wider than aedeagus, slightly over one-half aedeagus length; a large group of deciduous caltrop cornuti at distal portion of vesica, their spines elongate, several nondeciduous, spinelike cornuti below this group on right side.

Female. Forewing length  =  15.5 mm. Body characters similar to males, except: labial palpus shorter, Lp2 without an apical tuft; frontal scales short, without lateral crests, a few brown scales at lateral angles above clypeus; antenna delicately ciliate; FW and HW longer and broader than in males, outer margins more rounded; wing body colors not as vibrant as in males.

Terminalia (fig. 19C, F): Tg7 narrowing abruptly toward distal margin, lateral margins concave in distal third, anterior margin simple, posterior margin slightly convex, almost transverse; St7 extremely wide, anterior margin simple, posterior margin transverse, posterolateral angles with large, sclerotized, earlike depressions; Tg8 small, sclerotized, arching slightly upward, surface minutely spiculate; PA with posterior margins rounded; AA and PP long, tapered; PVP short, wide, spiculate; DB dorsoventrally compressed, short; CB large, roughly ovoid, signum located ventrally, extremely long (over two-thirds as long as CB) and wide, with a seam long midline, internal surface coarsely dentate; base of CB broadly sclerotized dorsally on either side of midline, a large group of long, internal spines below sclerite; DS arising dorsally on CB, approximately one-fourth from base.

Etymology

The name is derived from a combination of the Latin word aeris (“bronze”), and the Greek pteron (“wing”), in reference to the unusual bronze tone of the forewing in this species.

Distribution

Scotura aeroptera is known almost exclusively from material reared at La Selva Biological Station in Costa Rica (fig. 20), a well-known site located near the town of Puerto Viejo de Sarapiquí. A single INBio specimen was collected at Cerro Cocori (Limón Province), in the northeast corner of Costa Rica within a few meters of the Caribbean coast. This species thus appears to be restricted to lowland forests on the Caribbean side of the Cordillera Central, at elevations between 50 and 150 meters.

Biology

Caterpillars of Scotura aeroptera feed on Genipa americana (table 4), in the Rubiaceae (Dyer and Gentry, 2002). This is the first record of a dioptine larva specializing on Genipa. Interestingly, one of the outbreak hosts reported for S. annulata is the genus Randia (Janzen and Hallwachs, 2008), another member of the Rubiaceae. Scotura aeroptera may have a broader host range in the Rubiaceae than is so far known. Genipa fruit oxidizes blue-black when cut, producing dark skin paint used by the Chocó Indians in the Darién of Panama (Gentry, 1993).

Discussion

This moth is generally darker and more brilliant in color than other Annulata Group species. The HW of S. aeroptera is uniformly dark, whereas elsewhere in the Annulata Group the HW has a large, white central area. This species exhibits a wing pattern remarkably similar to that of Watsonidia (Arctiidae), with which it occurs in sympatry. Scotura aeroptera exhibits several genital apomorphies setting it apart from other described Annulata Group species, the most outstanding being: Male without a dorsal process on the uncus (fig. 19A); socii strongly tapered, heavily sclerotized; and valva apex subtriangular, ear shaped. In females (fig. 19C), the unusually large signum, large ovoid basal sclerite, and rounded papillae anales are distinctive.

During a visit to the INBio collection in Heredia, Costa Rica (January 2007), a single Annulata Group male was discovered with a bronzy wing pattern like that of S. aeroptera; initially I had identified it as such. Surprisingly, this specimen was collected near the base of the Osa Peninsula on the Pacific coast (fig. 20), whereas all verified specimens of S. aeroptera are from the Caribbean drainage. Dissection of the Osa specimen confirmed it to be an undescribed species. Closer study revealed that, not only are the male genitalia of the Pacific example markedly different from those of S. aeroptera, but prominent features of the wings and body distinguish it as well. Two features on the head readily separate S. aeroptera from the western taxon: First, the tiny black lateral spot on the first labial palpus segment of aeroptera is absent in the unnamed species, where Lp1 is instead uniformly orange; secondly, the front is creamy white to orange-yellow in aeroptera, but dark gray-brown in the Osa example. Their forewings differ as well. Most notably, the western taxon shows a pair of black streaks in the FW basal third, along the anal fold and vein 1A+2A. These do not occur in S. aeroptera.

Until additional material from the Osa becomes available, I refrain from describing that taxon, which would become the fourth member of the Annulata Group. Label data for the undescribed moth are as follows: 1♂, Costa Rica, Puntarenas, Peninsula de Osa, A. C. Osa, Est. Esquinas, 200 m, Dec 1993, J.F. Quesada, L S 301400_542200, #2544, INBio (genitalia slide no. JSM-1782).

Holotype

Male (pl. 1). Costa Rica: Heredia: Estación Biol. La Selva, 50 m, Gentry/Dyer, Apr 2000, Reared: #16256 (genitalia slide no. JSM-1479). The type is deposited at the AMNH.

Paratypes

Costa Rica: Heredia: 1♀, Estación Biol. La Selva, 50 m, Gentry/Dyer, Apr 2000, Reared: #6932 (genitalia slide no. JSM-1480).

Other Specimens Examined

Costa Rica: Limón: 1♂, Sector Cerro Cocori, Fca. de E. Rojas, L-N 286000, 567500, 150 m, Mar 1992, leg. E. Rojas (INBio).

Dissected

1♂, 1♀.

Scotura annulata (Guérin-Méneville), new combination

Figure 12G; plates 1, 36B [EX]

Lithosia annulata Guérin-Méneville, 1844: 519.

Type Locality

Mexico, Veracruz.

Type

Syntype ♀ (BMNH).

Zunacetha bipartita Walker, 1863: 134.

Type Locality

Honduras.

Type

Syntype ♂, ex Dyson Collection (BMNH).

Mieza nervosa Felder and Rogenhofer, 1875: pl. 139, fig. 43.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♀ (BMNH).

Discussion

Because Zunacetha is newly synonymized here, Scotura annulata becomes a new combination. This is one of the most common dioptine species in museum collections, and is also one of the most widespread, occurring from Mexico south to Argentina. Broad distributions of this sort are rare in the Dioptinae. A single specimen of S. annulata, supposedly at the USNM, was reportedly captured at Brownsville, Texas (Franclemont, 1970). However, I have not been able to locate that example.

The synonyms of annulata listed above were not verified by type dissections. Walker's bipartita is almost undoubtedly a synonym because its type locality (Honduras) is relatively close to the type locality of annulata (Veracruz, Mexico). Superficial study of the BMNH type of nervosa Felder and Rogenhofer, from Bogotá, Colombia, suggests that it too is a synonym of annulata. These authors assigned the species to the genus Mieza, at that time a genus containing all sorts of brightly colored moths, and placed loosely in the Bombycoidea. Felder and Rogenhofer's female type is missing its abdomen.

Three separate research groups in three different countries have reared Scotura annulata: Janzen and Hallwachs (University of Pennsylvania), in Costa Rica; A. Aiello (STRI), in Panama; and L.D. Otero (Universidad de Los Andes, Mérida), in Venezuela. The larvae (pl. 36B) feed most commonly on Hybanthus in the Violaceae (table 4), but have also been recorded on Acalypha diversifolia (Euphorbiaceae), as well as on Chamaedorea (Arecaceae), Randia (Rubiaceae) and Meliosma (Sabiaceae). When S. annulata occurs as an outbreak species, the larvae become facultative generalists, feeding on plants in a great number of families spanning taxonomic boundaries (Wolda and Foster, 1978; Harrison, 1987; L.D. Otero, personal commun.).

Distribution

Mexico (AMNH, BMNH, CMNH, CUIC, LACM, USNM); Guatemala (AMNH, CMNH, LACM, USNM, VOB); Belize (BMNH, VOB); Honduras (AMNH, BMNH, CUIC); Costa Rica (AMNH, BMNH, CMNH, INBio, LACM, NMW, UCB, USNM, VOB, ZMH); Panama (AMNH, BMNH, CMNH, LACM, USNM); Venezuela (AMNH, BMNH, CMNH, IZA); Guyana (CUIC); French Guiana (BMNH); Colombia (USNM); Ecuador (VOB); Peru (AMNH); Bolivia (AMNH, BMNH, NMW); Paraguay (USNM); Argentina (AMNH).

Dissected

♂, Mexico, Jalapa, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1162); ♂, Guatemala, Cayuga, May, Schaus and Barnes Collection, USNM (wing slide no. JSM-1618); ♀, Mexico, Veracruz, USNM (genitalia slide no. JSM-124); ♀, Mexico, Cordoba, May 1906, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1163); ♀, Mexico, Cordoba, May 1906, Wm. Schaus Collection, USNM (wing slide no. JSM-1619).

Scotura bugabensis (Druce), new combination

Figure 21, plate 1 [EX]

Zunacetha bugabensis Druce, 1895: 223, pl. 61, fig. 15.

Type Locality

Panama, Bugabá, 800–1500 ft.

Type

Syntype ♂ (BMNH).

Stenoplastis albibasis Warren, 1907: 200.

Type Locality

Peru, La Union, Río Huacamayo, Carabaya, 2000 ft.

Type

Holotype ♂, leg. G. Ockenden, wet s., Nov 1904 (BMNH).

Discussion

Synonymy of Zuncetha makes Scotura bugabensis a new combination. As with its sister species, S. annulata, this taxon shows a broad geographical distribution. The moth has been recorded from Costa Rica south to southeastern Peru at elevations between 0 and 600 meters. The species is widespread in the Amazon Basin. These wide distributions contrast with the third member of the Annulata Group, S. aeroptera, currently known from a small area in eastern Costa Rica (fig. 20). Within the Annulata Group, S. bugabensis is distinguished by having a gray, rather than white (S. annulata) or coppery brown (S. aeroptera) FW and HW ground color. It also lacks the yellow-orange FW markings found in the other two taxa.

There seem to be slight differences in wing pigmentation between South American and Central American bugabensis; examples from South America tend to be dark gray beyond the FW discal cell. In Central American material this wing region is whitish. I have not determined whether this difference is geographically consistent.

All authors subsequent to Warren (1907), who described albibasis, have treated that name as a synonym of bugabensis. My studies suggest the existence of two species, but I am unable to establish their identities with certainty. I dissected the BMNH male holotype of albibasis (JSM-1528), from Río Huacamayo Peru, and its genitalia are identical with those of Peruvian material identified as bugabensis. However, females seem to show differences, particularly in the size of the signum. I retain albibasis as a synonym of bugabensis pending further study.

Distribution

Costa Rica (INBio, BMNH, VOB); Panama (BMNH, USNM); Colombia (BMNH); Peru (AMNH, BMNH, USNM); Brazil (AMNH, BMNH, LACM, VOB); Venezuela (AMNH); French Guiana (AMNH, BMNH); Ecuador (AMNH, CMNH, LACM).

Dissected

♂, Costa Rica, Puntarenas, Est. Sirena, P.N. Corcovado, 0–100 m, Jul 1991, leg. G. Fonseca, INBio (genitalia slide no. JSM-839); ♂ type of albibasis Warren (genitalia slide no. JSM-1528); ♂, Peru, Madre de Dios, Tambopata Reserve, Laguna Chica, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. J.S. Miller, C. Snyder, A.V.Z. Brower and S. Rab-Green, AMNH (genitalia slide no. JSM-1161); ♂, Brazil, São Paulo de Olivença, Amazonas, Nov–Dec, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1159); ♀, Costa Rica, 800 m, V. Neilly, VOB (genitalia slide no. JSM-907); ♀, Peru, La Unión, Río Huacamayo, Carabaya, 2000 ft, wet s., Nov 1904, leg. G. Ockenden, BMNH (genitalia slide no. JSM-1529); ♀, Peru, Yahuarmayo, 1200 ft, Apr 1912, USNM (genitalia slide no. JSM-1160).

3. FLAVICAPILLA GROUP

Monophyly of the Flavicapilla Group is supported by synapomorphies of the male and female genitalia (figs. 22Figure 23Figure 24Figure 2526). In males, these include: the presence of small upright socii, usually held appressed to the uncus; a small, simple acute uncus; a quadrate valva apex; and a large, delicate BO. The base of the female corpus bursae shows a broadly sclerotized dorsal area, bearing longitudinal striae.

Within this clade, only two species show conspicuous FW markings (pls. 1, 2)—S. fulviceps and S. quadripunctata—both of which exhibit small, white FW spots. All other Flavicapilla Group species possess uniformly gray forewings. The HW typically shows a white central area and a wide gray band along the outer margin. Exceptions include, S. flavicapilla, S. signata and S. venata, in which the HW is diffuse whitish gray.

KEY TO FLAVICAPILLA GROUP SPECIES

1. Forewing uniformly gray to gray-brown (pls. 1, 2), veins lighter, FW rarely (venata) mottled gray-brown with a series of darker, wavy transverse lines5

FW gray to dark blackish gray (pls. 1, 2), with a conspicuous, white ovoid spot beyond DC, spot straddling stem of M3+CuA12

2. FW with a pair of small, white basal dashes in addition to ovoid spot, one in DC along its anterior margin and a second closer to base, posterior to anal fold; HW central area uniformly white4

FW without white basal dashes in addition to white spot on M3+CuA1; HW central area whitish, either veins lined with gray scales as they pass through, or central area suffused with gray3

3. Head gray; FW and HW ground color blackish gray; cubital veins in white central area of HW blackish gray as they pass through (Guyana Shield S to Brazil)fusciceps Warren

Head yellow; FW and HW ground color gray to light gray; white central area of HW suffused with gray scales (Guyana)abstracta Prout

4. FW dorsal surface with four maculations, two small white basal dashes and two round distal spots, the posterior one (on M3+CuA1) larger; FW ventral surface with a single basal dash and two distal spots (S Venezuela, Brazil)quadripuncta, sp. nov.

FW dorsal surface with three maculations, two small white basal dashes and a single round white spot on M3+CuA1; FW ventral surface with a single, round distal spot on M3+CuA1 (Amazon Basin)fulviceps (C. and R. Felder)

5. Hind wing slate gray, central area sometimes slightly lighter; wings short (FW length  =  11.5–14.5 mm)6

HW mostly white, margin broadly banded with gray; wings moderate in length (FW length  =  13.5–17.5 mm)8

6. Labial palpi, front and vertex uniformly bright, yellow-orange; FW gray-brown, without obvious pattern; body gray with a bluish iridescence7

Labial palpi and front light brown, vertex light yellowish brown; FW glossy gray-brown with a pair of darker brown, wavy transverse lines in basal fourth and in distal three-quarters; body glossy gray-brown (Brazil)venata (Butler)

7. Forewing with an ovoid fascia beyond DC (pl. 2), veins contrasting golden brown; male St8 with a V-shaped mesal excavation (fig. 26B); socii longer than uncus (fig. 26A); DS (fig. 26E) attached to a large dorsal appendix on CB (W Ecuador)occidentalis, sp. nov.

FW without a fascia (pl. 1), veins inconspicuous light gray; male St8 with a U-shaped mesal excavation (fig. 22B), socii barely longer than uncus (fig. 22A); DS (fig. 22C) attached to a small dorsal appendix on CB (Guyana Shield and Brazil)flavicapilla (Hübner)

8. Hind wing anal margin broadly gray (pls. 1, 2)9

HW anal margin white (pl. 1) (W Brazil, E Peru)niveilimba nom. nov.

9. Hind wing central area evenly white; DS sclerotized where it arises from CB (figs. 24E, 25C); socii lightly covered with setae (figs. 24A, 25A), apicies not acute10

HW central area lightly suffused with gray; base of DS membranous where is arises from CB; socii forming narrow, parallel upright wedges, apices acute; socii densely covered with fine pubescence (Guyana Shield S to Brazil and E Peru)intermedia Warren

10. Forewing veins gray, barely contrasting with darker gray ground color (pl. 1); socii divergent at apices (fig. 25A); sclerotized base of CB (fig. 25C) with a few fine striae (Venezuela and Colombia S to E Bolivia and W Brazil)nervosa Schaus

FW veins buff colored, strongly contrasting with slate-gray ground color (pl. 2); socii appressed, not divergent at apices; sclerotized base of CB (fig. 24E) with numerous course striae (Mexico S to Panama)leucophleps Warren

SPECIES INCLUDED AND MATERIAL EXAMINED

Scotura abstracta Prout, revised status

Plate 1

Scotura abstracta Prout, 1918: 408.

Type Locality

Guyana, Rio Demerara.

Type

Holotype ♀ (BMNH).

Discussion

Prout described abstracta as a subspecies of Scotura fulviceps C. and R. Felder (pl. 1) in which the FW has “both the proximal white spots wanting” (1918: 408), and the HW has “the white patch above blackened on the veins and in places dusted with blackish”. Subsequent authors regarded abstracta as a synonym of fulviceps (Hering, 1925; Bryk, 1930). After comparing genital dissections for S. abstracta and S. fulviceps, I here elevate the former to species status for the first time.

This taxon can easily be distinguished from S. fulviceps because, as Prout had noted, it lacks the two white basal FW spots. Instead, S. abstracta more closely resembles S. fusciceps (pl. 1). The FW dorsal and ventral surfaces of abstracta and fusciceps show a single, round white spot straddling the stem of M3+CuA1. Scotura abstracta and S. fusciceps are easy to distinguish because the head of S. abstracta is yellow, typical of most Scotura, whereas the head of S. fusciceps is gray. The latter is a larger and darker moth as well. Other than the BMNH holotype, the only material of S. abstracta I have seen is a series of two males and six females at the USNM, all collected in March 1912, on the Rio Potaro in Guyana. Scotura abstracta is so far known exclusively from Guyana, but S. fusciceps has been collected at locations across the Guyana Shield and into Amazonian Brazil.

Distribution

Guyana (BMNH, USNM).

Dissected

♂, Guyana, Tumatumari, Rio Potaro, Mar 1912, USNM (JSM-1157); ♀, Guyana, Tumatumari, Rio Potaro, Mar 1912, USNM (JSM-1158).

Scotura flavicapilla (Hübner)

Figures 10B, 22; plate 1, plate 36A [EX]

Atolmis flavicapilla Hübner 1823: pl. 393 (pl. 180), figs. 1–4.

Type Locality

Suriname.

Type

Not seen.

Scotura pyraloides Walker, 1854: 525.

Type Locality

Brazil, Pará.

Type

Syntype ♂, Bates Collection (BMNH).

Brachyglene uniformis Möschler, 1877: 657, pl. 9, fig. 25.

Type Locality

Suriname.

Type

Holotype ♀; not seen.

Discussion

The moth with which S. flavicapilla (pl. 1) could most easily be confused is the newly described S. occidentalis (pl. 2). Both have a brownish gray FW lacking obvious pattern, along with a slate-gray HW. They can be separated because the FW of occidentalis shows a diffuse fascia beyond the DC and light-colored veins; the FW in flavicapilla is featureless. Male and female genitalia in the two differ vastly (compare figs. 22, 26). Scotura flavicapilla is widespread throughout the Guyana Shield and Amazon Basin, whereas S. occidentalis is known from a small region in southwestern Ecuador (fig. 27).

Hübner's type of flavicapilla was not found. The type locality cited here (Suriname) is based on a note in Prout (1918: 408), whose source is unknown. Nevertheless, the identity of S. flavicapilla is not in doubt, being firmly established by Hübner's accurate color plate (pl. 180, figs. 14). My study of Walker's BMNH type of pyraloides confirms it to be conspecific with flavicapilla (Bryk, 1930). I was unable to locate the type of uniformis Möschler, and so retain that name as a synonym of flavicapilla following previous authors (see Bryk, 1930).

Caterpillars of S. flavicapilla (pl. 36A) were discovered feeding on Rinorea macrocarpa (Violaceae) in the forest understory of western French Guiana, near St. Laurent (table 4). Preserved larvae and pupae are deposited at the AMNH.

Distribution

French Guiana (AMNH, BMNH, NMW); Suriname (CUIC, ZMH); Guyana (USNM); Brazil (AMNH, BMNH, CMNH, CUIC, LACM, NMW, USNM, VOB, ZMH).

Dissected

♂, Suriname, Moengo, Boven, Cottica R., CUIC (genitalia slide no. JSM-154); ♂, French Guiana, Rt. des Mines, 12 km S St. Laurent du Maroni, leg. J.S. Miller, L.D. Otero and C. Snyder, ex larva on Rinorea sp., rearing lot #D94-10, AMNH (genitalia slide no. JSM-807); ♀, Suriname, Moengo, Boven, Cottica R., CUIC (genitalia slide no. JSM-155); ♀, Brazil, Pará, USNM (genitalia slide no. JSM-808).

Scotura fulviceps (C. and R. Felder)

Figure 23A–D; plate 1

Cymopsis fulviceps C. and R. Felder, 1874: pl. 105, fig. 25.

Type Locality

Brazil, Amazon River.

Type

Holotype ♂, Bates Collection (BMNH).

Pseuderbessa caresa Druce, 1885b: 535.

Type Locality

“Ecuador” [Peru].

Type

Syntype ♂, leg. Whitely (BMNH).

Scotura distinguenda Prout, 1918: 408. New synonymy.

Type Locality

Brazil, Upper Amazon, Fonte Boa.

Type

Syntype ♀, leg. S.M. Klages, Aug 1907 (BMNH).

Discussion

A specimen at the BMNH bears labels establishing it as the C. and R. Felder fulviceps type. Unfortunately, this specimen has had an abdomen glued to it that undoubtedly came from a different moth altogether; the re-attached, iridescent blue abdomen does not match the thorax and wings of fulviceps in either size or color. Furthermore, the genitalia of this abdomen are missing. Nevertheless, the Felder “Frankenmoth” type is sufficiently intact to establish the identity of fulviceps with certainty.

I here describe the new species S. quadripuncta, previously regarded as an aberration of fulviceps (Bryk (1930). This move is based on differences in genital morphology. Scotura fulviceps shows a wing pattern similar to that of S. quadripuncta; both exhibit a conspicuous white FW spot beyond the DC, as well a pair of small white dashes near the wing base. The two taxa differ most obviously by the presence of three FW spots in fulviceps, but four in quadripuncta (pl. 1).

Druce (1885b) described caresa as a species, but it was later made a synonym of fulviceps (Prout, 1918). My studies support that proposal. Furthermore, according to Prout, his species S. distinguenda differs from fulviceps in being larger, and in having coloration that is “dark sepia rather than black” (Prout, 1918: 48). I studied the type of Scotura distinguenda, but did not dissect it. My dissected material (JSM-1148, 1149) matches the distinguenda wing pattern precisely, and was collected at the type locality (Fonte Boa). Comparison of these preparations with dissected material of fulviceps provides convincing evidence that distinguenda is a newly recognized synonym. The BMNH holdings of “distinguenda” consist of two female syntypes, bearing identical label data.

According to K. Willmott (personal commun.), material at the BMNH collected by Whitely and labeled “Ecuador” was actually collected near the mouth of the Río Napo in Peru. The type locality for caresa (Druce) would thus be in Peru.

Distribution

Brazil (AMNH, BMNH, CMNH, CUIC, LACM, NMW, USNM, VOB); Guyana (BMNH, USNM); Peru (BMNH).

Dissected

♂, Brazil, Mouth Río Teffé/Río Solimoes, 5 Sep 1920, Cornell U. Exped. Lot 607 Sub 176, CUIC (genitalia slide no. JSM-1141); ♂, Brazil, Amazonas, Fonte Boa, leg. Fassl, USNM (genitalia slide no. JSM-1148); ♀, Brazil, Mouth Río Teffé‚/Río Solimoes, 2 Sep 1920, Cornell U. Exped. Lot 607 Sub 172, CUIC (wing slide JSM-183, genitalia slide no. JSM-156); ♀, Brazil, Amazonas, Fonte Boa, leg. Fassl, USNM (genitalia slide no. JSM-1149).

Scotura fusciceps Warren

Plate 1

Scotura fusciceps Warren, 1909: 73.

Type Locality

Brazil, Amazonas, Fonte Boa.

Type

Holotype ♂, leg. S.M. Klages, Jul 1906 (BMNH).

Scotura obstructa Warren, 1909: 73.

Type Locality

Brazil, Amazonas, Fonte Boa.

Type

Holotype ♂, leg. S.M. Klages, Jul 1907 (BMNH).

Discussion

Scotura fusciceps is extremely rare; I know of only three specimens other than the BMNH type. J.A. Cerda, who has spent years collecting at Camp Patawa in French Guiana, captured two of these and kindly donated them to the AMNH. The other example is a male at the NMW, from Taperinha, Brazil. Scotura fusciceps and S. nigricaput (pl. 1), the latter a member of the Auriceps Group, are the only Scotura species in which the vertex is not yellow. In both the head is instead slate gray, concolorous with the rest of the body.

Warren (1909: 73), when he described S. fusciceps, also described an “aberration” named obstructa. The type label data for these two differ only in that fusciceps was collected at Fonte Boa in July 1906, whereas obstructa was collected at the same site in July 1907. My own study of types supports Warren's hypothesis; obstructa, which lacks the white FW fascia on the dorsal surface but shows it below, is correctly regarded as a synonym of fusciceps. Other body characteristics of the two are identical.

Distribution

Brazil (BMNH, NMW); French Guiana (AMNH); Guyana (BMNH).

Dissected

♂, French Guiana, Kaw, Camp Patawa, 4°32′30″N, 52°9′W, 29 Apr 1994, leg. J.A. Cerda, (piège lumineux), ex Musaeo B. Hermier, AMNH (genitalia slide no. JSM-811); ♀, French Guiana, Kaw, Camp Patawa, 4°32′30″N, 52°9′W, 19 May 1993, leg. J.A. Cerda, at light, AMNH (genitalia slide no. JSM-812).

Scotura intermedia Warren, revised status

Plate 1

Scotura intermedia Warren, 1909: 73.

Type Locality

Suriname, Aroewarwa Creek, Maroewym Valley.

Type

Syntype ♂, leg. Klages, Jul–Sep 1905 (BMNH).

Discussion

Although Warren (1909) described intermedia as a valid species, subsequent authors considered it a subspecies of nervosa (Prout, 1918; Hering, 1925; Bryk, 1930). Genital differences demonstrate that S. intermedia is in fact distinct from S. nervosa, and I here raise it back to species status. The two appear to be sympatric almost throughout their ranges. They can be separated because the body of S. intermedia shows a faint blue-gray iridescence, especially in the HW, whereas S. nervosa is brownish gray, without a bluish cast. Their male genitalia differ most notably in the shape of the socii—divergent at their apices in nervosa, but straight and approximate in intermedia. Females differ in that the base of the ductus seminalis, where it arises from the corpus, is membranous in intermedia but sclerotized in nervosa.

This diagnosis sounds straightforward, but attempts to apply it to a range of material produced frustration. My conclusions are summarized in the discussion for nervosa (below). More work is required before the taxonomy of these species can be fully understood. I would note here the surprising conclusion that genital similarities indicate a closer relationship between intermedia and fulviceps, two moths with divergent wing patterns (pl. 1), than between intermedia and nervosa, which have extremely similar wings.

During a 1996 expedition to Tambopata Reserve, Peru, I discovered that caterpillars of Scotura intermedia were common on several Rinorea species living in the forest understory. A host-plant association with the violaceous genera Rinorea and Hybanthus has so far been reported in five species of Scotura (table 4).

Although there is a strong possibility that the name peruviana Hering belongs with intermedia, rather than as a synonym of nervosa, I have not made that change since my knowledge of Hering's taxon is inadequate.

Distribution

Suriname (BMNH, CUIC); French Guiana (AMNH, BHC, BMNH, USNM); Guyana (CUIC); Brazil (AMNH, NMW); Peru (AMNH).

Dissected

♂, French Guiana, Route de Kaw, D6, pk 38 (spk 1.8 from Camp Patawa), 04°33′N, 52°08′W, 250 m, 11 Sep 2004, leg. P. Green, S. Rab Green, B. Hermier, MV light, AMNH (genitalia slide no. JSM-1613); ♂, Brazil, Rondônia, 62 km S Ariquemes, Fazenda Rancho Grande, 165 m, 10°32′S, 62°48′W, 18–29 Sep 1996, leg. Ron Leuschner, AMNH (genitalia slide no. JSM-908); ♀, French Guiana, Route de Kaw, D6, pk 38 (spk 1.8 from Camp Patawa), 04°33′N, 52°08′W, 250 m, 11 Sep 2004, leg. P. Green, S. Rab Green, B. Hermier, MV light, AMNH (genitalia slide no. JSM-1614); ♀, French Guiana, St. Jean du Maroni, Dognin Collection, USNM (genitalia slide no. JSM-1155).

Scotura leucophleps Warren, revised status

Figure 24; plate 2 [EX]

Scotura leucophleps Warren, 1909: 74.

Type Locality

Costa Rica, Tuis.

Type

Holotype ♂ (BMNH).

Discussion

All authors subsequent to Warren (1909), who described Scotura leucophleps as a species, have regarded it to be a subspecies of S. nervosa (Prout 1918; Hering, 1925; Bryk, 1930). However, the genitalia of S. leucophleps (fig. 24) differ from those of S. nervosa (fig. 25), especially in the configuration of the male socii/uncus complex. Furthermore, in leucophleps the light, whitish-gray scales lining the FW veins show more contrast with the wing ground color, and the moths are slightly larger than nervosa. Based on these differences, I reinstate leucophleps to species status.

I have not dissected material of so-called nervosa from Colombia to see whether examples from that country might be conspecific with S. leucophleps. At present, the known range of S. leucophleps extends from Panama north at least as far as Nicaragua. Specimens from Mexico (CAS collection) also appear to be conspecific with leucophleps, which would extend the species' range even further. However, I have not verified the identity of Mexican material by dissections.

In 1994, while doing fieldwork in Panama, Cal Snyder (AMNH) discovered caterpillars of Scotura leucophleps feeding on Rinorea panamensis (Violaceae). The moth is associated with Rinorea squamata and R. deflexiflora in Costa Rica (table 4).

Distribution

Mexico (CAS); Nicaragua (CMNH, LACM, NMW); Costa Rica (AMNH, BMNH, NMW, INBio); Panama (AMNH, CUIC, LACM, ZMH).

Dissected

♂, Costa Rica, Limón, 9.4 km W Bribri, Suretka, 200 m, 9–11 Jun 1983, leg. D.H. Janzen and W. Hallwachs, INBio (genitalia slide no. JSM-445); ♀, Costa Rica, San José, Parque Braulio Carrillo, La Montura, 1150 m, 27 Jul 1982, leg. P.J. DeVries, AMNH (genitalia slide no. JSM-446).

Scotura nervosa Schaus

Figures 10A, 11, 12B, 12C, 25; plate 1

Scotura nervosa Schaus, 1896: 154.

Type Locality

Venezuela, Aroa.

Type

Syntype ♀, Wm. Schaus Collection (USNM type no. 11581).

Scotura distincta Hering, 1925: 510.

Type Locality

Brazil, São Paulo.

Type

Syntype ♂ (ZMH).

Scotura peruviana Hering, 1925: 510.

Type Locality

Peru, Huayabamba.

Type

Holotype ♀ (ZMH).

Scotura retracta Hering, 1925: 510.

Type Locality

“Colombia”.

Type

Holotype ♂ (ZMH).

Discussion

Specimens identified as Scotura nervosa are common in museum and private collections worldwide. However, these identifications are in many cases incorrect; the material often represents a composite of taxa. Resolving boundaries within this species complex is beyond the scope of the present work. However, I have attempted to stabilize the situation to some degree.

First, I have raised three taxa (S. intermedia Warren, S. leucophleps Warren, and S. nigrata Warren), all formerly treated as subspecies of nervosa (Bryk, 1930), to species status. This is based on comparison of wing venation and genital morphology with the structures of S. nervosa. One of the newly reinstated names, S. nigrata, is not closely related to nervosa and belongs in the Auriceps Group. Scotura leucophleps is exclusively Central American, whereas nervosa is restricted to South America.

Separating the final species pair—S. nervosa and S. intermedia—is extremely difficult. The two seem to co-occur throughout South America. Material from near the respective type localities can be separated based on male-female genital differences, but my attempts to separate examples from other regions without performing dissections have met with frustration. For the time being, I can say with a mild degree of confidence that the geographic range of S. nervosa extends from northern Venezuela west to Colombia, and south along the Upper Amazon Basin at least as far as Fonte Boa, Brazil. Scotura intermedia, on the other hand, appears to be somewhat more eastern in distribution, occurring across the Guyana Shield and south into Brazil. However, it is also broadly distributed in the western part of the Amazon Basin, including Rondônia and the Madre de Dios of Peru.

I am unable to address the status of the three remaining nervosa synonyms—distincta, peruviana, and retracta—all of which were described by Hering. Whether any of these constitute valid species must await dissection of the types, as well as detailed comparison with additional material.

Distribution

Venezuela (AMNH, BMNH, USNM, ZMH); Colombia (BMNH, NMW, ZMH); Ecuador (AMNH, LACM); Peru (AMNH, BMNH, CUIC, LACM, ZMH); Bolivia (BMNH, CUIC); Brazil (AMNH, BMNH, CUIC, LACM, ZMH).

Dissected

Syntype ♀ of nervosa (genitalia slide no. JSM-1152); ♂, Venezuela, Aroa, USNM (genitalia slide no. JSM-1153); ♂, Brazil, Ygarapè Preto, Upp. Amazons, Sep 1935, leg. S. Waehner, BMNH (genitalia slide no. JSM-809); ♂, Colombia, Cauca Valley, F.C. Nicholas, AMNH (wing slide no. JSM-182, genitalia slide no. JSM-157); ♂, French Guiana, USNM (wing slide no. JSM-1164); ♂, Ecuador, Napo, Tena, Río Misahuallí, 2100 ft, 1 Nov 1988, leg. J.S. Miller, blk. lt., AMNH (genitalia slide no. JSM-1156); ♂, Brazil, Amazonas, Fonte Boa, USNM (genitalia slide no. JSM-769); ♀, Brazil, Amazonas, São Paulo de Olivença, Nov–Dec, leg. Fassl, USNM (genitalia slide no. JSM-1530); ♀, Brazil, Amazonas, São Paulo de Olivença, leg. M. de Mathan, BMNH (genitalia slide no. JSM-810); ♀, Brazil, Rondônia, 62 km S Ariquemes, Fazenda Rancho Grande, 165 m, 10°32′S, 62°48′W, 9–18 Apr 1997, leg. E. Quinter, AMNH (genitalia slide no. JSM-909).

Scotura niveilimba Miller, nom. nov.

Plate 1

Scotura venata Butler, 1878: 60.

Type Locality

Brazil, Amazonas, Rio Juruá.

Type

Holotype ♀, leg. 4 Nov 1874, light (BMNH).

Discussion

Scotura venata Butler (1878) becomes a junior secondary homonym of Scotura venata (Butler, 1877a), since I have here moved the latter from Oricia to Scotura. For Butler's 1878 species I propose the replacement name Scotura niveilimba, nom. nov. The Scotura venata type (pl. 1)—now the type of S. niveilimba—exhibits a wing pattern similar to those of S. nervosa and S. intermedia. It differs in that the entire HW anal margin is white, whereas this region is dark gray in the others. I have not dissected the venata type. Ultimately, niveilimba may be revealed as a synonym of either nervosa or intermedia. Understanding taxonomic relationships among species in this complex is an extremely difficult problem, the resolution of which I leave to future work.

Etymology

This name comes from a combination of the Latin adjective niveus (“snowy”) and limbus (“border” or “hem”), referring to the white HW margin in this species, a trait that distinguishes niveilimba from Scotura nervosa and it relatives.

Distribution

Brazil (BMNH); Peru (CMNH).

Dissected

None.

Scotura occidentalis, new species

Figures 26, 27; plate 2

Diagnosis

The wing pattern of Scotura occidentalis (pl. 2) shows similarities to S. flavicapilla (pl. 1). In both species, the FW is uniformly brownish gray and the HW is slate gray, without a white central area. Differences between the two are subtle but consistent. One distinguishing feature is that the golden brown to buff-colored FW veins in S. occidentalis stand out slightly against the ground color, whereas the light gray FW veins in S. flavicapilla are almost concolorous with the wing. Furthermore, the FW in occidentalis exhibits a diffuse fascia beyond the DC. In males this fascia is sparsely scaled, and the swollen, buff-colored veins of the stridulatory organ—the bases of M1 and M2—contrast with the wing. Although a stridulatory organ is present, no light-colored FW fascia can be seen in S. flavicapilla.

Among the numerous male and female genital differences between S. occidentalis (fig. 26) and S. flavicapilla (fig. 22) are the following: posterior margin of male St8 with a V-shaped mesal excavation in occidentalis, U-shaped in flavicapilla; male socii longer than uncus, apices acute in occidentalis, socii shorter than uncus, apices blunt in flavicapilla; female corpus bursae in occidentalis an elongate oval with a wide sclerotized band, bearing deep folds across midsection, CB in flavicapilla almost round, with a small, faint sclerotized band near base; ductus seminalis attached to a large dorsal appendix at base of CB in occidentalis, attached to a small appendix in flavicapilla.

The geographical ranges of S. occidentalis and S. flavicapilla are widely divergent, with the new species known from a restricted region in southwestern Ecuador, while flavicapilla is broadly distributed across the Amazon Basin, from the Guyana Shield south to Peru and Brazil.

Description

Male. Forewing length  =  13.0–14.0 mm. Head: Labial palpus relatively short, curving upward to immediately above clypeus well below middle of front, palpus held close to front, all segments lemon yellow to bright orange-yellow; Lp1 moderately long, curving gently upward, ventral scales long, forming an irregular ridge below; Lp2 slightly over one and a half times as long as Lp1, wide, closely scaled but with longer scales along venter; Lp3 extremely short, bullet shaped; front lemon yellow to bright orange-yellow, scales pointing downward below antennal bases, then swooping horizontally toward midline; occiput covered with erect, gray to gray-brown scales; eye extremely large, rounded outward, gena absent, that area obscured by bulging eye; vertex covered with long, semierect, forward pointing lemon yellow to orange-yellow scales; antenna ciliate, pectinations absent, ventral surface densely covered with setae; scape lemon yellow to orange-yellow, slightly lighter ventrally; dorsum of antennal shaft tightly covered with appressed, glossy gray scales.

Thorax: Inner surfaces of legs light brownish gray, outer surfaces slate gray with a faint blue iridescence; pleuron covered with long, hairlike, light gray-brown and short blue-gray scales; patagium covered with long posteriorly pointing, slate-gray scales, a wide buff-colored band on either side of midline; tegula covered with long, glossy, light gray-brown to blue-gray scales, a buff-colored patch near base; dorsum light gray-brown to buff colored, with a wide, blue-gray stripe along midline; tympanum large, cavity deep, its internal surface scaleless; area surrounding tympanal cavity loosely covered with blue-gray scales, except lower margin scaleless; tympanal membrane large, ovoid, oriented horizontally.

Forewing: (Dorsal) Ground color gray-brown to slate gray to gray-brown (pl. 2), slightly lighter at base; veins lined with buff-colored to golden brown scales; a diffuse, ovoid fascia present immediately beyond DC, its surface more sparsely scaled than rest of wing, bases of M1 and M2 buff colored within fascia. (Ventral) Ground color uniformly blue-gray, veins near outer margin and within fascia pale blue-gray; area of fascia sparsely scaled, surface of fold between bases of M1 and M2 cellophane-like.

Hind wing: (Dorsal) Ground color slate gray to dark gray, with a blue iridescence; scaling sparse in central area of wing, from base to near outer margin. (Ventral) Similar to dorsal surface but ground color lighter; central area broadly covered with silvery white to pale blue-gray scales.

Abdomen: Dorsum glossy slate gray to gray-brown with a blue iridescence; venter light gray to light gray-brown.

Terminalia (figs. 26A–D): Tg8 moderate in size, roughly rectangular, longer than Tg7 but slightly narrower, anterior margin with a pair of short, wide apodemes, one on each side of midline, posterior margin with an extremely wide, quadrate mesal excavation; St8 longer and wider than Tg8, strongly tapered toward distal margin; anterior margin of St8 with a large, robust, tongue-shaped central process extending almost to anterior margin of St7, posterior margin greatly narrowed, with a deep, V-shaped mesal excavation; socii/uncus complex narrow, moderate in size, with a narrow attachment to arms of tegumen; uncus widest at base, gradually tapered, curving slightly downward, apex truncate; socii long and narrow, strongly tapered, extending beyond uncus, socii held close together, apices divergent; arms of tegumen thin, taller than vinculum, strongly narrowed near junction with uncus; arms of vinculum becoming wide ventrally, concave, arms meeting below to form a slightly concave ventral margin; saccus large, triangular, folded upward over valva bases; valva large, mostly membranous; BO extremely large, pleats numerous and long, lateral membrane delicate; costa extremely long and narrow, curving slightly upward, extending to apex; apex sclerotized, quadrate, sharply curved inward, lateral margin of apex bearing a long sclerite, this sclerite narrowing below and curling inward near top of BO; valva bases narrow; juxta wide and tall, bifid, each half tapering strongly dorsally; arms of transtilla narrow, oriented horizontally, then bent sharply downward near midline, arms meeting to form a wide, concave, horizontal sclerite above aedeagus; aedeagus long, relatively wide, cylindrical, slightly constricted in basal fourth; apex of aedeagus bearing an acute dorsal sclerite and a robust toothlike process ventrally; vesica large, widest in basal half, curving upward and narrowing toward apex, bearing a transverse cluster of robust, spinelike cornuti at midpoint, and a large group of deciduous caltrop cornuti in distal half.

Female. Forewing length  =  14.0 mm. Head, thoracic and abdominal characters similar to males, except: antennae thinner, with a dense covering of short setae on ventral surface; wings longer and broader; abdomen wider.

Terminalia (fig. 26E–G): Tg7 wide, narrower distally, anterior and posterior margins simple; St7 large and broad, anterior margin simple, posterior margin slightly convex; Tg8 wide, sclerotized, surface minutely spiculate, posterior margin simple; AA extremely long and thin, curving gently downward; A8 pleuron membranous, a thin sclerotized band along anterior margin; PA moderate in size, surface densely setose, dorsal margin bearing a few longer setae, posterior margin rounded; PP long and thin, almost straight; membrane below PA infolded; DB short and wide, dorsolaterally compressed, anterior portion swollen ventrally; ostium lightly sclerotized, almost membranous; CB large, an elongate oval, its surface strongly rugose, a broad sclerotized band across midsection bearing heavily sclerotized, elongate folds; a narrow, transverse, sclerotized band at CB base, its internal surface irregularly dentate; signum an extremely large, elongate oval with a longitudinal seam, internal surface coarsely dentate; DS attached to a large appendix, located near base of CB along dorsal midline, surface of appendix bearing numerous transverse wrinkles.

Etymology

The name for this species is derived from the Latin word occidentalis, meaning “western”, in reference to the fact that the taxon lives west of the Ecuadorian Andes.

Distribution

Scotura occidentalis is known exclusively from two southern Ecuadorian localities (fig. 27), both in the Pacific lowlands. The southernmost of those, near Zapote in El Oro Province, is located in dry forest at an elevation of 150 meters. The other location is near La Troncal in Cañar Province, approximately 100 km to the north. This second site is somewhat higher in elevation (475 meters) and lies in wet tropical forest. Scotura occidentalis thus appears to be endemic to the fascinating region southeast of Guayaquil. Little forest remains there, with huge expanses of this land planted with bananas, but the region appears to be rich in endemics.

Discussion

The most notable feature of S. occidentalis is its distribution. Scotura occidentalis is the first South American Scotura species known to occur on the Pacific side of the Andes. All the others live in the Amazon Basin into eastern Brazil. It will be interesting to unravel the life history of S. occidentalis to see whether the larvae feed on Rinorea or Hybanthus (Violaceae), the habit typical for Flavicapilla Group species, or whether they are instead associated with a novel host plant.

As is noted in the Diagnosis, S. occidentalis shows wing-pattern similarities to S. flavicapilla. However, numerous genital similarities suggest that, within the Flavicapilla Group, occidentalis is most closely related S. intermedia Warren (pl. 1), a species occurring from northern South America to southern Brazil and the Upper Amazon of Peru. Interestingly, intermedia resembles most other members of Scotura in exhibiting a white HW central area, whereas the HW of occidentalis is gray. Detailed phylogenetic study will be required to further understand relationships among these taxa.

Holotype

Male (pl. 2). Ecuador: El Oro: 2 km W Zapote on rd. to Piedras, 03°38.8′S, 79°53.0′W, 150 m, 9 Mar 2006, leg. J.S. Miller, E. Tapia & S. Rab Green, dry forest, MV light. The type is deposited at the AMNH.

Paratypes

Ecuador: El Oro: 9♂♂ 2 km W Zapote on rd. to Piedras, 03°38.8′S, 79°53.0′W, 150 m, 9 Mar 2006, leg. J.S. Miller, E. Tapia & S. Rab Green, dry forest, MV light, (AMNH; genitalia slide nos. JSM-1642, 1648). Cañar: 1♂, 1♀, 20 km E La Troncal, S 02°28.6′, W 79°16.3′, 475 m, 9 Mar 2003, at light UV/MV, western tropical dry forest, undisturbed, leg. S. Rab Green & M. Tapia (AMNH; genitalia slide no. JSM-1650).

Other Specimens Examined

None.

Dissected

2♂♂, 1♀.

Scotura quadripuncta, new species

Figure 23E–H; plate 1

Diagnosis

Scotura quadripuncta could potentially be confused with S. fulviceps, but is distinguished by having two white FW spots beyond the DC rather than one; S. fulviceps is missing the spot behind the radial sector. Another helpful trait for distinguishing the two species can be found on the abdominal venter: in S. quadripuncta, the venter bears a narrow white stripe along the midline, whereas in S. fulviceps, the venter is broadly buff colored, but it is without a contrasting white stripe.

Scotura quadripuncta and S. fulviceps differ strongly in their male genitalia (fig. 23). Most noticeably, the valva apices are radically different. In addition, the socii of S. fulviceps are gently tapered (fig. 23A), whereas those of S. quadripuncta are digitate (fig. 23E).

Description

Male. FW length  =  12.0 mm. Head: Labial palpus, front, and vertex yellow-orange; occiput light gray-brown; antennal scape yellow-orange, dorsum of shaft covered with glossy, light gray-brown scales; posterior margin of head with a thin white border.

Thorax: legs and pleuron glossy, light gray-brown, with areas of silvery white on T1 and coxa; patagium, tegula, and dorsum gray brown, with a faint blue iridescence; dorsum with a pair of faint white, longitudinal bands.

Forewing: (Dorsal) Ground color light steely gray-brown; a tiny basal dash along cubitus; a pair of small, elongate white basal spots, one within DC, the other between anal fold and 1A+2A; two additional white, elongate-oval spots beyond DC, one between radial sector and M2, the other, slightly larger, between fork of M3+CuA1 and CuA2; DC less than one-third FW length. (Ventral) Similar to dorsal surface, except no white spot within DC, other spots generally larger than on dorsal surface.

Hind wing: (Dorsal) Ground color light steely gray-brown; central area white, forming a large elongate oval. (Ventral) Similar to dorsal surface, white area slightly larger.

Abdomen: Dorsum steely gray-brown; a faint whitish stripe along pleuron; venter with a narrow, white longitudinal stripe along midline.

Terminalia (fig. 23E–H): Tg8 quadrate, anterior margin simple, posterior margin with a wide, shallow excavation; St8 gradually tapered distally, anterior apodeme long, gently contricted, posterior margin bearing a long, narrow U-shaped mesal excavation; apex of uncus truncate, minutely plicate; socii thumblike, slightly longer than uncus; valval costa narrow, almost straight; apex small, slightly concave, rounded distally; aedeagus long and slender, slightly constricted near base; vesica bearing deciduous caltrop cornuti distally, short spinelike cornuti at base.

Female. FW length  =  13.5–14.0 mm. Body coloration similar to males, except white FW spots generally larger.

Etymology

Warren (1909) obviously chose the name quadripuncta in reference to the four white FW spots in this taxon, contrasting it with S. fulviceps, which bears only three (pl. 1). I retain Warren's epithet since it was he who first recognized S. quadripuncta as being novel.

Distribution

This species is known almost exclusively from Amazonian Brazil. A single specimen was captured in southern Venezuela (see below). Its distribution is broadly sympatric with that of S. fulviceps, as well as many other Scotura species for that matter.

Discussion

Warren (1909: 73) named quadripuncta as an aberration of Scotura fulviceps (pl. 1), a status followed by all subsequent authors. According to Warren, the FW of quadripuncta is distinguished from S. fulviceps “in having a fourth white spot beyond the end of cell above the large outer spot”. My dissections show that S. quadripuncta is a species distinct from all other Scotura. Warren's observation is thus honored here, with S. quadripuncta being described as new.

Two wing-pattern phenotypes of S. quadripuncta seem to occur: A single USNM specimen from San Carlos de Río Negro, Venezuela, exhibits a FW identical to other examples of S. quadripuncta on its ventral surface, but the spot at the base of the radial sector is barely perceptible dorsally. Male genitalia (JSM-1150) suggest that this specimen is conspecific with S. quadripuncta.

Holotype

Male (fig. 23E–H). Brazil: Amazonas: Manaus, Reserva Ducke, AM-010, km 0.26, 2°55′S, 59°59′W, 14 Dec 1993, leg. J. Bolling Sullivan & Roger W. Hutchings, 15W UV light trap (Road) (genitalia slide no. JSM-1151). The type is deposited at the AMNH.

Other Material Examined

Brazil: Amazonas: 1♀, Teffé, Sep, leg. Fassl, Dognin Collection (USNM); 1♀, Fonte Boa, Upper Amazon, leg. Klages, May 1906 (BMNH); 2♀♀, Rio Purus, Hyutanahan, leg. S.M. Klages, Feb 1922 (CMNH). Venezuela: Amazonas: 1♂, San Carlos de Río Negro, 1°56′N, 67°03′W, 13–17 Dec 1984, leg. R.L. Brown (USNM; genitalia slide no. JSM-1150).

Dissected

2♂♂.

Scotura signata Hering

Plate 1

Scotura signata Hering 1925: 510.

Type Locality

Brazil, Tomar, Rio Negro.

Type

Holotype ♂ (ZMH).

Discussion

A series of AMNH specimens, collected at Tambopata, Peru, exhibit a uniformly gray FW and a semihyaline HW central area, thus matching the holotype of S. signata with precision. Genitalia in these moths (JSM-865, 866) are indistinguishable from those of flavicapilla. Hering (1925) noted wing pattern similarities between signata and flavicapilla, and implied that the two might be conspecific. However, until Hering's type of signata has been dissected, I retain species status for this taxon. It should be noted that Tambopata Reserve, on the Madre de Dios, is located above the Rio Madeira drainage system, whereas the Rio Negro, type locality for signata, is far removed, in a completely different Amazonian drainage. Type localities this far apart usually signal the existence of separate species.

Distribution

Brazil (ZMH); Peru (AMNH).

Dissected

♂, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′S, 6 Dec 1996, leg. J.S. Miller, C. Snyder, A. Brower, S. Rab Green, at light, AMNH (genitalia slide no. JSM-865); ♀, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′S, 6 Dec 1996, leg. J.S. Miller, C. Snyder, A. Brower, S. Rab Green, at light, AMNH (genitalia slide no. JSM-866).

Scotura venata (Butler), new combination

Plate 2

Stenoplastis venata Butler, 1877a: 359.

Type Locality

Brazil, Espírito Santo.

Type

Syntype ♂ (BMNH).

Scotura discolor Warren, 1906: 412. New synonymy.

Type Locality

Brazil, Rio de Janeiro.

Type

Holotype ♀ (USNM type no. 9170).

Discussion

Prout (1918) moved venata from Stenoplastis—where Butler (1877a) originally described it—to Oricia, and it has remained there ever since. However, morphological characters demonstrate conclusively that the species belongs in Scotura, as a member of the Flavicapilla Group, so Scotura venata (Butler, 1877a) becomes a new combination.

The traits in venata supporting this change include: presence of a FW stridulatory organ, characteristic of Scotura (fig. 12A, B) but not found in Oricia (fig. 31G); presence of a large, enclosed metathoracic tympanum typical of Scotura (fig. 11E, F); the occurrence of a quadrate male valva apex (e.g., fig. 22A); and presence of a large, striate basal sclerite on the female corpus bursa (e.g., fig. 24E). Earlier authors were perhaps misled by the head color of venata, which is light yellow with dusky gray scales, rather than bright yellow as in most Scotura species. Scotura venata is similar to S. delineata (pl. 1) in habitus, but differs considerably in genital morphology.

Aside from type material, I have seen only three series of S. discolor—one in the VOB collection (8♂♂, 6♀♀), one at the NMW (2♀♀), and eight specimens (7♂♂, 1♀) at the ZMH. All of this material was captured in eastern Brazil.

My examination of the female type of Scotura discolor Warren (1906), including study of its genitalia, suggests that this name is a new junior synonym of venata Butler (1877a). Because I have transferred venata Butler (1877a) from Oricia to Scotura, Scotura venata Butler, 1878, is now preoccupied. For the latter I have proposed the replacement name Scotura niveilimba (see above).

Distribution

Brazil (BMNH, NMW, USNM, VOB, ZMH).

Dissected

♂, Brazil, Bahia, Jequié, 600–750 m, 11–22 Nov 1995, leg. V.O. Becker, VOB (genitalia slide no. JSM-1139); ♀, Brazil, Bahia, Jequié, 600–750 m, 11–22 Nov 1995, leg. V.O. Becker, VOB (genitalia slide no. JSM-1140); ♀ type of discolor Warren, USNM (genitalia slide no. JSM-1135).

The following species have been transferred from Scotura:

longipalpata Dognin to Erbessa Walker

ovisigna Prout to Pseudoricia Prout

EREMONIDIA RAWLINS AND MILLLER, 2008

Figures 28Figure 2930; plate 2

Eremonidia Rawlins and Miller, 2008: 205–206. Type Species: Eremonidia mirifica Rawlins and Miller, 2008 (by monotypy).

Figure 28

Morphology of Eremonidia mirifica, sp. nov. ♂. A, head in lateral view; B, wings (A, illustration by J.S. Miller; B, illustration by J. Hyland, CMNH).

i0003-0090-321-1-1-f028.gif

Figure 29

Genitalia of Eremonidia mirifica, sp. nov. (JSM-1804, 1805). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f029.gif

Figure 30

Equally parsimonious cladograms showing relationship of Eremonidia to members of Clade 1 (fig. 7), based on characters of external adult anatomy (see Eremonidia: Discussion).

i0003-0090-321-1-1-f030.gif

Diagnosis

Superficially at least, E. mirifica, the only known species of Eremonidia, resembles moths in the Lithosiinae (Arctiidae), Doidae, or even Crambidae more than it does other dioptines. However, its wing venation (fig. 28B) and metathoracic tympanum instantly betray membership in the Dioptinae. The yellow head, glossy, silvery white FW, and gray-brown HW are unique.

The following wing-venation characteristics are notable: M3 and CuA1 separate in FW, but stalked in HW; male FW bearing a stridulatory organ, but DC much longer than one-third FW length; veins Rs2–Rs4 branching in the pattern 2+[3+4]. The wing venation of Eremonida is suggestive of a relationship with Xenomigia, where males possess a long-celled stridulatory organ (fig. 235G, H). Two traits set Eremonidia and Xenomigia apart. In the latter, M3 and CuA1 are widely separated in the HW, rather than being fused (fig. 28B), and the male antennae of Xenomigia are quadripectinate with long rami, whereas the male antennae of Eremonidia are subserrate. Genitalia characteristics are highly divergent (compare figs. 29 and 237).

Because of its yellow head, Eremonidia could possibly be confused with species in Scotura. However, rather than subserrate antennae, males in Scotura show finely ciliate antennae (figs. 11B, C). In addition, the relatively long, wide labial palpi of Scotura are porrect (fig. 10A). In contrast, the palpi in Eremonidia are short and narrow, curving closely against the head (fig. 28A). Both genera possess a FW stridulatory organ, but in Scotura the DC is short (figs. 12A–D).

Redescription

Male. FW length  =  12.5 mm. Head (fig. 28A): Labial palpus short and thin, curving strongly upward to immediately above clypeus, held close to front; Lp1 moderate in length, curving upward; Lp2 relatively thin, slightly shorter than Lp1; Lp3 short and delicate, conical; proboscis golden brown; scales of front short, pointing dorsomedially, scales becoming longer dorsally, forming a pair of minute tufts between antennal bases; eye large, gena absent, postgena narrow; vertex covered with semierect, forward-pointing scales; antenna subserrate, each flagellomere bearing a pair of densely ciliate, transverse flanges.

Thorax: Epiphysis large, foliate, almost three-fourths length of tibia; tibial spurs moderate in length; tegula relatively short, upper angle rounded distally; tegulae covered with long scales, outer margins fringed with hairlike scales; tympanal cavity extremely large and deep, membrane ovoid, enclosed, oriented horizontally.

Forewing (fig. 28B; pl. 2): Elongate, apical angle acute; vein R1 arising from DC; Rs1 arising from radial sector below Rs2–Rs4; veins Rs2–Rs4 in the pattern 2+[3+4]; M1 separate from radial sector; stridulatory organ present, M1 and M2 swollen at their bases; DC much longer than one-half FW length; M3 widely separate from CuA1.

Hind wing: Broad and full; apical angle rounded; vein M3 short-stalked with CuA1.

Abdomen: Short, gradually tapered, with a small, inconspicuous distal tuft of moderately long scales.

Terminalia (figs. 29A–C, E): Tg8 large, much longer than Tg7, roughly quadrate, slightly narrower posteriorly; St8 relatively short, narrower than St7, anterior margin bearing an extremely large, broadly rounded, saclike apodeme; socii/uncus complex moderate in size, heavily sclerotized, narrowly joined to arms of tegumen; arms of tegumen relatively wide, much taller than vinculum, narrowed at dorsum; arms of vinculum short and wide, convex; valva narrow, BO absent; costa narrow; ventral margin of valva sclerotized; inner surface of valva concave, otherwise featureless, with scattered coarse setae; arms of transtilla narrow, oriented horizontally, meeting above aedeagus to form a large, wide sclerotized plate; juxta moderately large, dorsal margin with a U-shaped mesal excavation; aedeagus relatively large, wide, moderate in length, slightly compressed dorsoventrally; base of aedeagus open, slightly expanded, apical portion curving downward to form a broad ventral point; opercular sclerite small, roughly triangular; vesica moderately long, shorter than aedeagus but slightly wider, bent gently upward; vesica bearing a large mass of deciduous caltrop cornuti along ventral surface, as well as a small, dense patch of nondeciduous spinelike cornuti near base.

Female. FW length  =  12.0 mm. Morphology similar to male, except: labial palpus shorter and thinner, barely ascending above clypeus; eyes smaller; antenna finely ciliate, lacking transverse flanges.

Terminalia (fig. 29D): Tg7 equal in width to Tg6, slightly longer, tapered toward distal margin; St7 equal in width to St6, longer; Tg8 moderately wide, lightly sclerotized along lateral margins, membranous dorsally; AA short, straight; A8 pleuron membranous, a thin, sclerotized band along anterior margin; PA relatively large, mostly membranous, dorsal margin lobate; setae of PA long, those on dorsal lobe longest; PP straight, moderate in length, their bases lightly sclerotized; DB short and wide, strongly dorsoventrally compressed, somewhat concave dorsally; ostium flattened, membranous; CB large, ovoid, completely membranous; signum located anteriorly on ventral surface of CB, internal surface coarsely dentate; DS attached to CB along dorsal midline, slightly less than one-half distance from base; DS thin, not expanded at point of attachment to CB.

Distribution

The two known specimens of E. mirifica were captured in separate mountain ranges, located relatively close together in the southwestern portion of the Dominican Republic, approximately 1 km from the Haitian border. These mountain ranges extend roughly in parallel, running east to west (see Rawlins and Miller, 2008).

Biology

Nothing is known regarding the host-plant relationships or immature stages of Eremonidia.

Discussion

Adult morphology suggests an affinity of Eremonidia with Clade 1 of the Dioptini (fig. 7), comprising Scotura, Cleptophasia, Oricia, and Erbessa. For example, the large, saclike anterior apodeme on male St8 in E. mirifica (fig. 29B) is reminiscent of St8 in Oricia (figs. 32B, 33D, 34D), although this apomorphy does not occur throughout Clade 1. Additional evidence for an affinity with Clade 1 includes possession of an unusually deep metathoracic tympanum, fully enclosing a large, horizontally oriented membrane. The tympanum of Scotura (figs. 11E, 11F, 12G) exemplifies this configuration. Again, morphological evidence is not ironclad; Erbessa exhibits a small, shallow tympanum (figs. 37E, 38H). The female genitalia of Eremonidia are relatively nondescript (fig. 29D), but are extremely similar to those of Erbessa (e.g., fig. 39E). At the very least, female structure confirms the plesiomorphic status of this genus, but provides few additional clues. Similarly, the occurrence of large, deciduous caltrop cornuti on the vesica in E. mirifica males (fig. 29C) supports placement in Clade 1, but offers little information beyond that.

Eremonidia was scored for adult morphological traits (appendix 1). Unfortunately, since only a single male and a single female of E. mirifica are known, it was not possible to sacrifice a specimen to make a whole-body preparation, necessary for scoring internal characters. When Eremonidia, minus characters of internal anatomy, was included in a cladistic analysis of all dioptine exemplars, two equally parsimonious cladograms resulted: Eremonidia is either the sister group to all remaining genera of Clade 1 (fig. 30A), or it is the sister to a subclade of Clade 1, comprising Cleptophasia + Scotura (fig. 30B). To resolve the position of Eremonidia within the Dioptinae, it would be best to perform an analysis that includes features of internal anatomy, as well as characters from DNA; more specimens are needed.

SPECIES INCLUDED AND MATERIAL EXAMINED

Eremonidia mirifica Rawlins and Miller

Figures 28, 29; plate 2

Eremonidia mirifica Rawlins and Miller, 2008: 207.

Type Locality

Dominican Republic, Independencia, Sierra de Neiba.

Type

Holotype ♂, leg. J. Rawlins, R. Davidson, C. Young, S. Thompson, Sierra de Neiba just south of crest, 5 km NNW Angel Feliz, 1780 m, 18-41N, 71-47W, 13–15 Oct 1991, cloud forest (CMNH).

Discussion

Eremonidia mirifica and Caribojosia youngi, both discovered quite recently in the cloud forests of the Sierra de Neiba, Dominican Republic, by CMNH expeditions, are the only members of the Dioptinae confirmed to occur in the Caribbean (Rawlins and Miller, 2008). Prout (1918) and Bryk (1930) listed Ephialtias draconis as occurring in Jamaica, but Todd (1981) concluded that the report is in error. Four Dioptinae have been reported from Trinidad (see appendix 2). One belongs in the Dioptini, while the others are from the Josiini. The Trinidadian josiines—Polyptychia hermieri, Lyces ena, and Josia ligula—are broadly distributed across northern South America, as is Erbessa priverna (Dioptini). Students of biogeography generally regard the fauna of Trinidad as a component of mainland South America (e.g., Wilson, 1988) rather than truly Caribbean, and Dioptinae reflect this hypothesis.

The question is, will more new dioptines be found from the Caribbean? Judging from the surprising discovery of E. mirifica and C. youngi, careful surveys of cloud forests on other islands, especially those with mountain ranges above 1500 meters in elevation, should be undertaken. Particular focus might be paid to habitats such as the Sierra Maestra along the southeastern coast of Cuba and the Blue Mountains of Jamaica.

Distribution

Dominican Republic (CMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1804); paratype ♀, Dominican Republic: La Vega-Monseñor Nouel; 1♀, Loma El Casabito, summit, 19-03N, 70-31W, 1390 m, 19–23 Nov 1992, leg. J. Rawlins, M. Klingler, R. Davidson, S. Thompson, cloud forest, CMNH (genitalia slide no. JSM-1805).

ORICIA WALKER, 1854

Figures 27, 31Figure 32Figure 3334; plates 2, 36C, 36E

Oricia Walker, 1854: 476. Type species: Oricia truncata Walker, 1854 (by monotypy).

Figure 31

Morphology of Oricia (♂♂). A, head of O. truncata, lateral view; B, head of O. truncata, frontal view; C, head of O. truncata, posterior view; D, head of O. phryganeata, lateral view; E, head of O. truncata, lateral view; F, O. truncata tegula; G, O. truncata wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f031.gif

Figure 32

Genitalia of Oricia hillmani, sp. nov. (♂ JSM-1236, ♀ JSM-1364). A, ♂ genitalia; B, ♂ St8; C, ♀ genitalia; D, aedeagus; E, ♂ Tg8, dorsal view.

i0003-0090-321-1-1-f032.gif

Figure 33

Genitalia of Oricia phryganeata (JSM-214, 215). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f033.gif

Figure 34

Genitalia of Oricia homalochroa (JSM-225, 226). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f034.gif

Diagnosis

Oricia is a small genus containing two closely related Central American species—homalochroa and truncata (Truncata Group)—as well as two species from South America—O. phryganeata and O. hillmani (Phryganeata Group). In all four, the eyes are extremely large and the labial palpi are elongate (fig. 31A–E), reaching either to below the middle of the front (Phryganeata Group) or to slightly beyond the antennal bases (Truncata Group). Within Clade 1 (fig. 7), the wing venation of Oricia (fig. 31G) is similar to that of Cleptophasia (fig. 8F): FW and HW veins M3 and CuA1 arise close together at the posterolateral angle of the DC, rather than being stalked as in most Dioptinae; the FW DC is long. Unlike Cleptophasia or Scotura (fig. 12A, B), but similar to Erbessa (fig. 38B, E, F), there is no male stridulatory organ. The proboscis in Oricia is atypical for dioptines in being light yellowish brown, rather than dark brown, a characteristic that helps define the unrelated genus Chrysoglossa, gen. nov. The male abdomen in Oricia is elongate and acute distally.

The two Oricia species groups exhibit quite different wing patterns (pl. 2). Furthermore, male antennal morphology is variable within the genus. Phryganeata Group species have male antennae in which each annulation shows two transverse whirls of setae arising from short flangelike structures. In the Truncata Group, on the other hand, the antennae can either have extremely short, flattened pectinations (O. truncata), or moderately long ones (O. homalochroa).

In general appearance, Oricia species show similarities to members of Erbessa (pls. 2–7), their sister genus. Oricia differs in having FW vein Rs1 stalked with Rs2–Rs4 (fig. 31G), whereas Rs1 arises separately near the anterolateral corner of the DC in Erbessa (figs. 38A, B, E, F). The male antennae of Erbessa are universally ciliate, without pectinations (figs. 36E, 36F, 37B, 37C), whereas those of Oricia exhibit at least some remnant of the pectinations.

Redescription

Male. FW length  =  14.0–19.0 mm. Head (fig. 31A–E): Labial palpus either greatly elongate, extending to antennal base (Truncata Group), or moderately long, reaching to immediately above middle of front (Phryganeata Group); Lp1 long, slightly curved, with a loose, short fringe below; Lp2 extremely long, at least one and a half to two times as long as Lp1; Lp2 with a wide, apical tuft of long scales on dorsal surface; Lp3 short, ovoid or quadrate; scales of front pointing dorsomedially, meeting together between antennal bases; proboscis light yellowish brown; pilifers long and thin; eye extremely large, rounded, bulging outward, ventral margin extending below gena; antenna variable in structure, either each annulation with two whirls of cilia on extremely short, transverse flanges (Phryganeata Group), or antenna bipectinate, with pectinations short and flat (O. truncata), or fairly long (O. homalochroa); antennae sometimes extremely long (Phryganeata Group).

Thorax (fig. 31F): Epiphysis short, wide at base, apex abruptly attenuated; tegula long, approximately two-thirds the length of mesoscutum, a weak sulcus dividing ventral angle from upper portion; tibial spurs long and thin; metathoracic tympanum large, deeply inset, surrounding sclerites either completely covered with scales, or partially scaleless behind; tympanal membrane large, ovoid, enclosed, facing ventrally.

Forewing (fig. 31G; pl. 2): Elongate; vein Rs1 stalked with Rs2–Rs4; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from distal margin of DC near base of Rs1–Rs4, UDC long; stridulatory organ absent; DC much longer than one-half FW length; M3 arising near posterolateral angle of DC, separate from, but approximate to, CuA1; FW either with a long, light yellow triangle in basal two-thirds, gray in distal third (Truncata Group), or FW mottled gray-brown, veins lighter, with an oblique white spot arising from anal margin (Phryganeata Group).

Hind wing (fig. 31G; pl. 2): Full; angle at apex either acute (Phryganeata Group) or rounded (Truncata Group); veins M3 and CuA1 stalked for a short distance, except in truncata, where they arise together from the posterolateral angle of the DC; HW either yellow with a narrow, grayish black margin (Truncata Group), or HW with a white central area and wide gray marginal band (Phryganeata Group).

Abdomen: Long to extremely long, apex acute.

Terminalia (figs. 32A, B, D, E; 33A–D; 34A–D): Tg8 slightly narrower posteriorly, posterior margin simple, anterior margin with a shallow mesal excavation, apodemes absent; St8 ovoid, widest near middle, rounded toward posterior margin; anterior margin with a huge central apodeme, comprising a complex, saclike structure, its posterior margin rounded, its anterior margin broadly tapered; socii/uncus complex fairly small, triangular at base, narrowly attached to tegumen; uncus short, apex blunt; socii either extremely short (Phryganeata Group) or long and thin (Truncata Group); tegumen wide to moderately wide, taller than vinculum; vinculum wide, convex; saccus large, wide, ventral margin gently convex, or concave at midline; upper margin of saccus forming a broad triangle, enclosing valva bases; valvae moderately long, attached tightly to ring in Truncata Group; BO either small with only a few pleats (Truncata Group), or extremely large, occupying at least three-quarters of valva (Phryganeata Group); costa of valva sclerotized, narrow, broadening distally; apical portion of valva forming a sclerotized, earlike structure; a small, straplike lateral sclerite below apex, connecting to upper margin of BO; arms of transtilla narrow, straplike, joining horizontally at midline; aedeagus moderately wide (Phryganeata Group), fairly narrow (O. truncata), or long and narrow, curved downward (O. homalochroa); vesica over half as long as aedeagus, shape variable; vesica with numerous large, deciduous caltrop cornuti, their spines elongate, usually with a few nondeciduous cornuti below those.

Female. FW length  =  16.5–20.5 mm. Head: Similar to males, but labial palpus shorter and thinner, apical tuft on Lp2 absent, Lp3 extremely small; antenna without pectinations, ventral surface densely covered with short cilia.

Thorax: Similar to males, except fore- and hind wings longer and broader; frenulum comprising two or three bristles.

Abdomen: Much shorter and wider than in males.

Terminalia (figs. 32C, 33E, 34E): Tg7 wider at anterior margin, either longer than St7 (Truncata Group), or slightly shorter (Phryganeata Group), anterior and posterior margins simple; St7 large, broad, slightly wider at anterior margin, anterior and posterior margins simple; Tg8 small, lightly sclerotized; anterior apophyses fairly short, straight; A8 pleuron membranous, anterior margin with a narrow, sclerotized band; PP long and thin, straight or bent slightly downward; PA membranous, relatively small, posterior margin rounded or with a small dorsal lobe (O. truncata); PVP moderately large and wide, lightly sclerotized, convex, surface minutely spiculate; region below ostium forming a narrow, transverse, sclerotized band (Phryganeata Group) or membranous (Truncata Group); DB short, dorsoventrally compressed, lightly sclerotized; Truncata Group with a small, dorsolateral appendix at junction of DB and CB, its surface rugulose; CB large, ovoid; signum variable in size and shape, located on ventral surface of CB, ranging from small and ovoid (O. homalochroa) to large and elongate (Phryganeata Group), its internal surface coarsely spiculate; DS arising on dorsum of CB along midline, approximately one-third from base; base of CB in Phryganeata Group broadly sclerotized, with a small central pocket, and at base a small, spiculate fold; entire CB (except for signum) membranous in Truncata Group.

Distribution

The two Oricia species groups do not overlap in distribution. The Truncata Group is known exclusively from Central America, with specimens collected as far north as Veracruz, Mexico, and as far south as Panama. In contrast, Phyganeata Group species are exclusively South American, occurring from Ecuador south to Bolivia. No Oricia specimens have been recorded from Colombia or Venezuela.

Biology

In the Area de Conservación Guanacaste, Costa Rica, caterpillars of Oricia truncata (pl. 36C, E) were discovered feeding on Rinorea squamata (Janzen and Hallwachs, 2008). Rinorea (Violaceae) is used as a host by three other dioptine genera (table 4)—Scotura, Pseudoricia, and Phanoptis (see fig. 356).

Discussion

When Walker (1854: 476) described Oricia, with truncata as the only included species, he suggested that the genus “seems to connect Eulepia with Lithosia”. Eulepia, a synonym of Spiris (Watson et al., 1980), is a genus in the Arctiinae (Arctiidae), while Lithosia is in the arctiid subfamily Lithosiinae. Dioptine taxa such as Oricia have been confounding Lepidoptera taxonomists for over 150 years.

Prout (1918) expanded Walker's generic concept to include six additional names—domina Schaus, homalochroa C. and R. Felder, damalis Schaus, prolifera Walker, phryganeata Warren, and venata Butler. Bryk (1930) placed damalis in synonymy with homalochroa, but otherwise, membership in Oricia has remained unchanged until the present time.

I have transferred two species, formerly in Oricia, to other genera—prolifera (pl. 4) is now in Erbessa, while venata (pl. 2) is now in Scotura. In addition, I consider domina a synonym of truncata. This leaves three previously described taxa in Oricia. I also describe a new species, hillmani, the sister to O. phryganeata. These four species are evenly divided into two subclades—the Truncata and Phryganeata groups.

Even though early dioptine taxonomists largely agreed on the composition of Oricia, the genus exhibits unusually divergent wing patterns, as well as considerable morphological variation. For example, male antennae vary from bipectinate in O. homalochroa of the Truncata Group to ciliate in both species of the Phryganeata Group. Genital morphology is similarly variable, especially across the two species groups.

According to my cladistic analyses, Oricia is the sister genus to Erbessa (fig. 7). Synapomorphies supporting this relationship (appendix 4) come from labial palpus shape, wing venation, and genital structure.

KEY TO ORICIA SPECIES GROUPS

1. Forewing and HW ground color light yellow (pl. 2), with greenish gray-brown markings in distal portions; antenna moderately long, bipectinate, pectinations short or moderately long; labial palpus elongate (fig. 31A, E), extending to antennal base or beyond; male abdomen moderately long (Central America)Truncata Group

FW ground color gray-brown, pattern mottled (pl. 2); HW central area white, with a dark gray outer margin; antenna extremely long (see pl. 2), threadlike, without pectinations, cilia on two, flangelike transverse ridges; labial palpus moderately long (fig. 31D), ascending to middle of front; male abdomen extremely long (South America)Phryganeata Group

SPECIES INCLUDED AND MATERIAL EXAMINED

1. PHRYGANEATA GROUP

This group (pl. 2) contains species with greatly elongate male antennae, mottled brown forewings, and hind wings with a white central area as well as a wide, brown outer margin. The male abdomen is also noticeably long.

KEY TO PHRYGANEATA GROUP SPECIES

1. Palpus with a ventral fringe of lemon yellow to light yellow scales on Lp1; front with dorsolateral triangles of buff-colored scales; HW mostly gray with a small white central area (pl. 2); apex of valva (fig. 32A) truncate, not expanded toward midline (W Ecuador)hillmani, sp. nov.

Lp1 completely gray-brown; front completely gray-brown; HW with a large white central area (pl. 2), outer margin with a gray-brown band, widest at apex and tapered toward anal margin; apex of valva (fig. 33A) broadly expanded toward midline (E Ecuador S to E Bolivia)phryganeata (Warren)

Oricia hillmani, new species

Figures 27, 32; plate 2

Diagnosis

This is the sister species of Oricia phryganeata, the only moth with which it could be confused. The two can be separated by the following body characters: In O. hillmani Lp1 bears a ventral fringe of yellow below, whereas this segment is completely gray-brown in phryganeata; in O. hillmani the gray-brown front has light buff to yellowish scales along its dorsolateral margins, whereas in O. phryganeata the front is entirely gray-brown; in O. hillmani the base of the tegulae and the lateral portions of the patagia are light yellow to yellow-orange, while in O. phryganeata only the tegulae are yellow-orange, the patagia themselves being completely gray-brown; the white FW spot, arising from the midpoint of the anal margin, is small and ovoid in O. phryganeata, reaching forward only as far as the cubitus on the posterior margin of the DC, whereas this white spot is figure-eight shaped in O. hillmani, extending from the FW anal margin forward to the middle of the DC, with a constriction where it crosses the cubitus. Another diagnostic feature separating the two taxa can be seen on the FW below: In hillmani the FW ventral surface is completely dark gray-brown, with no markings at all (though the white figure eight of the upper surface shows through faintly below). The FW ventral surface of phryganeata, on the other hand, shows a diffuse white spot, roughly corresponding with the white dorsal spot along the anal margin near the wing's midpoint.

Perhaps the easiest way to separate the two species is that the HW of hillmani is much darker, with only a small white central area; the rest of the wing, including the anal margin, is gray-brown. The HW of phryganeata is mostly white, with a broad, gray-brown marginal band (widest at the apex) that tapers near the anal fold; the anal margin is white, or sometimes light gray. The two taxa show differences in their male genitalia (compare figs. 32, 33), perhaps the most distinctive involving the shapes of Tg8 and the valva apex.

Description

Male (pl. 2). Forewing length  =  17.0–19.0 mm. Head: Labial palpus moderately long, relatively thin, smoothly curved upward to halfway up front, well short of antennal base; Lp1 long, Lp2 shorter than Lp1, Lp3 short, triangular, with apex acute; Lp1 gray-brown in upper half, a fringe of long, lemon-yellow to light yellow-scales below; Lp2 and Lp3 completely gray-brown; frontal scales pointing in from outer margins, then sweeping upward toward antennal bases to form a cone of scales at midline; central portion of front gray-brown, lateral margins buff to light yellow; occiput completely gray-brown; eye extremely large, bulging; vertex gray-brown, with yellowish to buff colored scales behind antennal bases; antenna ciliate, extremely long and threadlike; scape and dorsum of antennal shaft gray-brown.

Thorax: Legs gray-brown, with inner surfaces whitish to buff colored; spurs gray-brown on outer surfaces, whitish inside; pleuron covered with long, hairlike, light brown to gray-brown scales; patagium light yellow to yellow-orange, interrupted by a small, dark brown spot near cervical region; tegula yellow-orange at base, then covered with long, hairlike, dark brown to gray-brown scales, longest at apex; dorsum broadly dark gray-brown above, with wide, buff colored lateral stripes on either side of midline; tympanal cavity extremely deep, almost completely enclosing membrane; tympanal membrane large, oriented horizontally.

Forewing: (Dorsal) Ground color light chocolate brown; all wing veins lined with light yellow to buff colored scales; SC and base of R1 more widely lined at a point even with distal margin of DC; stem of Rs2+Rs3 more widely lined with buff colored scales; cell formed by M1 anteriorly and M2 posteriorly slightly darker beyond DC; a series of small, diffuse, whitish submarginal dashes present in cells between M1 and M2, M2 and M3, and M3 and CuA1; larger, dentate submarginal dashes in cells between CuA1 and CuA2, as well as CuA2 and 1A+2A; a white spot extending from 1A+2A near anal margin at FW midpoint, forward to middle of DC near its distal margin, spot constricted as it crosses cubitus to form a figure eight; veins Rs3 through 1A+2A with buff-colored lining slightly widened at outer margin; fringe dark gray-brown; stridulatory organ absent; DC long, greater than one-half FW length. (Ventral) Completely dark gray-brown, no maculations of any kind, white figure eight of dorsal surface showing through faintly below; veins R1 through 1A+2A thinly lined with yellowish-brown scales near outer margin.

Hind wing: (Dorsal) Almost entirely gray-brown, slightly lighter along anal margin; a white central area located near distal margin of DC, its anterior margin touching radius, its posterior margin crossing over CuA2; white central area tapered and becoming more diffuse toward wing base; fringe dark gray-brown. (Ventral) Similar to upper surface, except outer band slightly lighter gray-brown, veins lightly lined with buff-colored scales near outer margin.

Abdomen: Greatly elongate; gray-brown above, with a thin, buff-colored stripe along pleuron; sterna gray-brown, with broad, buff-colored transverse bands along anterior margins.

Terminalia (figs. 32A, B, D, E): Sides of Tg8 roughly parallel; anterior margin of Tg8 with a U-shaped, mesal excavation (not present in phryganeata), posterior margin simple; St8 broadly ovoid, widest in anterior third, tapering toward distal margin; anterior margin of St8 with a huge, pocket-shaped, mesal apodeme, posterior margin of pocket only slightly expanded distally (this margin widely expanded in phryganeata); posterior margin of St8 with a deep, V-shaped mesal excavation; uncus extremely short, dorsal surface crenulate; socii small, thumblike, upturned slightly; uncus/socii complex with a narrow attachment to tegumen; tegumen narrow, vinculum wider, expanded below; saccus wide, rounded upward at midline above, with a broad, shallow excavation at midline below; juxta lightly sclerotized, tall, tapered to a point dorsally; valva long, mostly membranous; BO large, greatly expanded below; costa thin, not heavily sclerotized, sides parallel; valva apex forming a sclerotized, cup shaped, quadrate structure, apex not produced inward (apex produced in phryganeata); transtillar arms long, thin, roughly horizontal in orientation, forming a small cup-shaped structure above aedeagus at midline; anal tube extremely long, extending well beyond uncus; aedeagus moderately wide, constricted at base, with a small, digitate ventral process at apex below; vesica fairly large, bearing numerous deciduous caltrop cornuti on posterior surface, each cornutus with one spine greatly elongated; base of vesica on right side with a group of long, spinelike cornuti (the homologous group short in phryganeata).

Female. Forewing length 19.0 mm. Body and wing characters similar to males except labial palpus not quite as long, curving dorsally to immediately above clypeus; antenna thinner than male, long and threadlike; FW somewhat more elongate, slightly longer than male; abdomen shorter, wider.

Terminalia (fig. 32C): CB broadly ovoid; DS arising dorsolaterally on left side near base of CB, with a widened, triangular, membranous base; signum large, elongate, ovoid, coarsely dentate, located ventrally in CB; a large sclerotized area on right side of CB near base, its internal surface “scaly”, with a gentle fold; a second, small sclerotized fold in CB at base, its surface spiculate; DB short, wide, sclerotized; PVP moderately wide, gradually convex, surface spiculate; posterior margin of PVP simple; PA rounded, with a few greatly elongate setae amongst shorter ones; anterior and posterior apophyses thin, straight, moderately long.

Etymology

This species is named in honor of Jan Hillman, who has collected extensively throughout Ecuador. Study of his vast material, deposited in the CMNH collection, Pittsburgh, was invaluable during the course of this project. He collected numerous examples of undescribed Dioptinae, including a paratype of O. hillmani.

Distribution

Oricia hillmani is indigenous to the western slope of the Ecuadorian Andes (fig. 27) at elevations ranging between 250 and 900 meters. Its sister species, O. phryganeata, on the other hand, is known from Ecuador south to Bolivia on the eastern side of the Andes. I have restricted the type series of Oricia hillmani to material collected at Tinalandia, near Santo Domingo de los Colorados. However, the moth has also been captured in the provinces of Esmeraldas and Guayas. Material from the latter site comprises a large series of 21 specimens (LACM) collected by Stuart McKamey near Bucay. Based on the current known distribution of O. hillmani, sampling in southwestern Colombia will provide additional material, thereby extending this species' distribution north.

Discussion

Oricia hillmani appears to be both diurnal and nocturnal; I have collected specimens in the day along forest trails, as well as at MV traps at night. Nothing is known concerning the biology of this species. The Truncata Group has been recorded from Rinorea (table 4), so that genus would be a logical host-plant candidate for the Phryganeata Group as well.

Holotype

Male (pl. 2). Ecuador: Pichincha: Tinalandia, 17 km E Sto. Domingo de los Colorados, 680 m, 16 Mar 2006, MV, leg. J.S. Miller & E. Tapia. The type is deposited at the AMNH.

Paratypes

Ecuador: Pichincha: Tinalandia, 1♂, 700 m, 20 May 1993, leg. J.S. Miller, day-coll. in forest understory (AMNH; genitalia slide no. JSM-1236); 1♀, 19 May 1993, leg. J.S. Miller, at light (AMNH; genitalia slide no. JSM-1394); 1♂, Tinalandia, 2200 ft, 18–20 Apr 1990, leg. J.W. Brown (LACM); 1♂, Tinalandia, 600 m, 16 km E Santo Domingo de los Colorados, 16–20 Apr 1986, leg. Stuart McKamey (LACM); 1♀, Tinalandia, 600 m, 16 km E Santo Domingo de los Colorados, 18–22 Apr 1990, leg. Brian Harris (LACM).

Other Specimens Examined

Ecuador: Esmeraldas: 1♂, 15 km W Río de Cristal near Alto Tambo, 900 m, 6 Dec 1995, leg. J. Hillman, forest remnants (CMNH). Pichincha: 1♀, Hac. Gomez, 32 km E Santo Domingo, 3.8 air km E Unión del Toachi at Río El Transito, 900 m, 18 Aug 1988, leg. S. McKamey (LACM). Guayas: 4♂♂, 17♀♀, Hac. San Juaquín, 4 road km SW Bucay, 250 m, 1–4 May 1986, leg. Stuart McKamey (LACM).

Dissected

1♂, 1♀.

Oricia phryganeata (Warren)

Figures 31D, 33; plate 2 [EX]

Stenoplastis phryganeata Warren, 1907: 200.

Type Locality

Peru, La Union, Río Huacamayo, Carabaya, 2000 ft.

Type

Syntype ♂, leg. G. Ockenden, wet s., Nov 1904 (BMNH).

Discussion

Oricia phryganeata occurs on the eastern slope of the Andes from northern Ecuador south to Bolivia, at elevations between 350 and 1500 meters. Genitalia dissections suggest that specimens collected at the type locality, Carabaya in southeastern Peru near the Bolivian border, are conspecific with material from Ecuador. This represents an extensive geographical range, not typical for the Dioptinae. Its sister species, the newly described O. hillmani, is endemic to western Ecuador (fig. 27). Characters for distinguishing the two taxa are discussed in the diagnosis and description for O. hillmani (above).

Distribution

Ecuador (AMNH, BMNH, CMNH, LACM, MNHN); Peru (BMNH, ZMH); Bolivia (AMNH).

Dissected

♂, Peru, La Union, Río Huacamayo, Carabaya, 2000 ft, wet s., Nov 1904, leg. G. Ockenden, BMNH (genitalia slide no. JSM-214); ♂, Ecuador, Napo, Río Jatunyacu near Tena, 25 km SW Pano, 1200 m, 11 Jul 1994, leg. Jan Hillman, rainforest, CMNH (genitalia slide no. JSM-756); ♂, Ecuador, Napo, Yasuní, 350 m, 6 Mar 1998, leg. G. Onore, AMNH (genitalia slide no. JSM-1395); ♀, Peru, La Union, Río Huacamayo, Carabaya, 2000 ft, wet s., Nov 1904, leg. G. Ockenden, BMNH (genitalia slide no. JSM-215); ♀, Ecuador, Napo, Parque Nacional Yasuní, 1 km SE PUCE station, 13 May 1996, leg. Jan Hillman, edge of virgin forest, CMNH (genitalia slide no. JSM-1396).

2. TRUNCATA GROUP

Truncata Group species (pl. 2), unmistakable with their yellow wings and gray markings, show little pattern similarity to members of the Phryganeata Group. However, morphological synapomorphies abound, and support for Oricia as a clade is strong (fig. 2). Prout (1918) first recognized this relationship.

KEY TO TRUNCATA GROUP SPECIES

1. Veins in greenish-gray distal portion of FW not contrasting (pl. 2); pectinations of male antenna extremely short; apex of valva concave, broadly triangular (fig. 34A); female Tg8 emarginate posteriorly (Mexico S to Panama)homalochroa (C. and R. Felder)

Veins in greenish-gray distal portion of FW contrasting (pl. 2), light yellow; pectinations of male antenna moderately long; apex of valva broadly truncate; female Tg8 simple posteriorly (Guatemala S to Panama)truncata (Walker)

Oricia homalochroa (C. and R. Felder)

Figure 34; plate 2 [EX]

Pyralopsis homalochroa C. and R. Felder, 1874: pl. 105, fig. 13.

Type Locality

Guatemala.

Type

Holotype ♀ (BMNH).

Pyralopsis damalis Schaus, 1912: 432.

Type Locality

Costa Rica, Juan Viñas.

Type

Syntype ♂ (USNM type no. 17115).

Discussion

Oricia homalochroa, a distinctive moth, occurs from Guatemala south to Panama, a distribution roughly congruent with that of its sister species, O. truncata. Oricia homalochroa is unusual in being found on both sides of the Cordillera Central. In Costa Rica, it has been recorded from Tortuguero on the Caribbean coast (LACM), as well as from the Osa Peninsula on the Pacific (AMNH). More typically in the Dioptinae, similar phenotypes occurring on either side of the Cordillera are revealed to be separate species.

The specimen figured as Pyralopsis homalochroa (C. and R. Felder, 1874: pl. 105, fig. 13), housed at the BMNH, is the presumed type. With its label stating simply “Guatemala”, this is the only example of homalochroa I have seen from that country. There are two additional specimens in the BMNH holdings, a male from Costa Rica and a male from Nicaragua. My dissections confirm that damalis Schaus is a synonym of homalochroa.

A specimen of O. homalochroa in the USNM collection bears label data stating “found alive in aircraft from Colombia, 21-IV-92; APHIS No. 93-05668”. This hardly confirms Colombia as a locality for the species, known otherwise exclusively from Central America. On the contrary, the finding suggests that the plane, originating in Colombia, made a stopover somewhere in Central America on its way to the United States, at which time the specimen of O. homalochroa flew in. One could speculate that the stop was related to drug trafficking, making this potentially the first case of forensic entomology involving the Dioptinae.

Distribution

Guatemala (BMNH); Nicaragua (BMNH, PTC); Costa Rica (AMNH, BMNH, INBio, LACM, USNM); Panama (AMNH, MNHN).

Dissected

♂, Costa Rica, Puntarenas, Fila Esquinas, 35 km S Palmar Norte, 150 m, 8°45′ × 83°20′, 7–8 Jan 1983, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-507); ♂, Costa Rica, Limón Prov., Hacienda Tapezco, 29 air km W Tortuguero, 40 m, 10°30′N, 83°47′W, 14 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller & C. Lewis, LACM (genitalia slide no. JSM-225); ♂ type of damalis Schaus, USNM (genitalia slide no. JSM-1234); ♀, Costa Rica, Limón Prov., Hacienda Tapezco, 29 air km W Tortuguero, 40 m, 10°30′N, 83°47′W, 14 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller & C. Lewis, LACM (genitalia slide no. JSM-226); ♀, Panama, Chiriquí, Rte. Gualaca-Fortuna, km 32, Hornito, 1000 m, 4–9 May 1980, leg. Th. Porion, MNHN (genitalia slide no. JSM-506).

Oricia truncata Walker

Figures 31A–C, 31E–G; plates 2, 36C, 36E [EX]

Oricia truncata Walker, 1854: 476.

Type Locality

Honduras.

Type

Syntype ♀, ex Dyson Collection (BMNH).

Oricia domina Schaus, 1912: 433. New synonymy.

Type Locality

Costa Rica, Limón.

Type

Syntype ♀ (USNM type no. 17617).

Discussion

Oricia truncata Walker and O. domina Schaus have historically been treated as separate species. They purportedly differ in the length and shape of the longitudinal yellow FW triangle arising from the wing base (Hering, 1925). In truncata the yellow triangle extends to immediately beyond the end of the discal cell, whereas in domina (pl. 2) the yellow extends to the outer margin of the wing, almost touching it. Having dissected numerous specimens matching both phenotypes, I conclude that they represent a single taxon. There are no differences in male or female genital morphology. Furthermore, there seems to be a continuum of wing patterns at all localities. I dissected truncata-like and domina-like specimens from Costa Rica, and found no morphological differences. The genitalia of the O. domina female syntype (JSM-1233) are identical with those of an O. truncata female from Veracruz, Mexico (JSM-431).

Oricia truncata, a common dioptine species in museum collections, occurs from Mexico south to Panama, but does not range into South America. As with its sister species, O. homalochroa, this taxon is unusual in being found on both sides of the Cordillera Central. For example, Oricia truncata has been captured in Costa Rica at Braulio Carrillo (eastern side) as well as on the Osa Peninsula (western side).

Larvae of Oricia truncata (pl. 36C, E), the only Oricia species for which the life history has been discovered, specialize on Rinorea squamata at the Area de Conservación Guanacaste (table 4). This same Rinorea species is utilized by larvae of Scotura leucophleps, which co-occurs with O. truncata at that site.

A careful search of the BMNH collections in March 2005 uncovered what appears to be Walker's type of O. truncata—a previously unmarked specimen (no type labels attached). That specimen bears a small round label, with the locality given simply as “Honduras” (accession number 45-123), as well as a printed identification label stating “Oricia truncata”. Both labels are typical of the ones found on Walker types.

Distribution

Mexico (AMNH, BMNH, CMNH, FNHM, LACM, NMW, SDNH, UCB, USNM, VOB); Belize (AMNH, LACM, USNM, VOB); Honduras (BMNH, CMNH, CUIC, LACM, BMNH, USNM); Guatemala (BMNH, CMNH, LACM, USNM, VOB); Costa Rica (AMNH, INBio, UCB, USNM); Panama (USNM).

Dissected

♂, Mexico, Chiapas, La Granja, Jun 1931, leg. C.C. Hoffmann, AMNH (genitalia slide no. JSM-145); ♂, Mexico, Chiapas, Palenque, Palenque Ruinas Motel, 4 Jan 1980, leg. R. Holland, at motel lights, AMNH (genitalia slide no. JSM-395); ♂, Mexico, Veracruz, Presidio, Jun, leg. C.C. Hoffmann, AMNH (genitalia slide no. JSM-430); ♂, Costa Rica, Guanacaste, 4 km E Casetilla, Rincón National Park, 750 m, 11 Apr 1983, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-1235); ♂, Costa Rica, San José, Estación Carrillo, Braulio Carrillo National Park, 700 m, Sep 1984, leg. I.A. Chacón, INBio (genitalia slide no. JSM-396); ♂, Costa Rica, Puntarenas, 15.7 km NE Rincón, 600 ft, Osa Peninsula, 25 Mar 1991, leg. J.S. Miller, at light, AMNH (genitalia slide no. JSM-397); ♀, Mexico, Veracruz, Presidio, Sep 1940, leg. C.C. Hoffmann, AMNH (genitalia slide no. JSM-431); ♀, Mexico, Veracruz, Presidio, Jun 1939, leg. C.C. Hoffmann, AMNH (wing slide no. JSM-178, genitalia slide no. JSM-146); ♀ syntype of domina Schaus, USNM (genitalia slide no. JSM-1233).

The following species have been transferred from Oricia:

prolifera Walker 1854 to Erbesssa

venata Butler 1877a to Scotura

ERBESSA WALKER, 1854

Figures 35Figure 36Figure 37Figure 38Figure 39Figure 40Figure 41Figure 42Figure 43Figure 44Figure 45Figure 46Figure 47Figure 48Figure 49Figure 50Figure 5152; plates 2–7, 36D, 36F–I, 37A–D, 37F

Figure 35

Erbessa heads (♂♂). A, E. leechi, lateral view; B, E. prolifera, lateral view; C, E. pyraloides, lateral view; D, E. leechi labial palpus; E, E. lindigii, lateral view; F, E. lindigii, frontal view; G, E. lindigii, posterior view (illustration by J.S. Miller).

i0003-0090-321-1-1-f035.gif

Figure 36

Scanning electron micrographs of Erbessa stroudi, sp. nov. ♂. A, head in lateral view; B, anterior portion of gena, between labial palpus and eye; C, second and third segments of right labial palpus, mesal view; D, apex of labial palpus, mesal view; E, antenna in ventral view, distal at left; F, sensillum styloconicum near distal margin of flagellomere.

i0003-0090-321-1-1-f036.gif

Figure 37

Scanning electron micrographs of Erbessa stroudi male. A, close-up of sensillum styloconicum in fig. 36F; B, antenna in lateral view, distal at right; C, junction of flagellomeres, lateral view; D, sensillum styloconicum from C; E, upper portion of metathorax in lateral view (anterior at left), showing tympanal opening; F, right epiphysis, mesal view.

i0003-0090-321-1-1-f037.gif

Figure 38

Erbessa morphology. A, E. dominula ♀ wings; B, E. leechi ♂ wings; C, E. prolifera tegula; D, E. pyraloides tegula; E, E. cingulina ♂ wings; F, E. prolifera ♂ wings; G, legs of E. pyraloides ♂; H, head, thorax, and A1 of E. lindigii ♂ (illustration by J.S. Miller).

i0003-0090-321-1-1-f038.gif

Figure 39

Genitalia of Erbessa albilinea, sp. nov. (JSM-208, 209). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f039.gif

Figure 40

Costa Rica, showing the known distributions of Erbessa albilinea, sp. nov., and E. stroudi, sp. nov.

i0003-0090-321-1-1-f040.gif

Figure 41

Genitalia of Erbessa labana (♂ JSM-1592, ♀ JSM-1593). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, caltrop cornuti from vesica; E, ♂ St8; F, ♀ genitalia.

i0003-0090-321-1-1-f041.gif

Figure 42

Erbessa genitalia. A, ♂ of E. lamasi, sp. nov. (holotype, JSM-1560); B, aedeagus of E. lamasi; C, ♂ Tg8 of E. lamasi; D, ♂ St8 of E. lamasi; E, ♂ of E. lindigii (JSM-210); F, ♀ of E. lindigii (JSM-211); G, aedeagus of E. lindigii; H, ♂ St8 of E. lindigii.

i0003-0090-321-1-1-f042.gif

Figure 43

Peru, showing the known distributions of Erbessa lamasi, sp. nov., and E. tegyroides, sp. nov.

i0003-0090-321-1-1-f043.gif

Figure 44

Genitalia of Erbessa leechi (JSM-989, 1548). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ genitalia; F, caltrop cornuti of vesica (illustration by J.S. Miller).

i0003-0090-321-1-1-f044.gif

Figure 45

Erbessa genitalia. A, E. papula ♂ (JSM-992); B, ♂ Tg8 of E. papula; C, aedeagus of E. papula; D, ♂ St8 of E. papula; E, ♀ holotype of E. mimica (JSM-323).

i0003-0090-321-1-1-f045.gif

Figure 46

Genitalia of Erbessa prolifera (JSM-212, 213). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f046.gif

Figure 47

Male genitalia of Erbessa pyraloides (JSM-642). A, genitalia; B, aedeagus; C, Tg8; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f047.gif

Figure 48

Genitalia of Erbessa sobria (JSM-398, 399). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f048.gif

Figure 49

Genitalia of Erbessa stroudi, sp. nov. (JSM-1307, 1308). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f049.gif

Figure 50

Genitalia of Erbessa tegyroides, sp. nov. (♂ JSM-1597, ♀ JSM-1598). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia.

i0003-0090-321-1-1-f050.gif

Figure 51

Genitalia of Erbessa thiaucourti, sp. nov. (♂ JSM-1659, ♀ JSM-1660). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia.

i0003-0090-321-1-1-f051.gif

Figure 52

South America, showing the known distributions of Dioptis beckeri, sp. nov., Dioptis fratelloi, sp. nov., Erbessa thiaucourti, sp. nov., and Polypoetes oteroi, sp. nov.

i0003-0090-321-1-1-f052.gif

Erbessa Walker, 1854: 319. Type species: Dioptis sobria Walker, 1854 (by monotypy).

Myonia Walker, 1854: 308. Type species: Josia evippe Walker, 1854 (by monotypy); a junior homonym of Myonia Dana, 1847 (Fossil, Mollusca).

Glissa Walker, 1864: 186. Type species: Glissa bifacies Walker, 1864 (by monotypy).

Diagnosis

Erbessa, containing 60 described species, is one of the largest genera in the subfamily, second only to Polypoetes with 63 (appendix 2). The included species vary greatly in body size, ranging from E. prolifera (pl. 4), the smallest taxon, to E. integra (pl. 7), the largest. Erbessa presents the most striking wing-pattern array of any genus in the Dioptinae (see pls. 2–7), and includes some of the subfamily's most beautiful taxa. The wings can vary from being boldly marked with bright orange or yellow (e.g., pl. 5), to being iridescent blue or hyaline (pl. 7). Judging from this pattern diversity one might initially doubt that Erbessa is monophyletic. However, closer study reveals a tight-knit group, held together by morphological homogeneity.

Most Erbessa species can be recognized by the following suite of traits: labial palpus greatly elongate (fig. 35A–E; fig. 36A), in male ascending to antennal base or beyond, in female extending upward to middle of front, joint between Lp1 and Lp2 elbowed; male and female antenna long, threadlike, ventral surface ciliate (fig. 36E, F; fig. 37B, C); eye moderately large (fig. 35A–C, E–G), gena narrow, surface spiculate (fig. 36B); metathoracic tympanum small, cavity fairly deep (figs. 37E, 38H); FW vein Rs1 arising from DC (fig. 38A, B, E), arising from radial sector in E. prolifera (fig. 38F); FW veins M3 and CuA1 separate; HW veins M3 and CuA1 variable, usually stalked, but approximate in a few species (e.g., E. salvini, E. integra), rarely completely free (E. pales); male abdomen elongate; female abdomen stout.

Erbessa species could potentially be confused with members of Phaeochlaena. Males are easily separable; the antennae in Erbessa are ciliate and the abdomen is long and slender, whereas in Phaeochlaena the male antennae are bipectinate and the abdomen is truncate (pls. 9, 10). Correct placement of females, which exhibit ciliate antennae in both genera, is more difficult. Hind-wing veins M3 and CuA1 are always widely separated at their bases in Phaeochlaena (fig. 70F), but are usually stalked in Erbessa (fig. 38A). Another useful difference can be found in the labial palpi. In both genera the male palpi are extremely long, with an elbowlike joint between Lp1 and Lp2 (compare fig. 35A, B and fig. 70A, B). In Erbessa, even the female palpi are usually folded elbowlike over the front, whereas in Phaeochlaena the female palpi are long, but extend away from the head. The first palpus segment is wide in Erbessa females (and males) whereas Lp1 is relatively narrow in Phaeochlaena (fig. 70B).

Redescription

Male. FW length  =  11.0–26.0 mm. Head (figs. 35, 36, 37A–D): Labial palpus elongate, folded elbowlike over front, extending dorsoposteriorly to antennal base or beyond; Lp1 ovoid, widest near middle; Lp2 extremely long and narrow, curved gradually upward near apex; Lp3 triangular, apex acute, bearing a single, thornlike spicule; eye relatively large, with a narrow scaleless region below; ocular sclerite emarginate ventrally; scales of front long, pointing inward toward midline and slightly upward to form an acute tuft between antennal bases; occiput (and Lp1) frequently clothed with yellow scales; antenna long and threadlike, pectinations absent; ventral surface of each antennal annulation with two transverse bands of setae.

Thorax (fig. 37E, F; fig. 38C, D, G, H): Epiphysis of foreleg small, foliate, apex acute; tegula large, dorsal arm long, frequently covered with yellow scales; metathoracic tympanum small, cavity fairly deep; tympanal membrane small, ovoid, oriented almost horizontally, but tipped slightly upward at lateral margin.

Forewing (fig. 38A, B, E, F; pls. 2–7): Somewhat elongate and narrow, outer margin subtriangular, anterior margin convex; wing veins frequently light colored compared to darker ground color, especially in basal half; Rs1 arising from DC; veins Rs2–Rs4 in the pattern [2+3]+4; stridulatory organ absent; DC longer than one-half FW length; veins M3 and CuA1 separate; wing pattern highly variable, but almost always contrasting and colorful; ventral surface roughly matching dorsal surface, but with light-colored areas larger.

Hind wing (fig. 38A, B, E, F; pls. 2–7): Moderately broad, frequently with a light-colored central area; some species with a contrasting spot near apex; veins M3 and CuA1 almost always stalked, but occasionally approximate, or rarely separate; ventral surface similar to dorsal surface except light-colored areas larger; frequently with a contrasting spot at apex; sometimes with white streaks from base.

Abdomen: Extremely long, often drawn to a narrow caudal point; frequently with longitudinal dorsal and lateral stripes.

Terminalia (figs. 39A–D, 41A–E, 42A–E, 42G, 42H, 44A–D through Figure 45Figure 46Figure 47Figure 48Figure 49Figure 5051A–D): Tg8 rectangular, often with a pair of blunt, rounded apodemes on anterior margin; St8 robust, larger than Tg8, broadly tapering distally, with a narrow, usually deep, medial notch on posterior margin; anterior apodeme of St8 long and robust, gradually tapering toward apex; genitalia with socii/uncus complex small, uncus beak shaped, socii delicate, porrect; tegumen narrow, shorter than vinculum; vinculum extremely wide, concave; ventral margin of genitalia forming a broad U; saccus comprising a large triangular envelope, partially enclosing valva bases; valvae extremely large and membranous, balloonlike, BO occupying almost entire valva; costa narrow, usually parallel-sided; apex of valva with a membranous sac, in some species this sac nearly free from valva, connected only by a thin duct; aedeagus moderate in size, not heavily sclerotized, constricted near base to become goblet shaped, frequently with a groove along dorsal midline; apex of aedeagus with a small ventral tooth; vesica moderate in size, with a series of long, spinelike cornuti basally and a larger series of deciduous caltrop cornuti beyond.

Female. FW length  =  12.5–30.0 mm. Head: Labial palpus shorter than in male, not as strongly elbowed, extending upward to middle of front or slightly above; Lp1 ovoid, widest near middle; Lp2 long, with a slight upward curve; Lp3 short, apex blunt; antenna lacking pectinations, ventral surface covered with short, fine setae. Other head features as in male (above).

Thorax: Similar to male.

Forewing: Broader than in male; pattern usually similar to male, but light-colored areas frequently larger.

Hind wing: Broader than in male but otherwise similar; frenulum comprising approximately six bristles.

Abdomen: Wide and broad, blunt at apex; frequently with dorsal and lateral stripes, as in male.

Terminalia (figs. 39E, 41F, 42F, 44EFigure 4546E, 48EFigure 49Figure 5051E): Tg7 wide, trapezoidal, anterior and posterior margins unmodified; St7 wide, quadrate, slightly narrower caudally, often with a shallow medial excavation along posterior margin, anterior and posterior margins otherwise unmodified; Tg8 relatively wide, not heavily sclerotized, posterior margin not specialized; AA and PP well developed, moderate in length; PVP wide, slightly convex, not elaborate; DB relatively short, lightly sclerotized, dorsoventrally compressed; CB large and ovoid, usually with conspicuous longitudinal folds; corpus bearing a single, oval-shaped signum located ventrally; internal surface of signum covered with prominent spicules; signum size variable, usually quite large, sometimes small; DS arising on dorsal surface of CB approximately one-third of distance from base; basal portion of DS slightly expanded; a pair of elongate to ovoid, lightly melanized sclerites in CB located on either side of DS.

Distribution

Erbessa is essentially a genus of the lowland tropics. The highest recorded elevation is 1800 meters (E. corvica from Bolivia), but the vast majority of species occur between 100 and 500 meters in the Amazon Basin. This appears to coincide with the distribution of the plant genus Miconia (pl. 36J), the most important host for Erbessa (see below).

Biology

Available host records for Erbessa are relatively few; larval food plants for only 10 species (17%) are known (table 4). However, recent discoveries have revealed the importance of Melastomataceae as a host. Eight Erbessa species—from Panama, Venezuela, Ecuador, and Peru—are now known to be associated with this plant family. Miconia (pl. 36J), containing over 1000 species and recognized as one of the largest neotropical plant genera (Gentry, 1993), is the most important host. These plants are abundant in moist and wet forests; at any particular site, it is common to find several Miconia species co-occurring. Henriettea (pl. 47D), the host of Erbessa salvini, and Conostegia, a second host for E. albilinea (table 4), are much smaller melastome genera closely related to Miconia.

The two remaining Erbessa species for which hosts have been reported are associated with very different plants. Erbessa pyraloides, from Brazil, has been recorded on three unrelated plant families—Oleaceae, Leguminoseae, and Myrtaceae (table 4). Of those records, I regard only the third to be well confirmed; larvae of E. pyraloides were observed in vast numbers on introduced Eucalyptus (de Campos and Cure, 1992). Obviously, Eucalyptus is not a natural host for E. pyraloides, but this plant family is utilized by another Erbessa species. Erbessa stroudi, sp. nov., has been discovered feeding on Eugenia valerii (Myrtaceae) at the Area de Conservación Guanacaste in Costa Rica. It is important to continue building the host list for Erbessa to determine whether Melastomataceae-feeders and Myrtaceae-feeders form separate clades.

Erbessa immatures exhibit two interesting morphological features: First, the larvae possess long stemapods on A8 (fig. 358C–E; pl. 36D, F, I; pl. 37A, B, D). These are analogous to the stemapods found in other notodontid subfamilies (Packard, 1895; Miller, 1991; Wagner, 2005), but their morphology differs (Miller, 1991). Within the Dioptinae, stemapods are known to occur in three genera—Erbessa, Phaeochlaena, and Phanoptis (pl. 37G). My cladograms suggest that these taxa do not form a clade (fig. 7), but that stemapods have instead evolved three separate times within the subfamily. The second novel structure occurs in Erbessa pupae. Here, the head exhibits a pair of greatly elongated horns (pl. 36H, 37C). These unusual structures are further mentioned in the Discussion (Future Research), in reference to their potential for providing characters useful for further refining the classification of the Dioptinae.

Discussion

My attempt to divide Erbessa into species groups was unsuccessful. Two factors contribute to this dilemma. First, of the 60 recognized species, male specimens were available for only 35; the remaining 25 taxa are known exclusively from females. The second problem is that genital morphology in Erbessa is monotonous. Female genital structure, a highly effective source of character information in some dioptine genera (e.g., Polypoetes), is tediously similar across all Erbessa species. Even male genitalia, usually regarded as the holy grail for species differences in Lepidoptera, are remarkably uniform. This combination, missing character information along with a scarcity of character information, doomed my efforts to divide the genus into subgroups.

Dioptis stands in sharp contrast to Erbessa. Here, the species exhibit general similarity of wing pattern (pls. 17–21) but dramatic differences in male and female genitalia (e.g., compare figs. 195 and 202). Another interesting contrast between Erbessa and Dioptis involves their geographical distributions. Erbessa species seem to be relatively widespread yet rare, whereas in Dioptis the species are highly localized, but appear to be relatively common at sites where they occur. It will be interesting to discover whether these contrasts reflect underlying biological differences.

In the list of material examined for Erbessa (below), I simply discuss the species in alphabetical order, noting wherever possible my best estimate regarding the taxonomic affinities of each. Erbessa is probably a case where species relationships should be studied using a combined analysis of DNA and morphology. Since there are no species groups, Erbessa species are grouped on the color plates according to wing-pattern similarity. It is hoped that this reflects relationship to some extent.

Seven Erbessa species were originally described in Phaeochlaena, emphasizing the superficial resemblance between the two genera. However, differences, which are noted in the Erbessa diagnosis (above), are numerous. Basic structure of the male and female genitalia in the two genera is wildly different. Generic misplacements have probably occurred when female specimens were the only ones available to the original author, since these are more difficult to assign correctly to genus.

Both Prout (1918) and Hering (1925) divided Erbessa into three subgroups. Hering (1926a) later implied that these constituted subgenera. The first, Dialephtis C. and R. Felder (type  =  salvini C. and R. Felder), contained taxa in which the HW is yellow or white, and the wings lack hyaline areas (e.g., pl. 4). It included 26 taxa, roughly half the species in the genus. The second grouping, Erbessa Walker (type  =  sobria Walker), contained species where the wings are thinly scaled, often with hyaline areas. A total of 11 species, such as the iridescent, clear-winged E. pales and E. capena (pl. 7), were included. The third and final subgroup was Myonia Walker (type  =  evippe Walker), characterized by species with a dark FW and HW ground color (e.g., pl. 3). It totaled 19 species, but included a disparate assemblage. In my opinion, none of these subgroups are tenable. One of the few apomorphic genital features in Erbessa, presence of a small, saclike appendix at the apex of the male valva (Character 249; figs. 45A, 47A, 49A), occurs in various taxa belonging to all three subgroups. Variation within Erbessa regarding whether HW veins M3 and CuA1 are stalked or separate crosses all three subgroup boundaries as well. Based on these observations, I have not employed the Erbessa subgroupings of previous authors here.

It is difficult to explain the phenomenon where Erbessa, at least as reflected in collections, shows a discrepancy in abundance of males and females. In certain taxa, male specimens are unknown and descriptions are based exclusively on females (e.g., E. labana and its apparent relatives). Elsewhere, the opposite situation obtains, with species known only from males (e.g., cingulina, inaria, augusta). In yet others (e.g., priverna, salvini), males and females are collected with equal frequency. My own field experience suggests that Erbessa adults are rare, regardless of their sex. My cladistic analyses suggest that Oricia and Erbessa are sister genera (fig. 7). Six Erbessa species were described by earlier authors in Oricia, an indication of superficial similarities between the two. The two genera differ in palpus shape: Lp1 is wide in Erbessa (fig. 35A–E), but narrow in Oricia (fig. 31A, D, E). Furthermore, Lp3 is ovoid in Oricia, but terminates in a sharp spine in Erbessa. These genera generally differ in the placement of FW vein Rs1, which arises from the DC in Erbessa (fig. 38A, B, E), but is stalked with Rs2–Rs4 in Oricia (fig. 31G). Since prolifera shows Rs1 arising from the radial sector (fig. 38F), it was placed by Prout (1918) in Oricia. However, when all adult morphological characters are taken into account, this species arises within Erbessa, at the base of the genus phylogeny (fig. 3). In my classification, E. prolifera stands apart as the only member of Erbessa in which Rs1 arises from the radial sector.

Watson et al. (1980) pointed out that Myonia Walker is a junior homonym of Myonia Dana, a fossil mollusk. They further noted that Josia evippe (Walker), the type species of Myonia, is congeneric with Dioptis sobria (Walker), the type species of Erbessa, so the latter becomes an available subjective replacement name. Having examined the appropriate types, I here confirm the Watson et al. (1980) proposal. As a result of that nomenclatural change, the species treated by Prout (1918), Hering (1925), and Bryk (1930) as belonging to Myonia are listed below in Erbessa.

Erbessa species exhibit few morphological characters useful for separation. The key below utilizes all the structural differences I could find. However, many of these show variability. The condition of HW veins M3 and CuA1 provides an example: In the vast majority of Erbessa species, and in most Dioptinae, these veins are fused at their bases, forming a long stalk that arises from the posterolateral angle of the DC. In a few Erbessa taxa these veins are touching, but not stalked. However, the two character states can occur in what seem to be closely related species pairs, such as E. biplagiata and E. graba (pl. 5), or E. unimacula and E. celata (pl. 6). The veracity of such differences is thus in doubt. Wing patterns thus emerge as the primary means for separating Erbessa species (pls. 2–7), a notoriously variable character set I have elsewhere tried to avoid. Nevertheless, it is hoped the key below provides a useful starting point for identifying the members of this fascinating genus.

KEY TO THE SPECIES OF ERBESSA

1. Forewing vein Rs1 arising from DC (fig. 38A, B, E)2

FW vein Rs1 stalked with Rs2–Rs4 (fig. 38F)prolifera (Walker)

2. Hind wing veins M3 and CuA1 long stalked from posterolateral angle of DC (fig. 38A, B, E)9

Bases of HW veins M3 and CuA1 touching or separate, not stalked3

3. Midtransverse band of FW and entire central area of HW hyaline (pl. 7); FW and HW ground color dark brown to blackish brown with a blue iridescence4

FW and HW without hyaline areas5

4. Bases of HW veins M3 and CuA1 touching; hyaline transverse band of FW elongate, subapical maculation white; ♂ FW length over 20.0 mmcapena Druce

Bases of HW veins M3 and CuA1 separate; hyaline transverse band of FW not elongate, ovoid, subapical maculation hyaline; ♂ FW length  =  16.0–18.0 mmpales (Druce)

5. Hind wing veins M3 and CuA1 approximate at bases6

HW veins M3 and CuA1 separate at bases; FW long (24.0–30.0 mm); FW orange in basal half with a wide, light yellow transverse band beyond (pl. 7); HW orange; FW and HW with large, dark brown, comma-shaped, marginal bandsintegra (C. and R. Felder)

6. Forewing with a single, large, triangular yellow marking extending from base to well beyond DC (pl. 4), distal margin of yellow triangle convex; FW and HW outer margin dark brown to brownish black7

FW with a single, small yellow to orange-yellow maculation, located at distal margin of DC or beyond; FW ground color olive brown; HW central area orange8

7. Ventral surface of HW dark brown along anterior margin from wing base to apex, brown margin displaced posteriorly in basal third (Panama N to Guatemala)salvini (C. and R. Felder)

Ventral surface of HW yellow-orange along anterior margin from wing base to apex (Panama S to Colombia)semimarginata (Dognin)

8. Forewing with a wedge-shaped orange marking along costa (pl. 6), this crossing bases of R1 and Rs1, extending to base of M2; HW anal margin uniformly orange-yellow (Peru, Bolivia)unimacula (Warren)

FW with an ovoid, light yellow spot beyond anterolateral angle of DC (pl. 6), this extending from Rs1 to M2; HW anal margin dark brown with an orange-yellow streak (Venezuela, Brazil)papula Dognin

9 (2). Forewing and HW bearing orange longitudinal stripes (pl. 4), mimetic of Josia oribia (Josiini; pl. 32); FW length  =  14.5 mm (Bolivia)mimica (Hering)

FW and HW without longitudinal stripes10

10. Central area of HW variously patterned, often yellow, white, or hyaline; HW occasionally with a white spot near apex (dorsal or ventral surface), spot never yellow or orange; FW pattern variable22

Central area of HW uniformly dark brown to blackish brown, without pattern; HW frequently with a comma-shaped spot at apex; FW dark brown to blackish brown, with a yellow or yellow-orange transverse band11

11. Apex of HW with a yellow or yellow-orange spot on dorsal surface (pls. 2, 3)12

Apex of HW without a spot on dorsal surface (ventral spot sometimes slightly visible dorsally)17

12. Transverse band of FW and spot at HW apex light yellow (pl. 3)13

Transverse band of FW and spot at HW apex orange to orange-yellow (pls. 2, 3)14

13. Yellow FW band wide for its entire length, band margins expanded slightly in posterior third; female genitalia with posterior margin of PA truncate; signum relatively small (Peru, Bolivia, SW Brazil)continens (Prout)

Yellow FW band gradually narrowing posteriorly, band bent slightly inward in basal third; posterior margin of PA rounded outward; signum large (Venezuela, Colombia)depravata (Hering)

14. Forewing and HW ground color blackish brown; HW with a turquoise blue to purplish-blue iridescence from base to near outer margin (pl. 2)15

FW and HW ground color dark chocolate brown (pl. 3); HW without iridescence (Colombia, French Guiana, Brazil)decolorata (Hering)

15. Wings relatively broad; ♂ FW length  =  18.5–21.0 mm; transverse FW band yellow to yellow-orange, relatively narrow16

Wings narrow (pl. 2); ♂ FW length  =  17.0 mm; transverse FW band orange, extremely wide, almost ovoid (Bolivia)euryzona (Prout)

16. Hind wing iridescence turquoise blue to cobalt blue; longitudinal stripe along abdominal pleuron white; costa of valva almost straight (fig. 39A); female Tg8 narrow (fig. 39E) (E Costa Rica)albilinea, sp. nov.

HW iridescence cobalt blue to purplish blue; longitudinal stripe along abdominal pleuron orange-yellow; costa of valva curved (fig. 42E); female Tg8 wide (fig. 42F) (Colombia N to Panama)lindigii C. and R. Felder

17. Hind wing dorsal surface blackish brown18

HW dorsal surface broadly iridescent blue, especially near anal margin (pl. 2); FW length  =  14.5–15.5 mm (French Guiana,Amazonian Brazil)leechi (Prout)

18. Hind wing (dorsal and ventral surfaces) lacking markings, except anterior margin sometimes edged with light yellow20

HW ventral surface with a spot near apex (pl. 3)19

19. HW ventral surface with an elongate, light yellow spot extending from near wing base to apex; FW length  =  15.0 mm (Venezuela, French Guiana)saga (Hering)

HW ventral surface with a small, ovoid orange-yellow spot near apex, this occasionally showing faintly through to dorsal surface; FW length  =  15.5–18.0 mm (Venezuela, Ecuador S to Peru and Brazil)labana (Druce)

20. Forewing with a yellow transverse band crossing near distal margin of DC (pl. 3)21

Basal two-thirds of FW yellow (pl. 4), forming a large triangle, its distal margin sinuate, base with a small dark streak; wing pattern mimetic of Scea species (Josiini; pl. 35) (Brazil)basivitta (Prout)

21. Transverse band of FW light yellow, wide (pl. 3); collar and occiput mostly light orange-yellow; FW length  =  16.0–18.5 mm (Guianas and Venezuela S to Brazil)clite (Walker)

Transverse band of FW orange-yellow, narrow (pl. 3); collar and occiput mostly brown, with small light orange-yellow areas; FW length  =  17.0 mm (Brazil)ursula (Hering)

22 (10). Forewing with a white, ovoid fascia crossing distal margin of DC (pls. 6, 7), this always present on ventral surface, usually on dorsum; HW central area semihyaline or white, outer margin blackish brown with an iridescent blue-gray to cobalt blue luster23

FW with light yellow or orange-yellow markings, no white fascia; HW central area usually yellow or orange-yellow, never semihyaline, outer margin never with blue iridescence31

23. Forewing ground color gray-brown, veins conspicuously lighter (pl. 6); FW base sometimes with a faint bluish iridescence, never with brilliant iridescent streaks; HW central area usually white, sometimes semihyaline24

FW ground color blackish brown; FW base with brilliant, cobalt blue iridescent streaks (pl. 7), outer portion of HW broadly iridescent blue; HW central area semihyaline29

24. Hind wing ventral surface with a conspicuous white spot at apex27

HW ventral surface without a white spot at apex25

25. Forewing with a white, transverse ovoid fascia beyond DC; HW semihyaline to white26

FW with a small, teardrop-shaped white spot along anal margin in basal half; HW white (Peru)conigera (Prout)

26. Front completely light yellow, area of vertex between antennal bases light yellow; gray-brown area of HW anal margin extending anteriorly to cubital vein of DC; FW length  =  18.5 mm (Colombia)semiplaga (Warren)

Front gray-brown with white lateral margins, vertex a mixture of gray-brown and white; gray-brown area of HW anal margin extending only to anal fold, cubital vein lined with gray-brown scales; FW length  =  14.0–15.0 mm (Bolivia)corvica (Dognin)

27. Forewing dorsal surface uniformly dark gray-brown, lacking a white fascia (an ovoid one present on ventral surface); FW veins contrasting light yellow; white region of HW extending to anterior margin; FW length  =  16.0 mm (SE Peru)lamasi, sp. nov.

FW dorsal surface with a white fascia (pl. 6); FW veins contrasting light gray-brown; white region of HW falling short of anterior margin28

28. White FW fascia relatively small, ovoid, its posterior margin ending at anal fold; central area of HW whitish, semihyaline, cubital vein gray blue; FW length  =  14.5–18.5 mm (Colombia E to Guyana, S to Brazil and Peru)sobria Walker

White FW fascia large, extending from anterior margin of DC posteriorly to anal margin; central area of HW white, cubital vein white; FW length  =  16.5–19.0 mm (E Ecuador)avara (Druce)

29. Hind wing with a white spot at apex on ventral surface, none dorsally (pl. 7); FW with a small white apical spot on dorsal and ventral surfaces30

HW dorsal and ventral surfaces with a white spot along anterior margin, located basal to apex above fork of Rs and M1; FW without a white apical spot; FW length  =  16.0–19.0 mm (French Guiana)thiaucourti, sp. nov.

30. Basal streaks of FW and anal margin of HW brilliant, iridescent turquoise blue; FW length  =  16.0–18.5 mm (E Colombia S to E Peru)cassandra (Druce)

Basal streaks of FW and anal region of HW iridescent purplish blue; FW length  =  13.0–17.0 mm (Guianas S to Amazonian Brazil)umbrifera (Walker)

31 (22). Forewing with a single, large, diamond-shaped, lemon-yellow area in basal three-quarters, apex of diamond extending distally to near outer margin (pl. 4); HW central area lemon yellow; wings elongate, FW length  =  13.0 mm (E Ecuador)alea (Druce)

FW pattern variable, not showing a large diamond-shaped area; wings variable in length, usually not short32

32. Hind wing dorsal surface with an ovoid submarginal spot near apex, immediately beyond yellow central area (pl. 7); HW cubital veins, anal fold and 2A dark brown as they pass through yellow central area; FW with an elongate transverse band crossing distal margin of DC, and a second, comma-shaped distal band comprising a series of submarginal spots; wings long (FW length  =  23.5–26.0 mm)33

HW without an ovoid spot near apex beyond yellow central area; all veins in yellow central area of HW concolorous; FW never with a comma-shaped submarginal band; wings variable in length34

33. Transverse FW band and HW central area orange-yellow; distal FW band and distal HW spot light yellow (Venezuela and French Guiana S to Peru and Brazil)citrina (Druce)

Transverse FW band and HW central area light yellow, concolorous with distal FW band and distal HW spot (E Ecuador S to Peru and Brazil)ovia (Druce)

34. Forewing ventral surface with a single, light yellow to orange-yellow transverse band of variable size, crossing distal margin of DC; FW never with an additional, yellow basal maculation (although ♂ frequently with white basal streaks)35

FW ventral surface with a yellow basal maculation, usually triangular in shape (often not expressed on dorsal surface), in addition to a yellow transverse band44

35. Transverse FW band and HW central area light lemon yellow (pl. 3); wings relatively broad, FW length  =  14.0 mm; FW and HW ground color olive brown, veins light ochreous brown (Brazil)tapajoza (Dognin)

Transverse FW band and HW central area orange-yellow; wings elongate, length variable36

36. Forewing with a light whitish yellow streak at base along anal fold (pl. 4), a second narrower basal streak anteriorto radius; occiput, collar and patagium white to whitish yellow; HW central area (dorsal surface) orange in ♂, white in ♀; wings short, FW length  =  12.0–14.0 mm (E Ecuador and Peru)tegyroides, sp. nov.

FW either dark brown, or with all veins near base lined with whitish yellow to orange-yellow scales, never with a prominent streak on anal fold; occiput, collar and patagium orange-yellow, sometimes partially brown; HW central area (dorsal surface) orange-yellow in both sexes; wings variable in length37

37. Orange-yellow transverse band of FW long, steeply angled (pl. 4); HW central area orange-yellow from base, dark brown marginal band wide at tornus; wings broad, long (FW length  =  20.0 mm)38

Orange-yellow transverse band of FW short, often ovoid, not steeply angled (pl. 4); HW orange-yellow central area variable in size, marginal band never wide at tornus; wing length variable39

38. Transverse FW band extending from subcosta anteriorly to anal fold posteriorly, falling short of tornus (Bahia, Brazil)prouti (Hering)

Transverse FW band extending from subcosta anteriorly to FW outer margin at tornus posteriorly (Petropolis, Brazil)maera (Schaus)

39. Ventral surface of HW with an orange-yellow, comma-shaped spot at apex beyond orange-yellow central area (pl. 4); FW veins contrasting with blackish-brown ground color, especially in basal third40

Ventral surface of HW without an orange-yellow spot at apex; FW veins barely contrasting with ground color; orange-yellow transverse FW band and HW central area variable in size and shape (Venezuela and Colombia S to Peru and Brazil)evippe (Walker)

40. Orange-yellow central region of HW irregularly shaped; HW anal margin lined with a mixture of orange-yellow and dark brown scales; FW much lighter brown than HW; FW veins conspicuously lined with light yellow in distal third (Suriname and French Guyana S to Amazonian Brazil)cuneiplaga (Prout)

Orange-yellow central area of HW regularly shaped; HW margin either entirely orange-yellow or entirely dark brown; FW ground color only slightly lighter brown than HW; FW veins in distal third only slightly contrasting41

41. Orange-yellow HW central area small, completely surrounded by dark brown (pl. 4), wing base and anal margin dark brown42

Orange-yellow central area of HW large, extending to base (pl. 4), anal margin entirely orange-yellow43

42. Orange-yellow HW central area roughly ovoid; HW anal margin white on ventral surface (French Guiana, Venezuela, Brazil)mitys (Druce)

Orange-yellow HW central area extremely narrow, elongate; HW anal margin orange-yellow on ventral surface; FW veins in basal third much lighter than ground color, strongly contrasting; FW length  =  14.5 mm (Amazonian Brazil)desmotrichoides (Hering)

43. Yellow transverse band of FW extending anteriorly to costa, band itself somewhat wedge shaped; Lp2 mostly cream-colored, with a narrow brown lateral band; ♂ FW length  =  16.0–17.0 mm (French Guiana, Brazil)augusta (Warren)

Yellow transverse band of FW extending anteriorly only to subcosta, band itself an elongate oval; Lp2 mostly blackish brown, dorsal and ventral surfaces cream-colored; ♂ FW length  =  15.0–16.0 mm (Colombia, Ecuador)evippoides (Hering)

44 (34). Hind wing central area light yellow to whitish yellow45

HW central area bright lemon yellow to orange-yellow48

45. Forewing veins contrasting with dark brown ground color; FW pattern highly variable, if a yellow basal triangle present on dorsal surface, this never extending to wing base46

FW veins not contrasting with dark brown ground color; FW dorsal surface with a light yellow triangle in basal third (this touching wing base), as well as a small, light yellow oval beyond DC (pl. 5); FW length  =  16.0–17.5 mm (Ecuador, Peru)inaria (Druce)

46. Forewing with a large, light yellow area along anal margin (pl. 5), extending anteriorly to middle of DC, a second small, ovoid light yellow spot beyond DC (Amazonian Brazil)projecta (Warren)

FW without a yellow area along anal margin47

47. Forewing ground color dark chocolate brown, veins contrasting ochreous to orange-yellow (pl. 6); confluence of FW veins Rs2–Rs4 usually forming a diffuse ochreous patch; size, shape, and number (one or two) of light yellow FW maculations on dorsal surface variable; size and shape of light yellow HW central area variable; FW length  =  14.0–18.0 mm (E Peru, E Bolivia)cingulina (Druce)

FW ground color light chocolate brown, veins contrasting yellow to yellowish brown (pl. 3); confluence of Rs2–Rs4 not forming a conspicuous ochreous patch; FW dorsal surface with a single ovoid fascia beyond DC; HW central area comprising a small, ovoid yellow spot; HW anal margin light yellow; FW length  =  15.0 mm (Venezuela)seducta (Prout)

48. Forewing ground color greenish gray to reddish gray-brown, contrasting with blackish brown of HW outer margin; HW central area lemon yellow to orange-yellow; size and number (one or two) of FW maculations variable55

FW ground color dark brown to blackish brown, barely contrasting with blackish brown of HW outer margin; HW central area lemon yellow; FW always with two yellow maculations varying in shape and size49

49. Forewing with a bright yellow ovoid spot beyond DC (pl. 5), its anterior margin touching Rs1, its posterior margin extending beyond M2 but falling short of M3; FW with a second bright yellow maculation closer to base, its size and shape variable; FW veins contrasting light yellow to light brown50

FW with a bright yellow band in distal third (pl. 5), touching subcosta anteriorly, extending to CuA1 or beyond posteriorly; inner margin of band transverse, outer margin convex; FW always with a large, bright yellow basal triangle; FW veins not contrasting or barely contrasting52

50. Basal yellow maculation of FW located on anal margin (pl. 5), falling short of wing base, extending anteriorly to near middle of DC; anterior margin of HW (ventral surface) yellow in basal two-thirds (Colombia S to Peru)primula (Dognin)

Basal yellow maculation of FW not touching anal margin, located between cubitus and 1A+2A; anterior margin of HW (ventral surface) completely dark brown51

51. Basal yellow maculation of FW an elongate oval (pl. 5), never extending to wing base (E Colombia S to E Peru and Brazil)graba (Druce)

Basal yellow maculation of FW club shaped (pl. 5), tapered to wing base (Peru and Bolivia)biplagiata (Warren)

52 (49). Distal yellow band of FW located beyond DC; leading edge of yellow basal FW triangle extending beyond anterior margin of DC; FW costa yellow in basal three-quarters53

Distal yellow FW band straddling distal margin of DC; leading edge of yellow basal FW triangle reaching middle of DC, falling short of its anterior margin; FW costa entirely brown54

53. Anterior margin of FW basal triangle straight (pl. 5), touching radial sector for its entire length; Sc of FW uniformly brown; HW with a long, blackish basal streak along anal fold; FW length  =  16.0–18.0 mm (Costa Rica)stroudi, sp. nov.

Anterior margin of FW basal triangle excavated near wing base (pl. 5), here falling short of radial sector; Sc of FW light yellow near base; HW with an extremely short, diffuse brownish basal streak along anal fold; FW length  =  15.5–17.0 mm (Ecuador S to Bolivia)regis (Hering)

54. Distal yellow maculation of FW extremely large (pl. 5), roughly ovoid, its outer margin greatly convex, extending to near FW apex; FW veins Rs2–Rs4 arising in a trident; FW length  =  20.0 mm (E Peru)macropoecila (Hering)

Distal yellow maculation of FW a wide transverse band (pl. 5), its outer margin gently convex, falling well short of FW apex; FW veins Rs2–Rs4 in the arrangement [2+3]+4; FW length  =  17.0–19.5 mm (Colombia, Venezuela S to Brazil)pyraloides (Walker)

55 (48). Forewing dorsal surface with an elongate yellow basal dash56

FW dorsal surface without a basal dash58

56. Forewing reddish olive brown (pl. 5), with a wide, concave yellow transverse band extending from costa to immediately beyond CuA2; yellow basal FW dash short; HW, including anal margin, broadly orange-yellow; FW length  =  17.5–18.0 mm (Brazil)quadricolor (Walker)

FW ground color greenish gray to olive brown; FW with a narrow, straight, yellow transverse band extending from subcosta to slightly short of CuA2; yellow basal FW dash long, extending to halfway point of anal margin; yellow area of HW small, anal margin dark brown57

57. Forewing ground color dark olive brown (pl. 5), barely contrasting with outer margin of HW; maculations of FW and HW lemon yellow to yellow-orange; FW length  =  14.0–15.0 mm (E Brazil)longiplaga (Warren)

FW ground color light greenish gray (pl. 5), contrasting strongly with outer margin of HW; maculations of FW and HW light yellow; FW length  =  15.0–19.0 mm (SE Brazil, Uruguay, N Argentina)dominula (Warren)

58. Forewing dorsal surface with a large, light yellow, ovoid (males) or comma-shaped (females) band two-thirds out (pl. 6), band extending from costa to CuA2; basal half of FW light yellow between veins; HW central area lemon yellow to orange-yellow; FW length  =  20.0–25.0 mm (Venezuela and Trinidad E to French Guiana, S to Brazil)priverna (Cramer)

FW dorsal surface with a tiny, orange-yellow spot behind costa, located between R1 and base of Rs1 (pl. 6); FW otherwise uniformly olive brown; HW central area orange; FW length  =  17.5 mm (NW Peru)celata (Warren)

SPECIES INCLUDED AND MATERIAL EXAMINED

Erbessa albilinea, new species

Figures 39, 40; plate 2, plate 36I

Diagnosis

The yellow FW cross band and beautiful iridescent blue HW (pl. 2) of this striking Erbessa species distinguish it from most other members of the genus. Its wing pattern is similar to that of Getta tica (pl. 26), a species in the Josiini with which it co-occurs at midelevations on the Caribbean slope of Costa Rica. Females of the two could potentially be confused. However, in addition to a long list of morphological characters separating them, E. albilinea bears a teardrop-shaped orange-yellow spot near the HW apex that does not occur in G. tica.

A greater challenge is to separate E. albilinea from its sister species, E. lindigii, endemic to Colombia and Panama. However, in E. lindigii (pl. 2) the iridescent blue of the HW is a darker and more purplish compared with the turquoise to aquamarine blue of E. albilinea. The most reliable trait for separating the two species is the color of the thin longitudinal stripe along the abdominal pleuron—yellow-orange in E. lindigii but white in albilinea, thus giving the latter its scientific name. Their male and female genitalia provide subtle, but clear-cut means for separation.

Description

Male. Figure 39A–D; plate 2. Forewing length  =  18.5–21.0 mm. Head: Labial palpus elongate with an elbowlike joint between Lp1 and Lp2, palpus curving upward, apex extending posteriorly beyond antennal base; Lp1 relatively short and wide, ovoid, closely covered with cream to yellow scales ventrally, dark brown scales dorsally; Lp2 two and a half times as long as Lp1, widened below midpoint, then tapering toward apex; Lp2 gray-brown, dorsal surface white, ventral region near junction with Lp1 white; apex of Lp2 bearing a tuft of creamy white to light brown scales on upper surface, this partially obscuring Lp3; Lp3 extremely short, conical, with a long apical spine hidden beneath scales; front covered with short, appressed scales pointing dorsomedially, a thin scaleless region along midline, dorsal scales forming a pair of short tufts between antennal bases; front gray-brown with a few scattered white scales along lateral margins; occiput dark brown in dorsal third, yellow-orange below; eye moderately large, surrounded by a narrow scaleless band anteriorly and posteriorly, gena broadly scaleless; vertex covered with anteriorly directed, dark brown scales, a small patch of white scales at midline; antenna extremely long and thin, pectinations absent, venter densely setose; scape dark brown on dorsal surface, white below; dorsum of antennal shaft closely covered with appressed, glossy, dark brown scales.

Thorax: Prothorax, including area above procoxa, creamy yellow to lemon yellow, proepimeron dark brown; procoxae creamy white, mesal and lateral surfaces gray-brown, remainder of legs white to creamy white on inner surfaces, gray-brown on lateral ones; meso- and metathoracic pleura with anterior half creamy white, posterior half dark brown; patagium dark gray-brown with a faint bluish iridescence, scales pointing posteriorly, anterior face of patagium bearing a thin layer of yellow to orange-yellow scales; tegula covered with long, hairlike, dark gray-brown scales, these bearing a faint bluish iridescence, lateral margin thinly lined with long white scales; dorsum dark gray-brown with a bluish iridescence; tympanum with a moderately large, shallow scaleless depression; tympanal membrane small, ovoid, oriented almost horizontally.

Forewing: (Dorsal) Ground color blackish brown, veins, especially in basal half, slightly lighter; a narrow, lemon-yellow, oblique band crossing outer margin of DC, extending from subcosta to near tornus, terminating at vein 1A+2A; lateral margin of yellow band extending slightly beyond distal margin of DC. (Ventral) Similar to dorsal surface, except ground color lighter, oblique band wider; cubitus lined with white scales from base to fork of CuA1.

Hind wing: (Dorsal) A brilliant, iridescent aquamarine to turquoise blue area from base to beyond apex of DC, this area becoming darker cobalt blue at its lateral margin; outer margin of wing blackish brown, this widest at apex, becoming narrow toward tornus; anterior margin with a lemon-yellow to orange-yellow band in distal half, this becoming comma shaped at apex; anal margin a mixture of iridescent blue and hairlike gray scales. (Ventral) Ground color dark brown, with a faint blue-green iridescence; 3A, 2A and cubitus—including base of CuA2 and fork of CuA1+M3—broadly lined with white scales; anterior margin of wing, from Sc+R to costa, white in basal half, yellow to orange-yellow in distal half, this yellow band becoming comma shaped slightly short of apex; anal margin fringed with hairlike, dirty white scales.

Abdomen: Elongate; dorsum iridescent turquoise blue to cobalt blue, iridescence becoming darker and fainter at Tg8; pleuron iridescent bluish to dark gray-brown with a longitudinal white line, widest at base, becoming abruptly thinner, then terminating at A7; venter white.

Terminalia (fig. 39A–D): Tg8 short, anterior margin with a broad, shallow mesal excavation, posterior margin simple, posterior one-third of tergum more heavily melanized; St8 long, wider than Tg8, wide anteriorly, abruptly narrowing toward distal margin; anterior margin of St8 with a broad, gradually tapered mesal apodeme, posterior margin with a deep, narrow, U-shaped mesal excavation; uncus/socii complex small, narrowly attached to ring; uncus small, beak shaped, apices minutely truncate; socii narrow, digitate, longer than uncus, drooping downward near apices; tegumen thin, much shorter than vinculum, sides roughly parallel; vinculum tall, narrow dorsally, extremely wide ventrally, joining saccus to form a huge, wide ventral envelope, this folded upward to enclose valva bases; dorsal margin of saccus forming a triangular process at midline; valvae almost completely membranous; BO extremely large, occupying most of valva, membrane delicate, heavily pleated; dorsal margin of BO forming a wide, cup shaped sclerite in distal third; costa long and sclerotized, narrow, almost straight, becoming obsolete at apex; apex of valva simple, mostly membranous; transtillar arms narrow, curving downward to form a simple junction at midline; anal tube greatly elongate, upright; valva bases wide; juxta U-shaped; aedeagus relatively long, moderately wide, abruptly narrowed in basal fourth to form a necklike constriction; apex of aedeagus with a long, thin dorsal sclerite and a small, blunt ventral process; vesica slightly wider and shorter than aedeagus; distal portion of vesica bearing deciduous caltrop cornuti, a transverse band of roughly 20 long, thin, spinelike cornuti near middle.

Female. Forewing length  =  21.0–23.0 mm. Head: Similar to male except labial palpus shorter, curving upward to above middle of front, but well below antennal base.

Thorax: Similar to male.

Forewing: (Dorsal) Broader and longer than male; pattern similar, except transverse band much wider, its lateral margin extending well beyond distal margin of DC, band slightly more orange in color. (Ventral) Similar to male, but lacking the white scaling along cubitus.

Hind wing: (Dorsal) Similar to male, except iridescence darker, more cobalt to Windsor blue than turquoise; teardrop-shaped maculation along anterior margin near apex larger and darker orange-yellow than in male. (Ventral) White scaling along veins thinner and fainter than in male.

Abdomen: Wider and shorter than in male; blue iridescence of dorsum less brilliant.

Terminalia (fig. 39E): Tg7 slightly tapered toward distal margin, anterior and posterior margins simple; St7 shorter than Tg7, slightly tapered toward distal margin, anterior margin simple, posterior margin gently convex; Tg8 a narrow transverse band, thinly joined at dorsal midline; AA extremely short, apices truncate; DB extremely short; ostium short, wide, lightly sclerotized, dorsoventrally compressed; CB ovoid, membrane deeply rugose; a pair of elongate, faint, lightly sclerotized areas along dorsum of CB posterior to attachment of DS; DS attached dorsally on CB, slightly less than halfway from base; signum small, slightly infolded, located ventrally, inner surface coarsely dentate; PA moderate in size, lightly sclerotized, with a thumblike dorsal process; PP relatively short, robust, almost straight.

Etymology

This species name is derived from the Latin words albus and linea, in reference to the white longitudinal line along the abdominal pleuron, the best diagnostic character for separating E. albilinea from its closest relative, E. lindigii, in which the abdominal line is yellow.

Distribution

Confirmed examples of Erbessa albilinea are known exclusively from Costa Rica on the Caribbean slope of the Cordillera Central (fig. 40). The species occurs from Braulio Carrillo National Park north to Estación Pitilla in the Area de Conservación Guanacaste. This distribution thus extends from the eastern side of Volcán Barva north to the eastern slopes of Volcán Orosí, the terminal volcano of the Cordillera Central. All six specimens of E. albilinea were collected at precisely the same elevation—700 meters. Erbessa lindigii has been recorded from central Colombia north to Panama. In the latter country, it is found on the Pacific side of the Cordillera Central, and is thus not sympatric with E. albilinea.

The disposition of material, historically identified in collections as E. lindigii, occurring in Honduras (BMNH), Guatemala (BMNH, USNM), and Belize (BMNH), must await more detailed analysis. Those specimens either expand the range of E. albilinea northward, or represent a different species altogether. The only dissection performed, a USNM female from Cayuga, Guatemala (Schaus and Barnes Collection; genitalia slide no. JSM-991), confirms that this example is distinct from E. lindigii, as would be expected. Furthermore, the Guatemalan female exhibits features indicating that it represents a species distinct from E. albilinea. Central American material north of Costa Rica is thus, in all probability, an undescribed taxon. However, males must be studied to fully evaluate this issue.

Biology

The caterpillar rearing teams at the Area de Conservación Guanacaste in Costa Rica have established two host-plant records for E. albilinea (table 4). Not surprisingly, both plants follow the majority of Erbessa hosts in belonging to the family Melastomataceae. One of them—Miconia dolichopoda—is in the genus most commonly utilized by Erbessa, while the other, Conostegia subcrustulata, represents a new genus record. While Miconia contains over 1000 species, Conostegia is much smaller, with only 43 (Gentry, 1993).

Caterpillars of E. albilinea and E. lindigii (pl. 36G, I) differ from other Erbessa larvae in showing a contrasting tiger-stripe pattern, running almost the entire length of the body. In other species (pl. 36D, F; pl. 37A, B, D, F), black transverse stripes are much fewer in number.

Discussion

Erbessa albilinea resembles E. lindigii, but can be separated by the body coloration differences discussed in the diagnosis above, such as the white vs. yellow abdominal stripe. Similarities in their genitalia are not surprising, since almost all Erbessa species share the same fundamental genital structure. Nevertheless, notable differences between the two species include the configuration of the valval costa, which is longer and shows less curvature in albilinea (fig. 39A) than in lindigii (fig. 42E). Both taxa appear to belong in a small subclade of Erbessa along with the Amazonian E. decolorata (Hering) (pl. 3). All three are comparable in size and coloration, except that decolorata is almost entirely dark blackish brown, and shows only faint hints of purplish iridescence in the HW.

Holotype

Male (pl. 2). Costa Rica: Guanacaste: P. N. Guanacaste, Est. Pitilla, 9 km S Sta. Cecilia, L_N_330200, 380200, 700 m, 19 May–3 Jun 1993, leg. C. Moraga. The holotype is deposited at INBio, Heredia, Costa Rica.

Paratypes

Costa Rica: San José: P. N. Braulio Carrillo, Estación Carrillo, 700 m, leg. I. & A. Chacón, 1♂, 1♀, Mar 1985 (INBio, male genitalia slide no. JSM-208); 2♀♀, Apr 1985 (INBio, genitalia slide no. JSM-209); 1♂, 1♀, May 1985 (INBio).

Other Specimens Examined

None.

Dissected

1♂, 1♀.

Erbessa alea (Druce)

Plate 4

Microgiton alea Druce, 1890: 499.

Type Locality

Ecuador, Sarayacu.

Type

Holotype ♀, leg. C. Buckley (BMNH).

Discussion

Only three specimens of E. alea were seen: A BMNH male (JSM-1605); the female holotype; and a recently collected female (JSM-1813), reared on an unknown host plant by G. Rodriguez-Castaneda (Tulane University). The relationship of this species to other Erbessa is unclear. The moth is small (♂ FW length  =  13.0 mm) and the wings are narrow. The pattern of alea is unique, but shows vague similarities to the wings of E. prolifera (pl. 4), at least with regard to the shape of the yellow areas on the FW and HW. However, the wing venation and genitalia of E. alea differ from those of prolifera, instead being typical for Erbessa. For example, Rs1 arises from the DC, separte from the radial sector; the BO of the valva is large, membranous and delicate. Erbessa prolifera, on the other hand, shows wing venation unique in Erbessa; Rs1 is stalked with Rs2–Rs4 (fig. 38F). Furthermore, the valvae in E. prolifera (fig. 46A) are unusual in being narrow, with a small, poorly defined BO.

Erbessa alea shows sexual dimorphism in wing pattern (pl. 4); the yellow FW area is distally acute in males, but is rounded at its apex in females.

Distribution

Ecuador (AMNH, BMNH).

Dissected

♂, Ecuador, [no additional data], BMNH (genitalia slide no. JSM-1605); ♀, Ecuador, Napo, Cañon del Río Jondachi, 10 km N Tena on road to Narupa, 00°49.667′S, 77°45.435′W, 783 m, 4 Jun 2007, rearing no. 22056, leg. Genoveva Rodriquez-Castaneda, AMNH (genitalia slide no. JSM-1813).

Erbessa augusta (Warren)

Plate 4

Oricia augusta Warren, 1909: 70.

Type Locality

Brazil, Humayta, Rio Madeira.

Type

Holotype ♂, leg. W. Hoffmanns, Jul–Sept 1906 (BMNH).

Discussion

Erbessa augusta, a striking moth (pl. 4), has been recorded from two widely separated Amazonian localities—Humayta, Brazil, and Kaw, French Guiana. However, this species is so rare that attempts to characterize its distribution are premature; E. augusta is known to me from only five male specimens, four of which were collected in French Guiana.

Similarities in wing pattern and male genital morphology suggest that, within Erbessa, E. augusta belongs in a clade with E. evippoides (pl. 4) from Colombia and Ecuador, and E. desmotrichoides (pl. 4) from Amazonian Brazil. In all three, the HW ventral surface exhibits a teardrop-shaped yellow-orange spot at the apex, which merges with a yellow-orange basal area. This spot distinguishes these taxa from similar Erbessa species, such as E. evippe and its relatives, in which the HW ventral surface is broadly white in the basal two-thirds and lacks a spot at the apex.

Erbessa augusta (♂ FW length  =  16.0–17.0 mm) is larger than E. evippoides (FW length  =  15.0–16.0 mm) and E. desmotrichoides (FW length  =  14.0 mm). Additionally, the yellow transverse FW band of augusta is larger and extends further anteriorly, touching the costal margin. In both evippoides and desmotrichoides the FW band falls short of the costa.

Distribution

Brazil (BMNH); French Guiana (AMNH, BHC, BMNH).

Dissected

♂, French Guiana, /225/, D6 pk 6.5, 4°41′30″N, 52°18′30″W, 18 Mar 1995, leg. J.-Y. Gallard, ex Bernard Hermier Collection, AMNH (genitalia slide no. JSM-1587).

Erbessa avara (Druce)

Figures 357–359; plates 6, 36D, 36F [EX]

Scotura avara Druce, 1899: 301.

Type Locality

Ecuador, Sarayacu.

Type

Holotype ♂, leg. Buckley (BMNH).

Discussion

This species was moved by Prout (1918: 402) from Scotura, where it had been described (Druce, 1899), to his Section II of Myonia. It was retained there by subsequent authors (Hering, 1925; Bryk, 1930), and is here combined with Erbessa.

Erbessa avara has been collected exclusively in eastern Ecuador at relatively low elevations (400–550 meters). The large white FW fascia, which touches the anal margin posteriorly (pl. 6), makes this species distinctive. The HW ventral surface of E. avara shows a sharply defined white spot at the apex. Except for the BMNH type, which was collected in the 1800s, all the material of E. avara I have seen was captured within the past 15 years. There is a particularly large series in the collection of Padre Francisco Piñas (Quito, Ecuador), captured at Puerto Napo.

In October 2004, Elicio Tapia and I discovered Erbessa avara larvae feeding on Miconia (Melastomataceae) at Jatún Sacha Biological Station, near the Napo River. The host plant (pl. 36J), a small tree, was growing in the yard of a snack bar, along the gravel road leading to the biology station.

Based on similarities of wing pattern in adults (pl. 6) and body coloration in larvae (pls. 36D, 36F, 37B), Erbessa avara is a close relative of E. sobria, whose immatures were discovered in Venezuela, also associated with Miconia (table 4). These two species also share wing pattern similarities with E. lamasi, sp. nov. (pl. 6), from southeastern Peru.

Distribution

Ecuador (AMNH, BMNH, CMNH, FPC, LACM, MNHN, VOB).

Dissected

♂, Ecuador, Morona-Santiago, Morona de Santiago, 12 km W Santiago military camp, 550 m, 10 Aug 1996, leg. Jan Hillman, lowland forest, CMNH (genitalia slide no. JSM-1329); ♀, Ecuador, Morona-Santiago, Morona de Santiago, 12 km W Santiago military camp, 550 m, 10 Aug 1996, leg. Jan Hillman, lowland forest, CMNH (genitalia slide no. JSM-1330).

Erbessa basivitta (Prout)

Plate 4

Myonia basivitta Prout, 1918: 403.

Type Locality

“Brazil”.

Type

Holotype ♀ (BMNH).

Discussion

The wing pattern of E. basivitta (pl. 4) is highly unusual for Erbessa, but study of the BMNH type—one of only two known examples of this species—confirms its placement in this genus. Erbessa basivitta exhibits the following characteristics: FW veins M3 and CuA1 separate; HW veins M3 and CuA1 stalked; labial palpi elongate, folded over front; metathoracic tympanum small, membrane round, oriented horizontally. The abdomen of the type is missing, so genital characters could not be examined. An intact female specimen of E. basivitta in the ZMH collection was presumably the model used for the color figure in Hering (1925: fig. 68g). As is true of the holotype, the label on the ZMH specimen simply gives “Brazil” as its provenance.

The wing pattern exemplified by E. basivitta occurs across a wide range of taxonomic groups. For example, similar wings occur in the josiine Scea erasa (pl. 35), from Cuzco, Peru; these two dioptines are apparently not sympatric. Prout (1918) noted that Erbessa basivitta is extremely similar in size and wing pattern to Euryptidia basivitta Walker (pl. 35), a Brazilian species in the Lithosiinae (Arctiidae), apparently choosing the name for this Erbessa based on its resemblance to the lithosiine.

Distribution

Brazil (BMNH, ZMH).

Dissected

None.

Erbessa biplagiata (Warren)

Plate 5

Oricia biplagiata Warren, 1897: 421.

Type Locality

Bolivia, Reyes.

Type

Holotype ♀, leg. Stuart, 7 Aug 1895 (BMNH).

Myonia peruviana Dognin, 1919: 11.

Type Locality

Peru.

Type

Syntype ♂, ex Staudinger, “fin” 1903 (USNM type no. 30920).

Discussion

Erbessa biplagiata appears to be a close relative of E. graba and E. primula (pl. 5). These three species show similarities in their wing patterns and genital morphology. More detailed taxonomic study may reveal that E. biplagiata, E. graba, and E. primula represent a single, widespread species with variable wing pattern.

I follow Bryk (1930) in treating peruviana as a synonym of biplagiata; Dognin (1919) originally described it as a biplagiata subspecies. The only visible difference between type material for the two names involves the size and shape of the basal FW maculation, when viewed dorsally—it is larger with more even margins in peruviana. On the FW ventral surface, the basal maculations of the two are essentially identical.

Distribution

Bolivia (BMNH); Peru (AMNH, CUIC, USNM).

Dissected

♂ Syntype of peruviana Dognin, USNM (genitalia slide no. JSM-971).

Erbessa capena Druce, revised status

Plate 7

Erbessa capena Druce, 1885b: 534.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♂, leg. C. Buckley (BMNH).

Discussion

This is one of the few current members of Erbessa that was originally described there. Prout (1918) placed capena in his Section II of Myonia, and it was retained in that genus (under subgenus Erbessa) by Hering (1925) and Bryk (1930). The species is here re-combined with Erbessa, following the original author (Druce, 1885b).

Erbessa capena is the largest of the hyaline-winged Erbessa species, with a ♂ FW length of 21.0–22.0 mm, compared with 16.0–17.0 mm for E. pales (pl. 7). In addition, the two can be separated by wing venation; the bases of HW veins M3 and CuA1 are touching in capena, but separate in pales. Erbessa capena is extremely rare. The sum of known material includes: four ♂♂ at the BMNH, one ♂ at the USNM, and two ♀♀ at the ZMH. Interestingly, E. capena appears to be widespread in South America. Each of the four BMNH specimens was collected in a different South American country, altogether spanning thousands of kilometers.

Distribution

Colombia (BMNH); Ecuador (BMNH); Peru (BMNH); Brazil (ZMH); French Guiana (BMNH, USNM).

Dissected

♂, French Guiana, St. Jean du Maroni, Le Moult Collection, USNM (genitalia slide no. JSM-976).

Erbessa cassandra (Druce), revised status

Plate 7

Pseuderbessa cassandra Druce, 1885b: 535.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♀, leg. Buckley (BMNH).

Discussion

I have reinstated cassandra to species status; it had previously been considered a subspecies of umbrifera Walker (Bryk, 1930). Erbessa cassandra is larger than E. umbrifera (pl. 7), and the blue basal markings of the FW and HW are more brilliant. There are numerous genital differences in males and females. Erbessa cassandra occurs at low to mid elevations along the eastern side of the Andes from Colombia south to Peru, whereas E. umbrifera is endemic to the Guyana Shield south into Amazonian Brazil.

Distribution

Colombia (OUMNH, ZMH); Ecuador (AMNH, BMNH); Peru (AMNH, BMNH, CAS, MNHN, MUSM, ZMH).

Dissected

♂, Peru (Central), Région du Péréné, 1923, leg. Dr. Verone, MNHN (genitalia slide no. JSM-686); ♂, Peru, Río Napo, leg. Whitely, BMNH (genitalia slide no. JSM-1001); ♀, Peru, Madre de Dios, Tambopata Reserve, 200 m, Dec 1994, leg. S. Fratello, day coll., AMNH (genitalia slide no. JSM-1002).

Erbessa celata (Warren)

Plate 6

Dialephtis celata Warren, 1906: 410.

Type Locality

Peru, Cajón.

Type

Holotype ♀, Wm. Schaus Collection (USNM type no. 9165).

Discussion

Prout moved celata to Myonia, and Hering (1925) considered it a member of Myonia in subgenus Dialephtis. This species belongs in a taxonomically difficult group within Erbessa that includes E. unimacula and E. priverna (pl. 6). In all three taxa, the FW is greenish gray with a light yellow maculation on the costa halfway out, and the HW is orange or orange-yellow with a blackish margin. In E. celata, the FW maculation is almost absent. The FW and HW undersides in these species are extremely similar. Of the three, E. priverna, from the Guyana Shield, is the most common.

The type locality for Erbessa celata, Cajón, Peru, is one of the historical sites frequented by the collector Otto Garlepp. It is located near the town of Pilcopata (Cuzco Province) in the Cosñipata Valley. I visited the site in 2005, but was unable to collect examples of E. celata. Other material I have seen approximating the holotype in wing pattern (BMNH, USNM) also comes from southeastern Peru.

Distribution

Peru (USNM).

Dissected

Holotype ♀ (genitalia slide no. JSM-1590).

Erbessa cingulina (Druce)

Figure 38E; plate 6

Phaeochlaena cingulina Druce, 1885b: 536.

Type Locality

“East Peru”.

Type

Syntype ♂, leg. Whitely (BMNH).

Stenoplastis albifrons Warren, 1904: 501.

Type Locality

Bolivia, Yungas, 1200 m.

Type

Syntype ♂, leg. Simons, end of dry season, Nov 1901 (BMNH).

Phaeochlaena aurantica Druce, 1885b: 536, pl. 33, fig. 17.

Type Locality

Bolivia.

Type

Syntype ♂, leg. Buckley (BMNH).

Myonia quadriguttata Hering, 1925: 502. New synonymy.

Type Locality

Peru, Moxos.

Type

Holotype ♂ (ZMH).

Stenoplastis semimaculata Warren, 1904: 502.

Type Locality

Peru, Upper Río Toro, La Merced, 3000 [ft].

Type

Holotype ♂, leg. Simons, Aug–Sep 1901 (BMNH).

Stenoplastis spumata Warren, 1904: 19.

Type Locality

Bolivia, Chulumani, 2000 m.

Type

Holotype ♂, leg. Simons, wet season, Jan 1901 (BMNH).

Myonia stenoxantha Hering, 1925: 504. New synonymy.

Type Locality

Peru, Huayabamba.

Type

Holotype ♂, leg. Garlepp (ZMH).

Discussion

The various names previously subsumed under E. cingulina present a confusing array of wing patterns (see pl. 6). Bryk (1930) listed one subspecies and three “aberrations”. Each differs from the nominate form in the number of forewing spots. In the cingulina syntype there are two light yellow FW spots: one a third of the way out, straddling the cubitus and the anal fold, and the other immediately beyond the DC. The syntypes of these variants show either the basal spot only, the distal spot only, or no spots at all (aurantica). A series of male genital dissections, along with study of wing and body coloration, suggests that all are synonyms of E. cingulina. Two additional species described by Hering—quadriguttata and stenoxantha—exhibit male genitalia (JSM-961, 1607) identical in all respects with those of material matching cingulina. Although Bryk (1930) regarded both as species, I sink them as new synonyms of cingulina.

This brings to six the number of junior synonyms of E. cingulina. Of these, the only one showing differences in genital morphology is aurantica (Druce), where the uncus/socii complex is more rounded at its dorsum than in all the others. This name applies to specimens lacking light yellow FW maculations (dorsal surface) altogether (see pl. 6). The known material is from Bolivia. Druce (1885b) described aurantica as a species, but Prout (1918) and subsequent authors regarded it as a cingulina subspecies. Further taxonomic research is required on this entire complex before species boundaries can be understood.

In conclusion, Erbessa cingulina, as defined here, shows high wing-pattern variability. Interestingly, the ventral wing surfaces are fairly uniform. A complete range of E. cingulina pattern types can be seen in the BMNH and USNM collections. The species occurs from northern Bolivia north to central Peru, along the eastern slope of the Andes. There is a huge series at the BMNH, the bulk of which was collected at an elevation of approximately 1000 meters.

Distribution

Peru (AMNH, BMNH, CUIC, MNHN, MUSM, OUMNH, USNM, ZMH); Bolivia (BMNH, CUIC, MUSM, USNM).

Dissected

♂, Peru, Pozuzo, 800 m, Oct 1906, Dognin Collection, USNM (genitalia slide no. SM-960); ♂, Peru, Chanchamayo, USNM (genitalia slide no. JSM-962; wing slide no. JSM-977); ♂, Peru, San Martín, Cayumba Puente, 24 Oct 1946, leg. J.C. Pallister, AMNH (genitalia slide no. JSM-961); ♂, Peru, Río Pachitea, leg. G. Tessmann, ZMH (genitalia slide no. JSM-1607); ♂, Bolivia, Yungas de La Paz, 1000 m, Dognin Collection, USNM (genitalia slide no. JSM-959).

Erbessa citrina (Druce)

Plate 7

Neolaurona citrina Druce, 1898b: 214.

Type Locality

Peru, Amazonas, Iquitos.

Type

Syntype ♀, ex Staudinger (BMNH).

Neolaurona conjuncta Dognin, 1910a: 17.

Type Locality

French Guiana, Saint-Laurent du Maroni.

Type

Holotype ♀ (USNM type no. 30975); abdomen re-attached backward.

Discussion

My search of museum collections worldwide uncovered 17 specimens (including types) of Erbessa citrina, and all are females. This phenomenon, rarity or complete absence of males in collections, occurs in several other Erbessa species. A biological explanation is unknown. Erbessa citrina and its close relative, E. ovia (pl. 7), are lowland species occurring in northern South America and the Amazon Basin.

The wings of E. citrina conform to the famous “tiger stripe” pattern, defining a mimicry ring that includes a huge array of neotropical butterflies and moths (see DeVries, 1987: fig. 7). For example, similar wing patterns occur within Castnia (Castniidae), Chetone (Arctiidae: Pericopinae), Dismorphia (Pieridae), and Melinaea and Heliconius (both Nymphalidae). In the Dioptinae, Phaeochlaena hazara (pl. 9) also belongs to this mimicry ring. Whether E. citrina serves as an unpalatable model, a palatable mimic, or is an unpalatable member of a Müllerian complex remains to be determined. Its host plant and larvae have not yet been discovered.

Even without dissection it is obvious that Dognin's (1910a) type of conjuncta is conspecific with E. citrina. Interestingly, both Druce and Dognin described their respective taxa in Neolaurona, a synonym of Phaeochlaena.

Distribution

Peru (AMNH, BMNH, MUSM, ZMH); Venezuela (AMNH, IZA); French Guiana (BHC, BMNH, NMW, USNM); Brazil (BMNH).

Dissected

♀, Peru, Iquitos, Amazonas, Nov 1878, leg. M. de Mathan, BMNH (genitalia slide no. JSM-978).

Erbessa clite (Walker), new combination

Plate 3

Josia clite Walker, 1854: 312.

Type Locality

Brazil, Pará.

Type

Syntype ♀, Bates Collection (BMNH).

Ephialtias aequivoca Warren, 1901: 440. New synonymy.

Type Locality

Venezuela, Suapure.

Type

Holotype ♀, leg. Klages, 16 Feb 1899 (BMNH).

Discussion

This species, described in Josia (Walker, 1854), was moved by Prout (1918: 427) to the josiine genus Getta. Surprisingly, subsequent authors retained it there (Hering, 1925; Bryk, 1930). Characters of the labial palpi, wing venation, and metathoracic tympanum in the female holotype demonstrate that clite instead belongs in Erbessa. Erbessa clite (Walker) thus becomes a new combination. The simple wing pattern of E. clite (pl. 3) is roughly similar to that of Getta niveifascia (pl. 26), a species also described by Walker (1864). The latter had until now been regarded as a synonym of clite.

Having made these discoveries, it also became clear after study of BMNH types that Erbessa aequivoca (Warren) is a junior synonym of Erbessa clite, a proposal formalized here. Whereas females are relatively common, I located only four E. clite males (see pl. 3). These were housed at the AMNH and in the Bernard Hermier Collection (Cayenne, French Guiana). Erbessa clite is similar in size and wing pattern to E. labana Druce (pl. 3), differing in that its HW ventral surface is uniformly blackish gray, whereas labana exhibits an orange, comma-shaped spot near the apex on the wing's ventral surface.

Distribution

Brazil (BMNH, JBS, NMW); Venezuela (AMNH, BMNH, ZMH); French Guiana (AMNH, BHC); Guyana (BMNH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1402); ♂, Venezuela, Oucatopi Island, leg. S.M. Klages, AMNH (genitalia slide no. JSM-957); ♀, [no locality], USNM (genitalia slide no. JSM-979).

Erbessa conigera (Prout)

Plate 6

Myonia conigera Prout, 1918: 402.

Type Locality

Peru, Upper Río Toro, La Merced.

Type

Holotype ♀, leg. Simons, Aug–Sep 1901 (BMNH); abdomen missing.

Discussion

Erbessa conigera, known to me from two female specimens—the BMNH type (pl. 6) and a female at the OUMNH—is roughly similar in size and wing pattern to E. avara (pl. 6), endemic to eastern Ecuador. However, these species differ in that the HW underside of avara bears a white spot at its apex, whereas there is no spot in conigera. Judging from superficial appearance, another potential relative may be Erbessa projecta (pl. 5), which differs from E. conigera in showing a white FW spot beyond the DC, in addition to the spot on the FW anal margin. Like E. conigera, E. projecta lacks a white spot at the HW apex below. Until additional material of E. conigera becomes available, it is impossible to speculate further on the taxonomic position of this taxon within Erbessa.

Distribution

Peru (BMNH); Ecuador (OUMNH).

Dissected

None.

Erbessa continens (Prout), revised status

Plate 3

Myonia continens Prout, 1918: 402.

Type Locality

Peru, La Merced, Chanchamayo, 2000–3000 ft.

Type

Holotype ♀, leg. Watkins (BMNH).

Myonia amplificata Hering, 1925: 505. Revised synonymy.

Type Locality

Bolivia, Río Songo, 1200 m.

Type

Holotype ♀, leg. Garlepp (ZMH).

Myonia caeneides Prout, 1918: 402.

Type Locality

Ecuador, Sarayacu.

Type

Holotype ♀, leg. C. Buckley (BMNH).

Myonia flavifascia Hering, 1925: 505. Revised synonymy.

Type Locality

Peru, Yurimaguas.

Type

Holotype ♀ (ZMH).

Discussion

Prout (1918) regarded Erbessa labana (Druce) to be a single species showing highly variable wing pattern. He described five different taxa to encompass this variation, notating each as “form. (? sp.) nov.” Here, one of Prout's forms—continens (pl. 3)—is elevated to species status, with another—caeneïdes—placed as a synonym of it. The remaining forms Prout described are retained as synonyms of E. labana, following Hering (1925) and Bryk (1930).

My rationale for these changes is as follows: First, E. labana is distinctive because the HW is completely dark dorsally, but bears an orange spot at the apex on its ventral surface (pl. 3). Erbessa continens and E. caeneïdes, on the other hand, show a light yellow spot at the HW apex on both the dorsal and ventral surfaces (pl. 3). Their wing length is also consistently shorter than verified examples of E. labana, and their female genitalia differ slightly.

It is clear, therefore, that a species separate from labana exists in which the wings show a dark brown ground color, there is a light yellow transverse band in the FW, and the HW bears a light yellow spot at the apex, visible on both wing surfaces. However, this diagnosis applies to another Erbessa species, E. depravata (Hering), described from Venezuela. My studies suggest that, although E. depravata and E. continens are extremely similar in size and wing pattern (pl. 3), the two constitute distinct species. They are separable because the FW band is wide for its entire length in E. continens, but narrows posteriorly in E. depravata. Female genitalia of the two also differ (see species key, above).

Hering (1925: 505), in describing depravata, also described two subspecies of it—amplificata and flavifascia. These taxa show wide FW bands, and I therefore associate them with E. continens, rather than with E. depravata.

Erbessa continens could potentially be confused with E. decolorata (pl. 3), a dark brown Erbessa species with a HW spot at the apex (dorsal and ventral surfaces). However, Erbessa decolorata differs in exhibiting orange, rather than light yellow wing markings. It is also considerably larger than E. continens (♀ FW length  =  14.5–16.5 mm), with a female FW length of 17.5–18.0 mm.

As currently conceived, E. continens occurs from southeastern Peru to Bolivia, as well as in the Matto Grosso of Brazil. However, not having dissected the type of caeneides Prout, the northern limits of the taxon are as yet undefined. There is a strong possibility that caeneides represents a third species. Perhaps the taxonomy of this difficult complex will become clear once males of all the phenotypes are eventually discovered and dissected.

Distribution

Ecuador (BMNH); Peru (BMNH, ZMH); Bolivia (CMNH, ZMH); Brazil (BMNH, CMNH).

Dissected

♀, Brazil, Matto Grosso, Cuyabá, leg. Paul Zobrys, BMNH (genitalia slide no. JSM-1603); ♀, Bolivia, Prov. del Sara, leg. Steinbach, CMNH (genitalia slide no. JSM-1602).

Erbessa corvica (Dognin)

Plate 6

Myonia corvica Dognin, 1923: 28.

Type Locality

Bolivia, Corvico, 1800 m.

Type

Holotype ♀ (USNM type no. 30972).

Myonia pleniplaga Prout, 1918: 402. Revised synonymy (formerly a synonym of semiplaga Warren).

Type Locality

Bolivia, Yungas de Coroico, 1800 m.

Type

Holotype ♀, leg. Garlepp, Oct 1906–Mar 1907 (BMNH).

Discussion

I know Erbessa corvica (pl. 6) exclusively from females. Unfortunately, female genitalia provide few informative characters for separating species within Erbessa. Wing pattern, which then becomes the only reasonable option for separation, is notoriously variable in some species complexes, such as E. cingulina (pl. 6) and E. evippe. Based on available material, E. corvica is endemic to northeastern Bolivia; no examples are known from Peru.

Prout (1918: 402) described pleniplaga as a subspecies of Erbessa semiplaga (Warren), from Colombia. My examination of the pleniplaga type instead suggests that it is a synonym of corvica. Notably, their type localities, including an elevation unusually high for Erbessa—1800 meters—are the same.

Distribution

Bolivia (BMNH, CMNH, USNM).

Dissected

♀, Bolivia, Prov. del Sara, 450 m, Jul 1914, leg. J. Steinbach, CMNH (genitalia slide no. JSM-982).

Erbessa cuneiplaga (Prout)

Plate 4

Myonia cuneiplaga Prout, 1918: 401.

Type Locality

“Surinam”.

Type

Holotype ♀ (BMNH).

Discussion

Only four specimens of E. cuneiplaga were seen: the female type and a broken male (missing its right FW and abdomen), both at the BMNH; a USNM female (JSM-1600); and a specimen (♀) that can be seen on the web site of René Lahousse—“Hétérocères de Guyane Française” ( www.guianensis.fr).

Based on this tiny sample, E. cuneiplaga occurs in the Guyana Shield, as well as into Amazonian Brazil. Little can be said regarding the relationship of this taxon to other Erbessa species; the female genitalia are typical for the genus and offer few clues. Intact males of E. cuneiplaga are sorely needed.

Distribution

Suriname (BMNH); French Guiana (BMNH); Brazil (USNM).

Dissected

♀, Brazil, Amazonas, Rio Manes, USNM (genitalia slide no. JSM-1600).

Erbessa decolorata (Hering)

Plate 3

Myonia decolorata Hering, 1925: 504.

Type Locality

Brazil, Leopoldina, Espiritu Santo.

Type

Holotype ♀, leg. “Michls.”, 1897, Staudinger Collection (ZMH).

Discussion

Hering (1925) noted that E. decolorata (pl. 3) is similar in size and appearance to E. lindigii (pl. 2), but its HW is instead uniformly brown, without the brilliant blue iridescence. Erbessa decolorata also resembles E. continens (pl. 3), but differs in that its wing markings are rich orange, rather than being light yellow. The FW length of decolorata (18.5–19.0 mm) is longer than any known example of continens (FW length  =  14.0–17.0 mm).

Specimens of E. decolorata were misidentified in the USNM collection as Brachyglene caenea (pl. 15), with which it shares a similar wing pattern. However, the two taxa can easily be separated; among other features, the labial palpi in E. decolorata are elongate and elbowlike, even in females, whereas they are extremely short in B. caenea.

I know E. decolorata from six female specimens—two at the USNM, two at the ZMH, including the type, and two in the BHC—collected in three different South American countries. It seems unlikely that all are conspecific, especially considering how widely separated they are geographically; the USNM material is from Villavicencio, Colombia, whereas the ZMH moths are from Epíritu Santo in eastern Brazil. However, until corresponding males are discovered it will be difficult to resolve this issue.

Distribution

Brazil (ZMH); Colombia (USNM); French Guiana (BHC).

Dissected

♀, Colombia, Villavicencio, leg. Apollinaire, USNM (genitalia slide no. JSM-1601).

Erbessa depravata (Hering)

Plate 3

Myonia depravata Hering, 1925: 505.

Type Locality

Venezuela, Orinoco.

Type

Syntype ♂/♀ (ZMH).

Discussion

Erbessa depravata is extremely similar to E. continens (pl. 3), but the two can be distinguished by the shape of the yellow FW band; in E. depravata the band narrows posteriorly, whereas in E. continens it remains wide for its entire length. Their female genitalia differ in the shape of the signum and papillae anales (see species key, above). According to the species concepts adopted here, E. depravata is endemic to Venezuela and the northeastern portion of Colombia. Erbessa continens, on the other hand, is more southern in distribution, occurring in Peru, Bolivia, and western Brazil. My search of the world's museums uncovered less than a dozen E. depravata specimens, the only known male being a ZMH syntype. The latter was not dissected.

As part of his original description of depravata, Hering (1925: 505) described two subspecies—amplificata (from Bolivia) and flavifascia (from Peru). These names are here placed as synonyms of E. continens since their FW bands are wide. Furthermore, both types were collected within the known range of E. continens, rather than that of E. depravata.

A series of three AMNH females, captured in Mocoa and Puerto Limón, Colombia (Putumayo Province), near the Ecuadorian border, show an extremely wide FW band, much wider than that of E. depravata, and even wider than known examples of E. continens. This series appears to represent an undescribed species.

Distribution

Venezuela (BMNH, IZA, ZMH); Colombia (BMNH, USNM, NMW, ZMC, ZMH).

Dissected

♀, Colombia, Upper Río Negro, 800 m, leg. Fassl, BMNH (genitalia slide no. JSM-464).

Erbessa desmotrichoides (Hering)

Plate 4

Myonia desmotrichoides Hering, 1925: 505.

Type Locality

Brazil, Amazonas, Maçauari.

Type

Holotype ♂ (ZMH).

Discussion

For many years, my knowledge of E. desmotrichoides was based solely on a photograph of the male holotype (pl. 4), the only known specimen. Its wing pattern led me to doubt membership in the Dioptinae; I instead thought that the species might be related to Epidesma obliqua Schaus, a member of the Arctiidae (Ctenuchinae). The two moths are remarkably similar in wing pattern. Part of my confusion stemmed from the fact that the labial palpi of the desmotrichoides type had at some point in time been broken off at the first segment, making them appear short. Elongate labial palpi, folded elbowlike over the front, are one of the defining features for Erbessa. However, after borrowing and dissecting the Hering type (March 2005), I confirmed it to be a dioptine.

As a testament to Hering's taxonomic insights, since he never examined its genitalia, desmotrichoides is correctly placed in Erbessa. The moth exhibits all features of the genus: veins M3 and CuA1 separate in FW, but stalked in HW; socii/uncus complex small; uncus beaklike; socii delicate, digitate and porrect; tegumen narrow; saccus extremely large, enclosing valva bases; valva membranous; BO large, membrane fragile; aedeagus goblet shaped; vesica with deciduous caltrop cornuti. Wing-pattern similarities suggest a close relationship between E. desmotrichoides and E. cuneiplaga (pl. 4), as well as with E. augusta.

The locality as given on the desmotrichoides type label is “Massuaury”, a common locale on specimens at the ZMH. The modern name for this location is Maçauari (03°08′S, 57°30′W), near Parintins, Brazil, on the Amazon River (G. Lamas, personal commun.).

Distribution

Brazil (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1420).

Erbessa dominula (Warren)

Figure 38A; plate 5

Oricia dominula Warren, 1909: 70.

Type Locality

Argentina, La Soledad, Province Entre Ríos, “close to frontier of Uruguay”.

Type

Holotype ♂, leg. Miss E. A. Britton, 19 Apr 1905 (BMNH).

Discussion

Warren (1909) described this species in Oricia, but Prout (1918) moved it to Section I of Myonia (subgenus Dialephtis), a placement followed by Hering (1925).

Judging from the relatively large series that exist in several museum collections, Erbessa dominula is quite common in northern Argentina, Uruguay, and southeastern Brazil. The type locality is at the confluence of the Río Paraná and the Río Uruguay, a short distance north of Buenos Aires.

Based on wing pattern and genital similarities (pl. 5), E. dominula is closely related to three other Brazilian species—E. pyraloides, E. longiplaga, and E. quadricolor. All exhibit an unusual condition of the male genitalia in which a small, ovoid, membranous appendix is attached to the valva apex by a threadlike duct (fig. 47A). The function of this unusual structure is unknown.

Distribution

Argentina (BMNH, FML); Uruguay (BMNH, IZA, USNM); Brazil (AMNH, MCZ).

Dissected

♂, Uruguay, Florida, Feb 1952, leg. P. Arnav, BMNH (genitalia slide no. JSM-465); ♂, Brazil, Pelotas, Rio Grande do Sul, 4 May 1961, leg. C. Biezanko, AMNH (genitalia slide no. JSM-143); ♀, Uruguay, Colon, Montevideo, 7 May 1896, leg. Oldfield Thomas, BMNH (genitalia slide no. JSM-466); ♀, Brazil, Pelotas, Rio Grande do Sul, 4 May 1961, leg. C. Biezanko, AMNH (genitalia slide no. JSM-144, wing slide no. JSM-177).

Erbessa euryzona (Prout)

Plate 2

Myonia euryzona Prout, 1922: 268.

Type Locality

Bolivia (eastern), S. Julian, Chiquitos, 400 m.

Type

Holotype ♂, leg. J. Steinbach, May (BMNH).

Discussion

Prout (1922) assigned euryzona—one of the few taxa he described after his landmark 1918 paper—to Myonia. Hering (1925) and Bryk (1930) retained it there. Here it is combined with Erbessa.

Known exclusively from the male holotype, this beautiful species appears to be related to E. lindigii (Colombia north to Belize) and perhaps E. leechi (Brazil, French Guiana). In all three (pl. 2), the FW bears an orange-yellow cross band on a dark brown ground color, while the HW shows blue iridescence on its dorsal surface, and diffuse white streaks from the base ventrally. Erbessa euryzona (♂ FW length  =  17.0 mm) is intermediate in size between E. leechi (♂ FW length  =  14.5 mm) and E. lindigii (♂ FW length  =  18.5–20.0 mm). Its HW ventral surface is nearly identical with that of E. lindigii, i.e., mostly dark at the base and showing a comma-shaped orange spot at the apex. The HW ventral surface in leechi is whiter and lacks the orange spot. Until the type is dissected and more material is acquired, the taxonomic affinities of euryzona cannot be more accurately assessed.

Distribution

Bolivia (BMNH).

Dissected

None.

Erbessa evippe (Walker)

Plate 4

Josia evippe Walker, 1854: 309.

Type Locality

Brazil, Tapajos.

Type

Syntype ♂, Bates Collection (BMNH).

Myonia assimilis Hering, 1925: 506. New synonymy.

Type Locality

Brazil, Amazonas, Tapajos.

Type

Syntype ♂ ( =  type of Isionda pyraloides Walker, 1856: 1658) (BMNH).

Oricia imitatrix Warren, 1909: 71. New synonymy.

Type Locality

Brazil, Rio Madeira, Humayta.

Type

Syntype ♂, leg. W. Hoffmanns, Jul–Sep 1906 (BMNH).

Discussion

This is one of two Erbessa species originally described by Walker (1854) in Josia. The other, clite, was subsequently assigned to Getta of the Josiini by Prout (1918), and remained there until the current paper, where it becomes a new combination in Erbessa. Prout (1918) did manage to correctly assess the status of Walker's evippe, placing it in Myonia.

Erbessa evippe is relatively large (♂ FW length  =  17.0–18.5 mm), and shows a yellow, transverse ovoid FW band of variable shape and width, as well as a yellow HW central area of variable size. The majority of specimens in collections are from Amazonian Brazil. The species appears to belong in a clade with E. maera, E. mitys, and E. prouti. The latter may ultimately be revealed as a synonym of evippe. In all these (pl. 4), the HW ventral surface is broadly streaked with white at the base, thus distinguishing them from E. evippoides and E. augusta, in which the HW ventral surface exhibits yellow-orange at the base, as well as a comma-shaped, orange-yellow spot at the apex. The wing pattern of Erbessa maera is roughly similar to that of E. evippe, but shows a much more steeply angled, and longer, FW cross band.

Hering (1925) erected assimilis as a replacement name for pyraloides Walker (1856), since two Walker taxa with the name pyraloides belong in Erbessa. The older one (1854) is upheld, while the second one (1856) became assimilis. My study of type material shows that assimilis Hering, previously regarded as a distinct species, is instead a synonym of evippe.

The name imitatrix, attributed to Warren (1909) who described it as a species of Oricia, had been a mystery. Prout (1918: 403) placed the taxon in Myonia and wondered whether imitatrix might be a synonym of evippe. Hering (1925: 506) had clearly never seen a specimen, yet remarked “it may belong to a different genus”. I discovered the type of E. imitatrix Warren, somewhat hidden among a long series of nontype material of evippe at the BMNH. Baron de Worms made a dissection of that specimen (his dissection number 444/50). Wing-pattern similarities strongly suggest that Prout's suspicions were correct—E. imitatrix is a synonym of evippe. I here formalize that hypothesis.

Distribution

Brazil (BMNH, CMNH, CUIC, MNHN, NMW, OUMNH, USNM, ZMH); Colombia (ZMC, ZMH); Venezuela (BMNH, USNM, ZMH); Ecuador (BMNH); Peru (MUSM).

Dissected

♂, Brazil, Amazonas, Santarem, USNM (genitalia slide no. JSM-986); ♂, Amazonas, USNM (genitalia slide no. JSM-1432); ♀, Brazil, Amazonas, Taperinha, USNM (genitalia slide no. JSM-987); ♀, [no data], USNM (genitalia slide no. JSM-985).

Erbessa evippoides (Hering)

Plate 4

Myonia evippoides Hering, 1925: 506.

Type Locality

Colombia.

Type

Holotype ♂, “Mssn., G.” (ZMH).

Myonia xanthogramma Hering, 1926a: 278, fig. 3. New synonymy.

Type Locality

Colombia, Mocoa.

Type

Holotype ♂ (ZMH); abdomen missing.

Discussion

Hering (1925) described Myonia evippoides (pl. 4) in his contribution to Seitz, and one year later described M. xanthogramma (Hering, 1926a). After study of the respective types, I conclude that xanthogramma is a junior synonym of evippoides—the two are indistinguishable in wing pattern, have the same wing length, and were both described from Colombia. Assuming my hypothesis is correct, it seems strange that Hering (1926a), a careful worker whose knowledge of the Dioptinae, and of Lepidoptera in general, is beyond reproach, described xanthogramma at all. He noted its similarity to E . augusta (Warren), but made no mention of his own species—evippoides, with which it is essentially identical.

According to my concept, E. evippoides occurs on the eastern slope of the Andes in Colombia and Ecuador. The xanthogramma type (ZMH) was collected at Mocoa, Colombia. That site is close to the Ecuadorian border, situated at an elevation of 600 meters between the headwaters of the Río Caqueta and the Río Putumayo, major tributaries of the Amazon. There is a series of five evippoides males at the BMNH, collected in Colombia by Fassl at an altitude of 800 meters on the Río Negro. Two recently collected examples (CMNH, VOB) establish Morona-Santiago, in southeastern Ecuador, as the southern known limit of evippoides.

Nothing can be said regarding the provenance of the evippoides type other than that it was collected in Colombia. The printed label on the type stating “Mssn.” means that the specimen was originally in the J. Peter Maassen collection (G. Lamas, personal commun.). It is uncertain what the “G.” refers to.

Although named by Hering for its similarity to E. evippe, E. evippoides instead appears to be more closely related to two other species—E. augusta (see discussion above) and E. desmotrichoides (pl. 4).

Distribution

Colombia (AMNH, BMNH, NMW, USNM, ZMH); Ecuador (CMNH, VOB).

Dissected

♂, Colombia, leg. Felipe Ovalle, AMNH (genitalia slide no. JSM-958).

Erbessa graba (Druce)

Plate 5

Phaeochlaena graba Druce, 1899: 294.

Type Locality

Peru, Río Napo.

Type

Syntype ♂, leg. Whitely (BMNH).

Discussion

Erbessa graba shows considerable variation with regard to the size and shape of the FW spots. Similar phenotypic variability occurs in other Erbessa species, such as E. cingulina (pl. 6; discussed above). Based on its wing pattern and genital morphology, E. graba belongs in a clade with E. primula Dognin and E. biplagiata Warren. It can be separated from these (pl. 5) because the spot near the posterior margin of the FW is ovoid, and is set off from the margin itself. In E. primula the homologous FW spot is larger and contiguous with the anal margin, while in E. biplagiata this maculation is elongate, extending inward to the FW base. However, it should be noted that species boundaries in this complex are poorly defined and may change after revisionary study. The type locality for E. graba is located near the mouth of the Río Napo in northeastern Peru.

Distribution

Brazil (AMNH, BMNH, NMW); Peru (AMNH, BMNH, MUSM); Colombia (AMNH, MNHN); Ecuador (BMNH, OUMNH, USNM).

Dissected

♂, Colombia, Bogotá, Hy. Edwards Collection, AMNH (genitalia slide no. JSM-973); ♂, USNM, [no data] (genitalia slide no. JSM-974); ♀, USNM, [no data] (genitalia slide no. JSM-975).

Erbessa inaria (Druce)

Plate 5

Phaeochlaena inaria Druce, 1885b: 535, pl. 33, fig. 16.

Type Locality

Ecuador, Intaj.

Type

Syntype ♂, leg. Buckley (BMNH).

Discussion

The wing pattern of E. inaria is distinctive. As holds true for E. cingulina, this species is known exclusively from males. The BMNH collection contains a large series of E. inaria (50 ♂♂ plus the type). Additional material includes two males at the ZMH and seven at the USNM. An undescribed species with a wing pattern similar to E. inaria is known from a single male collected in French Guiana (BHC). The male genitalia of Erbessa inaria exhibit an apomorphic condition found in several other Erbessa species, where the valva apex bears a small, membranous appendix, attached to the valva by a threadlike duct, a trait exemplified by the genitalia of E. pyraloides (fig. 47A).

Distribution

Ecuador (BMNH, OUMNH, USNM, ZMH); Peru (BMNH, OUMNH, ZMH).

Dissected

♂, Ecuador, Intaj, leg. Buckley, USNM (genitalia slide no. JSM-988).

Erbessa integra (C. and R. Felder), new combination

Plate 7

Clastognatha integra C. and R. Felder, 1874: pl. 104, fig. 8.

Type Locality

Brazil, “Amazons”.

Type

Not seen.

Discussion

Prout (1918) assigned this species to the genus Phaeochlaena Hübner (subgenus Clastognatha), and it has been retained there by all subsequent authors (Hering, 1925; Bryk, 1930). However, integra instead belongs in Erbessa, and that combination is newly proposed here. Earlier authors probably misplaced integra in part because of its wing venation; HW veins M3 and CuA1 are separate. That condition is found universally in Phaeochlaena (fig. 70F) but is relatively rare within Erbessa, where the vast majority of species show those veins stalked at their bases (e.g., fig. 38A). Additional apomorphies of Erbessa exhibited by integra include: tympanum small; female genitalia simple, CB with a single ovoid signum, DB dorsoventrally compressed.

Erbessa integra is highly distinctive because of its size and wing pattern (pl. 7); a female FW length of almost 30.0 mm makes this the largest species of Erbessa, and one of the largest Dioptinae. Although females of E. integra are well represented in collections, I have seen only a single male—at the Humboldt Museum in Berlin. Had previous authors been able to examine this male, which exhibits ciliate antennae, the species would not have been misplaced in Phaeochlaena, where the male antennae are pectinate (pls. 9, 10). Interestingly, the male labial palpi of E. integra are among the longest in the Dioptinae.

Distribution

Brazil (BMNH, CMNH, CUIC, NMW, USNM, ZMH).

Dissected

♀, “Amazon”, BMNH (genitalia slide no. JSM-682).

Erbessa josia (C. and R. Felder)

Plate 5

Phaeochlaena josia C. and R. Felder, 1862: 230.

Type Locality

Brazil, Bahia, Rio Negro.

Type

♂ (not seen).

Discussion

This is one of the few species in the Dioptinae whose identity I was unable to establish. The type is unknown. After its original description (Felder and Felder, 1862), E. josia was figured (C. and R. Felder, 1874; pl. 105, fig. 1), but that illustration is difficult to interpret. Hering (1925) provided a color illustration of what he called “Erbessa josia”, but his moth appears to be conspecific with Erbessa dominula (Warren), and bears little resemblance to the specimen in the Felder plate. To further complicate matters, Martin Honey (BMNH) has determined that the moth figured by C. and R. Felder, probably from Bogotá, was in all likelihood misidentified.

My tentative solution to this confused situation is to base the identity of E. josia on a single female specimen (from Teffé, Amazonas) identified as such in the BMNH collection. This identification, probably performed by Prout, shows few similarities with the moth figured by C. and R. Felder. A CMNH female from Brazil (Hyutanahan, Rio Purus) matches the BMNH example perfectly, and is here chosen to represent E. josia (pl. 5).

Distribution

Brazil (BMNH, CMNH, ZMH).

Dissected

♂, Brazil, Bahia, ZMH (genitalia slide no. JSM-321); ♀, [no data], ZMH (genitalia slide no. JSM-322).

Erbessa labana (Druce)

Plate 3

Getta labana Druce, 1899: 295.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♀, leg. C. Buckley (BMNH); abdomen missing.

Myonia attingens Prout, 1918: 402–403.

Type Locality

Brazil (“Amazons?”).

Type

Holotype ♀, ex coll. Smith, 1844–45 (BMNH).

Myonia pravesignata Prout, 1918: 402.

Type Locality

Brazil, Amazonas, Tefé.

Type

Holotype ♀, leg. M. de Mathan, Sep 1907 (BMNH).

Myonia simplificata Prout, 1918: 402.

Type Locality

Ecuador, Sarayacu.

Type

Holotype ♀, leg. C. Buckely (BMNH).

Myonia subalba Hering, 1925: 506. New synonymy.

Type

Peru, Amazonas, Pebas.

Type

Holotype ♂ (ZMH).

Discussion

The identity of Erbessa labana has confused authors throughout the history of dioptine systematics, and I spent considerable effort attempting to stabilize the situation. Although I now feel confident in having firmly established the identity of labana itself, my attempts to understand the associated names have met with only moderate success. I summarize my findings below.

Importantly, this is the only Erbessa species in which the FW is dark with a light yellow transverse bar, and the HW is dark on its dorsal surface but exhibits an orange spot at the apex on the ventral surface (see pl. 3). Erbessa clite is similar in size and coloration, but lacks the orange HW spot below. Examination of the ZMH type of subalba Hering suggests that it is in fact the male of Erbessa labana, previously known exclusively from females. This orange HW marking is particularly striking in the subalba male. I have thus placed subalba in synonymy with labana.

With this evidence in hand, it is interesting to note that E. labana males exhibit white markings on the wing ventral surfaces (pl. 3): a white streak on the FW running from the base along the cubitus; a white streak in the HW anterior to the radius; and a broad, white basal area of the HW. The ventral wing surfaces are completely dark in labana females. In several other Erbessa species where the HW is dark above, such as E. albilinea, E. lindigii, and E. clite, males exhibit similar white basal dashes or streaks on the wing ventral surfaces. These are invariably absent in females.

Prout (1918: 402) noted the possibility that labana shows extensive wing pattern variation, highlighting this variability by describing five so-called “forms”. In an attempt to unravel a confusing state of affairs, I have made the following taxonomic changes: First, one of Prout's forms—attingens—is probably a phenotypic variant of labana. The attingens type differs slightly from nominate labana in showing a faint dash of orange near the HW apex on its dorsal surface, in addition to the orange spot below. However, it otherwise appears to be a valid synonym. On the other hand, I am uncertain regarding the taxonomic status of simplificata and pravesignata; one or both of these will probably prove to be distinct species. I retain them as synonyms pending revisionary work. Two more of Prout's labana forms—caeneïdes and continens—I have placed together as synonyms representing a distinct species, using the latter as the valid name. Furthermore, these appear to be conspecific with E. depravata Hering (1925), which thus becomes a junior synonym of E. continens Prout (pl. 3).

It is interesting that Druce (1899) described labana in Getta, a genus of the Josiini. He was perhaps (unwisely) following the lead of Walker (1854), who had incorrectly described Erbessa clite, a similar moth (pl. 3), in Getta. Although Prout (1918) caught Druce's misplacement, Walker's mistake was not revealed until the current paper, now more than 150 years after the moth was described.

Distribution

Venezuela (IZA); Ecuador (BMNH); Peru (AMNH, CUIC, ZMH); Brazil (NMW).

Dissected

♂ type of subalba Hering (genitalia slide no. JSM-1592); ♀, Venezuela, Bolívar, El Hormiguero Meseta de Nuria, 500 m, 13–17 Jul 1974, Expedición Instituto Zoología Agricola, Fac. Agronomía, IZA (genitalia slide no. JSM-1593).

Erbessa lamasi, new species

Figures 42A–D, 43; plate 6

Diagnosis

This species shares wing-pattern similarities with E. avara and E. conigera (pl. 6); the broad, immaculate white central area of the HW in these is unique for Erbessa. Another apparent relative, E. sobria (pl. 6), is smaller and shows a semihyaline, whitish HW central area. Together, these species exhibit extremely similar HW ventral surfaces, with a small but conspicuous, immaculate white spot at the apex. However, their FW differs considerably: in avara and conigera there is a large white spot arising from the trailing edge; sobria exhibits an ovoid spot at the distal margin of the DC; while in lamasi, the FW is uniformly gray, without pattern other than the thin light yellow lines tracing the wing veins.

Erbessa lamasi could potentially be confused with one of the phenotypes of E. cingulina (pl. 6)—aurantica Druce—which lacks the FW spots typical of other cingulina forms. However, the HW central area of lamasi is immaculate white, whereas in cingulina/aurantica this area is creamy yellow. Furthermore, in all phenotypes of cingulina the bases of FW veins Rs2–Rs4 form an ochreous brown trident, absent in lamasi. On the ventral surface, a white HW spot at the apex, present in lamasi but absent in cingulina, easily separates these taxa.

The male genitalia of E. lamasi (fig. 42A–D) are unique for the genus in that the membranous valva apex bears fine striae in a fanlike configuration. Furthermore, the appendix at the valva apex, characteristic of many Erbessa species (e.g., fig. 47A), is large in lamasi and its surface is striate.

Description

Male. (pl. 6). Forewing length  =  16.0 mm. Head: Labial palpus elongate, curving elbowlike over front, apex extending to slightly beyond antennal base; Lp1 short, ovoid, widest near middle, covered with bright, yellow-orange scales, except dark brown scales dorsally; Lp2 over three times as long as Lp1, wide, laterally compressed, slightly narrowed toward apex; lateral surface of Lp2 gray black, dorsal surface light yellow-orange in basal two-thirds, creamy white in distal third, ventral surface light yellow-orange near base, creamy white beyond, mesal surface of Lp2 gray black in basal three-fourths, light creamy yellow to apex; Lp3 short, ventral surface gray black, dorsal surface creamy yellow, distal scales drawn to a long, sharp point; scales of front pointing dorsomedially, a narrow scaleless seam along midline, dorsal scales slightly longer, forming short tufts between antennal bases; scales of front creamy white; occiput covered with erect, bright yellow-orange scales, a small blackish gray patch above; eye large, bulging outward, bordered by a narrow scaleless band behind, slightly wider above; gena quadrate, broadly scaleless; vertex covered with appressed, forward-pointing dark gray scales, a few scattered light yellow-orange scales along midline and behind antennal bases; antenna greatly elongate, threadlike, ciliate; scape glossy blackish gray dorsally, creamy white ventrally; dorsum of antennal shaft tightly covered with short, glossy, blackish gray scales.

Thorax: Prothorax with pleuron and region below head yellow-orange; procoxa white on outer surfaces, gray on inner ones; rest of legs creamy white to beige on inner surfaces, light gray on outer ones; meso- and metathoracic pleura covered with long, hairlike white to cream-colored scales, a lower level of shorter gray scales, a patch of long light yellow scales near FW base; anterior portion of patagium with a transverse band of erect, orange-yellow scales, dark gray behind, with a patch of light yellow on either side of midline, midline whitish yellow; tegula long, anterior margin yellow-orange to light yellow from base, posterior margin white, central portion covered with long, hairlike dark gray scales; dorsum dark gray, with a creamy white to light yellow stripe along midline, a faint row of scattered whitish scales on either side of midline; tympanum with a fairly large, cup shaped, scaleless depression; tympanal membrane small, ovoid, inset, facing almost ventrally.

Forewing: (Dorsal) Dark coppery brown, darker gray-brown toward outer margin; veins, excluding costa but including anal fold and extension of M2 through DC to base, evenly lined with light yellowish brown scales; fringe blackish gray. (Ventral) Ground color dark gray; veins thinly lined with light gray; a diffuse white streak from base immediately behind DC; a round, whitish spot located basal to distal margin of DC, its anterior margin falling short of radius, its posterior margin crossing cubitus but falling slightly short of CuA2.

Hind wing: (Dorsal) Central area immaculate white, extending out to distal margin of DC and to slightly short of M3+CuA1; scattered dark gray scales at base; a wide black to dark charcoal-gray band along outer margin from apex to tornus, surface of band slightly iridescent blue, band widest anteriorly, narrowed toward tornus; anal margin fringed with long, hairlike white scales. (Ventral) Similar to dorsal surface, except: marginal band gray black, bearing a conspicuous white spot at apex, its anterior margin touching Sc+R, its posterior margin touching M1; basal fourth with a dark gray streak along anterior margin of DC.

Abdomen: Dorsum iridescent gray blue, with a wide, white longitudinal stripe along midline; dorsomesal stripe widest at base, tapered distally, terminating beyond distal margin of Tg5, then present as a thin line of scattered scales on Tg5–7; pleuron with a thin white longitudinal stripe on each side, stripe widest at base, terminating at A6; venter white to cream colored.

Terminalia (fig. 42A–D): Tg8 short, roughly rectangular, narrower than Tg7, slightly wider at distal margin; anterior margin of Tg8 convex, posterior margin simple, with a small, shallow U-shaped mesal excavation; a wide lightly melanized band beyond distal margin of Tg8; St8 long, narrower than St7 but wider than Tg8; anterior margin of St8 with a long, wide, gradually narrowed mesal apodeme, apodeme almost as long as St7, its posterior margin with a small, tonguelike fold; lateral margins of St8 bowed outward slightly near middle, then strongly narrowed toward posterior margin; posterior margin of St8 narrow, with a deep, narrow U-shaped mesal excavation; uncus/socii complex small, narrowly attached to ring; uncus short, curved slightly downward, apex truncate, with small serrations; socii narrow, digitate, porrect, longer than uncus; tegumen tall but shorter than vinculum, extremely narrow, slightly wider dorsally; vinculum tall, narrow in dorsal half, becoming extremely wide in ventral half, joining saccus to form a huge, wide envelope, folded upward to enclose valva bases; dorsal margin of saccus curving upward, forming a low knob at midline; valvae almost completely membranous; BO extremely large, occupying most of valva, membrane delicate, heavily pleated; costa sclerotized, relatively wide, sides parallel, curving gradually and becoming narrow near apex, terminating below valva apex; apex of valva broadly membranous, inner surface with a fanlike series of striae; apex bearing a large, long, membranous appendix, its surface with faint striae; transtillar arms narrow, oriented horizontally, junction at midline simple; anal tube greatly elongate, upright; aedeagus relatively long, wide in distal two-thirds, basal third abruptly narrowed to form a necklike constriction; apex of aedeagus with a narrow dorsal sclerite and a small, acute ventral process; vesica moderately large and wide, approximately half as long as aedeagus, distal portion bearing deciduous caltrop cornuti, a transverse row of long, spinelike cornuti near base.

Female. Unknown.

Etymology

This species is named in honor of Gerardo Lamas Müller, Director of the Museo de Historia Natural, Lima Peru, and curator in the Departamento de Entomología. Gerardo, a world renowned lepidopterist and expert on Ithomiinae, has graciously hosted my visits to Peru. He accompanied me on the collecting trip to the Cosñipata Valley, near Cuzco (October 2005), during which the only known specimen of Erbessa lamasi was captured by one of his students, Juan José Ramírez.

Distribution

So far known exclusively from the type locality, at 1020 meters in southeastern Peru (fig. 43), E. lamasi occurs at a somewhat higher altitude than most Erbessa species, which typically live in lowland forests at elevations below 500 meters. Erbessa cingulina shows an altitudinal range similar to E. lamasi, having been consistently collected at 1000 meters in eastern Peru and Bolivia.

Discussion

As noted in the diagnosis (above), E. lamasi appears to be a close relative of E. avara, from eastern Ecuador, and E. sobria, a widespread species known from Colombia and Venezuela south to the upper Amazon Basin of Brazil and Peru. In addition to the distinguishing features mentioned in the diagnosis for lamasi, these three taxa can be separated by the colors on the dorsum of the head: In lamasi the vertex is almost entirely dark gray-brown, with a few scattered light yellow scales along the midline and narrow streaks of light yellow behind the antennal bases; the vertex of avara bears a conspicuous transverse orange-yellow band along its anterior margin; finally, the vertex of sobria is dark brown with a few white scales anteriorly and small patches of white behind each antennal base. Male genital morphology can easily be used to separate the three taxa.

Since caterpillars of E. avara (pl. 36D, F) and E. sobria (pl. 37B) have been reared on Miconia in the Melastomataceae, it is likely that this plant serves as the host for E. lamasi as well. So far, seven Erbessa species are known to be associated with Miconia (table 4).

Holotype

Male (fig. 42A–D; pl. 6). Peru: Cuzco: Cosñipata Valley, Quebrada Quita Calzón, S13°01′21″, W71°39′52″, 1020 m, 25 Oct 2005, leg. J.J. Ramírez, day, on flowers. The type is deposited at the AMNH.

Paratypes

None.

Other Specimens Examined

None.

Dissected

Holotype (genitalia slide no. JSM-1560).

Erbessa leechi (Prout)

Figures 35A, 35D, 38B, 44; plate 2 [EX]

Myonia leechi Prout, 1918: 402.

Type Locality

Brazil, Amazonas, Santarem.

Type

Holotype ♂, leg. Leach, Oct 1884 (BMNH).

Scotura longipalpata Dognin, 1923: 29–30. New synonymy.

Type Locality

Brazil, Amazonas, Taperinha.

Type

Syntype ♂, leg. Fassl (USNM type no. 33118).

Discussion

This species, one of the smallest members of Erbessa, has the longest labial palpi of any dioptine. In males, the palpi arch upward, curving over the front and extending well past the antennal bases (fig. 35A, D), almost reaching the prothorax. The male genitalia of E. leechi (fig. 44A–D) are unusual for Erbessa. Instead of possessing large membranous valvae with a huge, heavily pleated BO (e.g., fig. 41A), the valvae in E. leechi are narrow and lack pleats. The aedeagus is extremely large relative to the rest of the genitalia, and the vesica is wide. The vesica bears deciduous caltrop cornuti similar to those found throughout Erbessa.

If genitalia are compared, E. leechi is most similar to E. prolifera (fig. 46); of all the Erbessa species studied, these are the only two in which the valvae are narrow. On the other hand, the wing patterns of these moths are strikingly different (see pls. 2, 4), and their wing venation differs—E. prolifera is the only Erbessa species in which FW vein Rs1 arises from the radial sector (fig. 38F). In E. leechi, it arises from the DC (fig. 38B) as in other Erbessa (fig. 38A, E). The iridescent blue HW of E. leechi suggests an affiliation with E. euryzona and E. lindigii (pl. 2). Further study is required to assess the phylogenetic position of E. leechi within Erbessa.

Comparison of the leechi type at the BMNH with the USNM type of Scotura longipalpata (Dognin) reveals the latter to be a newly recognized junior synonym. Erbessa leechi is rare; I have seen only six specimens in collections. The two USNM male syntypes of longipalpata comprise their holdings. In addition to the male type of leechi at the BMNH, their collection contains one of the three known females. Of the two remaining females, one resides in the Bernard Hermier Collection (Cayenne, French Guiana) and the other is at the LACM.

Distribution

Brazil (BMNH, LACM, USNM); French Guiana (BHC, BMNH).

Dissected

♂ type of longipalpata Dognin, USNM (genitalia slide no. JSM-989); ♂ co-type of longipalpata, Brazil, Taperinha, Amazonas, USNM (genitalia slide no. JSM-996, palpus/antenna slide no. JSM-997, wing slide no. JSM-998); ♀, French Guiana, Colln. C. Bar, BMNH (genitalia slide no. JSM-1548).

Erbessa lindigii (C. and R. Felder)

Figures 35E–G, 38H; 42E–H; plate 2, plate 36G, H [EX]

Phelloë lindigii C. and R. Felder, 1874: pl. 105, fig. 19.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♂ (BMNH).

Discussion

This moth occurs with considerable frequency in collections, but never in large numbers. Previous authors subsumed two species under the name lindigii. According to my revised concept, E. lindigii is known from Colombia and Panama. Morphological characteristics of E. lindigii include: male FW ventral surface with dark gray scales along veins near base; FW ground color dark gray-brown; HW with a deep purplish luster; abdominal pleuron bearing narrow, yellow lateral stripes; male valvae with costa sclerotized at its apex; female signum of CB relatively large.

Specimens from Central America north of Panama, previously considered as lindigii, instead represent a newly recognized species—E. albilinea (described above). This taxon is characterized as follows: Male FW ventral surface with white scales along wing veins near base; FW ground color velvety black; HW with a brilliant turquoise iridescence; abdomen with white lateral stripes along pleuron; costa of valva not sclerotized at its apex; signum small.

A search through the BMNH collection (Feb 2005) uncovered C. and R. Felder's type of E. lindigii. There are two handwritten labels on that specimen: The first, in red writing, states “Phelloë Lindigii, N. i. t.” (the latter meaning “in tabula” or figured); the second, in black writing, says “366, Gen nov, Bogota”. The style and appearance of these labels corresponds precisely with those on other Felder BMNH types. Baron de Worms made a genitalia preparation of the lindigii type (his preparation number, 446/50).

In 1994, Annette Aiello discovered larvae of E. lindigii (pl. 36G) feeding on Miconia impetiolaris (Melastomataceae) in Panama. This was the first record of Melastomataceae-feeding in Erbessa. Since that time, six additional Erbessa species have been reared from Miconia (table 4), and two additional melastome genera have been added to the host list, Henriettea and Conostegia. The pupae of E. lindigii (pl. 36H) are remarkable in being strongly patterned, and in showing an extremely long, bifid process on the head.

Distribution

Colombia (BMNH, CAS, NMW); Panama (AMNH, BMNH, CAS, LACM).

Dissected

♂, Colombia, Don Amo, 2000 ft, Jul, leg. H.H. Smith, BMNH (genitalia slide no. JSM-210); ♀, Colombia, Onaca, St. Marta, 2000 ft, leg. Engelke, BMNH (genitalia slide no. JSM-211).

Erbessa longiplaga (Warren), revised status

Plate 5

Paratryia longiplaga Warren, 1907: 198.

Type Locality

Brazil, Rio de Janeiro.

Type

Syntype ♂, leg. E. May (BMNH).

Discussion

Warren (1907) described longiplaga as a species, but subsequent authors (Prout, 1918; Hering, 1925; Bryk, 1930) regarded it as a synonym of E. pyraloides (Walker) 1854. I here revise it to species status. Although the two taxa show superficial similarities (pl. 5) and are sympatric, genital differences confirm that longiplaga is distinct from pyraloides. The only material of longiplaga of which I am aware consists of five specimens—three females, one male, plus the male syntype—at the BMNH. The wings of longiplaga (♂ FW length  =  14.0–15.0 mm) are shorter than those of pyraloides (♂ FW length  =  17.0–19.0 mm), and they show more contrasting light-colored lining of the FW veins. In addition, their genitalia differ, most notably in the configuration of the male valva apex and in the shape of the female ostium.

Erbessa longiplaga is the apparent sister species of E. dominula (pl. 5). The male genitalia of these two differ in subtle ways. For example, the uncus of E. longiplaga is less robust, and its socii are thinner. Like E. pyraloides and E. dominula, E. longiplaga is one of the Erbessa species in which males possess an apical appendix on the valva (e.g., fig. 47A).

Distribution

Brazil (BMNH).

Dissected

♂, Brazil, Alto de Serra, São Paulo, May 1928, leg. R. Spitz, BMNH (genitalia slide no. JSM-1425); ♀, Brazil, Alto de Serra, São Paulo, 11 Mar 1929, leg. R. Spitz, BMNH (genitalia slide no. JSM-1426).

Erbessa macropoecila (Hering)

Plate 5

Myonia macropoecila Hering, 1925: 502.

Type Locality

Peru, Chanchamayo.

Type

Holotype ♀ (ZMH).

Discussion

Other than the type in Berlin, the only specimen of E. macropoecila known to me is a BMNH female (pl. 5), also collected at Chanchamayo, Peru. This species is extremely close in wing pattern to E. pyraliodes (pl. 5), known mostly from southeastern Brazil, but differs in exhibiting larger yellow areas on the wings. The transverse, ovoid subapical maculation on the FW of E. macropoecila occupies the majority of the wing's distal third. Erbessa macropoecila also resembles E. stroudi, sp. nov. (pl. 5), from Costa Rica, but the yellow basal FW triangle in E. macropeocila is smaller, while the subapical FW spot is much larger. The female FW length of E. macropoecila (19.0 mm) falls within the range for E. pyraloides, but is longer than any known example of E. stroudi.

An apomorphic condition of the FW venation in E. macropoecila separates it from other Erbessa as far as I am aware. Here, veins Rs2–Rs4 arise together in a trident. Elsewhere in Erbessa, these veins are in the arrangement [2+3]+4 (fig. 38A, C, F). The FW of E. cingulina (fig. 38E) almost shows a trident, so this trait should be surveyed across the genus.

Distribution

Peru (BMNH, ZMH).

Dissected

♀, Peru, Chanchamayo, La Merced, Nov 1904, leg. C.O. Schunke, BMNH (genitalia slide no. JSM-1606).

Erbessa maera (Schaus)

Plate 4

Lyces maera Schaus, 1892: 285.

Type Locality

Brazil, Petropólis.

Type

Holotype ♂, Wm. Schaus Collection (USNM type no. 11573).

Discussion

I know this highly distinctive species from the male holotype, from one male at the BMNH, and from two females (MPM, ZMH). All of these were collected at Petrópolis, Brazil. The angle of the FW cross bar and the bar's extreme length (pl. 4) make E. maera easily recognizable. Synapomorphies of wing pattern (particularly on the ventral surface) and genitalia suggest that E. maera belongs in a subclade within Erbessa that includes E. evippe, E. mitys, and E. prouti (pl. 5). It can be distinguished from these as the only species in which the orange-yellow transverse FW band extends all the way across the wing, almost touching the tornus.

Erbessa maera is a close mimic of Lyces angulosa (Walker) in the Josiini (pl. 29), also from southern Brazil. The two are nearly identical in size and wing pattern. Characters of their respective tribes provide obvious means for separation.

Distribution

Brazil (BMNH, MPM, USNM, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1595); ♀, Brazil, Petrópolis, 24 Apr 1960, J.R. Neidhoefer Collection, acquired from P. Gagarin, MPM (genitalia slide no. JSM-1596).

Erbessa mimica (Hering)

Figure 45E; plate 4

Myonia mimica Hering, 1925: 504.

Type Locality

Bolivia, Río Songo.

Type

Holotype ♀ (ZMH).

Discussion

This species, known exclusively from the female holotype (pl. 4), is a precise mimic of Josia oribia (pl. 32; see also Miller, 1996). Their resemblance is so close that Hering, in fact, deserves considerable credit for correctly placing mimica in Erbessa, rather than in Josia. Upon careful examination, E. mimica exhibits all the morphological features of Erbessa. Its female genitalia (fig. 45E) are unremarkable.

Interestingly, Garlepp collected the type of E. mimica on the Río Songo in Bolivia along with a series of J. oribia (Hering, 1925: 504). I have searched hundreds of specimens, identified throughout the world's collections as J. oribia—a fairly common moth—hoping to find additional examples of E. mimica, but to no avail. It will be fascinating to unravel the steps that led to the evolution of such an aberrant wing pattern within Erbessa. The very existence of E. mimica is testament to the remarkable fluidity of wing-pattern evolution in the Dioptinae.

Distribution

Bolivia (ZMH).

Dissected

Holotype ♀ (genitalia slide no. JSM-323).

Erbessa mitys (Druce)

Plate 4

Myonia mitys Druce, 1899: 297.

Type Locality

Brazil, Amazonas, Santarem.

Type

Syntype ♂, leg. Leech, Oct 1884 (BMNH).

Discussion

Erbessa mitys appears to be closely related to E. evippe (pl. 4), found throughout the Amazon Basin. However, mitys differs in its extreme rarity; I know the species from only five males, including the BMNH syntype. The male genitalia of E. mitys and E. evippe are similar, differing most notably in the length and curvature of the valval costa. Their wing patterns differ in more dramatic ways; E. mitys shows only a small, ovoid, yellow-orange spot in the central area of the HW, whereas the HW of evippe tends to be more broadly colored. The ventral surface of the HW in mitys is whiter near the base.

Distribution

Brazil (BMNH); French Guiana (BHC); Venezuela (USNM).

Dissected

♂, Brazil, Pará, leg. A.M. Moss, BMNH (genitalia slide no. JSM-1591).

Erbessa ovia (Druce)

Plate 7

Neolaurona ovia Druce, 1893: 292, pl. 19, fig. 17.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♀, leg. C. Buckley (BMNH).

Discussion

As with its sister species, Erbessa citrina (pl. 7), males of E. ovia are unknown. To my knowledge, the world's holdings of E. ovia comprise 10 female specimens—eight at the BMNH (including the type), one at the ZMH, and one at the MUSM in Lima, Peru. Hering (1925: 504) postulated that E. citrina might simply be a vividly colored version of the duller whitish E. ovia. I compared female genitalia of the two taxa using specimens from the same locality, Iquitos, Peru (slide Nos. JSM-978 and JSM-990), and found no morphological differences. However, Erbessa species show relatively uniform female genital structure. It would therefore be prudent to await the discovery of E. citrina and E. ovia males to see whether genital differences exist, before formally proposing synonymy. Erbessa ovia and E. citrina occur together in the Upper Amazon Basin, but the latter appears to have a broader distribution, also being found in the Guyana Shield and Venezuela.

Distribution

Ecuador (BMNH); Peru (BMNH, MUSM, ZMH); Brazil (BMNH).

Dissected

♀, Ecuador, Sarayacu, leg. C. Buckley, BMNH (genitalia slide no. JSM-685); ♀, Peru, Iquitos, Upper Amazon, Apr 1932, leg. G. Klug, BMNH (genitalia slide no. JSM-990).

Erbessa pales (Druce)

Plate 7

Metastatia pales Druce, 1893: 285, pl. 19, fig. 4.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♂, leg. C. Buckley (BMNH).

Discussion

Although the male type of E. pales is in miserable condition (abdomen, right HW and part of right FW missing), the identity of this species is not in doubt. As is so often the case with Erbessa species, females (n  =  15) are much more common in collections that males (n  =  3). Even with such limited material available, it is clear that E. pales is widely distributed across the Upper Amazon Basin, from Ecuador south to Bolivia and east into Brazil (São Paulo de Olivença, BMNH). Erbessa pales is the apparent sister species to E. capena (pl. 7), a larger moth also with transparent wings. Males of the two species show marked differences in the shape of their valva apices.

Erbessa pales bears resemblance to unrelated Dioptinae with hyaline wings, such as Hadesina limbaria (pl. 14) from western Ecuador and Colombia, as well as to Lepidoptera in other families, such as Isostola divisa Walker, a member of the Pericopinae (Arctiidae). Hyaline wings appear to have evolved multiple times in the Dioptinae (see Discussion: Wing Pattern).

While we were on an expedition (January 2009) to the Río Shiripuno in eastern Ecuador (S01°06′17″, W76°43′54″; 230 m), Wilmer Simbaña, from the Yanayacu Biological Station, discovered an Erbessa larva feeding on an unknown species of Miconia. The caterpillar pupated during our trip and I was able to bring it to Brooklyn, NY, where it emerged as an adult female of E. pales.

Distribution

Ecuador (AMNH, BMNH, CMNH, NMW); Brazil (BMNH); Peru (BMNH, CUIC, MUSM, ZMH); Bolivia (BMNH, LACM, ZMH).

Dissected

♂, Ecuador, Sarayacu, leg. C. Buckley, BMNH (genitalia slide no. JSM-467); ♀, Ecuador, Sarayacu, leg. C. Buckley, BMNH (genitalia slide no. JSM-468).

Erbessa papula (Dognin)

Figure 45A–D; plate 6

Myonia papula Dognin, 1923: 27.

Type Locality

Brazil, Amazonas, Taperinha.

Type

Syntype ♂, leg. Fassl (USNM type no. 30918).

Discussion

Erbessa papula is yet another Erbessa species showing an apomorphic condition of the male genitalia where the valva apex bears a membranous appendix (fig. 45A). The orange-yellow HW central area and olive-colored FW seem to establish a relationship between E. papula and three additional species—E. priverna, E. celata, and E. unimacula (pl. 6).

A series of specimens from Suapure, Venezuela (CUIC) is extremely close in wing pattern to E. papula; these differ from papula type material in having a slightly larger, but less clearly defined, basal dash. Genital dissections show slight differences between the Venezuelan and Brazilian examples, but I have retained them as E. papula pending future research.

Distribution

Brazil (USNM); Venezuela (CUIC).

Dissected

Syntype ♂ (genitalia slide no. JSM-992); ♂, Venezuela, Suapure, Caura River, 26 Dec 1899, leg. E.A. Klages, CUIC (genitalia slide no. JSM-994); ♂, Venezuela, Suapure, Caura River, 18 Jan 1900, leg. E.A. Klages, CUIC (genitalia slide no. JSM-141); ♀ [“type”], Brazil, Amazonas, Taperinha, USNM (genitalia slide no. JSM-993); ♀, Venezuela, Suapure, Caura River, 23 Jan 1900, leg. E.A. Klages, CUIC (genitalia slide no. JSM-995).

Erbessa primula (Dognin), revised status

Plate 5

Myonia primula Dognin, 1919: 10.

Type Locality

Ecuador, Loja.

Type

Holotype ♂ (USNM, type no. 30917).

Myonia ederi Prout, 1918: 400. New synonymy.

Type Locality

Colombia (SE), Río Caqueta.

Type

Holotype ♀, leg. Dr. M. Eder and T. Alexander (BMNH).

Discussion

Erbessa primula was first described as a species (Dognin, 1919), but was relegated by Hering (1925) to a synonym of E. graba Druce. I here revise it to species status. After a series of dissections, along with grueling deliberation, I am now convinced that Prout's (1918) species “ederi” is a synonym of primula, and that together these constitute a taxon distinct from graba. This species complex, comprising primula, graba, and biplagiata (pl. 5), poses an extremely challenging taxonomic problem. More work remains before it can be fully resolved. Wing-pattern differences between these taxa are noted in the discussion of E. graba (above), and in the key to Erbessa species.

A lowland Brazilian species—Erbessa projecta (Warren), known from the female holotype (pl. 5)—may be yet another close relative of E. primula; the major difference between them is that the bright yellow to yellow-orange areas of the FW and HW in primula are instead light yellow to creamy white in projecta.

Distribution

Colombia (BMNH, USNM); Ecuador (AMNH, LACM, USNM); Peru (AMNH, CUIC).

Dissected

Holotype ♂ (genitalia slide no. JSM-972); ♂, Colombia, Caqueta, Morelia, Río Bodoquero, 430 m, 19–20 Jan 1969, leg. Duckworth & Deitz, USNM (genitalia slide no. JSM-1588); ♂, Ecuador, Sucumbios, Garza Cocha—Anyagu, 175 km ESE of Coca, La Selva, 23 Jul 1994, leg. P.J. DeVries, AMNH (genitalia slide no. JSM-1589); ♂, Peru, Putumayo, La Chorrera to La Sombra, 21 Aug 1920, leg. Diaz, CUIC (genitalia slide no. JSM-1594).

Erbessa priverna (Cramer)

Plate 6

Phalaena Noctua priverna Cramer, 1777: pl. 166 E, p. 108.

Type Locality

“Surinam”.

Type

Not seen.

Discussion

Erbessa priverna is a common Erbessa species in museum collections. Unlike many other members of the genus, males and females have been collected in approximately equal proportions. Based on its general appearance, E. priverna belongs in a species complex with celata, papula, and unimacula (pl. 6). Of these, it has the largest wingspan; the FW length of E. priverna females can reach 25.0 mm. I was unable to locate the type of priverna, but the color figure in Cramer (1777) is adequate to firmly establish the identity of this taxon.

Erbessa priverna is found in the Guyana Shield of northern South America, extending as far west as central Venezuela. It also occurs south into Brazil. Among the series of nearly 100 specimens at the BMNH, a single female of E. priverna was captured in Trinidad, B.W.I. (leg. T.T. Dyer, 1922). Only five species of Dioptinae have been recorded from Trinidad (appendix 2). Andres Orellana reared Erbessa priverna in Venezuela on an unidentified species of Miconia (table 4).

Material from the eastern slope of the Colombian and Ecuadorian Andes (LACM, BMNH, USNM) represents an undescribed species. These show a wing pattern similar to that of E. priverna, but differ in having a smaller FW costal bar. The FW length is also shorter. Dissections (JSM-469, 470; Colombia, Villavicencio, 400 m, leg. Fassl, BMNH) reveal their genitalia to be distinct.

Distribution

French Guiana (AMNH, BMNH, BHC, CAS, MNHN, NMW, OUMNH, USNM); Suriname (CUIC); Guyana (AMNH, BMNH, CMNH, USNM, ZMC); Venezuela (AMNH, CUIC, IZA, LACM, MNHN); Brazil (MCZ, BMNH, OUMNH); Trinidad (BMNH).

Dissected

♂, Guyana, Kamakusa, Dec 1922, AMNH (genitalia slide no. JSM-683); ♀, Venezuela, Río Carrao, Auyun Tepui—Río Iyavapa, 1000 ft, Mar 1993, leg. S. Fratello, AMNH (genitalia slide no. JSM-684).

Erbessa projecta (Warren)

Plate 5

Oricia projecta Warren, 1909: 71.

Type Locality

Brazil, Rio Madeira, Humayta.

Type

Holotype ♀, leg. W. Hoffmanns, Jul–Sep 1906 (BMNH).

Discussion

As far as I am aware, E. projecta is known exclusively from the holotype. It appears to be a light-colored version of Erbessa primula (pl. 5), endemic to Ecuador, Colombia, and Peru, and would thus belong in a species complex with primula, graba, and biplagiata. Its apparent relatives occur at elevations between 500 and 1000 meters along the eastern slope of the Andes. The habitat of E. projecta, Humayta (08°16′52″S, 72°02′06″W) in the Upper Amazon, is at an elevation of approximately 230 meters.

Distribution

Brazil (BMNH).

Dissected

None.

Erbessa prolifera (Walker), new combination

Figures 35B, 38C, 38F, 46; plate 4 [EX]

Josia prolifera Walker, 1854: 302.

Type Locality

Brazil, Ega.

Type

Syntype ♀, ex Bates Collection (BMNH).

Glissa bifacies Walker, 1864: 186.

Type Locality

Brazil, Ega.

Type

Syntype ♂, ex Bates Collection (BMNH).

Oricia grandis Bryk, 1953: 225.

Type Locality

Brazil, Amazonas, Solimões, Teffe.

Type

Holotype ♀ (not seen), leg. 15 Dec 1924, ex Melins Collection.

Adelphoneura nerias C. and R. Felder, 1874: pl. 105, fig. 31.

Type Locality

Amazon, Brazil.

Type

Holotype ♀ (BMNH).

Discussion

Perhaps because of its unusual wing pattern (pl. 4), Erbessa prolifera has had an interesting taxonomic history. Walker (1854) described it first in Josia (Josiini), and then again 10 years later, as Glissa bifacies, misplaced in the Chrysaugidae ( =  Pyralidae: Chrysauginae). Cajetan and Rudolf Felder (1874) also described this species, under the name nerias, in a genus they erected for it: Adelphoneura. Prout (1918) moved prolifera to Oricia, but his rationale was not clearly stated. The moth certainly does not resemble any other Oricia species. Subsequent authors (Hering, 1925; Bryk, 1930) followed Prout.

My cladistic results (fig. 3) suggest that prolifera instead belongs in Erbessa, in a basal position on the genus phylogeny. Characters of Erbessa, exhibited by E. prolifera are numerous: The male labial palpi are greatly elongate (fig. 35B)—with an elbowlike joint—extending upward well beyond the antennal bases, almost reaching the prothorax; Lp3 is short and bears a hooklike spine at its apex (fig. 35B); the long, threadlike male antennae are ciliate; and the foreleg epiphysis is extremely short. The wing venation of E. prolifera is characteristic of Erbessa—M3 being separate from CuA1 in the FW, but stalked with it in the HW—with one significant exception. In most Erbessa species, Rs1 arises from the DC (fig. 38A, B, E), whereas in E. prolifera (fig. 38F) the configuration is typical of most Dioptinae, including Oricia (fig. 31G), with Rs1 arising from the radial sector below Rs2–Rs4.

Based on similarities of the male genitalia, especially the narrow valva, small BO, and large operculum of the aedeagus (fig. 46A, C), Erbessa prolifera could potentially be a close relative of E. leechi Prout (fig. 44). The two differ dramatically in wing pattern, however, and my cladistic analysis utilizing adult morphology did not reveal a sister-group relationship between the two (fig. 3).

As has been the case with most other Felder types, I discovered a specimen at the BMNH, bearing labels with characteristic red handwriting, that undoubtedly represents the type of nerias. That moth, a female, appears to be conspecific with prolifera. I did not locate the type of grandis, described by Bryk (1953) as a subspecies of prolifera.

Although the majority of material has been collected in Brazil, E. prolifera seems to occur throughout the Upper Amazon north to Guyana. The species is not common; specimens of E. prolifera can be found in the collections of several museums, but usually only one or two individuals in each. This is the smallest member of Erbessa (♂ FW length  =  11.0–11.5 mm).

Distribution

Brazil (CUIC, BMNH, NMW, SDNH, USNM, VOB, ZMH); Guyana (BMNH); Peru (BMNH).

Dissected

♂, Brazil, Pará, leg. A.M. Moss, BMNH (genitalia slide no. JSM-212, wing slide no. JSM-1797); ♀, Peru, Yahuas Terr., BMNH (genitalia slide no. JSM-213).

Erbessa prouti (Hering)

Plate 4

Myonia prouti Hering, 1925: 503.

Type Locality

Brazil, Bahia.

Type

Holotype ♀, Séllo (ZMH).

Discussion

Erbessa prouti is known exclusively from the female holotype (pl. 4). Hering (1925: 503) suggested that prouti is related to E. augusta (Warren). However, dissection of the prouti type, along with study of its wing pattern, suggests that the species belongs in a complex with E. evippe, E. mitys and E. maera (pl. 4). Females of these share the following characteristics: FW with a white fringe near apex; HW without a yellow distal spot on ventral surface; base of HW ventral surface black. The female genitalia of prouti indicate that, although the species is similar in wing pattern to E. maera, from Petropolis, Brazil, the two are distinct. Their wing patterns differ only in that the transverse FW band is shorter in prouti, ending at the anal fold. In E. maera, the band extends almost to the wing margin, near the tornus. The anterior apophyses of the female genitalia are short and truncate in E. prouti, but longer and acute at their apices in E. maera.

Distribution

Brazil (ZMH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1776).

Erbessa pyraloides (Walker)

Figures 35C, 38D, 38G, 47; plate 5 [EX]

Chrysauge pyraloides Walker, 1854: 376.

Type Locality

Brazil, Tapajos.

Type

Syntype ♂, ex E. Doubleday Collection (BMNH).

Discussion

According to Biezanko (1962a), Erbessa pyraloides is a common species in the vicinity of Pelotas in southeastern Brazil. It is also well represented in many museum collections. The species can be recognized by its contrasting yellow-and-black wing pattern (pl. 5). It is also relatively large, with a male FW length of between 17.0 and 19.0 mm.

Among three Brazilian host-plant records for Erbessa pyraloides (table 4) is a description of it as an outbreak pest on Eucalyptus cloeziana (de Campos and Cure, 1992), an introduced tree occurring throughout South America. This is the second example of an Erbessa species in association with Myrtaceae, the other being E. stroudi, sp. nov. (pl. 5), from Costa Rica. Wing-pattern similarities suggest that these two species may be close relatives. Furthermore, their male genitalia exhibit an apomorphic feature of certain Erbessa species—presence of an appendix at the valva apex (figs. 47A, 49A).

Bryk (1930) recognized E. longiplaga (Warren) as a synonym of E. pyraloides. However, after studying the type of longiplaga and having dissected a male and female, I here reinstate that name to species status (see above).

Distribution

Brazil (BMNH, CUIC, LACM, MPM, NMW, USNM, ZMC, ZMH); Colombia (ZMH); Venezuela (CAS).

Dissected

♂, Brazil, Río de Janeiro, 7 June 1934, leg. P. Gagarin, J.R. Neidhoefer Collection, MPM (genitalia slide no. JSM-642); ♀, Brazil, Río de Janeiro, 16 July 1934, leg. P. Gagarin, J.R. Neidhoefer Collection, MPM (genitalia slide no. JSM-643).

Erbessa quadricolor (Walker)

Plate 5

Phaeochlaena quadricolor Walker, 1856: 1677.

Type Locality

Brazil, Pará.

Type

Holotype ♀ (OUMNH).

Discussion

The type of quadricolor is unusual for Walker species in being housed at the Oxford University Museum of Natural History, rather than at the Natural History Museum, London. The BMNH collection includes a fairly large series, all from Pará, the quadricolor type locality. Based on dissection of a male and female (JSM-472, 473), E. quadricolor (pl. 5) is closely related to E. papula (pl. 6). Both exhibit a greenish-gray FW ground color and an orange-yellow HW central area. The wing patterns of the two differ mainly in the size and shape of the FW basal dash and cross bar, both of which are larger and more prominent in quadricolor. On the ventral surface their wings are the same, and the body markings seem to be identical. The valvae of the male genitalia in E. quadricolor and E. papula bear a small, ovoid, membranous appendix, attached to the apex by a threadlike duct. Presence of this unusual structure potentially serves as a synapomorphy uniting several Erbessa species, including E. dominula, E. longiplaga, E. pyraloides (fig. 47A), and E. stroudi (fig. 49A).

Distribution

Brazil (BMNH, OUMNH, USNM, ZMH).

Dissected

♂, Brazil, Pará, leg. A.M. Moss, BMNH (genitalia slide no. JSM-472); ♀, Brazil, Pará, BMNH (genitalia slide no. JSM-473).

Erbessa regis (Hering)

Plate 5

Myonia regis Hering, 1925: 502.

Type Locality

Peru, Puerto San Mateo.

Type

Holotype ♂, leg. Garlepp, 1894 (ZMH).

Discussion

Erbessa regis appears to be widely distributed across the upper Amazon Basin, from Bolivia north to Ecuador. Of the 18 known specimens, Phil DeVries collected the only female (JSM-1604). A CMNH female from Brazil (Hyutanahan, Rio Purus, Feb 1922, leg. S.M. Klages) probably represents an undescribed species. This differs from E. regis in showing dark streaks along the HW inner margin, radiating from the base. The species most similar in wing pattern to E. regis is E. stroudi, sp. nov. (pl. 5), endemic to Costa Rica. These two can be separated by the shape of the yellow basal FW triangle (see species key, above).

Distribution

Ecuador (AMNH); Peru (AMNH, BMNH, CUIC, MUSM, ZMH); Bolivia (AMNH, CMNH).

Dissected

♂, Peru, Junín, Palcazu, leg. Sedlmayr, BMNH (genitalia slide no. JSM-471); ♀, Ecuador, Sucumbíos, Garza Cocha—Añyangu, 175 km ESE of Coca, La Selva, 2 Sep 1994, leg. P.J. DeVries, AMNH (genitalia slide no. JSM-1604).

Erbessa saga (Hering)

Plate 3

Myonia saga Hering, 1925: 505.

Type Locality

Venezuela, Puerto Cabello.

Type

Holotype ♀, leg. Hahnel (ZMH).

Discussion

My knowledge of Erbessa saga is based on three specimens—the female holotype in Berlin, a male in the BHC, and a female at the CMNH. Superficial study of that material suggests that E. saga belongs in a species complex with E. clite, E. continens, and E. labana (pl. 3). Erbessa saga can be recognized by its yellow transverse FW band, combined with presence of an elongate yellow mark on the HW ventral surface, originating at the apex and extending toward the base. The FW veins stand out in contrast with the dark brown ground color, and the FW is quite sharply angled at its apex. A female example from northern Venezuela (CMNH) is similar to the saga type, but shows a shorter transverse FW band.

Distribution

Venezuela (CMNH, ZMH); French Guiana (BHC).

Dissected

None.

Erbessa salvini (C. and R. Felder)

Plate 4

Dialephtis salvini C. and R. Felder, 1874: pl. 105, fig. 14.

Type Locality

“Guatemala”.

Type

Syntype ♀ (BMNH).

Discussion

Three names—E. salvini, E. semimarginata and E. bicurvata—pose a difficult taxonomic problem. In this paper, I recognize only two, placing bicurvata Bastelberger (1908) as a junior synonym of semimarginata Dognin (1902). The remaining problem is to separate E. salvini and E. semimarginata. A distinguishing feature of the HW, best seen on the ventral surface, was noted by Dognin (1902) and Hering (1925): (1) Material in which the dark brown marginal band (pl. 4) extends along the HW anterior margin to the base should be referred to Erbessa salvini, known from Costa Rica, Nicaragua, and Guatemala; (2) material in which the brown marginal band terminates near the apex so that the HW anterior margin is orange-yellow should be called Erbessa semimarginata (pl. 4), endemic to Colombia. The wings of E. salvini tend to be lighter yellow overall, whereas E. semimarginata is more orange-yellow. However, this feature is difficult to assess without having examples of both species at hand. Male and female genitalia in the two species differ in subtle ways, most notably in the length of the costa of the valvae—short in E. salvini, but longer in E. semimarginata.

The question now arises, which species occurs in Panama? I was able to locate only two Panamanian specimens—a male from Chiriquí (MNHN, leg. T. Porion) and a female from Cerro Campana (USNM, leg. G.B. Small). Based on the diagnostic traits given above, the male is E. semimarginata whereas the female is E. salvini. I conclude that both species occur in Panama. Undoubtedly, there is more to this story than meets the eye.

It is interesting that only five described species of Erbessa occur in Central America—albilinea, lindigii, salvini, semimarginata, and stroudi. The 55 remaining Erbessa are exclusive to South America, with the vast majority of those endemic to the Amazon Basin.

Janzen and Hallwachs (2008) established the host plant of Erbessa salvini as Henriettea tuberculosa (table 4). The moth thus mirrors most Erbessa species in its association with Melastomataceae, but is unusual in feeding on a plant genus other than Miconia.

Distribution

Guatemala (BMNH); Nicaragua (BMNH); Costa Rica (AMNH, BMNH, INBio); Panama (USNM).

Dissected

♂, Costa Rica, Guanacaste, P.N. Guanacaste, Estación Pitilla, 9 km S Santa Cecilia, 700 m, Sep 1989, leg. C. Moraga and P. Rios, 330200.380200, INBio (genitalia slide no. JSM-967); ♂, Costa Rica, San José, P.N. Braulio Carrillo, Estación Carrillo, 700 m, Nov 1984, leg. I.A. Chacón, INBio (genitalia slide no. JSM-797); ♀, Costa Rica, Heredia, 3 km SW Puerto Viejo, Finca La Selva, 75 m, 29 May 1971, leg. Opler, AMNH (genitalia slide no. JSM-798); ♀, Costa Rica, Guanacaste, P.N. Guanacaste, Estación Pitilla, 9 km S Santa Cecilia, 700 m, Jun 1994, leg. C. Moraga, L N 330200_380200, #3001, INBio (genitalia slide no. JSM-968).

Erbessa seducta (Prout)

Plate 3

Myonia seducta Prout, 1918: 403.

Type Locality

Venezuela, San Esteban.

Type

Holotype ♂, leg. S.M. Klages, Jul 1909 (BMNH).

Discussion

Erbessa seducta is extremely rare, known only from the male holotype (pl. 3) and a single female at the CMNH (JSM-1679). The moth, endemic to Venezuela, is distinctive in size, wing shape, and wing pattern. The wings of E. seducta somewhat resemble those of an E. cingulina phenotype originally described by Hering as quadriguttata. In both, the light yellow FW fascia and HW central area are small, and the HW anal margin is bordered with light yellow. However, E. seducta differs in exhibiting a lighter brown FW ground color, and in having yellow lining the FW veins, rather than ochreous brown. The wings of E. seducta (FW length  =  15.0–16.0 mm) are slightly shorter than in most examples of E. cingulina (male FW length  =  14.0–18.0 mm).

Distribution

Venezuela (BMNH, CMNH).

Dissected

♀, Venezuela, Esteban Valley, Las Quiguas, CMNH (genitalia slide no. JSM-1679).

Erbessa semimarginata (Dognin)

Plate 4

Dialephtis semimarginata Dognin, 1902: 342.

Type Locality

Colombia (“Côtes de Colombie”).

Type

Holotype ♀, Dognin Collection (USNM type no. 30916).

Dialephtis bicurvata Bastelberger, 1908: 267. New synonymy.

Type Locality

Colombia, Muzo.

Type

Holotype ♀ (BMNH).

Discussion

Erbessa semimarginata, known from Panama south to Peru, is the sister species of E. salvini (pl. 4), which occurs from Panama north to Guatemala. The two are extremely similar in wing length and wing pattern, but a reliable method for separation is provided above (see Discussion for E. salvini). Of the two, E. semimarginata is better represented in collections; the USNM holdings include a large series from Villavicencio near Bogotá, at 600 meters on the eastern slope of the Andes. The single record of this species for Peru (BMNH) deserves further study. To my knowledge, no examples of E. semimarginata have been captured in Ecuador.

I treat bicurvata, considered a valid species by previous authors (Prout, 1918; Hering, 1925; Bryk, 1930), as a junior synonym of semimarginata. My rationale is based on comparison of male and female genital dissections for specimens matching both types; I found no morphological differences. In his original description, Bastelberger (1908) suggested that bicurvata differs from E. semimarginata in showing more black along the FW anal margin. My study of material captured at a single locality suggests that this difference is not consistent.

Distribution

Colombia (AMNH, BMNH, USNM); (MNHN); Panama (MNHN); Peru (BMNH).

Dissected

Holotype ♀ (genitalia slide no. JSM-969); ♂, Colombia, Villavicencio, Amazonas, Dognin Collection, USNM (genitalia slide no. JSM-963); ♂, Colombia, Santa Fé de Bogotá, 1907, Acq. Donckier, BMNH (genitalia slide no. JSM-965); ♂, Panama, Chiriquí, Rte Gualaca-Fortuna, PK 32, Hornito, 1000 m, 4–9 May 1980, leg. T. Porion, MNHN (genitalia slide no. JSM-970); ♀, Colombia, Amazonas, Villavicencio, Dognin Collection, USNM (genitalia slide no. JSM-964); ♀, Colombia, Muzo, 400–800 m, leg. Fassl, BMNH (genitalia slide no. JSM-966).

Erbessa semiplaga (Warren)

Plate 6

Phelloe semiplaga Warren, 1905: 315.

Type Locality

Colombia, Cundinamarca, Cananche.

Type

Holotype ♀, leg. M. de Mathan, Jul 1903 (BMNH).

Discussion

Erbessa semiplaga belongs in a difficult complex that includes E. sobria and E. corvica (pl. 6). Even after lengthy study, species boundaries within this subgroup remain obscure. The type of E. semiplaga is a female with gray-brown FW ground color, a white ovoid FW spot beyond the DC, and a narrow white HW central area. The HW lacks a white spot at its apex on the ventral surface. Such a spot is characteristic of E. sobria (pl. 6), but does not occur in corvica. A USNM female from Villavicencio (pl. 6) matches the semiplaga type precisely and is, with little doubt, a verified example of the species. Other than this, the BMNH specimen dissected (JSM-981) and the type are the only confirmed examples of E. semiplaga I have seen.

Erbessa semiplaga is extremely similar in wing pattern to E. corvica Dognin, from Bolivia. The two differ in that semiplaga (FW length  =  18.5 mm) is larger than corvica (FW length  =  14.0–15.0 mm), and the white HW central area is more constricted along its posterior margin. A simple method for distinguishing the two concerns the coloring of the front, which is gray-brown with white outer margins in corvica, but is entirely light yellow in semiplaga.

Distribution

Colombia (BMNH, USNM).

Dissected

♀, Colombia, Muzo, 400–800 m, leg. Fassl, BMNH (genitalia slide no. JSM-981).

Erbessa sobria Walker

Figure 48; plate 6; plate 37B, C [EX]

Erbessa sobria Walker, 1854: 319.

Type Locality

Brazil, Pará.

Type

Syntype ♀, Bates Collecton (BMNH).

Phelloe glaucaspis Walker, 1854: 320. New synonymy.

Type Locality

Brazil, Pará.

Type

Syntype ♂, Bates Collection (BMNH).

Discussion

Erbessa sobria can be recognized by the steely, blue-gray FW ground color and white transverse oval, as well as by the presence of two white areas on the wing ventral surfaces (pl. 6)—a small, inconspicuous fringe lining the FW apex, and a prominent spot at the HW apex. The size and shape of the semihyaline, white HW central area varies, as does the size and shape of the FW oval. Variation of this kind is typical of Erbessa.

Walker's two syntypes of Erbessa sobria—both females collected at Pará—were discovered at the BMNH, obscured in their main collection, thanks to the efforts of Martin Honey and his incredible knowledge of the holdings in London. After careful study of these types, I have concluded that Erbessa glaucaspis Walker, previously known exclusively from males, is conspecific with E. sobria, known from females. Features of their wing patterns are entirely consistent with those of other Erbessa male-female pairs, and the types of both taxa were collected at Pará. Walker (1854) described sobria and glaucaspis only one page apart in the same publication, at that time placing them in the genus Dioptis. Within Dioptis he erected “Group 2, Erbessa” for sobria, and “Group 3, Phelloe” for glaucaspis, thus essentially creating two different genera for the same species.

Luis Daniel Otero reared Erbessa sobria (pl. 37B, C) in Venezuela on the plant genus Miconia (Melastomataceae).

Material from western Ecuador is superficially similar to E. sobria, but dissection (♂, Ecuador, Los Ríos, La Chima, Río de las Juntas, pr. Bahahoyo, Jun–Jul 1893, leg. M. de Mathan, BMNH, genitalia slide no. JSM-1491) reveals it to be an undescribed species, differing from sobria in the shape of the socii/uncus complex. Known museum material (AMNH, LACM, BMNH) includes four males and three females. I leave description of this taxon for future work.

Distribution

Brazil (BMNH, NMW); Colombia (BMNH, USNM); Ecuador (LACM); Peru (CUIC, MUSM); Venezuela (AMNH, BMNH); Guyana (MNHN).

Dissected

♂, Colombia, Antioquia, Santa Elena, 8000 ft., Jul 1920, leg. A. Hall, BMNH (genitalia slide no. JSM-398); ♀, Colombia, Antioquia, Santa Elena, 8000 ft., Jul 1920, leg. A. Hall, BMNH (genitalia slide no. JSM-399).

Erbessa stroudi, new species

Figures 36, 37, 40, 49; plate 5; plate 37D, F

Diagnosis

The wing pattern of Erbessa stroudi shows basic similarities to that of E. pyraloides (pl. 5), from South America, a fairly common species in collections. However, the closest relative of stroudi appears to be the much rarer E. regis (pl. 5), known from Ecuador, Peru, and Bolivia. Several pattern differences can be used to separate E. regis and E. stroudi: First, the yellow of the HW in regis is more darkly pigmented than the yellow of the FW; in E. stroudi the FW and HW are equally pigmented. Second, in stroudi there is a diffuse blackish streak in the yellow central area of the HW, extending along the anal fold from the base outward approximately one-third of the wing's length (longer in females). The corresponding HW streak of E. regis is much shorter. The final wing-pattern difference involves the shape of the basal FW triangle. Its anterior margin is straight in stroudi, but is excavated near the base in regis. Erbessa regis shows a small, light yellow basal streak along the SC near this excavation. A basal streak does not appear in E. stroudi.

A body character useful for separation involves the middorsal abdominal stripe—wide at its base in E. regis, but relatively narrow in E. stroudi. The most obvious difference between E. stroudi and these similar appearing Erbessa species is their geographic distributions—both E. pyraloides and E. regis occur exclusively in South America, whereas E. stroudi is endemic to Costa Rica. The male genitalia of E. stroudi (fig. 49A–D) and E. regis are extremely similar, differing mostly in the size and shape of the membranous area at the valva apex.

Description

Male. Figures 36, 37; plate 5. Forewing length  =  16.0–18.5 mm. Head: Labial palpus elongate, curving over front, apex extending beyond antennal base; Lp1 rich, yellow-orange; Lp2 creamy yellow on dorsal and ventral surfaces, blackish brown on sides; Lp3 brownish black on ventral surface, creamy yellow above; front clothed with short, upwardly pointing, creamy yellow scales which extend beyond antennal bases; occiput yellow-orange; eye large, rounded outward, gena narrow; vertex brownish black with a yellow-orange streak along midline; antenna extremely long, threadlike; scape brownish black above, creamy yellow below; dorsal surface of antennal shaft blackish brown.

Thorax: Prothoracic pleuron and patagium yellow-orange; procoxae yellow-orange on outer surface, cream colored inside, dark brown laterally; rest of prothoracic legs creamy white on inner surfaces, dark brown on outer surfaces; meso- and metathoracic legs creamy white on inner surfaces, dark brown on outer ones; tegulae covered with long, orange-yellow scales, trimmed on lateral margins with blackish brown scales; dorsum blackish brown with a yellow-orange stripe along midline and a few yellow, hairlike scales laterally; pleuron of mesothorax cream colored, with a dark brown patch below wing base; metathorax clothed in long, cream-colored to creamy yellow scales; tympanum small, membrane ovoid, facing ventrally.

Forewing: (Dorsal) A rich, yellow-orange triangle in basal half, extending to four-fifths out on DC; triangle touching anterior margin of DC and extending posteriorly to 1A+2A; a dome-shaped, yellow-orange subapical spot, extending from R1 to CuA1; costa yellow-orange in basal third; anterior, outer, and anal margins bordered with blackish brown, border widest near apex; a wide, blackish-brown transverse band from costa to tornus, straddling discocellular veins of DC. (Ventral) Pattern almost identical to dorsal surface, except brown areas slightly lighter in color.

Hind wing: (Dorsal) Central area rich yellow-orange; a blackish streak along anal fold from base to one-third out; a shorter, blackish basal streak along midline of DC; outer margin broadly bordered with black from apex to tornus, border wider at apex and near anal fold; anterior margin cream colored to whitish yellow; anal margin edged with blackish brown. (Ventral) Pattern as in dorsal surface except anterior margin completely yellow, and brown areas slightly lighter in color.

Abdomen: Dorsum black, a yellow-orange dorsal stripe along midline from base, narrowing distally, dorsum of A8 completely black; pleuron with thin, yellow-orange lateral stripes from base to end of A7; venter creamy white.

Terminalia (fig. 49A–D): Lateral margins of Tg8 parallel, posterior margin slightly concave, anterior margin with two, broadly rounded apodemes; St8 longer than Tg8, widest at anterior margin, gently tapering toward apex; posterior margin with a poorly defined, narrow, deep mesal excavation; uncus/socii complex small, narrowly attached to tegumen; uncus arching downward, its apex truncate; socii thin, porrect, gently curving upward; tegumen shorter than vinculum, sides thin, parallel; vinculum narrow in dorsal half, much wider below; saccus forming a large, upturned envelope with a small mesal process at dorsal margin; valvae membranous; BO extremely large, occupying most of valva, membrane delicate, androconia long and hairlike; costa of valva thinly sclerotized, arching downward at apex; apex of valva membranous, surface finely wrinkled, ventrolateral portion of apex bearing a small, ovoid, membranous appendix; transtillar arms narrow at base, wider distally, pointing sharply downward from valvae, forming a small transverse sclerite at midline; anal tube elongate, upright; aedeagus long, moderately wide, ventral margin sinuate; apex terminating in a long, slightly down-curved point; vesica moderately large, almost as long as aedeagus, bearing deciduous caltrop cornuti in distal portion, a transverse row of long, spinelike cornuti near base.

Female. Forewing length  =  16.5–18.5 mm. Head: Coloring similar to males; labial palpus shorter and thinner.

Thorax: Similar to males.

Forewing: Pattern similar to males except: yellow and brown areas slightly lighter in color; dome-shaped subapical spot larger, extending from R1 to CuA2.

Hind wing: Pattern similar to males, but basal streak along anal fold longer, greater than one-half wing length; anal margin a mixture of blackish-brown and yellow scales.

Abdomen: Coloring similar to males but yellow areas lighter; apex truncate, not long and narrow as in males.

Terminalia (fig. 49E): Tg8 a wide transverse band, membranous at midline; anterior apodemes extremely short, apices acute; DB extremely short; ostium short, sclerotized, dorsoventrally compressed, curved downward near middle; PA moderately large, almost membranous, posterior margin simple; CB ovoid, membrane with deep wrinkles; upper third of CB smoothly sclerotized; signum large, ovoid, internal surface coarsely dentate, located ventrolaterally on left side; DS arising dorsally from sclerotized portion of CB.

Etymology

This species is named in honor of Steven M. Stroud and his family, Myra Bonilla and Michael Stroud Bonilla, of San José, Costa Rica, in recognition of their more than two decades of extreme enthusiasm for protecting and supporting the Area de Conservación Guanacaste (ACG), where the type series of E. stroudi was reared and where the species should survive forever, owing to Stroud-supported rain forest conservation.

Distribution

Erbessa stroudi occurs on both slopes of the Cordillera Central in northern Costa Rica (fig. 40), almost from coast to coast. The type series was captured as larvae near Estación Cacao (ACG), on the Pacific face of Volcán Cacao in the northwestern portion of the country. The moth has also been collected on the eastern side, occurring from Braulio Carrillo east to Barra del Colorado and Cerro Cocori, a few kilometers from the Caribbean ocean. Erbessa stroudi has been recorded at elevations ranging between 10 and 1100 meters. Dan Janzen and his colleagues have reared most of the existing specimens, as part of an ongoing inventory of the caterpillar fauna of the ACG. Wild-caught adult material, in the holdings of INBio and SMNS, comes from eastern sites in three different Costa Rican provinces—Limón, Heredia, and Alajuela. This species thus appears to be quite widespread in lowland to midelevation forests. Presumably these habitats coincide with the distribution of its host plant (see below).

Biology

The host plant of E. stroudi is Eugenia valerii (Myrtaceae). Eugenia is the largest genus of neotropical Myrtaceae, with over 500 included species (Gentry, 1993). This plant association sets E. stroudi apart from most other Erbessa species for which hosts are known; these specialize on Miconia, Conostegia, or Henriettea, all in the Melastomataceae (table 4). Interestingly, a Brazilian Erbessa species, E. pyraloides, has been reported from Eucalyptus, a genus of Myrtaceae introduced to the American tropics.

The team of caterpillar specialists at ACG has discovered larvae of E. stroudi nearly 30 separate times on Eugenia valerii, with a single record from a second species of Myrtaceae, as yet unidentified. The caterpillars (pl. 37D, F) exhibit long stemapods on A8, typical of Erbessa larvae. Their body coloration is also typical for the genus. Erbessa stroudi immatures are most frequently found in rainforest understory at elevations between 640 and 1140 m elevation (D. Janzen, personal commun.).

Discussion

Erbessa stroudi is the fifth described species of Erbessa known to occur in Central America, the other four being E. albilinea, E. lindigii, E. salvini, and E. semimarginata. Erbessa stroudi belongs in a taxonomically complex clade of yellow Erbessa species in which the male valva bears a membranous appendix at its apex (figs. 45A, 47A, 49A). The precise phylogenetic position of E. stroudi within this group is unknown. The clade includes E. salvini, among others, but not E. lindigii or E. albilinea.

The adult type material for this species originates from caterpillars, collected in the field on their host plant. This reared material is slightly smaller than wild-caught examples. Therefore, FW lengths listed in the description are probably short compared to what would exist if all the material had been collected as adults.

Holotype

Male (pl. 5). Costa Rica: Guanacaste: Area de Conservación Guanacaste, Sector Cacao, Sendero Toma Agua, 1140 m, 10.93°N, 85.47°W, 17 Jan 1998, leg. Ruth Franco, Voucher # 98-SRNP-2053. The holotype is deposited in the INBio collection, Heredia, Costa Rica.

Paratypes

Costa Rica: Guanacaste: Area de Conservación Guanacaste, 1♂, 3♀♀, Sector Cacao, Sendero Arenales, 1080 m, 10.92°N, 85.47°W, 31 Nov 1998, leg. Mariano Pereira, Voucher #'s 98-SRNP-15778, 15779, 15780, 15784 (INBio; male genitalia slide no. JSM-1307, female genitalia slide no. JSM-1309).

Other Specimens Examined

Costa Rica: Alajuela: 1♂, Fca. San Gabriel, 16 km ENE Quebrada Grande, 650 m, Jul 1988, leg. Gauld & Mitchell (INBio); 1♂, P. N. Volcán Tenorio, Alberque Heliconias, L N 300250, 423500, 700 m, Aug 2001, leg. G. Rodriguez, #64124 (INBio). Heredia: 1♀, N. P. Braulio Carrillo, W Río Peje, Puesto Ceibo, 10°19.5′N, 84°04.8′W, 550 m, 19 Apr 2003, rainforest, Blacklight 30W, EC b (4), 18.30–19.30 h, leg. Gunnar Brehm (SMNS). Limón: 1♂, Río Sardinas, R.N.F.S. Barra del Colorado, L-N 291500, 564700, 10 m, 12–20 Sep 1993, leg. F. Araya, (INBio); 1♀, 14 Oct 1992, leg. F. Araya (INBio, genitalia slide no. JSM-1308); 1♂, Sector Cerro Cocori, Fca. de E. Rojas, L-N-286000, 567500, 150 m, Oct 1991, leg. E. Rojas (INBio).

Dissected

1♂, 2♀♀.

Erbessa tapajoza (Dognin)

Plate 3

Myonia tapajoza Dognin, 1923: 28–29.

Type Locality

Brazil, Amazonas, Rio Tapajoz.

Type

Holotype ♀, leg. Fassl (USNM type no. 30919).

Discussion

Erbessa tapajoza, a relatively small Erbessa species (FW length  =  14.0 mm), is easy to recognize by the shape of its conspicuous light yellow FW and HW bands. In addition, the FW veins stand out in contrast against an olive-brown ground color. I know E. tapajoza from three Brazilian female specimens—the holotype, another USNM example, and a specimen in the Vitor Becker Collection. A different USNM female, apparently collected in Venezuela, shows more constricted yellow FW and HW markings, and possibly represents a distinct species.

Distribution

Brazil (USNM, VOB).

Dissected

None.

Erbessa tegyroides, new species

Figures 43, 50; plate 4

Diagnosis

This relatively small moth (FW length  =  12.0–14.0 mm) has an appearance unlike any other Erbessa species (pl. 4). The dioptines to which E. tegyroides is most similar in size and wing pattern include Proutiella tegyra and P. jordani, both in the Josiini (pl. 26). These taxa exhibit an orange-yellow, oblique transverse FW band against a black ground color, as well as a HW with a white central area and a wide, black outer margin. They differ in the presence of a creamy yellow basal streak in the FW of tegyroides, absent in tegyra. Obviously, the two are also separable by a multitude of tribal and generic characters. For example, E. tegyroides exhibits the wing venation characteristics of Erbessa: FW vein Rs1 arising from DC; veins M3 and CuA1 separate in FW, stalked in HW. In contrast, P. tegyra shows wing venation traits of the Josiini: FW vein Rs1 arising from radial sector; veins M3 and CuA1 stalked in FW and HW. Another simple way to distinguish the two is by their labial palpi, which are greatly elongate, folded over the front in tegyroides, but short and porrect in tegyra. Additional differences can be found in the structure of the tympanum, antennae, and genitalia.

The only known male of E. tegyroides (pl. 4) differs markedly from the three females. Here, the HW central area is not white on its dorsal surface, but instead bears an elongate orange spot extending from the posterolateral angle of the DC to the fork of M3 and CuA1. The male shows the white HW central area below, but again differs from females in that this portion has a light orange area near its outer margin.

Description

Male (pl. 4). Forewing length  =  12.0 mm. Head: Labial palpus greatly elongate, curving upward, apex extending to antennal base; Lp1 relatively short, ovoid, all surfaces closely covered with cream-colored scales; Lp2 narrow, almost three times as long as Lp1, curving gently outward near middle, widest in basal third, then gradually tapered toward apex; lateral and mesal surfaces of Lp2 covered with short brown scales, dorsal and ventral surfaces creamy white; apex of Lp2 bearing a short, tight tuft of creamy yellow scales, obscuring Lp3; Lp3 extremely short, conical, with a long spine at apex; front covered with long, creamy white scales pointing dorsomedially, dorsal scales longer, forming short tufts between antennal bases; occiput creamy white, scales longer below; eye moderately large, bulging, with thin scaleless bands anteriorly and posteriorly, gena scaleless, relatively narrow; vertex covered with long, anteriorly directed brown scales and a few scattered cream-colored scales; antenna extremely long and thin, pectinations absent, venter densely covered with setae; scape brown on dorsal surface, creamy white below; dorsum of antennal shaft closely covered with appressed, glossy brown scales, a thin line of cream-colored scales laterally.

Thorax: Procoxa creamy white anteriorly, light brown posteriorly; rest of legs white to creamy white on inner surfaces, light brown on lateral ones; pleuron covered with a mixture of long yellowish, white and light brown scales; patagium with long, creamy white scales, curving posteriorly, a thin row of brown scales posteriorly; ventral portion of tegula white with a few yellowish scales, dorsal portion of tegula with long, white and yellowish scales on mesal margin, lateral margin with long, hairlike brown scales; dorsum brown, with a diffuse creamy white stripe along midline; tympanum with a moderately large, shallow scaleless depression; tympanal membrane small, ovoid, oriented almost horizontally.

Forewing: (Dorsal) Ground color dark brown to blackish brown; a narrow, creamy yellow basal streak in basal fourth along anterior margin of DC; a second larger, creamy yellow, elongate dash behind DC from base to one-third out, its anterior margin along anal fold, its posterior margin touching 1A+2A; a wide, orange, oblique transverse band passing through distal third of DC; orange band extending to slightly short of costa anteriorly, crossing anal fold posteriorly, but falling well short of tornus, lateral margin extending out to distal margin of DC. (Ventral) Similar to dorsal surface, except ground color lighter, basal streak absent, basal dash white, not creamy, located more anteriorly, immediately behind DC, transverse orange band slightly wider; subcosta white in basal fourth; costa cream colored in basal third.

Hind wing: (Dorsal) Ground color blackish brown, slightly lighter near base; a small, elongate oval shaped orange spot in central area, straddling posterolateral angle of DC and fork of M3+CuA1; orange spot infused with blackish brown scales along margins, especially toward base; anterior wing margin white from base to near apex; gray to gray-brown scales along 2A and 3A; anal margin white, fringed with long white hairlike scales. (Ventral) Silvery white with a wide, blackish brown marginal band; marginal band much wider at apex, gradually tapered toward tornus; silvery white portion enclosing a large, diffuse area of orange scales in outer half; anterior margin broadly white from base to near apex; anal margin silvery white.

Abdomen: Elongate; dorsum steely gray-brown with a bluish iridescence; posterior margin of Tg1-Tg4 with a white spot at midline; posterior margin of Tg5 and Tg6 with a wide ring of white scales; pleuron gray-brown with a white longitudinal stripe; venter creamy white.

Terminalia (fig. 50A–D): Tg8 short, anterior margin with two extremely short, wide apodemes in either side of midline, lateral margins rounded slightly outward, posterior margin with a shallow, U-shaped mesal excavation; St8 long, narrower than St7 but wider than Tg8, anterior margin with a long, wide mesal apodeme, its apex gradually tapered; mesal apodeme half as long as St8, its posterior margin with a small, tonguelike fold; posterolateral angles of St8 forming thin processes; lateral margins of St8 bowed outward slightly near middle, then gradually narrowed toward posterior margin, posterior margin with a faint, deep, U-shaped mesal excavation; uncus/socii complex extremely small, narrowly attached to ring; uncus small, dorsum arching smoothly downward, apex minutely truncate, ventral surface rugose; socii narrow, digitate, longer than uncus, drooping downward near apices; tegumen thin, much shorter than vinculum; vinculum tall, narrow dorsally, extremely wide ventrally, joining saccus to form a huge, wide envelope below, this folded upward to enclose valva bases; dorsal margin of saccus with a straplike process at midline; valvae almost completely membranous; BO extremely large, occupying most of valva, membrane delicate, heavily pleated; dorsal margin of BO forming a long, straplike sclerite; costa lightly sclerotized, narrow, short, curving gently upward; apex of valva mostly membranous, delicate, with a thin, down-curved sclerite; a tiny, ovoid, membranous appendix immediately below valva apex; transtillar arms relatively wide, curving sharply downward to form a simple junction at midline; anal tube greatly elongate, upright; valva bases relatively wide; juxta small, dorsal margin transverse, ventral margin U-shaped; aedeagus relatively long, moderately wide, abruptly narrowed in basal fifth to form a necklike constriction; apex of aedeagus with a long, thin dorsal sclerite and a small, acute ventral process; vesica wider than aedeagus, over two-thirds as long; distal portion of vesica bearing deciduous caltrop cornuti, a transverse row of eight long, spinelike cornuti near middle.

Female (pl. 4). Forewing length  =  13.5–14.0 mm. Head: Similar to male except labial palpus shorter, curving upward to above middle of front, but well below antennal base; Lp1 short, roughly ovoid; Lp2 narrow, over twice as long as Lp1; Lp3 short, conical; antenna thin, ventral surface densely covered with fine cilia.

Thorax: Similar to male.

Forewing: (Dorsal) Broader and longer than male; pattern similar to male but basal streak more diffuse, transverse band narrower, lighter in color, yellow-orange rather than orange. (Ventral) Similar to male, except white basal dash behind DC more diffuse, subcosta with only a few whitish scales at base, costa entirely brown.

Hind wing: (Dorsal) Differs from male in having a large, immaculate white central area, no orange spot; a wide, blackish brown marginal band, widest near apex; anterior margin of white area extending to immediately beyond DC, posterior margin touching 2A; white area extending from near base out to stem of M3+CuA1, outer margin unevenly curved; radius and anal fold thinly lined with dark brown scales from base as they pass through white area; anterior margin a mixture of white and gray-brown scales from base to near apex; anal margin broadly covered with a mixture of whitish and gray-brown scales, fringed with long whitish and gray scales. (Ventral) Similar to dorsal surface, except marginal band dark brown, anterior margin brown, anal margin whiter.

Abdomen: Differs from male in lacking white rings on Tg5 and Tg6, white dorsal spots on Tg1-Tg4 fainter.

Terminalia (fig. 50E): Tg7 slightly tapered toward distal margin, anterior margin simple, posterior margin with a tiny mesal excavation; St7 narrower and slightly shorter than Tg7, somewhat tapered toward distal margin, anterior margin gently convex, posterior margin with a wide, U-shaped mesal excavation; Tg8 a narrow transverse band, tapered at lower angle near anterior apodemes; AA extremely short, apices acute; DB extremely short; ostium short, wide, lightly sclerotized, dorsoventrally compressed; CB roughly ovoid, membrane with deep transverse wrinkles; a pair of elongate, faint, lightly sclerotized areas along dorsum of CB posterior to attachment of DS; DS attached dorsally on CB, slightly less than halfway from base; signum located ventrally, relatively large, deeply infolded, inner surface coarsely dentate; PA small, lightly sclerotized, roughly triangular; PP moderately long, bent slightly downward distally.

Etymology

This species name was chosen to reflect the remarkable similarity between females of E. tegyroides and the josiine Proutiella tegyra.

Distribution

The type material of E. tegyroides was collected at a single site—Tambopata Reserve in southeastern Peru (fig. 43). In addition, a female specimen was located in the collections of the BMNH. That example, from Ecuador, does not bear precise locality data other than a label reading “4c”.

Biology

Cal Snyder (AMNH) collected a larva of E. tegyroides at Tambopata, feeding on a species of Miconia (Melastomataceae), and reared it through to produce an adult female (table 4).

Discussion

Erbessa tegyroides is a remarkable member of Erbessa because of its unusual wing pattern, resembling that of an unrelated dioptine—Proutiella tegyra. Not only are their wings extremely similar, but the moths are roughly the same size. No other described Erbessa species even remotely resembles tegyroides, yet it and P. tegyra have been collected along the same trail at Tambopata Reserve in Peru, thus implying that the two are co-mimics. Interestingly, moths from additional families appear to be involved in this mimicry complex at Tambopata, including species of Arctiidae and Pyralidae (see pl. 26).

A single Ecuadorian LACM specimen represents an undescribed species, the probable sister taxon to E. tegyroides. This example was collected at Dureño in Sucumbíos Province, approximately 20 km E of Lago Agrio on the Río Agurico, an endangered locale in the heart of Ecuador's oil reserves.

Holotype

Female (pl. 4). Peru: Madre de Dios: Tambopata Reserve, 12°51′S, 69°18′W, 200 m, day coll., 6 Dec 1996, leg. A. Brower. The holotype is deposited at the AMNH.

Paratypes

Peru: Madre de Dios: Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 1♂, Ant Trail, 10 Dec 1996, at light, leg. Snyder, Brower, Rab-Green, AMNH (genitalia slide no. JSM-1597); 1♀, Dec 1997, leg. C. Snyder, ex larva on Miconia sp. (Melastomataceae), AMNH (genitalia slide no. JSM-1598).

Other Specimens Examined

1♀, Ecuador, “4c”, BMNH.

Dissected

1♂, 1♀.

Erbessa thiaucourti, new species

Figures 51, 52; plate 7

Diagnosis

The two Erbessa species with which E. thiaucourti could potentially be confused are E. cassandra Druce and E. umbrifera Walker (pl. 7). All three taxa have the same basic wing pattern, consisting of a blackish brown ground color with iridescent blue streaks at the FW base, as well as blue iridescence in the HW. In all three, the FW shows a white transverse oval located across the distal portion of the DC, and the HW central area is semihyaline. However, E. thiaucourti can be instantly separated from the other two species by the presence of a white spot along the HW anterior margin. This spot, visible on the dorsal and ventral wing surfaces, is situated basal to the apex. Both E. cassandra and E. umbrifera exhibit a small white HW spot, but it occurs at the apical angle immediately below the apex, and appears only on the ventral surface. The position of the white spot on the HW leading edge in E. thiaucourti is unique for Erbessa. Another, more subtle, wing-pattern difference is found in the FW. Both E. cassandra and E. umbrifera show a small white spot or fringe at the FW apex. This does not occur in E. thiaucourti. Erbessa thiaucourti also has narrower wings than either of these others.

The male and female genitalia of E. thiaucourti (fig. 51) easily distinguish it from E. cassandra and E. umbrifera. For example, in the others the male valva has a wide costa, whereas the costa is narrow in thiaucourti. Furthermore, the female signum is large in thiaucourti but small in cassandra and umbrifera. There are numerous additional genital differences.

Description

Male (pl. 7). Forewing length  =  14.5–16.0 mm. Head: Labial palpus greatly elongate, curving upward, held close to front, apex extending beyond antennal base; Lp1 short and wide, ovoid, a thin, uneven brown to dark brown stripe along lateral surface, ventral surface broadly yellow-orange at base, creamy white toward apex, dorsum with scattered cream-colored scales; Lp2 roughly two and a half times as long as Lp1, lateral and mesal surfaces dark gray-brown with a blue iridescence, narrow cream-colored stripes along dorsal and ventral surfaces, dorsal stripe yellowish at base; distal portion of Lp2 with an acute dorsal tuft of long, cream-colored scales extending beyond apex of Lp3; Lp3 short, conical, gray-brown with a blue iridescence; front covered with short, dorsomedially pointing scales, forming small tufts between antennal bases, margins of front white, central area gray-brown with a blue iridescence; occiput yellow-orange except for a small, dark brown region near dorsum, ventral scales longer; eye moderately large, bulging, surrounded by thin scaleless bands, gena scaleless, extremely thin; vertex covered with moderately long, somewhat appressed, anteriorly directed brown scales with a blue iridescence; antenna extremely long and thin, pectinations absent, venter densely covered with setae; scape gray-brown with blue iridescence dorsally, creamy white ventrally; dorsum of antennal shaft covered with short, appressed, glossy brown scales.

Thorax: Procoxa white to creamy white anteriorly, iridescent light brown to gray-brown posteriorly; rest of legs white to creamy white on inner surfaces, gray-brown with blue iridescence on lateral ones; propleuron yellow-orange; meta- and mesopleuron covered with a mixture of long white scales and shorter, light brown scales, all with a faint blue iridescence; patagium gray-brown with a turquoise blue iridescence, anterior surfaces with a thin band of long, yellow-orange scales, a few white scales at base; tegula covered with gray-brown scales showing a turquoise blue iridescence, a thin, curving band of white in central area from base to near distal margin; dorsum gray-brown with a turquoise iridescence; tympanum small, with a moderately deep, scaleless depression; tympanal membrane small, ovoid, oriented almost horizontally.

Forewing: (Dorsal) Ground color blackish brown with a violet iridescence; costa glossy gray-brown; a thin, iridescent turquoise to cobalt blue streak in basal third running anterior to DC; a second, slightly wider basal streak within DC; a third wider and longer streak in basal half, its anterior margin touching anal fold, its posterior margin touching 1A+2A, this streak iridescent turquoise blue to aquamarine; a large, white transverse ovoid fascia located slightly more than halfway out on wing, its anterior margin touching bases of R1 and Rs1, its posterior margin touching CuA2, its lateral margin touching, but not crossing, distal margin of DC and extending slightly beyond base of CuA1; surface of fascia glossy, sparsely covered with white foliate scales. (Ventral) Similar to dorsal surface, except ground color lighter gray-brown, and turquoise iridescence evenly distributed from base to white fascia, not forming basal streaks.

Hind wing: (Dorsal) Basal three-quarters blackish brown with a turquoise to cobalt blue iridescence, distal fourth blackish brown with a violet iridescence, violet region widest near apex; a semihyaline area from base to distal margin of DC, subtended by anterior margin of DC and anal fold; wing's anterior margin gray in basal half, bearing an elongate, comma-shaped white maculation in distal half, maculation tapered toward base, expanded distally to form a conspicuous white spot well short of apex; anal margin iridescent blue-gray, fringed with light gray, hairlike scales. (Ventral) Similar to dorsal surface, except white spot on anterior margin smaller, margin itself mostly gray-brown, area corresponding to semihyaline region of dorsal surface covered with a mixture of light gray and white scales; a faint wide, whitish band from base to margin along 2A.

Abdomen: Dorsum evenly gray-brown with a striking turquoise to cobalt blue iridescence; pleuron with a thin, broken white longitudinal stripe; venter immaculate white to creamy white.

Terminalia (fig. 51A–D): Tg8 longer than Tg7 but shorter than St8, much narrower than either; anterior margin of Tg8 broadly convex, lateral margins excavated in anterior third, posterior margin with a small, shallow mesal excavation, membrane beyond longitudinally striate; St8 long, narrower than St7 but wider than Tg8, anterior margin with a long, wide mesal apodeme extending almost to anterior margin of St7; apex of mesal apodeme rounded, its posterior margin with a small, tonguelike fold; posterolateral angles of St8 forming thin processes; lateral margins of St8 bowed outward beyond middle, posterior margin strongly tapered, blunt, bearing a slit along midline; uncus/socii complex small, narrowly attached to ring; uncus small, arching downward, dorsum irregular, apex minutely plicate; socii narrow, digitate, slightly longer than uncus; tegumen thin, much shorter than vinculum; vinculum tall, narrow dorsally, extremely wide ventrally, joining saccus to form a huge, wide envelope below, folded upward to enclose valva bases; dorsal margin of saccus with a knoblike process at midline; valvae almost completely membranous; BO extremely large, occupying almost entire valva, membrane delicate, heavily pleated, lateral margin curving strongly outward; dorsal margin of BO forming a deep, sclerotized fold, narrow in basal half, expanded in distal half; costa sclerotized, short and narrow, almost straight, sides parallel; apex of valva membranous, delicate, with a thin, down-curved dorsal sclerite; a tiny, ovoid, membranous appendix on inner surface of valva below apex; transtillar arms straplike, pointing downward to form a V-shaped junction at midline; anal tube elongate, upright; valva bases relatively wide, sclerotized; juxta small, somewhat elongate, dorsal and ventral margins narrowed; aedeagus relatively long, moderately wide, abruptly narrowed in basal fifth to form a necklike constriction; apex of aedeagus with a long, thin dorsal sclerite and a small, blunt ventral process; vesica wider than aedeagus, approximately half as long; distal portion of vesica bearing deciduous caltrop cornuti, a transverse row of seven long, spinelike cornuti near middle.

Female (pl. 7): Forewing length  =  19.0 mm. Wing pattern and body coloration similar to males, differing in the following: Wings considerably longer and broader; central area of HW more translucent, larger; labial palpus slightly shorter, apex falling short of antennal base; antenna finely ciliate; frenulum comprising approximately six bristles.

Terminalia (fig. 51E): Tg7 equal in length to Tg6, narrowing slightly toward distal margin, anterior and posterior margins simple; St7 narrower than St6, tapered toward distal margin, anterior margin simple, posterior margin with a shallow, extremely wide mesal excavation; Tg8 lightly sclerotized, a wide transverse band; AA short, thin, curled upward at apices; DB sclerotized, extremely short, dorsoventrally compressed, with a downward fold near middle; CB large, roughly ovoid, membrane with deep transverse wrinkles; a pair of elongate, ovoid, sclerotized areas in CB posterior to attachment of DS; DS attached dorsally on CB, approximately one-fourth of distance from DB; signum located ventrally, comprising a large, elongate oval, inner surface coarsely dentate.

Etymology

This species is named in honor of Paul Thiaucourt (Paris, France). Paul, an expert on Notodontidae, has published over 70 papers on the group during the course of more than 35 years of taxonomic investigation. He kindly provided me access to his personal collection in Paris, comprising approximately 40,000 specimens. His holdings include immensely important examples of Dioptinae, most collected by Thiaucourt himself in French Guiana, Ecuador, and Peru.

Distribution

Erbessa thiaucourti, so far known exclusively from French Guiana (fig. 52), overlaps in its geographical range with E. umbrifera, from the Guianas as well as Amazonian Brazil. As the distribution of E. thiaucourti becomes better understood, the species will undoubtedly show broader sympatry with E. umbrifera.

According to Bernard Hermier (personal commun.), the Counamama road begins between Sinnamary and Iracoubo (05°27′30″N, 53°9′30″W), and goes south to the type locality of E. thiaucourti, located at approximately 05°22′N, 53°9′W.

Discussion

The extreme rarity of E. thiaucourti is remarkable, especially considering that the known specimens were collected recently, between the years 2000 and 2002. This example showcases the amazing diversity of the neotropical moth fauna, and provides a strong case for repeated, long-term sampling. In addition to the type material cited below, examples of T. thiaucourti can be seen on the web site of René Lahousse—“Hétérocères de Guyane Française” ( www.guianensis.fr).

As is noted in the diagnosis above, E. thiaucourti is uniquely characterized by the position of the white spot along the HW anterior margin; no other Erbessa species shows a spot in that position.

Holotype

Male (pl. 7). French Guiana: Cayenne: /154/ Route forestière de la Counamama, pk 10, 10 May 2002, leg. B. Hermier, [piège lumineux], Hermier n° 19986, ex musaeo B. Hermier. The holotype is deposited at the AMNH.

Paratypes

French Guiana: Cayenne: Kaw, 1♂, Pk 37, 15 Jan 2000, leg. J-L Giuglaris, PL, coll. J.-A. Cerda (genitalia slide no. JSM-1959); 1♀, Kaw, Pk 40, 1 Sep 2002, leg. D. Faure, coll. J.-A. Cerda (genitalia slide no. JSM-1660).

Other Specimens Examined

None.

Dissected

1♂, 1♀.

Erbessa umbrifera (Walker)

Plate 7

Dioptis umbrifera Walker, 1854: 326.

Type Locality

Brazil, Pará.

Type

Syntype ♂, ex Bates Collection (BMNH).

Phelloe decorata Walker, 1864: 146–147.

Type Locality

Brazil, Ega.

Type

Syntype ♀, ex Bates Collection (BMNH).

Phelloe munda Walker, 1864: 146.

Type Locality

Brazil, Pará.

Type

Syntype ♂, ex Bates Collection (BMNH).

Discussion

Bryk (1930) listed three junior synonyms of E. umbrifera. I have raised one of those, cassandra Druce (type locality: Sarayacu, Ecuador), to species status. This move results from finding male and female genital differences between E. cassandra and E. umbrifera. According to my revised concept, Erbessa umbrifera is restricted to the lowland forests of the Guianas and Amazonian Brazil. In addition to genital differences, it can be distinguished from E. cassandra (pl. 7) by its smaller size and a less pronounced iridescent blue at the base of the FW and HW.

Interestingly, Francis Walker (1854, 1864) described umbrifera three times, all based on Amazonian material collected by Bates. In 1864, 10 years after his original description of umbrifera, he described a male as Phelloe munda, and in the next paragraph described a female as Phelloe decorata.

Distribution

French Guiana (AMNH, BMNH, BHC, MNHN, NMW, OUMNH, USNM); Guyana (BMNH); Suriname (BMNH, ZMH); Brazil (CMNH, BMNH, CUIC, MNHN, NMW, USNM).

Dissected

♂, Brazil, Pará, Reiche, 769-36, MNHN (genitalia slide no. JSM-999); ♀, French Guiana, Nouveau Chantier, Oct, leg. Le Moult, USNM (genitalia slide no. JSM-768); ♀, Brazil, Pará, Benevides, Oct 1918, leg. S.M. Klages, CMNH (genitalia slide no. JSM-1000).

Erbessa unimacula (Warren), revised status

Plate 6

Phaeochlaena unimacula Warren, 1907: 199.

Type Locality

Peru, Cuzco.

Type

Holotype ♀, leg. Garlepp, Jan 1901 (BMNH).

Discussion

Erbessa unimacula was considered a synonym of E. celata (Warren) by Prout (1918), Hering (1925), and Bryk (1930). Here, I elevate unimacula to species status, following the original author (Warren, 1907). Granted, this taxon is extremely similar in size and wing pattern to E. celata (pl. 6), but the two differ because E. unimacula bears a wedge-shaped spot along the leading edge of the FW, near the anterolateral angle of the DC. Only a tiny, diffuse spot occurs at that location in E. celata. Female genitalia in these species also differ, most noticeably in the shape of the DB. The species' distributions are disjunct; unimacula is endemic to the eastern Andes of southern Peru and northern Bolivia, whereas E. celata occurs in extreme northwestern Peru near the Ecuadorian border. For both taxa, males are unknown.

Distribution

Peru (BMNH, MUSM); Bolivia (AMNH, BMNH, USNM, ZMH).

Dissected

♀, Bolivia, Region Chapare, Jun 1951, Grace H. and John L. Sperry Collection, AMNH (genitalia slide no. JSM-1599).

Erbessa ursula (Hering)

Plate 3

Myonia ursula Hering, 1925: 505.

Type Locality

Brazil, Teffé.

Type

Holotype ♀ (ZMH).

Discussion

The female of E. ursula dissected (JSM-980) matches the appearance of the E. ursula holotype with precision, and was collected at the type locality. I consider it to be a verified example of this species. These are the only two specimens of E. ursula of which I am aware.

Comparison of wing pattern and genitalia suggests that E. ursula is a close relative of E. clite (Walker) (pl. 3), another Amazonian taxon. The two differ in that ursula has an orange-yellow, rather than light yellow, transverse FW band. The band in ursula is also narrower and more strongly curved. Comparison of female genitalia in E. ursula and E. clite shows a different signum shape, but the difference is slight. Time will tell, especially through discovery of E. ursula males, whether this species is distinct from E. clite or should be made a synonym of it.

Distribution

Brazil (USNM, ZMH).

Dissected

♀, Brazil, Teffé, Amazonas, Sep, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-980).

XENORMA PROUT, 1918

Figures 53Figure 54Figure 55Figure 5657; plate 8

Xenorma Prout, 1918: 397. Type species: Phaeochlaena cytheris Druce, 1891 (by original designation).

Figure 53

Morphology of Xenorma (♂♂). A, head of X. cytheris, lateral view; B, head of X. cytheris, frontal view; C, head of X. cytheris, posterior view; D, head of X. grandimacula, lateral view; E, X. cytheris tegula; F, X. cytheris wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f053.gif

Figure 54

Genitalia of Xenorma cytheris (♂ JSM-929, ♀ JSM-1028). A, ♂ genitalia; B, ♂ St8; C, caltrop cornuti from vesica, enlarged; D, aedeagus; E, ♂ Tg8; F, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f054.gif

Figure 55

Genitalia of Xenorma leucocrypta (♂ JSM-690, ♀ JSM-723). A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, caltrop cornuti from vesica, enlarged; E, aedeagus; F, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f055.gif

Figure 56

Genitalia of Xenorma ravida, sp. nov. (♂ JSM-1033, ♀ JSM-1034). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ genitalia.

i0003-0090-321-1-1-f056.gif

Figure 57

Ecuador, showing the known distribution of Xenorma ravida, sp. nov.

i0003-0090-321-1-1-f057.gif

Diagnosis

Xenorma species (pl. 8) can be recognized by labial palpi of moderate length (fig. 53A), strongly curved, and terminating in an acute apical tuft (fig. 53D). In almost all taxa, Lp1 and Lp2 are yellow, while Lp3 is brown. The eye tends to be somewhat small, with a wide postgena (fig. 53A–D). Other characters of Xenorma include: frontal scales pointing upward, forming a prominent, erect tuft between antennal bases; antennae bipectinate; FW veins M3 and CuA1 approximate at their bases, but separate (fig. 53F); FW DC long; and HW veins M3 and CuA1 stalked. Most species show a characteristic ovoid, yellowish or translucent FW spot of varying size (pl. 8), straddling the cubitus but located basal to the DC apex. In addition, there is a second, smaller subapical FW spot, located between Rs4 anteriorly and M2 posteriorly. This spot is sometimes faint on the wing's dorsal surface (e.g., X. leucocrypta, X. ovata), but is always clear ventrally. A pair of contrasting yellow lines near the base, one running along the anterior margin of the DC and the other along 1A+2A, characterizes the FW dorsal surface of some Xenorma species. The FW ventral surface bears a pair of diffuse, light yellow basal streaks, running along the subcosta anteriorly, and along the cubitus posteriorly. The HW invariably shows a light yellow central area.

Females differ from males in exhibiting shorter labial palpi with a less prominent apical tuft, but they are otherwise similar. Female antennae are bipectinate as in males (Prout, 1918), but their pectinations are shorter and they rest close to the antennal shaft.

Redescription

Male (fig. 53; pl. 8). FW length  =  12.5–16.0 mm. Head: Labial palpus moderate in length, curving sharply upward to middle of front; apex of palpus held close to front, Lp1 and Lp2 usually yellow or bright orange-yellow, Lp3 dark brown; Lp1 short, wide, with a loose ventral fringe; Lp2 wide, curving upward, its length one and a half times that of Lp1; Lp3 short, quadrate or bullet-shaped, with an acute apical tuft of long, almost bristlelike scales; scales of front elongate, pointing upward, forming a prominent, erect tuft between antennal bases; eye fairly small, gena broadly scaleless below (surface spiculate), a large scaleless area above eye surrounding antennal bases; antenna widely bipectinate, terminal 12–15 segments simple.

Thorax: Epiphysis narrow, long (almost as long as tibia itself), extending past apex of tibia; tegula long (fig. 53E), over two-thirds as long as mesoscutum, distal portion long, apex blunt, ventral process acute, separated from dorsal part by a weak sulcus; metathoracic tympanum large, with a well-developed depression, broadly scaleless below membrane; tympanal membrane large, roughly circular, facing ventroposteriorly.

Forewing (fig. 53F): Elongate, apical angle acute; ground color light brown to dark blackish brown; vein Rs1 long stalked with Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from anterolateral angle of DC, approximate to base of Rs1–Rs4 but clearly separate, UDC well developed; M2 arising closer to M1 than to M3; stridulatory organ absent; DC longer than one-half FW length; veins M3 and CuA1 arising close together at posterolateral angle of DC, not stalked; an ovoid, yellow or translucent spot straddling cubitus, located basal to apex of DC; a second, smaller spot near apical angle, its anterior margin touching Rs4, its posterior margin crossing M2; a pair of contrasting yellow lines near base, one along anterior margin of DC, the other along 1A+2A; ventral surface similar to dorsal one, except maculations larger; a pair of diffuse, light yellow streaks from base, one along Sc, the other along cubitus.

Hind wing (fig. 53F): Ovoid, outer margin rounded; ground color brown to dark blackish brown; M3 and CuA1 stalked; a dusty yellow, light yellow, or lemon yellow central area present, its size and shape variable.

Abdomen: Long, apex acute; dorsum brown to dark brown, venter white.

Terminalia (54A–E, 55A–E, 56A–D): Tg8 short, anterior margin with a pair of short broad apodemes, posterior margin broadly rounded, without lateral angles, some species (e.g., X. cytheris) with an unusual, W-shaped mesal excavation, its central process short and blunt; St8 short, wider than long, anterior margin with a short, wide mesal apodeme, it apex blunt; lateral margins of St8 variable, from convex (X. leucocrypta) to concave (e.g., X. ravida); posterior margin of St8 with a wide, indistinct, U-shaped excavation; socii/uncus complex relatively small, an extremely narrow attachment to tegumen; uncus short, wide at base, apex often truncate; socii extremely short, bases wide, apices laterally compressed, in some species closely approximated below apex of uncus; tegumen moderately wide, parallel sided, slightly taller than vinculum; vinculum extremely wide, each arm concave; ventral margin of genitalia horizontal or gently convex; saccus wide, upper margin forming a broad triangle between valva bases; juxta tall and narrow, divided along center; valvae large, mostly membranous; BO large, occupying almost half of valva, lateral margins curled anteriorly; costa of valva narrow at base, then greatly expanded to enclose distal portion of valva; apex itself variable in shape, sometimes forming a small, flattened process; arms of transtilla narrow, meeting in anellus to form a small point; aedeagus moderately long, weakly sclerotized, narrow at base, wider toward apex, a small necklike constriction in basal fourth; apex of aedeagus forming a small, tooth-shaped ventral process; vesica two-thirds the length of aedeagus, bulbous, upright, middle portion (posterior surface) with a set of extremely small, spinose or bifid cornuti, and a larger group of deciduous caltrop cornuti above those; distal portion of vesica with a single, large spinelike cornutus, its length and shape variable.

Female (fig. 54F, 55F, 56E). FW length  =  14.5–17.0 mm. Head: Labial palpus similar to male, except shorter and thinner, ascending to immediately below middle of front, apical scale tuft on Lp3 absent; frontal scales shorter than in male, not forming a prominent tuft between antennal bases; antenna bipectinate, rami short and thick, held close to antennal shaft.

Thorax: Similar to male.

Forewing: Longer than male, apical angle not as acute; wing pattern similar to male, but maculations larger.

Hind wing: Broader and more rounded than in male, outer margin gently convex; frenulum comprising 6–10 bristles.

Abdomen: Wider than male, not as acute at apex.

Terminalia: Tg7 large, much wider at anterior margin, gradually tapered posteriorly; anterior margin of Tg7 simple, posterior margin either rounded or transverse, with a deep, narrow excavation or a deep, U-shaped one; St7 wide, posterior half more heavily sclerotized than anterior one, these two sections often divided by a sclerotized, transverse groove; anterior margin of St7 simple, broadly convex, posterior margin with an extremely wide, U-shaped mesal excavation; Tg8 lightly sclerotized, forming a small rooflike structure, posterior margin with a small mesal notch; AA short, thin; pleuron of A8 membranous; PP long and thin, straight; PA membranous, moderate in size, elongate; PVP extremely wide, lightly sclerotized, surface either convex (e.g., X. cytheris, X. ovata) or concave (X. ravida); DB short, wide, membranous; CB large, ovoid, membranous, a narrower portion near base; a transverse, horseshoe-shaped sclerite on dorsum near base of CB, its surface concave, lateral portions of sclerite spinose on inner surface; signum small, figure-eight shaped, internal surface coarsely spiculate; DS arising on dorsum, near ostium, from a large membranous appendix at junction of CB and DB.

Distribution

Xenorma species are found from Mexico south to Bolivia and Pará, Brazil. They typically occur at elevations of 1000 meters or below, but one species, X. ovata (Dognin), has been recorded from 2400 meters on the western slope of the Colombian Andes.

Biology

In 1994, A. Orellana and L.D. Otero reared Xenorma leucocrypta in western Venezuela on an unidentified species of Cecropia (Urticaceae). This plant genus, containing approximately 100 species (Gentry, 1993), is one of the most prominent elements of early second-growth forests throughout the Neotropics. Additional Xenorma species will undoubtedly be discovered in association with Cecropia.

Discussion

My phylogenetic results place Xenorma at the base of a large clade in the Dioptini, containing 24 additional genera (Clade 2; fig. 7). This genus is thus of considerable evolutionary interest. Prout (1918) erected Xenorma largely because of its wing venation; M3 and CuA1 are separate in the FW but stalked in the HW (fig. 53F), whereas in the vast majority of Dioptinae these veins are stalked in both wings. The M3/CuA1 configuration of Xenorma also occurs in the large genus Erbessa (e.g., fig. 38A), perhaps explaining why Prout and subsequently Hering (1925) placed these two genera close together in their classifications as an indicator of relationship. My cladograms show that this particular venation trait is highly homoplastic within the Dioptini. Wing venation in the two genera differs in that vein Rs1 arises from the radial sector in Xenorma (fig. 53F), but from the DC in almost all Erbessa (fig. 38A, B, E).

The monophyly of Xenorma is strongly supported, with a Bremer support value of 28 (fig. 2). From a morphological standpoint, the clade shows considerable cohesion. For example, basic features of the male and female genitalia in Xenorma are similar across species (figs. 54Figure 5556), with most differences being related to subtleties in shape of the male socii/uncus complex and valval costa. Xenorma females differ most obviously in the configuration of the basal sclerite in the CB (compare figs. 54F, 55F, 56E).

KEY TO THE SPECIES OF XENORMA PROUT

1. Labial palpus segments Lp1 and Lp2 light yellow to orange-yellow, Lp3 brown3

All palpus segments uniform in color2

2. Labial palpus segments 1–3 entirely orange-yellow; fascia of FW central area ovoid (Central America)cytheris (Druce)

Lp1–Lp3 dark brown, a few scattered yellow-orange scales; fascia of FW central area large, slightly quadrate (Colombia)ovata (Dognin)

3. Front dark brown to blackish brown, lateral margins cream colored to light yellow5

Front almost entirely cream colored, with a small, light brown central region4

4. Forewing ground color dark brown (pl. 8), maculations lemon yellow; FW subapical spot small and narrow, transverse (E Brazil)australis Prout

FW ground color light brown (pl. 8), maculations light whitish yellow; FW subapical spot large, roughly ovoid (W Brazil)biorbiculata (Warren)

5. Subapical FW spot light yellow on dorsal and ventral surfaces7

Subapical FW spot semihyaline on dorsal surface with a sparse covering of brown scales, spot on ventral surface light yellow6

6. Forewing fascia covered with light yellow scales on ventral surface; wing ground color dark brown to blackish brown; bases of FW radius and 1A+2A thinly lined with light yellow, no basal streak (Venezuela)leucocrypta (Dognin)

FW fascia hyaline on ventral surface; wing ground color light chocolate brown; base of FW radius conspicuously lined with light yellow, a diffuse, light yellow basal streak present anterior to 1A+2A (W Ecuador)ravida, sp. nov.

7. Central fascia of FW small, extending from middle of DC anteriorly to immediately beyond CuA2 posteriorly8

Central fascia of FW large, forming a transverse oval that extends from radius anteriorly to anal fold posteriorly (Bolivia, Peru)grandimacula Hering

8. Forewing veins conspicuously lined with light yellow scales; outer margin of light yellow HW central area smoothly convex (Peru)pictifrons (Warren)

FW veins diffusely lined with light yellow scales; outer margin of light yellow HW central area broadly indented near anal fold (Guatemala?)exturbata Hering

SPECIES INCLUDED AND MATERIAL EXAMINED

Xenorma australis Prout, revised status

Plate 8

Xenorma australis Prout, 1918: 404.

Type Locality

“Brazil”.

Type

Holotype ♂, “ex. coll. Smith, 1844–45” (BMNH).

Xenorma deleta Prout, 1918: 404.

Type Locality

Brazil, “Itabapoana, Rio”.

Type

Holotype ♀ (BMNH).

Xenorma reducta Hering, 1925: 507, figs. 68h, 68i. New synonymy.

Type Locality

Bahia, Brazil.

Type

Syntype ♂/♀ (ZMH).

Discussion

Prout (1918) described australis, endemic to eastern Brazil, as a subspecies of cytheris, whose type locality is in Costa Rica. I dissected a male from Bahia and have confirmed that australis differs from all other Xenorma species, including cytheris, and should therefore be elevated to species status. Furthermore, based on superficial examination of types, I suggest that Hering's taxon reducta should be made a new synonym of australis. I retain Prout's deleta as a synonym of australis, following previous authors and pending dissection of types.

According to Prout (1918), X. australis differs from X. cytheris in that the FW of australis is broader and the yellow FW fascia, prominent in cytheris, is reduced “or even wanting” on the dorsal surface in australis, but is present ventrally. Xenorma australis also differs from X. cytheris is lacking the two basal FW dashes (pl. 8). The only other Xenorma species occurring in Brazil, X. biorbiculata (pl. 8), is known from the Upper Amazon. It is easily distinguished from X. australis in having a light brown, rather than dark brown, ground color in the wings.

Distribution

Brazil (BMNH, CAS, NMW, ZMH).

Dissected

♂, Brazil, Bahia, D. Davis, CAS (genitalia slide no. JSM-1032).

Xenorma biorbiculata (Warren)

Plate 8

Phaeochlaena biorbiculata Warren, 1909: 72.

Type Locality

Brazil, Amazonas, Fonte Boa.

Type

Syntype ♂, leg. S.M. Klages, May–Jul 1906 (BMNH).

Discussion

This species is apparently endemic to the Upper Amazon of Brazil. Although specimens are not particularly common, X. biorbiculata is represented in the four largest collections of Dioptinae. The longest available series (12♂♂, 8♀♀) is at the BMNH. Xenorma biorbiculata can be distinguished from other Xenorma species by its light brown FW ground color (pl. 8). Furthermore, the HW is unique in being grayish brown with a relatively small, light yellow central area.

Distribution

Brazil (AMNH, BMNH, USNM, ZMH).

Dissected

♂, Brazil, Amazonas, Fonte Boa, Jul 1906, leg. S.M. Klages, BMNH (genitalia slide no. JSM-687); ♀, Brazil, Amazonas, Fonte Boa, Jul 1906, leg. S.M. Klages, BMNH (genitalia slide no. JSM-688).

Xenorma cytheris (Druce)

Figures 53A–C, 53E, 53F; fig. 54; plate 8 [EX]

Phaeochlaena cytheris Druce, 1891: 2, pl. 41, fig. 11.

Type Locality

Costa Rica, Cachi.

Type

Syntype ♀, leg. H. Rogers (BMNH).

Discussion

Along with being the type of the genus, X. cytheris is the most common Xenorma species in collections. It is distinguished by having bright yellow FW and HW markings on a dark chocolate-brown ground color. In most other Xenorma, the markings are light yellow to whitish yellow, and the ground color varies from being blackish brown to light brown. Although caterpillars of X. cytheris have not been found, it will be important to search on foliage of Cecropia, the host of its Venezuelan relative, X. leucocrypta.

In March 2005, three syntypes of X. cytheris were located at the BMNH; all bear labels typical of Druce types described in the Biologia Centrali-Americana. Two of those are from Mexico (Orizaba and Cuesta de Misantla) while the third, a Costa Rican female, was figured (Druce, 1891).

Xenorma cytheris is broadly distributed in Central America, occurring from Veracruz, Mexico, south to Costa Rica. To my knowledge, it has not been captured in Panama. A series of specimens from Colombia (JBSC, USNM) matches the wing pattern of X. cytheris closely, but differs markedly in genital morphology, thus representing an undescribed taxon. I leave description of the Colombian species for future research, here retaining it under cytheris. Genitalia dissections for the undescribed Xenorma are as follows: ♂, Colombia, Valle, Hormiguero, 1000 m, lat. 3°17′, long. 76°29′, 19 Jan 1992, leg. J. Bolling Sullivan, JBSC (genitalia slide no. JSM-1029); ♀, Colombia, Valle, Hormiguero, 1000 m, lat. 3°17′, long. 76°29′, 19 Jan 1992, leg. J. Bolling Sullivan, JBSC (genitalia slide no. JSM-1030).

Distribution

Mexico (AMNH, BMNH, MNHN, USNM); Guatemala (USNM); Nicaragua (ZMH); Costa Rica (AMNH, BMNH, CMNH, FNHM, INBio, LACM, USNM, VOB); Colombia (JBSC, USNM).

Dissected

♂, Costa Rica, Turrialba, 600 m, 5 Jul 1971, leg. V.O. Becker, VOB (genitalia slide no. JSM-929); ♂, Mexico, Veracruz, Huatusco, Jun 1914, “4287”, USNM (genitalia slide no. JSM-1026, wing slide no. JSM-1027); ♀, Costa Rica, Heredia Prov., El Angel waterfall, 1350 m, 8.2 km downhill Vara Blanca, 5 Aug 1981, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-1028).

Xenorma exturbata Hering

Plate 8

Xenorma exturbata Hering, 1925: 507.

Type Locality

Guatemala (?).

Type

Holotype ♀ (ZMH).

Discussion

Based on its wing pattern, this taxon, known exclusively from the ZMH type (pl. 8), may be closely related to X. leucocrypta. The major difference between the two is that the subapical FW spot in leucocrypta is light gray to semihyaline, whereas in exturbata it is light orange-yellow. Alternatively, X. exturbata may be most closely related to its Central American congener, X. cytheris, with which it shares possession of a yellow basal streak along FW vein 1A+2A.

The type locality for X. exturbata is in doubt. There are two labels on the type specimen: a handwritten one stating “Tithraustes eteocles Druce, Guat.”, and a second typeset one simply reading “Mssn., G.” The first of these is I think an incorrect determination label, placed there long ago. Regarding the second label, “Mssn.” indicates that the type came from the Maassen Collection (G. Lamas, personal commun.). It is not known what the “G.” stands for, but it could perhaps refer to Guatemala. In his description, Hering (1925) cited Guatemala as this taxon's provenance.

Distribution

Guatemala (ZMH).

Dissected

None.

Xenorma grandimacula Hering

Figure 53D; plate 8

Xenorma grandimacula Hering, 1925: 507.

Type Locality

Bolivia, Río Songo, 1200 m.

Type

Holotype ♀ (ZMH).

Discussion

Hering (1925) noted in his original description that X. grandimacula differs from X. cytheris in showing sharply contrasting yellow veins at the FW base, but in lacking the two conspicuous basal dashes (pl. 8). The yellow HW central area also extends to the anal margin, whereas in X. cytheris the anal margin is dirty brown.

Xenorma grandimacula is extremely rare. Only four Bolivian examples are known: the female type, two BMNH females, and a beautiful AMNH male collected by Paul Goldstein and Bob Hanner (fig. 53D; pl. 8). Material in the AMNH and MUSM collections from Tingo María, Peru, bears close resemblance to X. grandimacula, and I tentatively consider these to be conspecific pending dissections and comparison with types.

Distribution

Bolivia (AMNH, BMNH, ZMH); Peru (AMNH, MUSM).

Dissected

None.

Xenorma leucocrypta (Dognin), new combination

Figure 55; plate 8 [EX]

Polypoetes leucocrypta Dognin, 1909: 225.

Type Locality

“Venezuela”.

Type

Holotype ♂ (USNM type no. 30924).

Discussion

I here transfer X. leucocrypta from Polypoetes—where previous authors had incorrectly placed it—to Xenorma. The species exhibits all the characteristics of Xenorma, and there is no doubt that it belongs here. Cladistic results (fig. 3) provide further confirmation. Dissections confirm that X. leucocrypta (fig. 55) is distinct from the Central American X. cytheris (fig. 54).

Based on my concept of this species, X. leucocrypta shows extensive intraspecific variation regarding the size of the whitish yellow central area of the HW, and of the whitish yellow FW fascia located near the distal margin of the DC; extremes range from large, conspicuous patches to very small hints of yellow. In the type, both wings are almost completely dark. After considerable deliberation, I recognize a single Venezuelan species of Xenorma, X. leucocrypta. However, the possibility remains that two taxa occur there—one in the western part of the country near Mérida, and the other from the area near Maracay. Slight genital differences seem to exist, but a single strong character for separation did not present itself.

Luis Daniel Otero (Universidad de Los Andes, Mérida) reared Xenorma leucocrypta (JSM-722, 723) in Venezuela on an unidentified species of Cecropia (table 4). Preserved larvae have been deposited at the AMNH.

Distribution

Venezuela (AMNH, BMNH, CMNH, IZA, USNM); Brazil (BMNH, CAS).

Dissected

Holotype ♂ (genitalia slide no. JSM-928); ♂, Venezuela, Aragua, Rancho Grande, nr. Maracay, 24 May 1948, N. Y. Zoological Society, AMNH (genitalia slide no. JSM-689); ♂, Venezuela, Aragua, El Limón, 450 m, 8 Jan 1981, leg. F. Fernandez Y., MV light, IZA (genitalia slide no. JSM-722); ♂, Venezuela, Barinas, San Isidro, NE de La Soledad, 1400 m, 9 Sep 1993, leg. L.D. Otero, D93-36, AMNH (genitalia slide no. JSM-723); ♂, Venezuela, Mérida, Via Chorros de Milla, Facultad de Ciencias Forestales, Mérida, 9–10 Nov 1995, leg. A. Orellana & L.D. Otero, reared ex Cecropia sp., AMNH (genitalia slide no. JSM-725); ♀, Venezuela, Aragua, Rancho Grande, nr. Maracay, 26 May 1948, N. Y. Zoological Society, AMNH (genitalia slide no. JSM-690); ♀, Venezuela, Barinas, San Isidro, NE de la Soledad, 1400 m, 27 Nov 1993, leg. L.D. Otero, S. Segnini & J.M. Segnini, AMNH (genitalia slide no. JSM-724).

Xenorma ovata (Dognin)

Plate 8

Phaeochlaena ovata Dognin, 1900: 438.

Type Locality

Colombia, Popayán.

Type

Holotype ♀, leg. 1897 (USNM type no. 30969).

Discussion

I was able to locate only four examples of Xenorma ovata, all females—three, including the type, are in the USNM collection and one is at the BMNH (Cañon del Tolima, Colombia). Genital (JSM-1031) and other body characters confirm that ovata is properly placed in the genus and that it is a valid species, showing features distinct from all other Xenorma. Based on this scant material, Xenorma ovata appears to be endemic to the Cauca Valley, on the Pacific slope of the Colombian Andes. With specimens collected at 2400 meters, X. ovata holds the elevation record for Xenorma; all other species occur below 1500 m.

Distribution

Colombia (BMNH, USNM).

Dissected

♀, Colombia, Quindiu, Río Toche, 2400 m, Dognin Collection, USNM (genitalia slide no. JSM-1031).

Xenorma pictifrons (Warren)

Plate 8

Phaeochlaena pictifrons Warren, 1907: 199.

Type Locality

Peru (SE), La Oroya, Río Inambari, 3100 ft.

Type

Holotype ♂, leg. G. Ockenden, wet s., Oct 1904 (BMNH).

Discussion

I know Xenorma pictifrons exclusively from the holotype (pl. 8), which was not dissected. The species is distinctive, and based on numerous superficial characters appears to be correctly placed in Xenorma. It bears close resemblance to X. grandimacula, from Bolivia, but differs in showing a much smaller yellow fascia in the FW central area, and in having a light yellow band across the base of the abdomen.

Distribution

Peru (BMNH).

Dissected

None.

Xenorma ravida, new species

Figures 56, 57; plate 8

Diagnosis

The wing-pattern elements of X. ravida correspond closely with those of other Xenorma species, such as X. cytheris and X. leucocrypta. Xenorma ravida can be distinguished from other members of the genus by a combination of characters: First, the FW and HW ground color is a lighter brown than in most others, where it is dark brown. In X. ravida, the FW spot within the DC is semihyaline and vein M1 is dark as it passes through, whereas in X. leucocrypta and X. cytheris this spot is uniformly light yellow. The subapical spot is semihyaline in X. ravida and X. leucocrypta, but light yellow in X. cytheris. Perhaps the most distinctive feature of the wings in X. ravida is that the HW dorsal surface is completely brown, with the light-colored central area of the ventral surface showing through. Other Xenorma species exhibit varying amounts of yellow on the HW dorsal surface.

Description

Male (pl. 8). Forewing length  =  13.0–16.0 mm. Head: Labial palpus moderate in length, curving upward to immediately short of antennal base, held close to front; Lp1 light yellow to lemon yellow, with short, tight scales below; Lp2 covered with short, lemon yellow scales, a small distal tuft of longer, light yellow scales on mesal surface; Lp3 light brown to brown, scales at apex elongate, forming a terminal point; maxillary palpi covered with lemon yellow scales; front clothed with long, dorsomedially directed scales, coming together to form a central crest between antennal bases; front cream to creamy yellow laterally, brown in central area from clypeus to vertex; occiput brown in dorsal fifth, cream to creamy yellow below; eye moderately large, rounded, surrounded by a thin scaleless area, scaleless area broader below and anteroventrally; vertex light brown to brown; antenna bipectinate, rami moderately long; scape brown, cream to light yellow below; dorsum of antennal shaft brown.

Thorax: Legs white to creamy yellow on inner surfaces, brown on outer ones; pleuron covered with long, cream to creamy yellow scales; patagium covered with long, upwardly pointing brown scales, a pair of creamy yellow patches anteroventrally and a narrow, creamy yellow stripe along midline; tegula yellow-orange, with brown, hairlike scales fringing margins, longest at apex; dorsum covered with short, light brown to brown scales, and longer, brown scales laterally; tympanum fairly deep, partially enclosed; tympanal membrane moderately large, ovoid, facing mostly ventrally, area immediately below membrane scaleless.

Forewing: (Dorsal) Ground color chocolate brown; anterior margin of DC lined with light yellow scales, forming a thin longitudinal line from base to less than halfway out on DC; a diffuse, short basal dash, comprising scattered, light yellow scales anterior to 1A+2A; a large, transverse, semihyaline fascia halfway out, located proximal to end of DC, cubitus sparsely lined with light yellow scales at it passes through, CuA2 brown; fascia extending from anterior margin of DC to immediately past CuA2; a smaller, transverse, subapical fascia present, its anterior margin touching the base of Rs2–Rs4, its posterior margin falling short of M3, veins M1 and M2 brown as they pass through. (Ventral) Similar to dorsal surface, ground color slightly lighter; a light creamy yellow longitudinal line in basal fifth, located immediately behind SC; a second, wider creamy yellow, basal dash located immediately behind cubitus, extending halfway out on DC; the two semihyaline fascias covered below with spatulate, creamy yellow scales.

Hind wing: (Dorsal) Ground color brown, a wide band of dark chocolate brown along outer margin; central area from base more sparsely scaled, light-colored ventral surface showing through above; a diffuse, creamy yellow, longitudinal line bisecting distal margin of DC. (Ventral) Anterior and outer margins dark chocolate brown; central area from based clothed with evenly dispersed, creamy yellow, spatulate scales; anal margin fringed with long, creamy yellow scales.

Abdomen: Moderately long, apex pointed; chocolate brown above, with a few scattered cream colored scales; venter cream to creamy yellow.

Terminalia (fig. 56A–D): Tg8 with sides roughly parallel in basal two-thirds, broadly rounded in distal one-third; lateral margins of St8 slightly concave, posterolateral shoulders of St8 excavated, posterior margin slightly convex; anterior margin of St8 with a broad, blunt mesal apodeme; socii/uncus complex thinly attached to tegumen; uncus broadly triangular, apex short, barely acute; socii serrate at elbows, distal section sharply upturned to uncus; tegumen slightly wider below; vinculum much wider than tegumen, saccus slightly convex at midline; valva with BO well developed, lower margin of BO membranous, expanded; costa of valva broadly sclerotized; valva apex sclerotized, forming an emarginate, spadelike process, curving inward; transtillar arms narrow, curving downward at midline; aedeagus relatively wide, gradually wider distally; apex with a short, straight tooth below; vesica fairly large, with deciduous caltrop cornuti near middle, along with small, dentate cornuti; a single robust, spinelike cornutus near apex of vesica.

Female. Forewing length  =  14.5–16.5 mm. Labial palpus shorter and thinner than in male, porrect, barely reaching clypeus; antenna bipectinate, rami short and thin; wing pattern and maculation similar to male.

Terminalia (fig. 56E): Tg8 forming a wide transverse band, margins simple; AA moderately long, thin; ostium slightly funnel shaped, broadly sclerotized above; DB short membranous, with a small, flat, melanized dorsal appendix; CB large, rounded, membranous; base of CB with a U-shaped sclerite above, its lateral angles coarsely spiculate; signum small, roughly figure-eight shaped, bearing small dentations; PA slightly emarginate; PP long, straight and thin.

Etymology

This name is taken from the Latin ravus, meaning grayish yellow, in reference to the color of the HW central area (dorsal surface), a distinguishing characteristic of the species.

Distribution

Xenorma ravida is known exclusively from western Ecuador (fig. 57) at elevations between 10 and 700 meters. The species has been collected with considerable regularity at Tinalandia, in Pichincha Province, which represents its northernmost limit. The remaining specimens have been captured further south in Los Ríos, Cañar, and Guayas provinces at a series of sites within relatively close proximity. The known distribution of X. ravida thus extends roughly 250 km north to south.

Discussion

The type series of X. ravida (♂ holotype, three paratypes) was captured in 1893 by M. de Mathan. The type locality, La Chima (01°53′60″S, 79°24′00″W), is approximately 60 km northeast of Guayaquil. This locale, situated on the Río Las Juntas, is at low elevation (12 m) in countryside now covered mostly by banana plantations.

The genitalia of Xenorma species show broad similarities (figs. 54Figure 5556). Males are separable by subtle differences in the shape of the uncus/socii complex, and in the valva apex. Females differ in the shape of Tg8 and the ostium, as well as in the shape of the U-shaped basal sclerite of the CB. The male valva and female Tg8 of Xenorma ravida (fig. 56) indicate a sister-group relationship with X. cytheris (fig. 54), from Central America.

A female from southern Ecuador labeled, “El Oro, 9 km NW Atahualpa, 1860 m, 5 Nov 1987, J. Rawlins, C. Young, R. Davidson, Cloud forest” (CMNH), shows a wing pattern extremely similar to that of X. ravida. It differs in that most wing veins are thinly lined with orange, and the lateral portions of the front are orange-yellow rather than creamy white. The subapical fascia is narrower, and the HW ventral surface is white, not creamy yellow. No other known material matches this specimen. Its female genitalia (JSM-1335) differ from those of X. ravida (JSM-1034). The most significant difference involves the shape of the U-shaped basal sclerite in the CB. Description of this species will await the discovery of additional specimens.

Another undescribed Ecuadorian Xenorma species is known from one male and two females (LACM), collected in the Oriente at Coca on the Río Napo. This material shows more yellow coloring in the FW and HW maculations than does X. ravida, and thus resembles X. grandimacula (pl. 8) in general appearance.

Holotype

Male (pl. 8). Ecuador: Los Ríos: La Chima, Río de las Juntas, pr. Babahoyo, Juin-Juillet 1893, M. de Mathan. The holotype is deposited at the BMNH.

Paratypes

Ecuador: Los Ríos: 1♂, 2♀♀, La Chima, Río Las Juntas, pr. Babahoyo, Jun–Jul 1893, leg. M. de Mathan (BMNH).

Other Specimens Examined

Ecuador: Pichincha: 1♂, Tinalandia, 700 m, 27–30 June 1980, leg. C.V. Covell Jr. (AMNH; genitalia slide no. JSM-1033); 1♀, Tinalandia, 15 Jun 1996, leg. F. Piñas (FPC; genitalia slide no. JSM-1034); 1♂, Tinalandia, May 1992, leg. J.B. Heppner (FNHM); 1♂, Santo Domingo de los Colorados, leg. R. Benoist (MNHN); 1♀, Santo Domingo de los Colorados, 22 Sep 1970, leg. R.E. Dietz IV (EMEC). Guayas: 3♂♂, 9♀♀, Hacienda San Juaquin, 4 road km SW Bucay, 250 m, 1–4 May 1986, leg. Stuart McKamey (LACM). Cañar: 1♀, 20 km SE La Troncal, 2200 ft, 22–28 July 1984, leg. Susan J. Weller & Nancy L. Jacobson, CUIC/AMNH Arctiidae Project (AMNH).

Dissected

1♂, 1♀.

The following species has been transferred from Xenorma: plataea Druce to Nebulosa

SAGITTALA MILLER, new genus

Figures 58, 59; plate 8

Type species: Ephialtias peba Druce, 1897.

Figure 58

Morphology of Sagittala peba (♂). A, head, lateral view; B, head, frontal view; C, head, posterior view; D, head, lateral view; E, wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f058.gif

Figure 59

Genitalia of Sagittala peba (♂ JSM-1312, ♀ JSM-1313). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♀ genitalia; E, ♂ Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f059.gif

Diagnosis

Sagittala peba (pl. 8), the only species in this genus, is among the most distinctive of all Dioptinae. The moths are small (FW length  =  11.0–13.0 mm) and possess extremely narrow forewings, acute at their apices. A single ovoid, orange-yellow FW fascia is located at the distal margin of the DC, conspicuously set against a blackish brown ground color. The HW central area is orange-yellow. On the FW ventral surface, males show a tiny patch of orange scales along M2 near the wing's outer margin. This ventral patch is larger, though diffuse, in females. Like most Dioptinae, veins M3 and CuA1 are stalked in the FW and HW (fig. 58F). There is no male FW stridulatory organ, and the DC is over one-half the wing length. This feature, along with the fact that FW vein M1 arises from the radial sector, distinguishes Sagittala from Brachyglene, where S. peba had most recently been placed (Bryk, 1930). Brachyglene males possess a well-developed FW stridulatory organ (fig. 145F) with a short DC, and vein M1 arises from the DC, separate from the radial sector.

The eyes of Sagittala are small (fig. 58A–D), and the bipectinate antennae possess long rami in males but shorter ones in in females. The labial palpi are short (fig. 58D), curving upward to immediately below the middle of the front; Lp2 is shorter than Lp1 (fig. 58A). The metathoracic tympanum is fairly shallow, but the membrane itself is unusually large. Many features of the genitalia in Sagittala are autapomorphic for the Dioptinae, an example being the lyre-shaped configuration of male St8 (fig. 59C).

Description

Male (fig. 58; pl. 8). FW length  =  11.0 mm. Head: Labial palpus short and thin, curving sharply upward to below middle of front; palpus held close to face, Lp1 and Lp2 light yellow, Lp3 brown; Lp1 long, strongly curved, with a loose ventral fringe of long scales; Lp2 slightly shorter than Lp1, bearing elongate scales at its apex; Lp3 short, bullet shaped, scales forming an acute apex; scales of front elongate, pointing upward, forming a wide, erect tuft between antennal bases; eye small, gena and area above eye broadly scaleless; scales of vertex long, erect, meeting frontal tuft between antennal bases; antenna widely bipectinate, terminal 7–10 annulations simple.

Thorax: Epiphysis long and narrow, approximately four-fifths as long as tibia, extending slightly beyond apex of tibia; tegula relatively small, slightly more than one-half as long as mesoscutum, upper and lower portions without a suture separating them; tegula base orange-yellow, distal portion dark brown; metathoracic tympanum large, cavity shallow, a large scaleless area below membrane; tympanal membrane large, roughly circular, facing lateroposteriorly.

Forewing: Lanceolate, narrow, apical angle acute; ground color blackish brown; vein Rs1 stalked with Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 stalked with radial sector, arising below Rs1; UDC absent; stridulatory organ absent; DC longer than one-half FW length; veins M3 and CuA1 stalked; an ovoid, almost quadrate, spot straddling distal margin of DC, its anterior margin touching base of radial sector, its posterior margin touching base of M3+CuA1; a short, orange-yellow basal dash present between anal fold and 1A+2A; ventral surface similar to dorsal one, except orange-yellow maculations slightly larger, some specimens with a faint orange-yellow spot along M2 near outer margin.

Hind wing: Somewhat triangular, angulate at apex; ground color dark brown to blackish brown; M3 and CuA1 long stalked; central area bright orange-yellow; outer margin of central area irregular, extended toward wing margin along stem of M3+CuA1.

Abdomen: Long, apex truncate; dorsum blackish brown, venter white.

Terminalia (fig. 59A–C, E): Tg8 elongate, much narrower than Tg7, a sclerotized rectangle along midline; lateral margins of Tg8 slightly concave in distal third, anterior margin with short, broad apodemes at lateral angles, posterior margin with a wide, shallow, quadrate mesal excavation; St8 longer than Tg8, strongly lyre shaped; anterior margin of St8 bearing a large, broad mesal apodeme, lateral margins gently convex, posterior margin bearing robust, heavily sclerotized arms at posterolateral angles, these processes separated by a deep mesal excavation, their apices curled outward distally; socii/uncus complex moderately large, with a narrow attachment to tegumen; uncus robust, long, curving gently downward, with a ventral keel, apex acute; socii large, laterally compressed, paddle shaped, with short setae on lateral surfaces; tegumen narrow, slightly shorter than vinculum, sides approximate; vinculum narrow, lateral margin irregular; ventral margin of genitalia gently concave at midline; saccus wide, dorsal margin forming a triangle between valva bases; juxta absent; valvae long and relatively narrow, mostly sclerotized; BO small, comprising a sclerotized ridge along ventral margin of valva, a few pleats visible; costa of valva expanded near base, narrowing and becoming obsolete distally; apex of valva quadrate, without processes; arms of transtilla narrow, extremely long, arching upward near middle to form a pair of robust processes reaching almost to socii/uncus complex; arms of transtilla meeting in anellus to form a laterally compressed sclerite at midline; aedeagus narrow, relatively long, sinuate, widest near base; apex of aedeagus forming a beaklike ventral process; vesica small, ovoid, opening upward, bearing a small group of minute, spinelike cornuti near middle.

Female. FW length  =  13.0 mm. Head: Labial palpus shorter and thinner than in male, more loosely scaled; frontal scales shorter than in male, not forming a tuft between antennal bases; antenna bipectinate, rami relatively short.

Thorax: Similar to male.

Forewing: Longer and slightly wider than male, otherwise similar; yellow maculations on both wing surfaces larger than male.

Hind wing: Broader than male; frenulum comprising approximately 6 bristles.

Abdomen: Wider than male, not truncate at apex.

Terminalia (fig. 59D): Tg7 large, slightly narrower posteriorly, anterior margin simple, anterolateral angles produced, lateral margins constricted beyond middle, posterior margin gently convex; St7 large, approximately equal in length to Tg7, widest anteriorly, a pair of lateral bulges in anterior half; posterior margin of St7 with a wide, shallow excavation, its border irregular; Tg8 lightly sclerotized, forming a robust, rooflike structure over PA, its posterior margin deeply bilobate; AA short and thin, slightly sinuate; A8 pleuron produced posteriorly to form a large, membranous, setose pocket, its posterior margin bilobed; PP extremely short, wide at bases, upturned at apices; PA large and membranous, triangular, posterior margin acute; PVP sclerotized, forming a blunt, triangular process posteriorly, distal portion densely spiculate, area immediately surrounding ostium slightly funnel shaped; DB short, heavily sclerotized, arching gently upward; CB large and membranous, an elongate oval; signum ovoid, slightly concave, located laterally on left side, inner surface of signum minutely dentate; DS arising dorsally at junction of CB and DB, its base expanded.

Etymology

This genus name is derived from a combination of two Latin words—sagitta, meaning “arrow”, and ala, “wing”. The name refers to the lanceolate FW in S. peba, the only species of Sagittala.

Distribution

So few specimens of Sagittala peba were available for study that statements regarding distribution are purely speculative. The type is from northern Panama, whereas the remainder of known material was captured in Costa Rica. The type was collected at an elevation of approximately 900 m. The highest altitude comes from the only known female, captured near 2000 meters on Cerro Pittier.

Biology

Nothing is known regarding the biology of Sagittala.

Discussion

The lone species in Sagitallapeba—was previously placed in Brachyglene (Bryk, 1930). However, my cladistic analyses (fig. 3) show that this species belongs in a genus of its own, far removed from Brachyglene. Adult morphology suggests that Sagittala belongs in Clade 5 (fig. 7), as the sister group to Phryganidia + Phanoptis. However, the synapomorphies for Clade 5 (appendix 4) are not uniquely derived, and none is particularly compelling. The uniqueness of Sagitalla is clear, but its relationship to other dioptine genera deserves further study.

Sagittala exhibits a host of unusual genital traits, examples being the shape of male St8, the unusual dorsal processes of the male transtillar arms (fig. 59A), and the presence of large, membranous lobes on the pleuron of female A8 (fig. 59D). Though roughly similar structures can be observed elsewhere in the Dioptinae, such as the elongate transtillar processes in the Albitumida Group of Nebulosa (figs. 183A, 184A), my analyses suggest that they are not homologous. The unusual genital morphology of Sagittala thus provides few clues regarding its phylogenetic affinities within the subfamily.

Sagittala peba (Druce), new combination

Figures 58, 59; plate 8 [EX]

Ephialtias peba Druce, 1897: 405, pl. 78, fig. 23.

Type Locality

Panama, Volcán de Chiriquí, 3000 ft.

Type

Holotype ♂, Godman-Salvin Coll., “97.-52” (BMNH).

Discussion

This species has been a source of taxonomic mystery ever since Druce (1897) described it. He referred peba to the genus Ephialtias in the Josiini, but Prout (1918) moved it to Brachyglene, where it has remained ever since (Bryk, 1930). Prout noted that the male FW DC is longer in peba (fig. 58E) than in other Brachyglene, all of which possess a short DC (fig. 145F), correlated with presence of a stridulatory organ, but he placed it there nonetheless. My studies confirm complete absence of a stridulatory organ in peba (fig. 58F). This, along with a host of other features, precludes its placement in Brachyglene. My cladistic analyses support the hypothesis that peba belongs in a genus of its own.

Additional research is needed on this fascinating and extremely rare moth. I have seen only four specimens of S. peba—the BMNH holotype, as well as two males and a female from the INBio holdings. I visited the cloud forests of Parque Nacional Tapantí in Costa Rica (January 2007) in an attempt to capture additional specimens of S. peba, but left there empty-handed.

Distribution

Panama (BMNH); Costa Rica (INBio).

Dissected

♂, Costa Rica, Cartago, P. N. Tapantí—Macizo de La Muerte, del Mirador 300 m NO, 1380 m, Jul 2002, leg. Delgado, TP de Luz, L N 191100 560650, #70692, INBio (genitalia slide no. JSM-1312); ♀, Costa Rica, Puntarenas, Parque International La Amistad, Sendero Cerro Pittier, 1 km N de la Estación Pittier, 1800–2000 m, 6 May 1997, leg. M. Moraga, Libre, L S 331800 577400, #75764, INBio (genitalia slide no. JSM-1313).

PHRYGANIDIA PACKARD, 1864

Figures 60Figure 61Figure 6263; plate 8

Phryganidia Packard, 1864: 348. Type species: Phryganidia californica Packard, 1864 (by monotypy).

Figure 60

Morphology of Phryganidia (♂♂) A, head of P. chihuahua, lateral view; B, head of P. naxa, lateral view; C, P. chihuahua wings; D, P. naxa tegula (illustration by J.S. Miller).

i0003-0090-321-1-1-f060.gif

Figure 61

Male genitalia of Phryganidia chihuahua (JSM-112). A, genitalia; B, aedeagus; C, Tg8; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f061.gif

Figure 62

Male genitalia of Phryganidia naxa (JSM-1753). A, genitalia, posterior view; B, genitalia, lateral view; C, aedeagus; D, Tg8; E, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f062.gif

Figure 63

Female genitalia of Phryganidia naxa (JSM-819). A, genitalia, lateral view; B, Tg8; C, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f063.gif

Diagnosis

The three species of Phryganidia are drab, gray-brown to charcoal gray (pl. 8). Phryganidia californica and P. chihuahua possess broad wings, whereas those of P. naxa are more elongate. Typically, the wings of Phryganidia lack contrasting markings, the only exception to this being some of the color forms of P. naxa, in which there can be a yellow FW fascia and a yellow central area of the HW (see Miller, 1987a). Males exhibit widely bipectinate antennae, whereas the female antennae bear short, thick pectinations. The labial palpi are short and thin (fig. 60A, B), curving strongly upward, but barely reaching above the clypeus. The FW DC is longer than one-half the FW length (fig. 60C), and there is no male stridulatory organ. Veins M3 and CuA1 are stalked in both the FW and HW. Phryganidia females exhibit a unique trait, where the caudal margin of Tg8 bears a pair of greatly elongate, sclerotized horns (fig. 63A, B). These processes can be easily seen in pinned specimens.

Redescription

Male (fig. 60; pl. 8). FW length  =  12.0–22.0 mm. Head: Labial palpus short, thin, curving sharply upward to immediately above clypeus; Lp1 curving upward, loosely scaled; Lp2 much shorter than Lp1, with bristlelike, erect scales distally forming a small tuft; Lp3 short, bullet-shaped; scales of front moderately long, pointing dorsally and slightly in toward midline, forming a small, wedge-shaped dorsal crest between antennal bases; eye relatively large, taller than wide, surrounded by a narrow scaleless band, wider below; eye sparsely covered with short setae; scales of vertex long, erect, loosely arranged; antenna widely bipectinate, terminal 2–3 annulations simple.

Thorax: Epiphysis long, over three-fourths length of tibia, extending beyond tibia apex; tegula short, shorter than one-half length of mesoscutum, distal portion rounded, ventral angle blunt; metathoracic tympanum large (P. chihuahua, P. naxa) or moderately large (P. californica), cavity fairly deep, scaleless; tympanal membrane large, ovoid, not enclosed.

Forewing: Broad and quadrate at outer margin, or more elongate with an oblique outer angle (P. naxa); vein Rs1 arising from radial sector below Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC near its anterolateral angle, slightly separate from base of Rs1–Rs4; stridulatory organ absent; DC approximately one-half length of FW; veins M3 and CuA1 stalked; wings drab brownish gray or charcoal gray, sometimes with a diffuse yellowish fascia (P. californica), or an orange-yellow, ovoid fascia (some examples of P. naxa) beyond DC (see Miller, 1987a).

Hind wing: Large and broad, especially so in P. californica and P. chihuahua, outer margin rounded; M3 and CuA1 stalked; evenly brownish gray or charcoal gray, except in rare examples of P. naxa (form fasciata) where there is an orange-yellow central area (see Miller, 1987a).

Abdomen: Relatively long; uniformly brown or gray, without pattern.

Terminalia (figs. 61, 62): Tg8 large, much longer than St8, anterior margin with a pair of short, broad apodemes, mesal margin slightly excavated, posterior margin with a wide, short, finely striate membranous section reaching almost to lateral angles, membrane extending anteriorly to form shallow lateral pockets; St8 short, wide, somewhat triangular, anterior margin with a long, extremely broad, conical mesal process, posterior margin with a U-shaped mesal excavation, bordered on either side be deep, sclerotized pockets; socii/uncus complex large, hoodlike, narrowly attached to tegumen; uncus extremely large and concave, truncate at apex, ventral surface covered with fine setae; socii long, sickle-shaped, wide at base, sharply upturned; anal tube long; tegumen moderately wide, over twice as tall as vinculum; vinculum narrow; saccus forming a U-shaped ventral structure at lower margin of genitalia, its dorsal margin forming a triangle between valva bases; valvae long, simple, wide, becoming widest near apex; BO absent; costa extremely wide, not heavily sclerotized; apex of valva rounded, sclerotized, with a small wedge shaped process at upper angle; arms of transtilla narrow, straplike, oriented horizontally, meeting at midline to form a small, anteriorly directed process above aedeagus; aedeagus extremely short, wide, straight or slightly curved, open at base; apex of aedeagus narrowed to a small, sclerotized ventral process; vesica small, shorter than length of aedeagus, arising upward from aedeagus at an angle of almost 90°.

Female. FW length  =  13.5–23.0 mm. Head, thorax, and wings similar to male, except: Labial palpus slightly shorter, Lp2 without a distal tuft; antennae with short (P. naxa) or moderately long (P. californica) pectinations; wings slightly shorter, broader, outer margins more rounded; wings completely without pattern, either light gray-brown, or charcoal gray; frenulum comprising 6–10 bristles.

Abdomen: Much wider than male.

Terminalia (fig. 63): Tg7 large, wide, over twice as long as Tg6, anterior margin broadly convex, posterior margin gently convex, in naxa with a pair of tiny mesal projections, a large area along midline raised; St7 large, wide, as long as or longer than Tg7, slightly narrower posteriorly; anterior margin of St7 gently convex, posterior margin with a U-shaped mesal excavation, upper sides of U sclerotized, forming rounded posterior processes; St7 membranous along midline, sometimes (P. californica) broadly so; St7 with a transverse groove in anterior fifth (P. naxa); Tg8 sclerotized, forming a rooflike structure, posterior margin with a pair of greatly elongate, mesal processes, these extending posteriorly well past PA; AA short, thick; A8 pleuron completely membranous; PP extremely short, acute; PA moderate in size, membranous, posterior margin slightly angulate; PVP apparently absent, that area membranous; DB extremely short, sclerotized; CB mostly membranous, relatively small, ovoid, abruptly narrowed near junction with DB, two groups of short internal spinules near base; signum absent; DS arising dorsally from CB in narrow region near base.

Distribution

Phryganidia includes the sole member of the Dioptinae represented north of the U.S.–Mexico border; P. californica occurs from Oregon south into the Baja Peninsula of Mexico (Miller, 1987a). Of the two remaining species in the genus, P. naxa is distributed from Nuevo León in northeastern Mexico south to Guatemala, whereas P. chihuahua is known exclusively from northern Mexico.

Biology

Beutelspacher (1986) reported P. naxa larvae as defoliators on various species of Quercus in northern Mexico. This corresponds with observations of P. californica, which defoliates oaks in California (Puttick, 1986). Nothing is known concerning the biology of the third Phryganidia species—P. chihuahua. However, judging from the habitats where it has been collected, dry, oak-pine forests at elevations of approximately 2500 meters, this taxon too is likely to be associated with Quercus.

Experiments with P. californica suggest that females produce a sex pheromone (Hochberg and Volney, 1984), although the chemical composition of the attractant has yet to be elucidated. This remains the only confirmed report of pheromones occurring in the Dioptinae.

Discussion

Phryganidia was revised in a previous publication (Miller, 1987a), and little has been learned about the genus since, except for Beutelspacher's (1986) research on the life history of P. naxa. Miller (1987a) provided an overview of adult morphology, while additional publications (Miller, 1991; 1992b) give information concerning the morphology of P. californica immature stages.

An important question remains: What is the relationship of Phryganidia to other dioptine genera? My analyses produce the somewhat surprising result that Phryganidia is the sister genus to Phanoptis (fig. 7); the clade Phryganidia + Phanoptis shows a relatively strong Bremer support value of 5 (fig. 2). However, not only are Phanoptis species (pls. 8, 9) extremely different from Phryganidia (pl. 8) in general appearance, but what is known concerning immature stages calls such a relationship into doubt. The larvae of Phanoptis exhibit short stemapods on A8 (pl. 37G). These are not present in Phryganidia (pl. 37E). Furthermore, the only known host of Phanoptis is Rinorea (Violaceae), a genus far removed from Quercus in terms of plant phylogeny (Soltis et al., 2005).

Although these pieces of evidence by themselves do not exclude a possible sister-group relationship between Phryganidia and Phanoptis, neither do they offer obvious support. As is generally true of the phylogenetic results presented in this paper, I place considerable confidence in the monophyly of the newly defined dioptine genera, but less confidence regarding relationships between them. Eventually, a robust hypothesis of intergeneric relationships, based on evidence from immature stages and DNA, as well as from adult morphology, should be generated.

KEY TO THE SPECIES OF PHRYGANIDIA

1. Wings concolorous (pl. 8); FW and HW never with light yellow markings2

Ground color of FW gray-brown (pl. 8), HW charcoal gray; FW sometimes with a large, light yellow fascia on dorsal or ventral surface; HW sometimes with orange-yellow central area (NE Mexico S to Guatemala)naxa (Druce)

2. Forewing and HW ground color light brown; tegula buff-yellow; FW length  =  12.0–18.0 mm (Oregon S to Baja)californica Packard

FW and HW ground color gray-brown; tegula gray-brown; FW length  =  19.0–22.0 mm (NE Mexico)chihuahua Miller

SPECIES INCLUDED AND MATERIAL EXAMINED

Phryganidia californica Packard

Plate 8, plate 37E

Phryganidia californica Packard, 1864: 348.

Type Locality

United States, California, San Mateo.

Type

Lectotype ♂ (MCZ).

Discussion

This is the only species of Dioptinae occurring north of the U.S.–Mexico border. Its taxonomy, biology, and distribution are summarized in Miller (1987a).

Distribution

California (AMNH, BMNH, CAS, CMNH, LACM, NMW, OUMNH, UCB, USNM, VOB, ZMH); Oregon (CMNH); Arizona (AMNH, LACM); Mexico (USNM).

Dissected

♂, California, Asilomar, 16 May 1972, Bryant Mather Colln., AMNH (genitalia slide no. JSM-110); ♂, California, USNM (wing slide no. USNM-29170); ♀, California, Monterey, 19 June 1947, leg. Melander, AMNH (genitalia slide no. JSM-111); ♀, California, USNM (wing slide no. USNM-29173).

Phryganidia chihuahua Miller

Figures 60A, 60C, 61; plate 8

Phryganidia chihuahua Miller, 1987a: 308.

Type Locality

Mexico, Chihuahua, Mesa del Huracán, 7400 ft.

Type

Holotype ♂, leg. J.E.H. Martin (CNC).

Discussion

Phryganidia chihuahua is rare, and females are unknown. Existing material includes the type series (10♂♂) from the CNC, and a male in the EME collection, Berkeley. A specimen at the CMNH, discovered after publication of Miller (1987a), falls outside the previously known range of P. chihuahua. That example was captured in Nuevo León, 11 km east-southeast of Galeana. All other localities for P. chihuahua are in the states of Durango and Chihuahua along the Sierra Madre Occidental. Galeana, on the other hand, is in the Sierra Madre Oriental, approximately 175 miles SW of Brownsville Texas. However, dissection of that male (JSM-1806) confirms it to be P. chihuahua, thus broadening the species' distribution eastward.

Distribution

Mexico (CMNH, CNC, EMEC).

Dissected

♂, Mexico, Chihuahua, Mesa del Huracan, 108°15′ 30°4′, 7400 ft, 21–25 Aug 1964, leg. J.E.H. Martin, CNC (genitalia slide no. JSM-112, wing slide no. JSM-114; appendage slide no. JSM-115); ♂, Mexico, Chihuahua, Mesa del Huracan, 108°15′ 30°4′, 7400 ft, 21–25 Aug 1964, leg. J.E.H. Martin, CNC (genitalia slide no. JSM-113); ♂, Mexico, Nuevo Leon, 11 km ESE Galeana, 1680 m, 22 Jun 1982, leg. J. Rawlins & O. Sholes, CMNH (genitalia slide no. JSM-1806); ♂, Mexico, Chihuahua, Mesa del Huracan, 108°15′ 30°4′, 7400 ft, 21–25 Aug 1964, leg. J.E.H. Martin, CNC (genitalia slide no. JSM-1807).

Phryganidia naxa (Druce)

Figures 60B, 60D, 62, 63; plate 8 [EX]

Typhonia naxa Druce, 1885a: 229.

Type Locality

Guatemala, Guatemala City, 5000 ft.

Type

Lectotype ♀, leg. Champion (BMNH).

Josia brevifascia Prout, 1918: 421. New synonymy.

Type Locality

“Amaz. SA”.

Type

Holotype ♂ (BMNH).

Phryganidia fasciata Hering, 1928: 271.

Type Locality

Tecpán, Guatemala.

Type

Syntype ♂ (ZMH).

Tithraustes watsoni Beutelspacher, 1986: 477–482. New synonymy.

Type Locality

Nuevo León, Mexico.

Type

Not seen (holotype ♂; UNAM).

Discussion

This species is remarkable in showing broad wing pattern variation (Miller, 1987a). Two new synonyms of P. naxa were discovered since Miller (1987a). First, Prout (1918), normally a careful worker, inexplicably described brevifascia in Josia, a genus with which it shares no similarities. My dissection of the BMNH brevifascia type (JSM-278) confirms it as a junior synonym of P. naxa. The locality label on the brevifascia type reads “Amaz. SA”, implying that the moth was collected somewhere on the Amazon. That label, undoubtedly incorrect since the species is known exclusively from Guatemala and Mexico, perhaps threw Prout off the track. The habitus of P. naxa has confused other taxonomists as well; Druce (1885a) originally described the species in Typhonia, a genus belonging in the family Psychidae.

The second new synonym is attributable to Beutelspacher (1986), who described Tithraustes watsoni from Nuevo León, Mexico, not realizing that his specimens were in fact misidentified material of Phryganidia naxa. Beutelspacher figured the larva and pupa of P. naxa for the first time, also showing adults and their male genitalia. He discovered that the species is an important defoliator of Quercus in the state of Querétaro, Mexico.

Distribution

Guatemala (BMNH, LACM, USNM); Mexico (ARTC, CMNH, EMEC, UNAM).

Dissected

♂, Guatemala, Guatemala City, Nov, Schaus & Barnes Coll., USNM (genitalia slide no. JSM-1787); ♂, Guatemala, Guatemala City, Sep, Schaus & Barnes Coll., USNM (genitalia slide no. JSM-1788); ♂ syntype of brevifascia Prout (genitalia slide no. JSM-278); ♀, Guatemala, Volcán Sta. Maria, Schaus & Barnes Coll., USNM (genitalia slide no. JSM-1789); ♀, Mexico, Nuevo Leon, Chipinque Mesa, 4300 ft, 19 Sep 1975, at light, leg. J. Powell & J. Chemsak, EMEC (genitalia slide no. JSM-819).

PHANOPTIS C. AND R. FELDER, 1874

Figures 64Figure 65Figure 66Figure 67Figure 6869; plates 8, 9

Phanoptis C. and R. Felder, 1874: pl. 104, fig. 10. Type species: Phanoptis cyanomelas C. and R. Felder, 1874 (by monotypy).

Figure 64

Morphology of Phanoptis (♂♂). A, head of P. donahuei, lateral view; B, head of P. fatidica, lateral view; C, head of P. fatidica, posterior view; D, head of P. fatidica, frontal view; E, P. cyanomelas labial palpus; F, head of P. vitrina, lateral view; G, head of P. vitrina, frontal view; H, head of P. vitrina, posterior view; I, P. fatidica tegula; J, P. vitrina tegula; K, P. cyanomelas wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f064.gif

Figure 65

Scanning electron micrographs of Phanoptis cyanomelas ♂, HW dorsal surface. A, broad scales along veins and narrow scales between veins; B, apex of a vein scale, and a narrow scale from A; C, narrow scale from B; D, base of narrow scale; E, surface of narrow scale; F, tip of narrow scale.

i0003-0090-321-1-1-f065.gif

Figure 66

Genitalia of Phanoptis fatidica (♂ JSM-1239, ♀ JSM-1241). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f066.gif

Figure 67

Genitalia of Phanoptis cyanomelas (♂ JSM-1246, ♀ JSM-1249). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♀ genitalia; E, ♂ St8 (illustration by A. Trabka).

i0003-0090-321-1-1-f067.gif

Figure 68

Genitalia of Phanoptis donahuei, sp. nov. (♂ JSM-1672, ♀ JSM-1673). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8.

i0003-0090-321-1-1-f068.gif

Figure 69

Mexico and northern Central America, showing the known distribution of Phanoptis donahuei, sp. nov.

i0003-0090-321-1-1-f069.gif

Diagnosis

A combination of wing venation and head characters provides the most effective means for recognizing Phanoptis species (pls. 8, 9). First, the wings are large, up to 30.0 mm long in females. Veins M3 and CuA1 are widely separate in both the FW and HW (fig. 64K), and the FW DC is much longer than one-half the wing length. These features distinguish Phanoptis from other Dioptinae with hyaline wings, including large Dioptis taxa, such as D. candelaria and D. phelina (pl. 18). Although these latter bear superficial resemblance to Phanoptis, in Dioptis veins M3 and CuA1 are usually stalked in the FW and HW (fig. 190D–G), and the DC is less than one-half the FW length. Males in the two genera can be quickly separated by their antennal morphology—bipectinate in Phanoptis, but quadripectinate in Dioptis (fig. 188C, D). A useful feature for distinguishing Phanoptis from other clear-winged Dioptinae can be found on the head; the proboscis is light yellowish brown in Phanoptis, but dark brown in others.

Other than Phanoptis, the only dioptines with the bases of M3 and CuA1 widely separate in both wings are Phaeochlaena (fig. 70F) and Xenomigia (fig. 235G, H). It is nearly impossible to confuse these genera because their wing patterns are so different (compare pls. 9, 10, and 22, 23). However, even venation alone provides characters for separation. In Xenomigia, FW veins M1 and M2 are swollen to form a male stridulatory organ, absent in Phanoptis. Phaeochlaena is unusual in that FW vein Rs1 arises from the DC, separate from Rs2–Rs4, whereas Phanoptis shows the more typical configuration, in which Rs1 is stalked with the remaining veins of the radial sector. Many additional features, including differences in labial palpus shape, distinguish these three genera.

Redescription

Male (figs. 64, 65; pls. 8, 9). FW length  =  20.0–27.0 mm. Head: Labial palpus short, wide, curving upward to clypeus or slightly above; Lp1 short, curved upward, with a loose fringe of long scales below; Lp2 straight or nearly so, either shorter than Lp1 or approximately the same length, closely scaled; Lp3 short, ovoid or quadrate; clypeus scaleless; scales of front short, densely packed, swooping downward from below antennal bases, then pointing horizontally to form a low, diffuse cone at midline above clypeus; eye large, gena narrowly scaleless below; antennae bipectinate, rami long.

Thorax: Epiphysis long, narrow, extending slightly beyond apex of tibia; tegula short, wide, ventral process wide and rounded, tegula without a sulcus separating dorsal and ventral portions; metathoracic tympanum small but deeply inset; tympanal membrane small, enclosed, facing ventrally.

Forewing: Triangular, anal angle acute; vein Rs1 stalked with Rs2–Rs4; veins Rs2–Rs4 in pattern [2+3]+4; M1 widely separate from base of Rs1–Rs4, UDC long, at a shallow angle from radial sector; stridulatory organ absent; DC extremely long, almost two-thirds FW length; veins M3 and CuA1 widely separate, M3 arising from posterolateral angle of DC, CuA1 arising basally from cubitus; pattern either dark brown to blackish brown with three large hyaline areas and dark veins passing through (P. cyanomelas, P. donahuei, P. taxila, P. vitrina), iridescent blackish blue with a single white transverse band (P. fatidica), or dark brown with a reddish transverse band (P. miltorrhabda).

Hind wing: Elongate or rounded; veins M3 and CuA1 widely separate, M3 arising from posterolateral angle of DC, CuA1 arising basally from cubitus; pattern either uniformly dark (P. fatidica, P. miltorrhabda), or broadly hyaline with a dark marginal band and dark veins.

Abdomen: Moderately long, swollen in distal section; dorsum dark, venter usually white, a thin white line along pleuron.

Terminalia (figs. 66A–D, 67A–C, 67E, 68A–C, 68E): Tg8 either narrowing distally, with a truncate mesal process at posterior margin, or wide and quadrate, with a pair of large humps on either side of midline, posterior margin slightly concave (P. fatidica); anterior margin of Tg8 broadly convex with a pair of short, broad lateral apodemes; St8 wide, somewhat quadrate; anterior margin of St8 either with a short, broad, transverse mesal apodeme, or a short, wide apodeme, its leading edge concave; socii/uncus complex large; uncus either absent, or greatly elongate and robust, apex truncate (P. fatidica); socii either long, swollen at the bases and narrow at the apex, or forming a huge X-shaped structure (P. fatidica); tegumen taller than vinculum, expanded above; vinculum short, narrow; saccus a narrow transverse band, its upper margin not extending upward to valva bases; valvae either extremely wide or long and extremely narrow (P. fatidica), BO absent; in all species except P. fatidica a large, conspicuous tuft of androconia on valva's lateral surface; costa wide or narrow; apex truncate and concave with various marginal processes, or expanded into a large paddle-shaped structure (P. fatidica); arms of transtilla narrow, meeting to form a small sclerite at midline, or transtilla absent (P. fatidica); aedeagus long and sclerotized, narrow in distal two-thirds, wider at base; apex of aedeagus acute below; opercular sclerite in some species bearing a small, dorsal tooth; vesica approximately one-half length of aedeagus, pointing upward at a sharp angle from aedeagus; cornuti either absent (P. fatidica), or short and spinelike.

Female (pls. 8, 9). FW length  =  22.0–30.0 mm. Head: Labial palpus thinner than male, approximately the same length; Lp2 shorter than Lp1; antenna bipectinate, rami short to moderately long.

Thorax: Similar to male.

Forewing: Longer and broader than male, outer margin more rounded; pattern similar to male, lighter in color, slightly less intense.

Hind wing: Longer and broader than male; frenulum comprising 5–8 bristles.

Abdomen: Shorter and wider than male, distal portion swollen.

Terminalia (figs. 66E, 67D, 68D): Tg7 large, extremely wide, anterior margin simple, posterior margin gently convex, or with a large, deep V-shaped fold (P. fatidica); St7 large, wide, anterior margin simple, posterior margin broadly concave; a transverse groove anterior to posterior margin, in P. fatidica with a deep, round central pocket; surface of St7 either setose (P. fatidica) or spiculate; Tg8 short, sclerotized, posterior margin angulate, crenulate; AA short; A8 pleuron sclerotized; PP short or absent; PP moderately large, or large, surfaces densely spiculate, posterior margins convex; PVP wide, sclerotized, surface with numerous longitudinal striae; DB heavily sclerotized, dorsoventrally compressed, funnel shaped, widest at ostium; CB membranous, either extremely large with a smaller ventral appendix, or an upright oval (P. fatidica); signum absent (P. fatidica), or a large, transverse dorsal sclerite, its internal surface sharply dentate; DS arising dorsally at base of CB; an ovoid sclerite along ventral midline on CB in P. vitrina and P. cyanomelas.

Distribution

Phanoptis shows a broad distribution, extending from Mexico south to Bolivia. In South America the species are exclusively Andean, with the inclusion of the northern range of Venezuela. None has been recorded from the Amazon or upper Amazon Basin. Phanoptis donahuei, sp. nov., from southern Mexico and Guatemala, is the northernmost member of the genus. Two species—cyanomelas and vitrina—occur in Central America south into Colombia, while fatidica is distributed from Venezuela to Peru. The southernmost representative is miltorrhabda, endemic to Peru and Bolivia. In general, Phanoptis species are rare; P. miltorrhabda is known from only three specimens, while P. taxila is known exclusively from the holotype.

Biology

The life history of only one Phanoptis species, P. cyanomelas, has been discovered. On two separate occasions at Finca La Selva, Costa Rica (Limón Province), caterpillars of P. cyanomelas were recorded feeding on Rinorea (Violaceae). In the first instance, Phil DeVries (July 1979) found a single larva and reared it to an adult (AMNH). The second case is attributable to Dyer and Gentry (2002), who documented the complete life history of P. cyanomelas.

Phanoptis is one of four dioptine genera now recorded from Rinorea (table 4). This assemblage of taxa is widely dispersed on the dioptine cladogram (see Discussion: Host Plants, and fig. 356). Based on available evidence, it appears that an association with Rinorea evolved at least three separate times within the subfamily.

Caterpillars of P. cyanomelas are striking (pl. 37G). In addition to an unusual black and white, tiger-stripe pattern on the body, the anal prolegs are modified into stemapods, similar to, but shorter than, those found in Erbessa (e.g., pl. 37A). Stemapods are unique to the Notodontidae, but have evolved multiple times within the family (Godfrey and Appleby, 1987; Miller, 1991; Kitching and Rawlins, 1999). In the Dioptinae, they have now been reported in three genera—Phanoptis, Erbessa, and Phaeochlaena. This constitutes only partial documentation of their occurrence across the subfamily since larvae for many genera have yet to be found. Nevertheless, the genus cladogram constructed from adult morphology (fig. 7) suggests that stemapods have evolved multiple times by convergence.

Discussion

If one considers wing pattern alone, the six described species of Phanoptis comprise an unlikely group. Members of the Cyanomelas Group possess hyaline wings with dark veins (pl. 9), while in the Fatidica Group (pl. 8) patterns diverge. Phanoptis fatidica is unique with its iridescent blackish blue wings, while the highly unusual P. miltorrhabda (pl. 8) is the only dioptine, other than Anticoreura salmoni (pl. 25), to exhibit reddish FW markings. Nevertheless, these wing-pattern characteristics are autapomorphic and belie species interrelationships. When all adult morphological evidence is taken into account, the monophyly of Phanoptis is extremely well supported (fig. 2; appendix 4).

Like their wing patterns, genital morphology in the two Phanoptis species groups diverges strongly. Again, however, most of these differences are autapomorphies. For example, the male socii/uncus complex of P. fatidica is extremely strange, particularly the huge X-shaped configuration of the socii (fig. 66A). Prout (1918) placed fatidica in Phanoptis, and my research provides additional support for his hypothesis.

Wing transparency in Phanoptis results from having large areas between the veins sparsely covered with thin, curved scales (fig. 65A–C). The wing veins themselves are densely lined with wide, elongate ovoid scales (fig. 65A, B), making them opaque. The thin scales are cylindrical (fig. 65C, E), gradually tapering to a point (fig. 65F). Scale morphology in other genera with transparent wings shows an identical configuration, even though the hyaline-winged trait appears to have evolved many times separately in the Dioptinae (see Discussion: Wing Pattern).

The taxonomic history of Phanoptis is relatively straightforward. This is probably attributable to the fact that the group's wing venation, the most important character system of earlier workers (Prout, 1918), is instantly recognizable. The genus was established by C. and R. Felder (1874), who included a single species—cyanomelas. Subsequent authors (Druce, 1885a, 1907; Prout, 1922) described individual species. It was Prout (1918) who moved fatidica from Phelloe, currently a synonym of Erbessa, to Phanoptis. Bryk (1930) listed five species of Phanoptis. In this paper a sixth, donahuei, is described. Here, Phanoptis is for the first time divided into species groups—the Cyanomelas and Fatidica groups.

KEY TO PHANOPTIS SPECIES GROUPS

1. Labial palpus segment 1 orange-yellow, Lp2 completely or partially orange-yellow, Lp3 dark brown; wings hyaline (pl. 9); CB of female genitalia large, with a ventral appendix (figs. 67D, 68D); female papillae anales without a dorsal knob between them; posterior margin of male Tg8 gradually narrowed, with a broad mesal process (figs. 67C, 68E); uncus absent (figs. 67A, 68A)Cyanomelas Group

Labial palpus blackish brown, without yellow, occasionally with white scales on dorsum of Lp1; wing pattern variable (pls. 8, 9); CB of female genitalia relatively small, ovoid (fig. 66E), without a ventral appendix; female with a sclerotized dorsal knob between papillae anales; posterior margin of male Tg8 with a hornlike central process (fig. 66C); uncus greatly elongate (fig. 66A)Fatidica Group

1. FATIDICA GROUP

The Fatidica Group contains three species with highly divergent wing patterns (pls. 8, 9). Nevertheless, the clade is supported by several synapomorphies, and shows diagnostic characters distinguishing it from the Cyanomelas Group. Dissections provide direct confirmation that P. fatidica and P. miltorrhabda belong together in this species group, but the membership of P. taxila is somewhat questionable. The evidence to date is circumstantial since the holotype, the only known specimen of that species, has not been dissected. My decision to place P. taxila in the Fatidica Group is based on its wing pattern, as well as on the presence of brown labial palpi (see species group key, above).

KEY TO FATIDICA GROUP SPECIES

1. Transverse FW band whitish or hyaline, ground color dark blackish brown with a purple iridescence; HW hyaline or completely blackish brown2

Transverse FW band rosy red to salmon colored, ground color dark gray-brown (pl. 8); HW chocolate brown; FW length  =  20.0 mm (Peru, Bolivia)miltorrhabda Prout

2. Forewing and HW completely black to blackish brown with a purple iridescence (pl. 8), except for a narrow, white transverse FW band beyond DC; FW length  =  18.5–23.5 mm (Venezuela, Colombia S to Peru)fatidica (Dognin)

Forewing mostly hyaline in basal half (pl. 9), a wide, white transverse band beyond DC; HW broadly hyaline in central area; FW length  =  21.5 mm (Colombia)taxila Druce

Phanoptis fatidica (Dognin)

Figures 64B–D, 64I, 66; plate 8 [EX]

Phelloe fatidica Dognin, 1910a: 17.

Type Locality

Peru, Oxapampa, 2000 m.

Type

Holotype ♀ (USNM type no. 30948).

Discussion

The wing pattern of Phanoptis fatidica stands out in the Dioptinae. No other species shows a uniformly iridescent blue-black FW and HW with a single white transverse FW band. Material in collections suggests that P. fatidica occurs from Venezuela west to Colombia, then south along the eastern slope of the Andes to central Peru. However, closer study reveals a problem: The female genitalia of Venezuelan specimens (JSM-1238) differ from the Peruvian type (JSM-1237). In addition, the white transverse FW band is narrower in Venezuelan material. There are no known Peruvian males, but a male from Ecuador (JSM-1691), which one might suggest is conspecific with the type, again differs markedly from Venezuelan examples. I conclude that an undescribed species, closely related to P. fatidica, occurs in the vicinity of Rancho Grande, Venezuela. I refrain from describing that taxon, however, not because the undescribed species is rare—on the contrary it occurs in large series at the AMNH and USNM—but instead because we are in dire need of samples from near the fatidica type locality, Oxapampa, Peru.

At Rancho Grande, so-called “Phanoptis fatidica” occurs in sympatry with a remarkable mimic, Ctenucha andrei Rothschild (Arctiidae: Ctenuchinae). The ctenuchine is slightly smaller and has browner forewings (pl. 8), but can otherwise be separated from the Phanoptis only by careful examination of its wing venation and tympanum, both of which betray membership in the Arctiidae.

Distribution

Peru (USNM); Ecuador (SMNS); Colombia (BMNH, USNM); Venezuela (AMNH, BMNH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1237); ♂, Ecuador, Zamora-Chinchipe, Estación Científica San Francisco, 03°58.4-6′S, 79°04.6-6′W, 1880–2000 m, Quebrada 2, forest, 6 Nov 2000, leg. G. Brehm, SMNS (genitalia slide no. JSM-1691); ♂, Colombia, Muzo, Sep 1918, Dognin Collection, USNM (genitalia slide no. JSM-1239); ♂, Venezuela, Aragua, Rancho Grande, 1084 m, 21 Jul 1948, leg. H. Fleming, AMNH (genitalia slide no. JSM-1692); ♀, Venezuela, Aragua, Rancho Grande, 1084 m, 7 Jun 1948, leg. H. Fleming, AMNH (genitalia slide no. JSM-1238); ♀, Colombia, Muzo, Sep 1918, Dognin Collection, USNM (wing slide no. JSM-1240, genitalia slide no. JSM-1241).

Phanoptis miltorrhabda Prout

Plate 8

Phanoptis miltorrhabda Prout, 1922: 268.

Type Locality

Peru, Chanchamayo.

Type

Holotype ♂ (BMNH).

Discussion

Phanoptis miltorrabda is known to me from three specimens: the male holotype, a female from Bolivia collected by P. Germain in 1888 (BMNH), and a female at the AMNH collected in Bolivia over 100 years later (JSM-1693). Not only can I confirm Prout's placement of miltorrhabda in Phanoptis, but morphological traits, including structure of the female genitalia, suggests that miltorrhabda is the sister species to P. fatidica.

In terms of wing pattern, P. miltorrhabda is one of the most fascinating members of the Dioptinae; red markings are rare in the group. In his original description, Prout (1922: 268) explained the moth's anomalous pattern by saying that the species was “evidently drawn off by mimetic association with the butterflies Actinote erinome Felder and Eresia castilla Felder”.

Prout's hypothesis deserves consideration. The second of these butterflies, now called Castilia castilla (Nymphalidae: Melitaeinae), is endemic to Colombia and Ecuador. The species is not sympatric with Phanoptis miltorrhabda, and could not therefore be involved in a mimetic association with it. However, the other butterfly, now Abananote erinome (Nymphalidae: Heliconiinae: Acraeini), does occur in sympatry with P. miltorrhabda, so the two are potential mimics. Their wing patterns are extremely similar. Abananote larvae feed on pyrrolizidine alkaloid–containing Asteraceae, and these butterflies are thought to be chemically protected (DeVries, 1987). Whether P. miltorrhabda is chemically protected or not is entirely speculative. Its host plant is unknown, although Rinorea, the host of P. cyanomelas, would be an appropriate guess. A developmental study of wing pattern evolution within Phanoptis, with particular attention being paid to explaining the wings of P. miltorrhabda, would be a fascinating endeavor.

Distribution

Peru (BMNH), Bolivia (AMNH, BMNH).

Dissected

♀, Bolivia, Chaparé, San Onofre, 1200 m, 9 Aug 1998, leg. J.-Y. Gallard, AMNH (genitalia slide no. JSM-1693).

Phanoptis taxila Druce

Plate 9

Phanoptis taxila Druce, 1907: 309.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♀ (BMNH).

Discussion

The female holotype, the only know specimen of Phanoptis taxila (pl. 9), is missing the distal portion of its abdomen, so its genital morphology will never be known. Nevertheless, P. taxila is highly distinctive. Examination of the type shows that the species is properly placed within Phanoptis. Based on the presence of a single transverse FW band, without the second, smaller subapical band that occurs in Cyanomelas Group species, P. taxila may be related to P. fatidica. This hypothesis is further supported by the presence of brown labial palpi in P. taxila, rather than the yellow ones found in members of the Cyanomelas Group. Acquisition of males and intact females will be required to better understand the position of this species within Phanoptis.

Distribution

Colombia (BMNH).

Dissected

None.

2. CYANOMELAS GROUP

This subgroup includes three closely related species (pl. 9). Their wing patterns and morphology, including male and female genitalia, show only subtle differences. Available Cyanomelas Group material from South America is scant. Additional collecting there will invariably produce novel taxa.

KEY TO CYANOMELAS GROUP SPECIES

1. Labial palpus segment 1 and Lp2 entirely orange-yellow, Lp3 dark brown; wing ground color iridescent purplish brown (pl. 9)2

Lp1 orange-yellow, Lp2 mostly dark brown with scattered orange-yellow scales at base, Lp3 dark brown; wing ground color iridescent blue-black; transverse FW band hyaline (pl. 9), usually without white scales; FW length  =  21.5–30.0 mm (E Costa Rica S to Ecuador)cyanomelas C. and R. Felder

2. Wing veins finely lined with blackish brown scales; dorsal margin of male costa slightly arched near base; female Tg8 strongly crenulate; PA small, dorsal angle acute; FW length  =  23.0–30.0 mm (SW Costa Rica S to Colombia)vitrina Druce

Wing veins thickly lined with blackish brown scales; dorsal margin of costa arching abruptly upward (fig. 68A); female Tg8 finely crenulate; PA large, dorsal angle rounded (fig. 68D); FW length  =  20.0–24.0 mm (SE Mexico, Guatemala)donahuei, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Phanoptis cyanomelas C. and R. Felder

Figures 64E, 64K, 65, 67; plate 9 [EX]

Phanoptis cyanomelas C. and R. Felder, 1874: pl. 104, fig. 10.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♂ (BMNH).

Discussion

The geographical ranges of Phanoptis cyanomelas and P. vitrina overlap extensively, and the two species are frequently confused in collections. Means for separating them are provided in the species key (above). In the Felder type of P. cyanomelas (BMNH), the FW is completely hyaline with no white scales in the transverse band. The dark areas of the wings are almost blue-black, contrasting sharply with the transparent regions in between. On the other hand, in the Druce type of P. vitrina (also BMNH), the FW transverse band is translucent white, the veins passing through the band are mostly white, and the dark regions of the wings have a generally brownish color. Another difference is that the transparent apical bar is larger in P. cyanomelas.

Phanoptis cyanomelas and P. vitrina occur together from Colombia north to Costa Rica. However, at least with regard to Central American material, locality data on museum specimens suggests a working hypothesis—that P. cyanomelas is endemic to the Caribbean side of the central Cordillera, whereas P. vitrina is from the Pacific side. In Costa Rica (see fig. 4), P. cyanomelas has been captured in Limón Province on the Caribbean coast (AMNH, INBio), whereas P. vitrina has been collected exclusively on the Osa Peninsula (AMNH).

One cautionary note: P. cyanomelas and P. vitrina exhibit nearly identical genitalia; the apical regions in the male valvae differ slightly. Furthermore, some Costa Rican specimens show an intermediate wing pattern, where the wing ground color is dark, typical of cyanomelas, but the veins passing through the FW cross band bear white scales, as in vitrina. The taxonomy of these species needs attention.

Phanoptis cyanomelas has been reared in Costa Rica on an as yet unidentified species of Rinorea (Violaceae), a plant genus utilized by three additional dioptine genera (table 4).

Distribution

Costa Rica (AMNH, BMNH, FNHM, INBio, LACM, USNM); Panama (AMNH, BMNH, LACM, PMNH, USNM, ZMH); Colombia (AMNH, BMNH, NMW, USNM); Ecuador (BMNH, LACM, USNM).

Dissected

♂, Panama, Panama Prov., Cerro Campaña, 1000 m, 7 May 1993, leg. C. Snyder, AMNH (genitalia slide no. JSM-1243); ♂, Colombia, Villavicencio, préz Bogotá, Jul 1918, leg. Apollinaire, USNM (wing slide no. JSM-1245, genitalia slide no. JSM-1246); ♂, Ecuador, leg. C. de Labonnefon, Dognin Collection, USNM (genitalia slide no. JSM-1244); ♂, Costa Rica, Heredia, Finca La Selva, 50–100 m, 20 Jul 1979, leg. P. DeVries, “host plant Rinorea”, AMNH (genitalia slide no. JSM-415); ♀, Costa Rica, Cartago, Jul 1909, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1247).

Phanoptis donahuei, new species

Figures 64A, 68, 69; plate 9

Diagnosis

Phanoptis donahuei shows a wing pattern similar in its basic elements to those of P. cyanomelas and P. vitrina (pl. 9). It differs from them in that the hyaline areas are more restricted, with the veins more thickly lined with blackish brown scales. In males, the white transverse FW band is particularly narrow. Phanoptis donahuei can also be distinguished from other Cyanomelas Group species by its generally smaller size. Females overlap in size with some female examples of P. vitrina and P. cyanomelas, but males of donahuei are consistently smaller. The genitalia of P. donahuei clearly set this taxon apart. For example, its male valva shape is unique (fig. 68A). Furthermore, P. donahuei is endemic to southeastern Mexico and Guatemala (fig. 69), whereas the other two species are not known north of Costa Rica.

Description

Male (fig. 64A; pl. 9). Forewing length  =  20.0–21.5 mm. Head: Labial palpus fairly long and wide, porrect, Lp1 and Lp2 approximately equal in length, Lp3 extremely short, conical; Lp1 and Lp2 bright orange-yellow, Lp3 dark brown; scales of front moderately long, erect, pointing anteriorly; front covered with brown scales, a triangular patch of white scales below antennal bases; occiput dark brown in upper three-fourths, white below; eye moderately large, round, completely surrounded by a thin, scaleless band; vertex dark brown with a tiny patch of white scales on dorsum, a small white lateral patch behind each eye; scape dark brown above, white below; antennal shaft dark brown.

Thorax: Coxa white on inner surfaces, a mixture of white and brown scales laterally; femur and tibia light brown on outer surfaces, white on inner ones; spurs extremely short, buff colored; pleuron covered with a mixture of white and light brown scales; patagium dark brown, with a small white patch at midline; tegula covered with dark brown scales having a bluish sheen, lower angle white; scales of dorsum dark brown, with a bluish sheen; tympanum small, heavily sclerotized, forming a shelflike structure; membrane deeply inset, facing ventrally.

Forewing: (Dorsal) Ground color dark chocolate brown to blackish brown, with a purplish iridescence; a hyaline area in basal third, cubitus and anal fold lined with blackish brown scales a they pass through; fork of cubitus and CuA2 forming a darkened wedge; a transverse band in distal two-thirds located basal to distal margin of DC, extending from subcosta to immediately beyond CuA2, band narrowest anteriorly; surface of transverse band sparsely covered with white scales, veins lined with white as they pass through; a small, diffuse, subapical hyaline band, touching Rs4 anteriorly and falling short of M3 posteriorly, veins M1 and M2 blackish brown as they pass through; anal margin dark brown. (Ventral) Similar to dorsal surface, except a dusting of white scales near base along subcosta and cubitus.

Hind wing: (Dorsal) Anterior and outer margins broadly banded with dark brown; rest of wing hyaline, veins lined with dark brown. (Ventral) Similar to dorsal surface, but a dusting of white scales near base; costa white.

Abdomen: Dorsum gray-brown with a steely blue iridescence; a thin white lateral line along pleuron; venter white.

Terminalia (fig. 68A–C, 68E): Tg8 widest at anterior margin, narrower posteriorly; posterior margin of Tg8 abruptly narrowed at corners to form a spatulate central process anterior margin with wide, short apodemes at lateral angles; St8 wider than Tg8, widest in anterior third; posterior margin of St8 with smoothly rounded lateral humps and a shallow, U-shaped mesal excavation; anterior margin of St8 with two wide apodemes, broadly fused at the midline; uncus/socii complex large, hinged at junction with ring; uncus apparently absent, or fused with bases of socii; socii large, extremely wide at base, narrowing to blunt apices, socii upturned; tegumen wide, bowed laterally near midpoint, constricted at junction with vinculum; vinculum narrow, short; saccus forming a small, transverse structure, margin horizontal below; valva large, heavily sclerotized, curved inward; BO comprising a large, lateral pocket near base of valva, pleats absent, androconia short; costa broadly sclerotized, with an earlike expansion along margin near midpoint; valva apex heavily sclerotized on lateral surface, distal margin with three, heavily sclerotized processes, the middle one longest, the upper one short and blunt; ventral margin of valva sinuate; central portion of valva bearing a pocket of dark, tightly packed, fleshy setae two-thirds out; transtillar arms narrow, oriented horizontally, meeting at midline to form a small, anteriorly directed process; aedeagus long, base wide, bell shaped, then abruptly narrowed one-third out; opercular sclerite with a small, thornlike process near apex above; ventral portion of aedeagus apex without a point or process; vesica narrow, with a patch of short, straight, spinelike cornuti distally.

Female (pl. 9): FW length  =  22.5–24.0 mm. Wing and body characters similar to male except: Wings longer; ground color lighter, chocolate brown; white transverse FW band wider.

Abdomen: Dorsum gray-brown with a slight purplish iridescence; pleuron bearing a thin white longitudinal line; venter white.

Terminalia (fig. 68D): Tg7 large, gradually tapered distally, anterior margin simple, posterior margin broadly rounded; St7 robust, slightly narrower than St6, anterior margin simple, posterior margin broadly concave; St7 with a wide, deep transverse groove near posterior margin; Tg8 sclerotized, short and wide, posterior margin finely crenulate; AA extremely short and wide, triangular; PA relatively large, posterior margin straight, upper angle rounded; PP robust, short, and wide, slightly broadened at apices; PVP extremely wide, wrapping upward to touch Tg8, midline bearing longitudinal striae, each lateral angle of PVP bearing a shallow depression; ostium comprising an extremely wide, dorsoventrally compressed funnel: DB sclerotized, constricted and elbowed upward near middle; DS attached dorsally at junction of DB and narrowed base of CB; CB extremely large, membranous, ovoid, narrowing toward DB, bearing a prominent, round appendix ventrally, appendix somewhat bilobed; CB with a diffuse, finely spiculate ventral sclerite near base; signum located dorsally, comprising a transverse, dentate structure with a large, lateral internal ridge.

Etymology

This species name honors Julian P. Donahue, curator emeritus of the entomology department at the Natural History Museum of Los Angeles County. Julian graciously sent me two extensive loans of Dioptinae from the LACM, one in 1986 and another in 2006. These showcase that museum's unparalleled collections of Mexican material. The earlier loan contained two males of Phanoptis donahuei, whereas the more recent one included 11 additional examples (8♂♂, 3♀♀). This LACM material comprises the P. donahuei type series.

Distribution

Phanoptis donahuei has been collected at three localities in southern Mexico (fig. 69)—two close together in Veracruz and a third in Chiapas—spanning a distance of less than 300 km. The Chiapas locality is located close to the Guatemalan border, while Catemaco and Dos Amates, essentially the same site, are on the Gulf coast approximately 150 km SE of Veracruz. These are lowland locations, covering altitudes of between 200 and 500 meters.

A single USNM female from “Quirigua” demonstrates the occurrence of P. donahuei in Guatemala. That example, originally from the Schaus and Barnes Collection, does not indicate a year of capture, but was probably collected near the turn of the 20th century. Quiriguá (15°16′00″N, 89°05′00″W) is located in the state of Izabal, in close proximity to the Guatemala-Honduras border at an elevation of approximately 100 meters. That site (fig. 69), along the Río Motagua near the town of Los Amates, represents a significant southward range extension for P. donahuei.

Discussion

Males of P. donahuei are easy to recognize because the white transverse band of the FW is consistently narrower than in other Phanoptis species (pls. 8, 9), and the moths themselves are relatively small. Females are more difficult; some specimens of P. vitrina show similar size and wing pattern to females of P. donahuei. Other than comparison of genital morphology, the best way to separate these is by the thick scaling of dark brown on the FW and HW veins in donahuei, compared to the thin scaling of vitrina.

In addition to the material listed below, the collection of Alonso and Rafael Turrent (Mexico City) contains 21 examples of P. donahuei from Chiapas. It will be important to sample more extensively in Mexico and Guatemala to better establish the geographical boundaries of this species. The northern limit of P. donahuei is potentially determined by the northernmost distribution of its host plant, almost certainly a species of Rinorea.

Holotype

Male (pl. 9). Mexico: Veracruz: Catemaco, 23 Sep 1972, leg. Peter Hubbell (LACM). The type is deposited at the LACM.

Paratypes

Mexico: Veracruz: 1♂, Dos Amates, 18.43°N, 95.0°W, 17 Oct 1971, leg. Peter Hubbell (LACM); 1♂, Catemaco, 18.47°N, 95.17°W, 23 Nov 1972, leg. Peter Hubbell (LACM); 4♂♂, 1♀, Catemaco, 23 Sep 1972, leg. Peter Hubbell (LACM); 1♀, Catemaco, Dos Amates, 15 Sep 1972, leg. Peter Hubbell (LACM); 1♂, Dos Amates, 15 Oct 1973, leg. Peter Hubbell (LACM; genitalia slide no. JSM-416); 1♂, 20 Oct 1973, leg. Peter Hubbell (LACM); 1♀, Dos Amates, nr. Santiago Tuxtla, 18.08°N, 95.05°W, Aug 1973, leg. Peter Hubbell (LACM; genitalia slide no. JSM-1673). Chiapas: 1♂, San Quintin, 16.4°N, 91.35°W, 3 Sep 1971, leg. Robert Wind (LACM; genitalia slide no. JSM-1672).

Other Specimens Examined

Guatemala: Izabal: 1♀, Quiriguá, Sep, Schaus and Barnes Collection (USNM).

Dissected

2♂♂, 1♀.

Phanoptis vitrina Druce

Figure 64F–H, 64J; plate 9 [EX]

Phanoptis vitrina Druce, 1885a: 162, pl. 14, fig. 26.

Type Locality

Panama, Volcan de Chiriquí, 3000–4000 ft.

Type

Syntype ♂ (BMNH).

Discussion

Phanoptis vitrina can be distinguished from P. cyanomelas by its semitransparent white, rather than hyaline, FW cross band. Furthermore, the wing ground color of P. vitrina is generally chocolate brown rather than bluish black. Perhaps the best character for separating the two species is the color of Lp2, which is orange-yellow in P. vitrina, but mostly brown in P. cyanomelas. A greater difficulty comes in separating P. vitrina from P. donahuei, in both of which Lp1 and Lp2 are completely orange-yellow. The most reliable trait, other than genital differences, is the width of blackish brown scaling on the wing veins. The veins are more thinly lined in P. vitrina. As is touched upon with reference to P. cyanomelas, it appears that in Costa Rica and Panama, P. vitrina occurs on the western side of the Cordillera Central whereas P. cyanomelas is eastern.

Distribution

Colombia (USNM); Panama (AMNH, BMNH, CAS, LACM, NMW, USNM, ZMH); Costa Rica (AMNH, BMNH, LACM, USNM, VOB, ZMH).

Dissected

♂, Panama, Bugabá, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1242); ♂, [no data], Collection Brooklyn Museum, USNM (genitalia slide no. JSM-1249); ♀, “Colombia”, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1248).

PHAEOCHLAENA HÜBNER, 1818

Figures 70Figure 71Figure 72Figure 73Figure 74Figure 75Figure 76Figure 7778; plates 9, 10

Phaeochlaena Hübner, 1818: 18, 32. Type species: Phaeochlaena tendinosa Hübner (1818), by subsequent designation by Butler (1878: 62). P. tendinosa is a junior subjective synonym of Zygaena gyon Fabricius (1787) (see Watson et al., 1980).

Figure 70

Morphology of Phaeochlaena (♂♂). A, head of P. solilucis, lateral view; B, head of P. gyon, lateral view; C, head of P. gyon, frontal view; D, head of P. gyon, posterior view; E, P. gyon tegula; F, P. costaricensis wings; G, P. hazara tegula (A, illustration by S. Goodman; B–G, illustrations by J.S. Miller).

i0003-0090-321-1-1-f070.gif

Figure 71

Scanning electron micrographs of Phaeochlaena solilucis ♂. A, spinules (among scales) at apex of Lp3; B, mesal surface of Lp2 (distal at left), showing scaleless area.

i0003-0090-321-1-1-f071.gif

Figure 72

Male genitalia of Phaeochlaena amazonica (JSM-678). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f072.gif

Figure 73

Genitalia of Phaeochlaena costaricensis, sp. nov. A, ♂ genitalia (JSM-1338); B, ♂ St8; C, ♂ Tg8; D, aedeagus (JSM-511); E, ♀ genitalia (JSM-820); F, ♀ St7 (illustration by J.S. Miller).

i0003-0090-321-1-1-f073.gif

Figure 74

Costa Rica, showing the known distribution of Phaeochlaena costaricensis, sp. nov.

i0003-0090-321-1-1-f074.gif

Figure 75

Genitalia of Phaeochlaena gyon (♂ JSM-1697, ♀ JSM-1698). A, ♂ genitalia; B, ♂ Tg8; C, ♀ genitalia; D, aedeagus; E, ♂ St8.

i0003-0090-321-1-1-f075.gif

Figure 76

Genitalia of Phaeochlaena lampra (♂ JSM-916, ♀ JSM-919). A, ♂ genitalia; B, ♂ Tg8; C, ♀ genitalia; D, aedeagus; E, ♂ St8.

i0003-0090-321-1-1-f076.gif

Figure 77

Genitalia of Phaeochlaena hazara (JSM-216, ♀ JSM-217). A, aedeagus; B, ♂ genitalia; C, ♂ Tg8 (left) and St8 (right); D, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f077.gif

Figure 78

Male genitalia of Phaeochlaena solilucis (JSM-1695). A, genitalia; B, Tg8; C, St8; D, aedeagus.

i0003-0090-321-1-1-f078.gif

Diagnosis

Moths in Phaeochlaena are distinctive (pls. 9, 10); the apparently aposematic wing markings are mostly bright yellow or orange on a brown ground color. The following combination of morphological characters is useful for separating Phaeochlaena from other Dioptinae: Male labial palpi greatly elongate (fig. 70A, B), elbow shaped, extending upward to antennal bases or beyond; female palpi porrect, not reaching antennae; male antennae bipectinate; female antennae ciliate; eyes large, postgena fairly wide (fig. 70A, B); tympanal cavity small and moderately deep, tympanal membrane oriented horizontally; male FW costa often slightly concave; FW veins R1 and Rs1 arising from anterior margin of DC, not stalked with radial sector (fig. 70F); FW discal cell much longer than one-half wing length; FW and HW veins M3 and CuA1 widely separate, arising from DC; male Tg8 extremely large, wide (figs. 72B, 73C, 75B, 76B, 77C, 78B), arching upward, its anterior margin bearing a pair of short apodemes, posterior margin sclerotized, with a deep mesal notch.

Females of Phaeochlaena and Erbessa can sometimes be confused because in both the antennae are ciliate. Certain Erbessa taxa, such as E. salvini (pl. 4) and E. stroudi (pl. 5), show Phaeochlaena-like yellow and dark brown wing patterns. However, members of the two genera can be distinguished because HW veins M3 and CuA1 are separate in Phaeochlaena (fig. 70F), but stalked in Erbessa (fig. 38A, B, E, F). Males of the two genera are easily separated; the antennae are bipectinate and the abdomen is truncate in Phaeochlaena, whereas the antennae are ciliate (figs. 36E, 37B) and the abdomen is elongate in Erbessa. Obviously, the HW venation character, cited above for females, also applies to males.

Redescription

Male (figs. 70, 71). Forewing length  =  13.5–23.5 mm. Head: Labial palpus greatly elongate, folded elbowlike over front, ascending to beyond antennal base; Lp1 relatively nararow; Lp2 greatly elongate, with a slight curve distally; Lp3 tiny, ovoid, apex bearing small spicules; eye large, completely surrounded by scales except a relatively narrow scaleless band below; front clothed with elongate, dorsomedially pointing scales, these meeting along midline; frontal scales elongate dorsally, forming an acute tuft between antennal bases; antenna widely bipectinate almost to apex, distal 15 segments simple; scales of vertex short, pointing anteriorly.

Thorax: Epiphysis elongate, narrow, but not extending beyond tibia, apex acute; tegula moderately large, dorsal arm blunt; metathoracic tympanum small, cavity fairly deep, area below membrane scaleless; tympanal membrane ovoid, oriented almost horizontally, but facing slightly posteriorly.

Forewing (pls. 9, 10): Broad, apex angulate; anterior margin slightly concave near middle; pattern with three yellow areas, a large, triangular one in basal third (showing only ventrally in gyon), a transverse band from subcosta to slightly short of tornus (showing ventrally in gyon), passing across outer margin of DC, and a subapical spot of variable size; veins in dark areas frequently light yellow; Rs1 arising from DC, not stalked with Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; veins M3 and CuA1 widely separate; DC long, stridulatory organ absent.

Hind wing (pls. 9, 10): Broad to relatively broad; central area yellow, outer margin dark brown; M3 and CuA1 widely separate.

Abdomen: Relatively short, truncate at apex; dorsum yellow with a brown stripe along midline and brown stripes along pleuron; venter white to whitish yellow.

Terminalia (figs. 72; 73A–D; 75A, B, D, E; 76A, B, D, E; 77A–C; 78): Tg8 wide and broad, anterior margin with a pair of short, broad apodemes; posterior margin of Tg8 sclerotized, often with a deep, V-shaped or U-shaped mesal excavation, posterolateral angles sometimes with long digitate processes; St8 smaller than Tg8, sometimes highly reduced, anterior margin either simple (most species), or with an extremely wide apodeme, excavated in the middle (P. hazara); posterior margin of St8 sclerotized, with a V-shaped mesal notch; in hazara, pleuron of segment 8 with large, lateral sclerotizations; socii/uncus complex fairly wide at base; uncus tall, expanded near apex, distal margin trilobed with central process digitate; socii long and thin, curving upward; tegumen taller than vinculum, wider near middle; vinculum short, narrow; ventral portion of vinculum forming a large, wide envelope, folded upward over valva bases; lower margin of genitalia with a mesal excavation (except convex in gyon complex); valvae short and broad, mostly membranous, covered with setae on inner surface; BO absent; lower margin of valvae sometimes sclerotized; transtillar arms extremely wide, oriented horizontally, meeting along midline to form a short, anteriorly directed process; aedeagus highly variable: short and wide (P. costaricensis), moderately wide and sinuate (e.g., P. solilucis, P. amazonica), or extremely long and narrow (P. gyon, P. lampra); vesica variable in size, cornuti often small and thornlike, in P. costaricensis extremely large and robust.

Female. Forewing length  =  14.5–27.0 mm. Head: Labial palpus shorter than in male, extending upward to well short of antennal base; antenna ciliate.

Thorax: Similar to male.

Forewing: Broader than male, dark ground color and yellow-orange markings less intense, maculations slightly larger.

Hind wing: Differ from male as in FW; frenulum comprising 8–12 bristles.

Abdomen: Short and broad, truncate distally.

Terminalia (figs. 73E, F; 75C; 76C; 77D): Tg7 extremely wide, anterior portion of tergum often less sclerotized than posterior portion; anterior margin of T7 simple, posterior margin either simple, or with a U-shaped mesal excavation; St7 not as wide as Tg7, anterior margin simple, posterior margin lightly sclerotized, with a U-shaped or V-shaped mesal excavation; St7 sometimes with large, lateral lobes (e.g., P. gyon); Tg8 short and wide, posterior margin minutely spiculate, with a mesal notch; anterior apophyses variable in length, from short to moderately long; A8 pleuron mostly membranous, with a thin, straplike sclerite along anterior margin; PA moderate in size, posterior margins straight; PP bent slightly downward, either long and narrow, or short and thick; PVP large and wide, lightly sclerotized, surface often smooth; ostium ovoid or extremely narrow, often dorsoventrally compressed; DB sclerotized, usually short, but sometimes moderately long (e.g., P. hazara) or extremely long (e.g., P. lampra); DS attached at junction of DB and CB on right side; CB ovoid or round, in some species broadly sclerotized near base; signum small and ovoid with internal surface finely spiculate, or signum absent.

Biology

The earliest host records for the Dioptinae date to Mabilde (1896), and somewhat later, to Bastelberger (1908), both of whom described the immature stages of Phaeochlaena gyon. The caterpillars purportedly feed on Aristolochia, commonly known as Pipevine (Aristolochiaceae). This plant genus, well known as the host of Battus butterflies (Papilionidae), is famous for its toxicity (e.g., Miller and Feeny, 1989). Unfortunately, there has been no subsequent documentation of an association between P. gyon and Aristolochia. The only modern host record for Phaeochlaena comes from Belo Horizonte, Brazil, where Doug Yanega (April 1997) reared larvae of P. lampra on Solanum (Solanaceae). If Aristolochia is truly the host plant for P. gyon, then an association with Solanum for its close relative, P. lampra, would represent a dramatic shift.

At that same Brazilian site, Yanega collected adult males of P. lampra in large numbers from the carcass of a cow. Presumably, the moths were imbibing essential nutrients from the putrefying body. Although other dioptines, such as Euchontha frigida (Walker) and Pareuchontha olibra, sp. nov., have been observed “puddling”, presumably to take up sodium, this is the first report of a dioptine visiting a dead animal.

Phaeochlaena adults are usually diurnal. According to Biezanko (1962a), adults of P. lampra in the vicinity of Pelotas, Brazil, were commonly observed flying during the day, visiting flowers of Acacia and Mimosa (Leguminoseae). This same species was also attracted to lights in southeastern Brazil during the months of April, May, and July (Biezanko, 1962b). Based on museum data, other Phaeochlaena species have, at least on occasion, been collected at lights.

I have watched adults of P. costarecensis in the Osa Peninsula (Costa Rica) during midday, flying in forest light gaps approximately 3–5 meters above the ground. Similarly, I have collected P. solilucis females near the Napo River (Ecuador), flying in the dappled sunlight of the forest understory.

To my knowledge, there are no photographs or alcohol-preserved specimens of Phaeochlaena immatures in collections. The only known examples consist of blown larvae, as well as pupal exuvia, both for P. gyon (BMNH, NMW). These show that the caterpillar bears long stemapods on A8, and that the pupa has a small, truncate horn on its head. This horn is perhaps homologous with the head processes of Erbessa (pls. 36H, 37C) and Scotura pupae (fig. 360A).

Discussion

Phaeochlaena is unusual for the Dioptinae in claiming a preponderance of species group names; although only seven species are currently recognized (appendix 2), 13 additional names are listed as synonyms, mostly under P. gyon and P. solilucis. This phenomenon can perhaps be attributed to the showy wing patterns of Phaeochlaena species. As has occurred in many butterfly taxa, early authors seem to have given each wing pattern variant a different name.

Determining which of these is valid and which should remain in synonymy is beyond the scope of this project. For example, my attempts to provide definitive identifications for P. solilucis and P. bicolor have met with frustration. Between the two, there are nine associated species group names. Neither wing pattern, which is highly variable, nor genital morphology, where differences are subtle and seemingly inconsistent, provides help in identification. For these taxa, my classification simply defers to Bryk (1930).

The six names currently listed as synonyms of P. gyon provide an equally imposing morass. Phaeochlaena gyon, as identified in collections, undoubtedly comprises a group of cryptic species. For some of these, available names exist, but for others, new names will be needed. For example, P. gyon purportedly occurs in Central America, from Panama north to southeastern Mexico (Bryk, 1930). Its type locality is Cayenne, French Guiana. My dissections demonstrate that Central American material represents a species, distinct from gyon, for which no existing name seems to be available. The genus Phaeochlaena would benefit from a species-level revision; I estimate that the resulting list of valid species will be double the number that appears in this classification.

It was not until near the turn of the 20th century that lepidopterists began describing Dioptinae in earnest. However, in 1787 Fabricius described two species—Phaeochlaena gyon and Josia megaera. “Phaeochlaena” seems to have been an extremely difficult word for early lepidopterists to spell, as attested by the eight different misspellings listed in the generic synonymy of Bryk (1930). Hübner (1818) had a particularly difficult time; even though it was he who described the genus, Hübner misspelled Phaeochlaena three different ways in his original publication.

Phylogenetic analyses based on adult morphology suggest that Phaeochlaena arises at the base of Clade 6 (fig. 7), which includes Pikroprion, Argentala, and Polypoetes. Bremer support for Clade 6 is strong (fig. 2). The list of synapomorphies (appendix 4) includes the presence of elongate male labial palpi, and a jawlike male eighth abdominal segment. However, as is noted in the Discussion (Future Research: The Morphology of Immatures), certain larval and pupal traits suggest an affinity between Phaeochlaena and Clade 1 (fig. 7), which includes Scotura, Oricia, and Erbessa. For example, in Clade 1 taxa for which the pupae are known, these exhibit unusual processes on the head (e.g., fig. 360A). The pupa of Phaeochlaena gyon also possesses a projection on the head, but this trait does not occur in Polypoetes (pl. 37J–M). Future research on the Dioptinae should attempt to solidify relationships between the genera. The phylogenetic position of Phaeochlaena will be an important focus of such research.

The monophyly of Phaeochlaena itself is extremely well supported. Based on my species sample, it shows a Bremer support value of 22 (fig. 2). Three synapomorphies from male genitalia deserve mention—St8 is short (e.g., figs. 73B, 78C); the uncus is broad and hoodlike, trifid at its apex (e.g., figs. 75A, 76A); and the valvae are short and lobate (e.g., fig. 73A), with only a remnant of the BO along their ventral margins.

KEY TO THE SPECIES OF PHAEOCHLAENA

1. Forewing mostly orange-yellow to lemon yellow, or mostly olive brown to dark brown (pls. 9, 10); HW central area orange-yellow to lemon yellow; wings without complex dark brown markings, FW without a U-shaped maculation; FW length  =  13.5–22.0 mm2

Wings showing a “tiger stripe” pattern; FW mostly ochreous orange (pl. 9); HW central area ochreous orange; orange areas of FW and HW overlaid with complex blackish brown markings, FW with a U-shaped, dark brown maculation near distal margin of DC; FW length  =  22.5–27.0 mm (French Guiana, E Ecuador S to Peru, W Brazil)hazara (Butler)

2. Ventral surface of FW with three orange-yellow markings: a large basal triangle, a transverse band near distal margin of DC, and an ovoid subapical spot3

Ventral surface of FW with two orange-yellow markings (pl. 9): a basal triangle and a large, transverse ovoid spot immediately beyond DC; FW length  =  13.5–16.5 mm (Brazil, Bolivia, Venezuela)amazonica Druce

3. Dorsal surface of FW mostly olive brown to dark brown (pl. 9), with a small, rectangular, orange-yellow subcostal spot approximately halfway out, and a tiny subapical spot between Rs4 and M1; orange-yellow central area of HW narrow; FW length  =  14.0–17.5 mm4

Dorsal surface of FW mostly orange-yellow to lemon yellow (pls. 9, 10), with a large basal triangle and a large, transverse-ovoid subapical spot between base of Rs2–Rs4 and M2, usually with a large transverse band near distal margin of DC; orange-yellow area of HW broad; FW length  =  15.0–21.5 mm5

4. Forewing ground color olive brown to light chocolate brown, HW ground color dark brown; subcostal FW spot light orange-yellow, subapical spot semihyaline, whitish; frontal scales creamy yellow; apex of male valva quadrate (fig. 75A); aedeagus gently curved (fig. 75D), denticulate near midpoint; lobes of female Tg8 (fig. 75C) small (French Guiana W to Colombia, N to Mexico, S to Bolivia)gyon (Fabricius)

FW ground color dark chocolate brown, HW ground color blackish brown; subcostal FW spot rich orange-yellow, subapical spot orange-yellow; frontal scales orange-yellow; apex of male valva tapered (fig. 76A); aedeagus strongly curved (fig. 76D), smooth near midpoint; lobes of female Tg8(fig. 76C) large (SE Brazil S to Uruguay, Argentina)lampra Prout

5. Yellow-orange anal margin of HW (dorsal surface) with a diffuse patch of blackish brown scales (pl. 9), located on vein 2A approximately two-thirds from base; apex of male aedeagus strongly dentate ventrally (fig. 73D); vesica bearing huge, thornlike cornuti (SW Costa Rica S to NW Panama)costaricensis, sp. nov.

Anal margin of HW uniformly orange-yellow, without a patch of blackish brown scales (pls. 9, 10); apex of male aedeagus finely spiculate (fig. 78D); vesica bearing tiny cornuti, or none (Upper Amazon Basin)6

6. Forewing completely yellow to yellow-orange in basal two-thirds (pl. 10), with a subapical spot; FW without a blackish brown transverse band, this represented only by a small tooth arising from costa one-third out; FW anal margin yellow-orange (French Guiana W to Colombia, S to Ecuador)bicolor (Möschler)

Yellow-orange portion of FW divided into three parts (pl. 9)—a basal triangle, a transverse band of varying width crossing distal margin of DC, and a transverse-ovoid subapical spot; FW anal margin blackish brown or yellow-orange (Colombia S to Argentina, W Brazil)solilucis Butler.

SPECIES INCLUDED AND MATERIAL EXAMINED

Phaeochlaena amazonica Druce

Figure 72; plate 9

Phaeochlaena amazonica Druce, 1899: 294.

Type Locality

Brazil, Santarem, “Amazons”.

Type

Syntype ♂, leg. Leech, 10.84 (BMNH).

Campylona brunnea Warren, 1904: 500.

Type Locality

Venezuela, Maripa, Caura River.

Type

Holotype ♀, leg. Klages, Jun 1901 (BMNH).

Discussion

Phaeochlaena amazonica, the smallest species in the genus (pl. 9), is instantly recognizable by having only two yellow FW maculations; all other Phaeochlaena species show three, although in gyon and lampra these are visible on the ventral surface only. Furthermore, the FW ground color of P. amazonica is light brown, contrasting with the dark brown marginal band of the HW. In most Phaeochlaena species the FW and HW ground colors are similar in tone.

A single Bolivian specimen of P. amazonica is known (AMNH), but most material was collected in Amazonian Brazil. Although I did not confirm its synonymy by dissection, wing pattern suggests that the female type of brunnea is conspecific with amazonica. This was the position taken by Hering (1925) and Bryk (1930), but a note of caution should be added. The type of brunnea was collected at Maripa, Venezuela, on the Río Caura a short distance from the Orinoco. The type of amazonica, on the other hand, is from Santarém on the Amazon. When moths are collected from two such widely separate drainage systems, it often portends species-level differences.

Distribution

Bolivia (AMNH); Brazil (AMNH, BMNH, LACM, MNHN, MPM, NMW, VOB, ZMH); Venezuela (BMNH).

Dissected

♂, Brazil, Manaus, Rio Negro, MNHN (genitalia slide JSM-678); ♂, Brazil, MA, Acailandia, 150 m, 19–27 Nov 1980, leg. V.O Becker and G.S. Dubois, VOB (genitalia slide JSM-914); ♀, Brazil, Rondônia, Fazenda Rancho Grande, 62 km S Ariquemes, linea C-20, 7 km E B-65, 10°32′S, 62°48′W, 165 m, 13 Nov 1991, leg. S. Borkin, R.J. Sullivan, along C-20 and Hill Forest trails NW of farm buildings, MPM (genitalia slide JSM-679).

Phaeochlaena bicolor (Möschler)

Plate 10

Campylona bicolor Möschler, 1877: 659, pl. 9, fig. 27.

Type Locality

Suriname.

Type

Holotype ♂, “Bgth.”, 1873 (ZMH).

Campylona costidentata Dognin, 1908: 264.

Type Locality

French Guiana, Saint-Laurent du Maroni.

Type

Holotype ♀ (USNM type no. 30974).

Discussion

In this paper, I apply a somewhat restricted species concept to P. bicolor. In Möschler's ZMH type, there is no blackish-brown transverse FW band crossing the DC, as occurs in P. solilucis (pl. 9). Instead, the FW band of P. bicolor is represented by a small tooth, pointing inward from the dark costal edge. Precisely this same pattern is found in the female type of costidentata (USNM), a synonym of bicolor (Hering, 1925; Bryk, 1930). The specimen of P. bicolor figured here (pl. 10) is of an intermediate pattern, characterized by a thin, tapered brown band crossing the wing.

Phaeochlaena material showing these pattern elements, quite rare in collections, occurs from French Guiana west to Amazonian Colombia, and south to Napo, Ecuador. However, I am not satisfied with this hypothesis. In Ecuador, specimens can be found with (solilucis-type) and without (bicolor-type) transverse FW bands, and these are not separable by genital characters. Furthermore, an extensive genital survey of so-called bicolor and solilucis examples, chosen from various South American locations, revealed no easy way to separate these taxa.

An alternative explanation is that bicolor and solilucis together represent a single species, highly variable in wing pattern. If this is ultimately proven to be true, then bicolor (Möschler, 1877), rather than solilucis (Butler, 1878), becomes the senior name. Detailed examination of species concepts within Phaeochlaena will be a challenging project—one I leave for future research.

Distribution

Suriname (ZMH); French Guiana (BHC, MNHN, USNM); Brazil (AMNH, USNM); Colombia (AMNH); Ecuador (AMNH, PTC, USNM).

Dissected

♂, French Guiana, St. Laurent du Maroni, Dognin Collection, USNM (genitalia slide no. JSM-1701); ♂, Ecuador, Morona-Santiago, Rte. Limon-Mendez, km 17, 980 m, 12–13 Feb 1983, leg. C. Lemaire and P. Thiaucourt, PTC (genitalia slide no. JSM-680); ♀ type of costidentata Dognin, French Guiana, St. Laurent du Maroni, Dognin Collection, USNM (genitalia slide no. JSM-1702); ♀, Colombia, Putumayo, Caucaya, 28 Nov 1948, leg. Richter, AMNH (genitalia slide no. JSM-681).

Phaeochlaena costaricensis, new species

Figures 70F, 73, 74; plate 9 [EX]

Diagnosis

The most reliable wing-pattern character for separating P. costaricensis from other Phaeochlaena species is the presence in costaricensis of a small, diffuse patch of blackish-brown scales in the orange-yellow area of the HW, located along vein 2A near the tornus (pl. 9). In most specimens this HW spot is conspicuous, but in others, it is represented by a sparse dusting of blackish-brown scales.

The species with which P. costaricensis could most easily be confused is P. solilucis (pl. 9), from the Upper Amazon of South America. In addition to the HW spot, a way to separate them is by head coloring: in P. costaricensis, the front is entirely light yellow to lemon yellow, whereas in P. solilucis the front is gray-brown along its midline, with cream-colored lateral bands. Furthermore, in P. costaricensis, Lp2 is almost entirely yellow on its lateral surface, with a short blackish-brown stripe near the apex, whereas in P. solilucis, Lp2 shows a broad, blackish-brown lateral stripe for almost its entire length. In general, the Central American taxon tends to have wings more orange in color, whereas those of the South American species are usually lemon yellow.

The male genitalia of P. costaricensis and P. solilucis show dramatic differences. The aedeagus of P. costaricensis is coarsely spinose at the apex (fig. 73D), and the vesica bears huge, thornlike cornuti. In contrast, the aedeagus of P. solilucis is finely dentate at the apex (fig. 78D), and the vesica bears tiny cornuti. Male St8 shows differences as well; the posterior margin is lobate in P. costaricensis (fig. 73B), but bears a U-shaped mesal excavation in P. solilucis (fig. 78C).

Description

Male (pl. 9). Forewing length  =  15.0–18.4 mm. Head: Labial palpus elongate, folded elbowlike over face, extending beyond antennal base almost to vertex; Lp1 orange, closely scaled; Lp2 yellow-orange, with a thin, dark brown lateral line distally, and a tuft of long, creamy yellow scales at apex; Lp3 dark brown, apex with sclerotized spinules; front with upwardly pointing yellow-orange to orange scales, reaching beyond antennal bases; occiput rich, orange-yellow; vertex with long, dark brown scales, and lateral patches of yellow-orange scales behind antennal bases, a few yellow scales on posterior margin; antenna widely bipectinate; scape dark brown above, yellow to creamy yellow below; antennal shaft dark brown above.

Thorax: Procoxa yellow-orange on ventral surface, creamy white on inner, dark brown laterally; rest of prothoracic legs brown on outer surfaces, creamy on inner ones; pleuron of meso- and metathorax cream, yellow-orange below wings; patagium orange-yellow, with dark brown lateral patches; prothoracic midline dark brown above; tegula rich orange at base, central area yellow-orange with cream colored scales near apex; tegula fringed with long, dark brown scales; dorsum dark chocolate brown, with wide, orange-yellow stripes on either side of midline; tympanal membrane small, ovoid, facing ventrally.

Forewing (fig. 70F): (Dorsal) Dark blackish brown, with three orange-yellow maculations: 1) a triangle from base to one-third out on wing, anterior margin of triangle touching radius, posterior margin touching 1A+2A; 2) a transverse band extending from costa to immediately beyond CuA2, passing across distal margin of DC; 3) an ovoid subapical spot, extending from base of Rs2+Rs3 to slightly beyond M2. (Ventral) Color and pattern almost identical with upper surface, maculations slightly larger.

Hind wing (fig. 70F): (Dorsal) Central area orange-yellow, with a blackish-brown marginal band extending from apex to tornus; band slightly narrower at point where M2 passes to margin; orange central area with a short, black basal dash along cubitus; a small, diffuse patch of blackish-brown scales in orange area on vein 2A, located near tornus, basal to marginal band; anterior margin whitish; anal margin with hairlike, light orange scales. (Ventral) Similar to dorsal surface, but without basal dash or diffuse spot; anterior margin completely orange-yellow.

Abdomen: Moderately long, bluntly tapered at apex; orange-yellow above, with dark brown lateral stripes and a dark brown stripe along midline; venter light yellow, with cream-colored scales along posterior margin of each sternum; A8 dark brown above, cream colored below.

Terminalia (figs. 73A–D): Tg8 wide and broad, posterolateral angles with long, delicate, digitate processes pointing distally; posterior margin of Tg8 with a deep, V-shaped mesal excavation, anterior margin with a pair of short, broad apodemes; St8 extremely small, triangular, narrowed distally; posterior margin of St8 with broad, sclerotized processes at lateral angles, anterior margin simple; socii/uncus complex somewhat broad; uncus moderately wide, trifurcate at apex, mesal process compressed, longer than lateral processes, a ventral ridge below; socii long and thin, bent near apex; tegumen taller than vinculum, gradually wider at halfway point; vinculum short, narrow, ventrally forming a large envelope, folded upward over valva bases; ventral margin of genitalia horizontal, with a small, mesal notch; valva extremely short and broad, mostly membranous, covered with long setae on inner surface; valva quadrate at outer margin, a brush of stouter setae along margin below; BO completely absent, ventral margin of valva sclerotized; aedeagus wide, relatively short, apex scoop shaped, coarsely spinose below; vesica large, quadrate, bearing approximately 10, extremely robust, spinelike cornuti distally.

Female. Forewing length  =  18.0–21.5 mm. Wing pattern and body characters similar to male, with the following differences: labial palpus shorter, apex falling well short of antennal base; FW broader; FW ground color lighter, brownish black; maculations lighter in color, lemon yellow to light orange; transverse band wider and slightly longer; subapical spot larger; abdomen broad, truncate at apex.

Terminalia (figs. 73E, F): Tg7 wide, slightly trapezoidal, anterior margin wider than posterior margin, both margins simple; St7 wide, with a wide, deep U-shaped mesal excavation on posterior margin, anterior margin simple; posterior margin of Tg8 minutely spiculate, bilobed, with a small mesal notch; AA relatively short, slightly upturned; PA tall, posterior margins straight; PP long and thin, tapered anteriorly, bent downward; PVP large, smooth, ovoid; ostium wide, dorsoventrally compressed; DB extremely short and wide, sclerotized; DS attached at junction of DB and CB on right side; CB ovoid, heavily sclerotized in anterodorsal half, posterior half with transverse wrinkles, membrane thickened, signum absent.

Etymology

Even though this species occurs in both Costa Rica and Panama, I chose the former country for its epithet. My reason for doing so is that material from Costa Rica, the bulk of which was kindly loaned to me by the Instituto Nacional de Biodiversidad in Heredia, first alerted me to the existence of an undescribed Phaeochlaena species. It was subsequently discovered that the moth also occurs in Chiriquí.

Distribution

Phaeochlaena costaricensis occurs in a relatively small region of Central America (fig. 74). In Costa Rica, the species is known exclusively from lowland forests (sea level to 200 meters) of the Osa Peninsula, on the Pacific coast in the southwestern part of the country near its border with Panama. Phaeochlaena costaricensis also lives in adjoining Chiriquí Province of Panama, at altitudes as high as 500 meters (Druce, 1891). Its known distribution thus spans a distance of less than 150 km.

Discussion

Phaeochlaena costaricensis is a classic cryptic species. For well over a hundred years, P. solilucis had been thought to occur in both Central and South America. Druce (1891: 1), in the Biologia Centrali-Americana, first noted the existence of so-called P. solilucis in Central America, stating that the Panamanian specimens figured (pl. 41, figs. 9 and 10) “agree well with the Amazonian type”. Oddly, the male and female moths in Druce's color plate lack the characteristic HW spot that distinguishes P. costaricensis from P. solilucis. Hering later used a Panamanian male to illustrate “P. solilucis” (Hering, 1925: fig. 68a), but in that case the HW spot is clearly visible. It was not until I made genital dissections comparing Central and South American examples of so-called P. solilucis that the existence of an undescribed taxon became clear. Even though four synonyms of P. solilucis exist in the literature (Bryk, 1930), all apply to South American material. Having verified that a new name is needed, I here describe P. costaricensis.

Holotype

Male. Costa Rica: Puntarenas: Peninsula de Osa, Rancho Quemado, 200 m, 21 Mar–7 Apr 1992, L-S 292500, 511000, INBIO CRI000 393618. The type is deposited in the INBio Collection, Heredia, Costa Rica.

Paratypes

Costa Rica: Puntarenas: Peninsula de Osa, 1♂, 6.5 km SW Rincón, 200 ft, 25 Mar 1991, leg. J.S. Miller, day, near stream (AMNH; genitalia slide no. JSM-511); 1♀, Río Agujas, 0 ft, Jan 1993, leg. S. Fratello (AMNH); 1♀, 1.8 mi. W of Rincón, 11 Feb 1971, leg. J.F. Donahue & C.L. Hogue, diurnal—flushed in jungle (LACM); 1♀, Golfito, 21 Aug 1957, leg. A. Menke (LACM); 1♂, Estación Sirena, Corcovado N. P., 1–100 m, Feb 1990, leg. G. Fonseca, 270500-508300 (INBio; preparación B. Espinoza); 2♂♂, Estación Sirena, Corcovado N.P., 1–100 m, Feb 1995, leg. G. Fonseca, L S 270500 508300 #4369 (INBio); 1♀, Golfito, P.N. Piedras Blancas, Estación El Bonito, 100 m, 17–18 Feb 2001, leg. M. Moraga, red mariposera, L_S_548350_292700 #61782 (INBio; genitalia slide JSM-1340); 1♂, Rancho Quemado, A.C. Osa, 200 m, 6–12 Feb 1994, leg. A.L. Marín, L S 292500_511000, #2612 (INBio); 1♀, Rancho Quemado, 200 m, Aug 1991, leg. F. Quesada (INBio).

Other Specimens Examined

Panama: 1♂, Chiriquí, leg. H. Rolle, “Berlin S. W. 11”, Wm. Schaus Collection (USNM; genitalia slide no. JSM-1338, wing slide no. JSM-1703); 1♂, Chiriquí, leg. H. Rolle (BMNH); 1♀, Chiriquí (BMNH); 2♂♂, 2♀♀, Chiriquí, leg. Ribbe (ZMH); 1♀, Chiriquí (AMNH; genitalia slide no. JSM-508); 2♂♂, 2♀♀, Chiriquí (CAS; female genitalia slide no. JSM-820).

Dissected

2♂♂, 3♀♀.

Phaeochlaena gyon (Fabricius)

Figures 70B–D, 70E, 75; plate 9 [EX]

Zygaena gyon Fabricius, 1787: 105.

Type Locality

French Guiana, Cayenne.

Type

Holotype ♂ (ZMC).

Phaeochlaena dorsistriga Strand, 1920: 135.

Type Locality

Not stated.

Type

Not seen.

Phaeochlaena fucata Prout, 1918: 399.

Type Locality

Brazil, Prov. Goyaz, Rio Uraguaya.

Type

Syntype ♂, leg. G.A. Baer, Jun–Jul 1906 (BMNH).

Phaeochlaena obtecta Möschler, 1877: 657, pl. 9, fig. 26.

Type Locality

Suriname (interior), 1876.

Type

Holotype ♀ (ZMH).

Phaeochlaena ochrophanes Prout, 1918: 398.

Type Locality

Brazil (“Amazons?”).

Type

Holotype ♂ (BMNH).

Actea remota Walker, 1856: 1649.

Type Locality

“West Coast of America”.

Type

Not seen.

Phaeochlaena tendinosa Hübner, 1818: 18, figs. 89, 90.

Type Locality

Brazil.

Type

Not seen.

Discussion

Phaeochlaena gyon, a common species in museum collections, has been reported to occur from Mexico south to Argentina (Bryk, 1930). After dissecting examples of so-called P. gyon representing eight different Central and South American countries, I conclude that several species are involved. However, a complete revision of Phaeochlaena would be required to fully resolve the taxonomy of P. gyon. In lieu of such research, I here make a single change from the classification of Bryk (1930) by raising the name lampra Prout, formerly a synonym of gyon, to species status. My reasons are given below.

First, my dissections show that males of P. gyon collected at or near its type locality, Cayenne, French Guiana, possess a quadrate valva apex (fig. 75A). Furthermore, the long, thin aedeagus is gently curved and bears tiny denticles near its midpoint (fig. 75D). In males from southeastern Brazil, on the other hand, the valva is tapered at its apex (fig. 76A), and the aedeagus is strongly curved, but smooth at its midpoint (fig. 76D). Wing pattern differences also exist. For example, specimens with a quadrate valva have a whitish to light yellow, often translucent, subapical FW spot, whereas narrow-valva specimens show a rich, orange-yellow subapical spot (see pl. 9).

Prout (1918) described four aberrations and subspecies of gyon from Brazil, delimited by differences in wing pattern. I have not dissected the types of those, but using Prout's descriptions (1918: 398–399), the name lampra (type locality: Castro, Paraná) should be applied to material with a yellow subapical FW spot (and by implication with a narrow valva and strongly curved aedeagus). Phaeochlaena lampra occurs from southeastern Brazil south to Uruguay, Paraguay, and northeastern Argentina.

A major problem remains unresolved: What is the distribution of Phaeochlaena gyon? Again referring to my dissections, it appears that P. gyon is endemic to the Guyana Shield and points west, at least as far as the Upper Amazon Basin of Colombia and Ecuador. The species' range south is unclear. What is clear, however, is that material from Mexico and Honduras shows genital morphology distinct from gyon. An undescribed Central American species thus occurs, perhaps being distributed as far south as Panama. I leave description of that taxon to future research. Its dissections (listed below) are referred to P. gyon. This Central American taxon appears to be much less common than its South American relatives (Druce, 1891).

Whether Prout's two remaining Brazilian subspecies names are in fact valid species must await dissections of the types—the yellow areas of the wings are lighter yellow in ochrophanes than in most examples of gyon, whereas in fucata these areas are a rich orange color, especially in the HW. In the meantime, I retain these, along with tendinosa Hübner (type locality: “Brazil”) and remota Walker (“West Coast of America”), as synonyms of P. gyon following previous authors. Strand's (1920) name dorsistriga was proposed without giving a type locality. Hering (1925) defined dorsistriga as a phenotype of gyon in which the FW bears a single subapical spot and broad light stripe on the anal margin. I have seen no material matching that description.

A single AMNH female from Río Carapo (Bolívar, Venezuela) shows a FW with a yellow basal triangle and a wide yellow transverse band. The wing pattern is unlike that of P. gyon, and the female genitalia of this moth (JSM-925) establish it as an undescribed close relative. No other specimens are known.

According to Zimsen (1964), the Fabricius type of gyon is in the holdings of the Zoologisk Museum, Copenhagen.

Distribution

Mexico (ARTC, BMNH, CAS, CMNH, FNHM, LACM, USNM); Guatemala (AMNH, BMNH, CAS, CMNH, USNM); Honduras (AMNH, BMNH, CAS, CMNH, OUMNH); Nicaragua (AMNH, CMNH); Costa Rica (AMNH, CAS, INBio); Panama (AMNH, BMNH, CAS, OUMNH, USNM); Colombia (BMNH, CUIC, LACM, OUMNH); Ecuador (LACM); Peru (AMNH, BMNH, CMNH, LACM, NMW, MUSM,); Bolivia (CMNH, CUIC); Venezuela (AMNH, CMNH, CUIC); Suriname (AMNH); Guyana (AMNH); French Guiana (BHC, BMNH, USNM, OUMNH).

Dissected

♂, French Guiana, Piste Crique Trésor et Crique Favard, 2 Nov 1988, leg. B. Hermier, BHC (genitalia slide no. JSM-1694); ♂, French Guiana, St. Laurent du Maroni, Dognin Collection, USNM (genitalia slide no. JSM-1700); ♂, Mexico, Veracruz, Dos Amates, Nov 1970, leg. Peter Hubbell, LACM (genitalia slide no. JSM-1696); ♂, Tela, Honduras, 1929, leg. J.P. Falconer, AMNH (genitalia slide JSM-790); ♂, Costa Rica, Puntarenas, Gulf of Nicoya, 12 Feb 1938, AMNH (genitalia slide no. JSM-791); ♂, Colombia, Cauca Valley, leg. F.C. Nicholas, AMNH (genitalia slide JSM-915); ♂, Ecuador, Napo, Yasuni Research Stn./Natl. Pk., 0.675°S, 76.398°W, 275 m, 5–17 Sep 1999, leg. R.H. Leuschner, LACM (genitalia slide no. JSM-1697); ♀, Suriname, Moengo, 20 Jan 1962, leg. B. Heineman, AMNH (genitalia slide JSM-128); ♀, Suriname, Moengo, 20 Jan 1962, leg. B. Heineman, AMNH (genitalia slide no. JSM-1698); ♀, Honduras, Río Tamash, leg. Parish, CMNH (genitalia slide JSM-793).

Phaeochlaena hazara (Butler)

Figure 70G, 77; plate 9 [EX]

Pericopis hazara Butler, 1871: 287–288.

Type Locality

Brazil, Villa Nova [♂]; Ecuador [♀].

Type

Not seen.

Phaeochlaena heliconides Prout, 1918: 399.

Type Locality

Peru, Pachitea.

Type

Holotype ♀ (BMNH).

Discussion

At first glance, P. hazara is very different from other Phaeochlaena species. Its wing pattern is unique for the Dioptinae. However, morphological characters firmly place hazara in Phaeochlaena. This species and Erbessa citrina (pl. 7) belong in what lepidopterists have characterized as the “tiger stripe” mimicry complex (DeVries, 1997), a famous assemblage of neotropical butterflies and moths. Butler (1871), in his original description of P. hazara, pointed out its resemblance to the ithomiine butterfly Ithomia iphianassa Doubleday and Hewitson. Hering (1925) later noted that P. hazara is an excellent mimic of the butterfly Stalachtis calliope Linnaeus (Riodinidae). It also mimics Chetone histrio Boisduval, an arctiid in the Pericopinae. Phaeochlaena hazara and E. citrina are widely distributed throughout Amazonian South America.

Prout (1918) described heliconides as a “form” of P. hazara. The subapical FW band is yellow in P. hazara, but dark blackish brown, matching the FW ground color, in P. heliconides. The HW is more broadly orange in heliconides. My dissections confirm that the two are color forms of a single species; their female genitalia are identical. Both color forms have been collected along the same trail at Tambopata, Peru (MUSM).

I was unable to locate Butler's two syntypes of hazara—both originally from the Saunders Collection—supposedly at the BMNH. In the original description he gave the localities as Villa Nova, Brazil, and “Ecuador”.

Distribution

Brazil (AMNH, BMNH, LACM, NMW, USNM, ZMH); Ecuador (BMNH, USNM, ZMH); Peru (AMNH, MUSM, BMNH, ZMH); French Guiana (BHC, BMNH).

Dissected

♂, Peru, Amazonas, Pebas, Oct 1880, leg. M. de Mathan, BMNH (genitalia slide no. JSM-216); ♀, Peru, Amazonas, Cavalle Cocho, May–Jul 1884, leg. M. de Mathan, BMNH (genitalia slide no. JSM-217); ♀, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′W, 08 Dec 1996, leg. J. Grados, day coll., MUSM (genitalia slide no. JSM-920).

Phaeochlaena lampra Prout, revised status

Figure 76; plate 9

Phaeochlaena lampra Prout, 1918: 398.

Type Locality

Brazil, Paraná, Castro.

Type

Holotype ♂, leg. E.D. Jones (BMNH).

Discussion

Previous authors have treated lampra as a synonym of P. gyon (Hering, 1925; Bryk, 1930); it was initially described as a gyon subspecies (Prout, 1918). However, my discussion for P. gyon (above) provides the rationale for recognizing two species. Means for identifying P. lampra are listed in the Phaeochlaena species key, and are alluded to in the gyon discussion. Most importantly, the male valva apex in P. lampra is tapered (fig. 76A), not quadrate, and the subapical FW spot is orange-yellow rather than whitish, as in gyon (pl. 9). Phaeochlaena lampra, quite common in museum collections, occurs from southeastern Brazil south to Argentina. Its larvae feed on Solanum (table 4), a common host plant of butterflies in the Ithomiinae (Ackery, 1988), but novel for the Dioptinae. Based on its locality (Rio Grande do Sul), the moth whose larva and pupa is figured in Mabilde (1896), and whose host is listed as Aristolochia and Araujia by Biezanko (1962a), is in all likelihood Phaeochlaena lampra; these authors identified it as either P. gyon (Biezanko, 1962a) or P. tendinosa (Mabilde, 1896). It will be interesting to establish the host of true P. gyon, from northern South America.

Distribution

Brazil (AMNH, BMNH, CMNH, CUIC, MCZ, NMW, USNM); Paraguay (AMNH, BMNH, OUMNH, USNM); Uruguay (USNM); Argentina (AMNH, BMNH, FML, ZMC).

Dissected

♂, Brazil, Minas Gerais, Belo Horizonte, UFMG, Es. Ecologica, 25 Mar 1997, leg. D. Yanega, AMNH (genitalia slide no. JSM-916); ♂, Brazil, Suntos, AMNH (genitalia slide no. JSM-127); ♀, Brazil, Minas Gerais, Belo Horizonte, UFMG, Es. Ecologica, 25 Mar 1997, leg. D. Yanega, AMNH (genitalia slide no. JSM-919).

Phaeochlaena solilucis Butler

Figures 70A, 78; plate 9 [EX]

Phaeochlaena solilucis Butler, 1878: 62.

Type Locality

Brazil, Barreiras das Araras, Rio Solimões.

Type

Syntype ♀, 15 Nov 1874 (BMNH).

Campylona aurata Warren, 1905: 312.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♀ (BMNH).

Campylona contingens Warren, 1904: 14.

Type Locality

Ecuador, Coca, 260 m.

Type

Holotype ♀, leg. Haensch, 30 Mar 1900 (BMNH).

Phaeochlaena perintrusa Prout, 1918: 399.

Type Locality

Brazil, Rio Madeira.

Type

Holotype ♂ (BMNH).

Erylices subintrusa Warren, 1897: 421.

Type Locality

Brazil, between Manaos and Rio Jutahi.

Type

Holotype ♀, leg. M. Stuart (BMNH).

Discussion

Establishing the identity of Phaeochlaena solilucis has proved to be an extremely difficult problem, as attested to by the relatively large number of genitalia dissections listed below. After many hours spent on the issue, my understanding has barely advanced. Wing-pattern variation hints at the existence of more than one species. Four additional species group names have historically been associated with P. solilucis, each describing a particular pattern variant. However, my dissections across a wide spectrum of pattern phenotypes revealed no genital differences. In summary, I conclude that P. solilucis is a widespread species showing extensive wing-pattern variation.

To illustrate such problems, the type of P. solilucis has a prominent, dark brown transverse band in the FW as well as a blackish brown FW anal margin (pl. 9). At first, I suspected that material with a narrow, almost obsolete, cross band was a distinct species, to which the name contingens Warren could be applied. However, the genitalia of these phenotypes show no consistent differences. As another example, there are specimens identical to the solilucis type, except that the anal margin of the FW is yellow (pl. 9) instead of blackish brown. Again, these cannot be separated by genitalia. Furthermore, both phenotypes co-exist at certain localities.

I did not dissect the types of the four solilucis synonyms listed above, but instead retain them, following previous authors (Prout, 1918; Hering, 1925; Bryk, 1930). A more exhaustive study, perhaps employing characters from DNA, might reveal more than one species currently subsumed under solilucis. This will remain a challenge for the future.

A female with the following locality data almost certainly represents an undescribed species: Ecuador: Zamora-Chinchipe: Parque Nacional Podocarpus, Río Bombuscara, N. P. station, 4°06′S, 78°57′W, 1000–1200 m, 5–6 Dec 1999, leg. D. Bartsch & C. Häuser, day-coll., SMNS (genitalia slide no. JSM-1699). That specimen roughly matches the type of aurata Warren, but is larger and shows a white, rather than light yellow, subapical FW spot (pl. 10). The markings on the head are white, instead of yellow as in P. solilucis, and its genitalia are completely different from any other Phaeochlaena I have seen.

Distribution

Brazil (CMNH, CUIC, LACM, OUMNH, VOB, ZMH); Bolivia (AMNH, CMNH, CUIC); Argentina (BMNH); Peru (AMNH, BMNH, CAS, LACM, MUSM, ZMH); Ecuador (AMNH, BMNH, CMNH); Colombia (AMNH).

Dissected

♂, Peru, Madre de Dios, Tambopata Reserve, 30 km SW Pto. Maldonado, 300 m, 21 Oct 1983, leg. C.V. Covell Jr., AMNH (genitalia slide no. JSM-510); ♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, ant trail, 10 Dec 1996, leg. C. Snyder, A. Brower & S.R. Green, AMNH (genitalia slide no. JSM-923); ♂, Peru, Loreto, Pebas, 1913, BMNH (genitalia slide no. JSM-844); ♂, Brazil, Rondônia, Cacaulândia, 200 m, 15–20 Apr 1996, leg. V.O. Becker, VOB (genitalia slide no. JSM-921); ♂, Ecuador, Napo, Río Jatunyacu near Tena, 25 km SW Pano, 1200 m, 11 Jul 1994, leg. Jan Hillman, rainforest, CMNH (genitalia slide no. JSM-917); ♂, Ecuador, Napo, Río Jatunyacu, CMNH (genitalia slide no. JSM-918); ♂, Bolivia, Prov. del Sara, 450 m, leg. J. Steinbach, CMNH (genitalia slide no. JSM-1695); ♀, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, ant trail, 10 Dec 1996, leg. C. Snyder, A. Brower & S.R. Green, AMNH (genitalia slide no. JSM-924); ♀, Peru, Upper Río Marañon, 20 Sep 1929, H. Bassler Collection, BMNH (genitalia slide no. JSM-843); ♀, Peru, Upper Madre de Dios, 500–1200 m, leg. Fassl, USNM (genitalia slide no. JSM-1443); ♀, Brazil, Rondônia, Cacaulândia, 140 m, Nov 1991, leg. V.O. Becker, VOB (genitalia slide no. JSM-922); ♀, Bolivia, Yungas del Palmar, Jun 1951, Grace H. and John L. Sperry Collection, AMNH (genitalia slide no. JSM-509); ♀, Colombia, Putumayo, Caucaya, 28 Nov 1948, leg. Richter, AMNH (genitalia slide no. JSM-681).

The following species has been transferred from Phaeochlaena: integra C. and R. Felder to Erbessa Walker

PIKROPRION MILLER, new genus

Figures 79Figure 8081, 82C, 82D, 83C–F; plate 10

Type species: Pikroprion sullivani, sp. nov.

Figure 79

Morphology of Pikroprion sullivani, sp. nov. (♂). A, head, lateral view; B, head, frontal view; C, head, posterior view; D, tegula; E, head, lateral view; F, wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f079.gif

Figure 80

Genitalia of Pikroprion sullivani, sp. nov. (♂ JSM-1327, ♀ JSM-1328). A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, aedeagus; E, ♀ genitalia; F, ♀ St7 (illustration by J.S. Miller).

i0003-0090-321-1-1-f080.gif

Figure 81

Ecuador and southwestern Colombia, showing the known distribution of Pikroprion sullivani, sp. nov.

i0003-0090-321-1-1-f081.gif

Figure 82

Scanning electron micrographs of Argentala subcoerulea and Pikroprion sullivani (♂♂). A, antenna of A. subcoerulea, ventral view; B, a single antennal flagellomere of A. subcoerulea, ventral view; C, antenna of P. sullivani, ventral view; D, a single flagellomere of P. sullivani; E, labial palpus of A. subcoerulea in mesal view, distal at left; F, apex of labial palpus in A. subcoerulea.

i0003-0090-321-1-1-f082.gif

Figure 83

Scanning electron micrographs of Argentala subcoerulea and Pikroprion sullivani (♂♂). A, Apex of labial palpus of A. subcoerulea (mesal view, distal at left), showing thin spinules on Lp2 and Lp3; B, close-up of A. subcoerulea Lp3, showing spinules; C, labial palpus of P. sullivani (mesal view, distal at left); D, apex of P. sullivani labial palpus, showing short spinules; E, spinules on Lp3 of P. sullivani; F, a single spinule from E.

i0003-0090-321-1-1-f083.gif

Diagnosis

Because of its wing venation (fig. 79F), brown-and-white wing pattern (pl. 10), and elongate, elbowed labial palpi (fig. 79A, E), Pikroprion could potentially be misidentified either as a species of Argentala, or as a member of Polypoetes. It is closely related to both genera (fig. 7). However, males of Pikroprion sullivani, sp. nov., the only included species, are easily separated from Argentala by their widely bipectinate antennae (fig. 82C, D)—as opposed to subserrate ones in Argentala (fig. 82A, B)—and short FW DC (fig. 79F)—long in Argentala (fig. 84F). Pikroprion sullivani could be mistaken for a Polypoetes species, since both exhibit bipectinate male antennae. However, the short FW discal cell of Pikroprion, as opposed to the long one in Polypoetes (figs. 90G–I), is again distinctive.

Females in these taxa are somewhat more difficult to separate. In Polypoetes, female St7 is densely covered with setae (e.g., fig. 98C). This does not occur in Pikroprion (fig. 80F). In females of Argentala, the PVP is elongated to form a narrow, scaleless band along the midline of St7, and the ostium has apparently migrated anteriorly (e.g., figs. 85F, 85K, 86C). Pikroprion females exhibit no such sclerotized band.

This morphological discussion belies the fact that the wing pattern of P. sullivani (pl. 10) is unlike any member of either Argentala (pl. 10) or Polypoetes (pls. 10–14). Furthermore, when male and female genitalia are examined, numerous characters for separating these genera become immediately apparent. For example, the serrate socii of Pikroprion (fig. 80A) can be seen, along with the greatly elongate valva apices, in intact, pinned male specimens.

Description

Male. Head (fig. 79A–C, 79E, 82C, 82D, 83C–F). Labial palpus elongate, curving upward over front, apex terminating between antennal bases; Lp1 short, gently curved, Lp2 elongate, nearly twice as long as Lp1, Lp3 short, ovoid; distal portion of Lp2 and entire segment of Lp3 covered with conspicuous, yellowish-brown spinules on inner surfaces; scales of front pointing dorsomedially, scales short in central area, longer laterally, forming a central depression, a pair of diffuse dorsal tufts between antennal bases; eye extremely large, bulging, gena apparently absent; eye with a sparse covering of short setae; hypostomal bridge wide, extending posteriorly; scales of vertex pointing anteriorly, forming a short, rooflike overhang above frontal scales between antennal bases; antenna widely bipectinate.

Thorax: Epiphysis long and wide, almost as long as tibia but not extending beyond its apex; tegula long, approximately two-thirds as long as metascutum, dorsal portion wide, rounded, ventral portion blunt, transverse sulcus weak; metathoracic tympanum large, depression shallow, scaleless; tympanal membrane large, open, almost round, facing posteroventrally.

Forewing (fig. 79F; pl. 10): Large, broad, roughly triangular, with an almost 90° apical angle, anal angle also somewhat acute; vein Rs1 long stalked with Rs2–Rs4; veins Rs2–Rs4 in the pattern [2+3]+4, stalk of 3+4 short; M1 arising from DC very near base of Rs1–Rs4, UDC absent; stridulatory organ absent; DC shorter than one-half FW length; veins M3 and CuA1 long stalked; three conspicuous white markings on a dark brown ground color (see description of sullivani).

Hind wing (fig. 79F; pl. 10): Large and extremely broad, outer margin strongly convex; M3 and CuA1 long stalked; outer margin of DC obliquely angled.

Abdomen: Short, wide, expanded distally, terminus truncate.

Terminalia (fig. 80A–D): Tg8 extremely narrow, especially in distal half, without anterior apodemes; St8 much wider than Tg8, but narrower than St7, anterior apodeme wide and short, posterior margin with a deep U-shaped mesal excavation; socii/uncus complex broadly attached to tegumen, socii greatly elongate, serrate, uncus apparently absent; tegumen short and extremely wide, vinculum narrower, the entire ring oriented horizontally; saccus large, upper margin triangular, lower margin sinuate; valva large, heavily sclerotized, firmly attached to ring; BO large, partially sclerotized, wrapping around valva margin anteriorly; apex of valva with a greatly elongate, sclerotized process (visible in pinned specimens); arms of transtilla narrow; aedeagus long, narrow, widened at base; a bend of over 90° before apex; apex of aedeagus simple, without a ventral process; vesica long, bearing spinelike cornuti only.

Female. Head, thorax, and abdomen similar to male except: Labial palpus slightly shorter, distal portion without spinules; antenna bearing short thick pectinations; FW and HW longer and broader.

Terminalia (fig. 80E, F): Tg7 extremely large, well over twice as long as Tg6, anterior and posterior margins simple; St7 slightly shorter than Tg7, with a pair of sclerotized lateral pockets near posterolateral angles; Tg8 heavily sclerotized, bulbous, surface sculpted; AA long and thin; PP apparently absent; A8 pleuron sclerotized, posterior margins forming large, dentate lateral sclerites, these visible in intact, pinned specimens; PA large, laterally compressed, sclerotized, especially along posterior margin; PVP sclerotized, infolded; ostium wide, dorsoventrally compressed; DB short, folded, sclerotized; CB large, almost round; signum absent; DS attached ventrally at junction of CB and DB.

Etymology

This genus name (masculine) is derived from the Greek pikros “pointed” or “sharp”, and prion, “a saw”. It refers to the highly unusual, serrate socii of the male genitalia (fig. 80A). This is only one of several autapomorphies exhibited in the genitalia of this taxon, another example being the long narrow aedeagus, bent downward at an angle of over 90° (fig. 80D).

Distribution

The distribution of Pikroprion is outlined with regard to P. sullivani (below), the sole included species.

Biology

Unlike most species of Dioptinae, P. sullivani seems to be readily attracted to lights. Of the 25 specimens available for study, all were collected at light traps.

Discussion

My cladistic analyses suggest that Pikroprion, containing a single species, and Argentala, with six species, are sister genera (fig. 3), and that these together form the hypothetical sister group to Polypoetes. This lineage (Clade 7; fig. 7), comprising 70 described species, shows remarkable morphological diversity. When first faced with this phylogenetic result, I considered two options: One was to place all 70 species in a single, extremely complex genus—Polypoetes—its sister being Phaeochlaena (fig. 7). The other was to erect generic names for subclades of this large clade, leaving Polypoetes somewhat smaller in size. I chose the latter. My rationale is that, at least in this case, a more divided classification is more informative and easier to manage. Polypoetes, even in the relatively confined sense advocated here, remains highly diverse (appendix 2). It contains five species groups and shows a broad range of morphological variation. By recognizing Argentala and Pikroprion as separate entities, Polypoetes itself becomes somewhat easier to grasp.

Another viable option was to regard sullivani, with its distinctive morphology, as a member of Argentala, there then being two rather than three genera in Clade 7. I instead chose to erect Pikroprion for sullivani alone. Again, the reason for doing so is that more elegant generic definitions result. Pikroprion exhibits a unique set of apomorphies (appendix 4), as does Argentala. If the two are combined, their characterizations become difficult. The two genera nevertheless exhibit a strong set of synapomorphies, including having the male valvae tightly bound to the ring (figs. 80A, 85A, 85E, 86A, 88A). It is my contention that the current classification best represents the taxonomy and morphology of this challenging lineage.

Pikroprion sullivani, new species

Figures 79Figure 8081, 82C, 82D, 83C–F; plate 10 [EX]

Diagnosis

This is a fairly large dioptine, with broad wings. The bold pattern (pl. 10), comprising white markings on a dark brown ground color, is unmistakable. The wing venation (fig. 79F) is similar to that of Argentala (fig. 84F) and Polypoetes (e.g., fig. 90G); veins M3 and CuA1 are stalked in both the FW and HW, and a male FW stridulatory organ is absent. Pikroprion sullivani exhibits head characteristics typical of Argentala and most Polypoetes: labial palpi elongate (fig. 79A, E), folded elbowlike over front; palpi bearing small, distal spinules on Lp2 and Lp3 (figs. 79A, 83C–F); head with hypostomal bridge wide (fig. 79C), projecting posteriorly; eyes large and bulging (fig. 79A–C, 79E). The male and female genitalia of Pikroprion sullivani (fig. 80) are unique. For example, the male socii are elongate, curved upward, and their lateral margins are serrate (fig. 80A); the valva is large, heavily sclerotized and fused to the ring, so that the valvae do no easily open; and the valva apex bears a long, heavily sclerotized, curled process.

Description

Male. Forewing length  =  14.5–16.0 mm. Head (fig. 79A–C, 79E): Lp1 white, with a loose fringe of elongate scales below; Lp2 and Lp3 dark brown laterally, white on mesal surfaces; front dark brown in central area, lateral portions with long, immaculate white to light yellow, upwardly pointing scales; occiput covered with white scales, a tiny patch of brown scales dorsally; vertex dark brown with a small, white medial patch posteriorly; antennal scape and dorsal surface of shaft dark brown.

Thorax: Prothoracic coxa white, profemur and protibia dark brown on lateral surfaces, white on inner surfaces; meso- and metathoracic legs dark brown on lateral surfaces, white in inner surfaces; spurs dark brown; pleural region covered with white and light gray scales; patagium dark brown, with white scales on anterior margins; tegula bright orange at base, fringed with long, dark brown scales; dorsum dark brown with a pair of white, longitudinal stripes on each side of midline.

Forewing: (Dorsal) Dark chocolate brown with three white maculations (pl. 10); the first, a triangle from base to halfway out on DC, triangle straddling cubitus, extending from anterior margin of DC to anal fold; the second maculation a broad, elongate oval-shaped, white transverse band beyond DC, its anterior margin touching Sc, band extending posteriorly across M3+CuA, but falling short of 1A+2A; the third, a small, almost round, white subapical spot straddling veins Rs3 and Rs4; cubital vein sparsely lined with dark brown scales as it passes through white triangle; veins passing through brown areas dusted with orange-yellow scales; a diffuse, yellowish white streak behind costa in basal third. (Ventral) Pattern the same as on dorsal surface.

Hind wing: (Dorsal) Central area translucent white; a moderately wide, dark chocolate-brown outer margin (pl. 10); brown marginal band wider near apex; anal margin white, variably dusted with dark brown scales. (Ventral) Pattern identical to upper surface.

Abdomen: Dorsum brown to silvery gray, a few white scattered white scales, especially near base; venter white.

Terminalia (figs. 80A–D): Tg8 extremely narrow, widest at anterior margin, abruptly narrowed in distal one-half; posterior margin of Tg8 finely forked, each tine long and thin, ending in a sharp point; dorsum of Tg8 with a wide, deep groove in posterior half; anterior margin of Tg8 simple; St8 trapezoidal, widest at anterior margin, slightly narrower posteriorly; posterior margin of St8 with sclerotized processes at lateral angles and a deep, U-shaped mesal excavation, its edge sclerotized; anterior margin of St8 with a short, broad apodeme extending almost the entire sternum width; socii/uncus complex large, broadly connected to tegumen; uncus apparently absent; socii long, heavily sclerotized, strongly upturned, their lateral margins sharply serrate; tegumen extremely short, widest above; vinculum narrow but long, heavily sclerotized, oriented horizontally; saccus sinuate along ventral margin, dorsal margin forming an upturned triangular sclerite, enclosing valva bases; valvae large and bulbous, extremely wide at base, fused with ring, lateral surfaces heavily sclerotized; BO well developed mostly sclerotized, comprising a series of long pleats on ventral margin of valva, BO curling anteriorly; costa of valva with a finely setose hump near midpoint; costa of valva terminating in an extremely long process, curving behind socii/uncus complex, apex of process club shaped; a second, short, heavily sclerotized process above BO, its upper margin dentate; transtillar arms narrow, pointing downward, meeting to form a V-shaped structure at midline; aedeagus bell shaped at base, abruptly narrowed in distal three-fourths, elbowed sharply downward in distal fourth; apex of aedeagus finely dentate above; vesica long, wide, upturned, with a group of short, straight spinelike cornuti in basal half, covered with loosely dispersed, thin spinelike cornuti in distal half.

Female. Forewing length  =  15.5–17.0 mm. Head, thorax, and abdomen similar to male; wing pattern similar to male except white cross band larger, extending posteriorly to anal fold.

Terminalia (fig. 80E, F): Tg7 extremely large, almost quadrate, surface arching upward at midline; lateral margins of Tg7 slightly concave, anterior and posterior margins simple; St7 extremely wide, convex at lateral margins, with a pair of shallow, sclerotized pockets near posterolateral angles, their surfaces finely crenulate; angles of St7 beyond pockets produced into toothlike, sclerotized processes; posterior margin of St7 simple; anterior margin slightly concave; Tg8 heavily sclerotized, bulbous, enclosing upper margin of PA; Tg8 with a middorsal depression, dorsal surface coarsely crenulate, lateral surfaces densely spiculate; AA thin, slightly down-curved; pleuron of A8 sclerotized, forming leaflike lateral sclerites with jagged posterior margins, a toothlike process at posteroventral angle; leaflike sclerites produced posteriorly, partially enclosing PA; postvaginal area heavily sclerotized, infolded; ostium a wide, flat funnel; DB short, irregularly folded, sclerotized; DS attached to a small ventral sinus at base of CB near junction with DB; CB narrow in basal third, ventral surface sclerotized, large, rounded and membranous beyond; signum absent; PA sclerotized, upper one-third narrow, crenulate at dorsum, lower two-thirds wider; posterior margin of PA sinuate; PP apparently absent.

Etymology

This species is named in honor of J. Bolling Sullivan (Beaufort, NC), who has been collecting Lepidoptera since 1963 and has collected in the tropics since 1975. His material from Colombia, and more recently Costa Rica and Brazil, was an important resource during the course of this study, often providing crucial examples of rare and undescribed taxa. Bo captured a large series of Pikroprion sullivani in Colombia, adding to our biogeographical knowledge of this fascinating taxon.

Distribution

Pikroprion sullivani is endemic to Chocó habitat along the western slopes of the Andes (fig. 81). Its northernmost record is Anchicaya, near the Pacific coast of Colombia, a short distance northwest of Cali. It ranges south to Guayas Province in Ecuador, near Bucay, east of Guayaquil. All told, this distribution spans over 700 km. The altitudinal range of P. sullivani is relatively broad. The moths have been collected at elevations as low as 250 meters and as high as 1500 meters. Many of the localities at which P. sullivanai has been captured are disturbed habitats.

Discussion

When I first encountered specimens of Pikroprion sullivani in 1987, I incorrectly identified them as Momonipta albiplaga Warren (pl. 21), based on similarities in their wing patterns. Subsequent examination of the albiplaga holotype at the BMNH—the only known specimen of that species—quickly dispelled my theory. It became clear that this material in fact represents an undescribed species, unlike any other in the Dioptinae. The reason this striking taxon has not been described by earlier workers seems to be that museum specimens simply did not exist. All the material I have seen was collected within the past 25 years. It is difficult to explain the sudden appearance of Pikroprion sullivani in modern collections; perhaps its host plant is a weedy colonist, expanding into newly disturbed areas, and bringing the moth along with it.

Holotype

Male (pl. 10). Ecuador: Pichincha: Tinalandia, 700 m, leg. J.S. Miller, 20 May 1993. The type is deposited at the AMNH.

Paratypes

Ecuador: Carchi: 1♀, Chical, 1250 m, 0-56N, 78-11W, 10 Aug 1983, leg. J. Rawlins & R. Davidson (CMNH). Esmeraldas: 1♂, Río de Cristal, Cotacachi-Cayapas Reserve, 1350 m, 20 Aug 1996, leg. J. Hillman, virgin submontane forest (CMNH); 1 ♂, 1♀, 5 km E Alto Tambo, 900 m, 8 Dec 1995, leg. Jan Hillman, disturbed forest (CMNH; male genitalia slide no. JSM-1327, female genitalia slide no. JSM-1328). Pichincha: 1♂, Tinalandia, 700 m, 18 May 1985, leg. C.V. Covell Jr (AMNH; wing slide no. JSM-1463, genitalia slide no. JSM-438); 1♀, Tinalandia, 700 m, 23 May 1985, C.V. Covell Jr (AMNH; genitalia slide no. JSM-439); 2♂♂, Tinalandia, 600 m, 16–20 Apr 1986, leg. Stuart McKamey (LACM); 1♂, E Sto. Domingo, 8–14 May 1988, leg. Bohart & Hanson (USUC); 1♀, Sto. Domingo de los Colorados, Sept 22 1970, R.E. Dietz IV (EMEC); 1♂, above Toachi, S00°19.3′, W78°57.0, 900 m, 29 Apr 2000, at light UV/MV, leg. S. Rab Green & A. Tapia (AMNH). Cotopaxi: 1♀, San Francisco de Las Pampas, 1500 m, 10 Jun 1991, leg. G. Onore (AMNH). Guayas: 1♀, Hacienda San Juaquín, 4 road km SW Bucay, 250 m, 1–4 May 1986, leg. Stuart McKamey (LACM).

Other Specimens Examined

Colombia: Valle: 1♂, 10♀♀, Anchicaya, 650 m, Valle, 1–2 Feb 1989, leg. J. Bolling Sullivan (JBSC). Nariño: Ricuarte, 1♂, 1100 m, Jun 1946, leg. Von Schneidern (AMNH; genitalia slide no. JSM-440).

Dissected

3♂♂, 2♀♀.

ARGENTALA MILLER, new genus

Figures 82A, 82B, 82E, 82F, 83A, 83B, 84Figure 85Figure 86Figure 8788; plate 10

Type species: Tithraustes subcoerulea Warren (1901).

Figure 84

Morphology of Argentala (♂♂). A, head of A. subcaesia, lateral view; B, head of A. subcaesia, frontal view; C, head of A. subcaesia, posterior view; D, head of A. argoptera, sp. nov., lateral view; E, A. subcaesia tegula; F, A. subcaesia wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f084.gif

Figure 85

Genitalia of Argentala. A, ♂ of A. argoptera, sp. nov. (JSM-1320); B, aedeagus of A. argoptera; C, ♂ Tg8 of A. argoptera; D, ♂ St8 of A. argoptera; E, ♂ of A. mesitana (JSM-1117); F, ♀ of A. mesitana (JSM-1116); G, aedeagus of A. mesitana; H, ♂ Tg8 of A. mesitana; I, ♂ St8 of A. mesitana; J, ♀ Tg7 of A. mesitana; K, ♀ St7 of A. mesitana.

i0003-0090-321-1-1-f085.gif

Figure 86

Genitalia of Argentala brehmi, sp. nov. (♂ JSM-1427, ♀ JSM-1428). A, ♂ genitalia; B, aedeagus; C, ♀ genitalia; D, ♂ Tg8; E, ♂ St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f086.gif

Figure 87

Ecuador, showing the known distributions of Argentala argoptera, sp. nov., and A. brehmi, sp. nov.

i0003-0090-321-1-1-f087.gif

Figure 88

Genitalia of Argentala subcaesia (♂ JSM-1387, ♀ JSM-1388). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f088.gif

Diagnosis

Argentala species bear superficial resemblance to members of Polypoetes, a closely related genus (figs. 3, 7). The two share the presence of elongate, elbowed labial palpi (compare figs. 84A, 84D, 89B, 90A, 90D), a FW DC much longer than one-half the wing length (figs. 84F, 90G–I), and broad wings. In both, the male FW lacks a stridulatory organ. The metathoracic tympanum of Argentala is “open”; the tympanal membrane is not enclosed in a cavity, but is instead almost flush with the surface of the metepimeron, facing laterally. This configuration also occurs in Polypoetes, but the two tympana differ in that the membrane of Argentala is small, whereas in most Polypoetes it is large. The best way to separate Argentala and Polypoetes, at least for males, is that the former lack antennal pectinations (fig. 82A, B), but instead show short, transverse flanges where the rami would be. The majority of Polypoetes have long pectinations in males (e.g., fig. 93C, D). Exceptions are the Persimilis and Rubribasis groups, in which the male antennae (fig. 92A) show a configuration similar to that of Argentala. However, males in both Polypoetes groups exhibit short labial palpi (figs. 89A, 89C, 91D). Throughout these various clades, genital characters provide the most effective means for correct generic placement.

In summary, Argentala can be recognized by the follow set of characteristics: labial palpus elongate (fig. 84A, D), elbowed, in male reaching to antennal base or beyond; apex of Lp2 and distal half of Lp3 bearing thin, microscopic spinules on inner surface (fig. 82E, F; fig. 83A, B); male antenna subserrate, without pectinations, each segment bearing two dense whirls of cilia on transverse flanges (fig. 82A, B); FW broad, almost quadrate at apex, with a fascia beyond DC (pl. 10), fascia always visible on ventral surface, usually on dorsal one; FW ventral surface with a silvery white basal dash, rarely (A. argoptera) with a large basal triangle; DC much longer than one-half FW length (fig. 84F); HW broad, rounded at outer margin, ventral surface silvery white from base to distal margin of DC or beyond (pl. 10), anal margin white; male genitalia with valvae tightly held to ring (figs. 85A, 85E, 86A, 88A), costa of valva produced into a long, sclerotized apical process (visible in intact specimens); female genitalia with ostium migrated anteriorly (figs. 85F, 86C, 88E), opening near posterior margin of St6, St7 extremely wide and deeply excavated (fig. 85K); female PVP thus forming a longitudinal, fairly wide, scaleless sclerotized band (visible in intact specimens), usually weakly convex along midline, with fine, transverse striations (fig. 86C).

Description

Male. FW length  =  12.0–16.0 mm. Head (figs. 82A, B, E, F; fig. 83A, B; fig. 84A–D): Labial palpus elongate, extending upward to antennal bases, folded elbowlike over front, bearing a loose distal tuft near apex; Lp1 short, curving gently upward; Lp2 extremely long, curving gently outward in distal third; Lp3 short, conical; apex of Lp2 and distal half of Lp3 bearing thin microscopic spinules on inner surface; front with upwardly pointing scales forming a central depression, lateral scales elongate, forming tufts below antennal bases; eye large, bulging outward (A. argoptera), or moderately large, not bulging, then surrounded by a scaleless band with gena broadly scaleless below; hypostomal bridge wide, extending posteriorly; antenna subserrate, each segment bearing two transverse rows of cilia, the posterior row born on raised, flangelike processes; scales on vertex long, pointing forward, forming a transverse ledge over apex of palpus.

Thorax: Epiphysis foliate, short, wide, not reaching apex of tibia; tegula moderately long, distal portion blunt, apex rounded, with a weak sulcus below; metathoracic tympanum comprising an extremely shallow, scaleless depression; tympanal membrane relatively small, forming a triangle with rounded angles, facing laterally.

Forewing (fig. 84F; pl. 10): Broad, almost triangular, outer margin straight or weakly convex; ground color dark chocolate brown to blackish brown; most species with a conspicuous, ovoid fascia immediately beyond DC, especially prominent on ventral surface; anterior margin of fascia falling short of, or touching, base of Rs1–Rs4, posterior margin touching fork of M3+CuA1; vein Rs1 arising from radial sector before Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4, stem of 2+3 extremely short; base of M1 touching base of Rs1–Rs4; stridulatory organ absent; DC much longer than one-half FW length; veins M3 and CuA1 long stalked; without dorsal pattern except for fascia (A. subcoerulea with a white basal dash); veins usually thinly lined with yellow or yellow-orange scales; ventral surface in most species with a white basal dash behind cubitus (FW base completely white in A. argoptera).

Hind wing (fig. 84F; pl. 10): Broad, outer margin rounded; ground color darker than FW, dark brown to blackish brown; M3 and CuA1 long stalked; central area dark or white above; ventral surface silvery white from base to beyond DC, anal margin more extensively silvery white.

Abdomen: Moderately long, slightly tapered or truncate distally; sclerotized apical processes of valvae usually visible.

Terminalia (fig. 85A–E, G–I; fig. 86A, B, D, E; fig. 88A–D): Tg8 short, lightly sclerotized, widest anteriorly, gradually narrowing distally; St8 relatively wide, lightly sclerotized, narrowest at anterior margin, gradually wider distally; apodeme on anterior margin of St8 broad, convex, with a triangular or tonguelike mesal fold; posterior margin of St8 with a broad, deep mesal excavation; socii/uncus complex wide, roughly quadrate, broadly attached to tegumen; apex of uncus apparently absent, represented by a small, apical notch; socii arising more than halfway out on socii/uncus complex; socii narrow at base, then broad and bladelike, laterally compressed, sharply upturned, apices variable in shape; tegumen moderately wide, much taller than vinculum, sides roughly parallel, dorsal portion of tegumen forming a wide “neck” below socii/uncus complex; vinculum extremely short, concave; lower portion of genitalia wide, ventral margin almost horizontal or gently convex; dorsal margin of saccus curving upward at midline to form a wide, low triangle, its apex meeting between valva bases; valvae tightly held to ring; valva elongate, relatively narrow, except BO abruptly expanded below; inner surface of valva mostly membranous, slightly expanded inward above base; inner valva surface covered with long setae, a brush of straight setae below apex; costa robust, narrow, heavily sclerotized, sides roughly parallel except slightly wider at base, costa curving sharply inward in distal portion; valva apices forming heavily sclerotized processes, their distal margins variable in shape, often spatulate and minutely serrate (e.g., fig. 85E; mesitana), sometimes acute (e.g., fig. 88A; subcaesia); valva apices meeting near midline, sometimes crossing anterior to socii/uncus complex; transtillar arms wide, robust, oriented horizontally from valva base, then bending sharply downward to meet above aedeagus; junction of transtillar arms forming a large, V-shaped structure; aedeagus wide in basal third, then much narrower, usually slightly sinuate; apex of aedeagus curving upward, forming an acute ventral process; opercular sclerites of vesica greatly elongate; vesica long and narrow, or moderate in length, wider than distal portion of aedeagus; vesica with an apical patch of delicate, spinelike cornuti.

Female. FW length  =  14.0–16.5 mm. Head: Labial palpus shorter than male, but folded elbowlike over front, apex of Lp3 reaching to middle of front; Lp2 long, ventral margin curved slightly outward; antenna ciliate, each annulation with paired, transverse rows of bristles.

Thorax: Similar to male.

Forewing: Broader and more triangular than male, colors and wing pattern slightly less intense, otherwise similar.

Hind wing: Similar to male but broader; outer margin, including fringe, trimmed in white to whitish brown between veins CuA2 and 2A (e.g., A. brehmi; pl. 10); frenulum comprising six or more bristles.

Abdomen: Wide dorsoventrally, shorter than male.

Terminalia (figs. 85F, 85J, 85K, 86C, 88E): Ostium displaced anteriorly, opening slightly short of St6 posterior margin; PVP forming a wide scaleless band running the length of St7, its surface either smooth (e.g., mesitana), or covered with transverse striations (e.g., brehmi); Tg7 large, wide, lateral margins excavated to form a waist near middle; St7 extremely wide, posterolateral angles greatly expanded, smoothly rounded; posterior margin of St7 excavated for its entire length to accommodate displaced ostium, forming a huge, wide, U-shaped excavation; Tg8 membranous; AA and PP elongate, thin; PA robust, dorsoventrally elongate, surface finely spiculate; PVP forming a wide, greatly elongate band; ostium simple; DB upright, relatively short, flat; DS arising dorsally at junction of DB and CB from a conspicuous membranous appendix; CB round or almost so, membranous; signum small, located near base of CB, inner surface spiculate or smooth; CB with a pair of deep, rugose pockets located opposite signum, their inner surfaces coarsely spiculate.

Etymology

This genus name is derived from a combination of the Latin words argentinus (“silvery”) and ala (“wing”). In all members of Argentala, the ventral surface of the hind wing is broadly silvery white from the base to beyond the discal cell (see pl. 10). The silvery white area invariably extends even further out along the anal margin, creating a distinctive pattern not expressed on the wing's dorsal surface. Gender feminine.

Distribution

Argentala species are restricted to cloud forests. They occur from the Andes of southern Ecuador north to Guanacaste Province in Costa Rica, and as far west in northern South America as Maracay, Venezuela. So far, the genus is not known from Peru or Bolivia. However, these are relatively obscure moths, so additional records will undoubtedly be discovered, perhaps expanding the group's distribution.

Biology

Nothing is known concerning the biology of Argentala. The majority of specimens have been collected at lights, but all species are rare.

Discussion

This genus constitutes a fascinating clade with a checkered taxonomic history. Each of the four previously described species—mesitana, subalba, subcaesia, and subcoerulea—was originally placed in a different genus. Dognin (1917) described mesitana in Polypoetes, where it has remained until the present work. The most obscure of these taxa, subalba from Venezuela, known from only four specimens worldwide, was described by Walker (1854) in Chrysauge, currently in the Pyralidae (Chrysauginae) but at that time regarded as a genus of “Lithosiidae” (now Arctiidae: Lithosiinae). The remaining two species, subcoerulea Warren and subcaesia Prout, were described in the dioptine genera Tithraustes and Momonipta respectively. Prout (1918) united three of these taxa—subalba, subcoerulea, and subcaesia—in the genus Momonipta Warren. Unfortunately, Momonipta itself was poorly defined, then containing 19, mostly unrelated, dioptine species. Hering (1925) placed Momonipta in synonymy with Stenoplastis C. and R. Felder, but otherwise retained Prout's generic concept precisely. Bryk (1930) followed suit.

My cladistic analyses show that Argentala is the sister group to Pikroprion (figs. 3, 7), and that these belong in a larger clade (Clade 7; fig. 7) that includes Polypoetes. Contrary to the hypotheses of previous authors, the species now in Argentala do not belong in either Momonipta or Stenoplastis, both of which are revealed in this paper as small genera with affinities to Monocreaga and Tithraustes respectively (fig. 7). The monophyly of Argentala is indisputable, being supported by 21 synapomorphies (appendix 4). In addition to describing the new genus here, I also describe two new Argentala species from Ecuador: argoptera and brehmi. A third taxon remains undescribed. This latter species, from western Ecuador, is represented in the AMNH collection by a single male (Cañar, El Chorro, leg. S. Rab Green & M. Tapia, 2003; genitalia slide no. JSM-1393).

KEY TO THE SPECIES OF ARGENTALA

Species identifications in Argentala (pl. 10) are challenging, in part because some taxa exhibit considerable intraspecific wing-pattern variation. For example, the HW can vary from being uniformly brown to showing an oblong white central area. Similarly, the FW fascia beyond the DC can be white and conspicuous in some color forms, or entirely absent in others. Such variation is demonstrated by A. brehmi and A. subcaesia. The other four Argentala species are known from so few specimens that similar variability in wing coloration cannot be ruled out. The key below therefore relies largely on other morphological features.

1. Lateral portions of front lined with white or cream-colored scales3

Lateral portions of front lined with yellow to light yellow scales2

2. Eye relatively small, not bulging (fig. 84A), gena wide; scales on inner surface of Lp2 white (W Colombia)subcaesia (Prout)

Eye large and bulging (fig. 84D), gena narrow; scales on inner surface of Lp2 yellow (W Ecuador)argoptera, sp. nov.

3. Base of FW (dorsal surface) brown (pl. 10), anal fold concolorous with rest of wing4

Dorsal surface of FW with a light yellowish-white basal dash (pl. 10) along anal fold (NW Colombia to NW Costa Rica)subcoerulea (Warren)

4. Forewing and HW ground color dark chocolate brown; posterior margin of male St8 with a broad, U-shaped mesal excavation; apices of socii narrowly spatulate; paired spiculate pockets on female CB located dorsally, slightly on left side5

FW and HW ground color dark charcoal gray to blackish brown; posterior margin of male St8 with a wide mesal excavation (fig. 86E); apices of socii broadly spatulate (fig. 86A); paired pockets on female CB located laterally on right side (fig. 86C) (southern Ecuador)brehmi, sp. nov.

5. Central area of HW (dorsal surface) creamy yellowish white (pl. 10); FW length  =  14.0–15.0 mm; female AA long and thin, slightly sinuate; sclerotized distal portion of male valva curving horizontally (Colombia)mesitana (Dognin)

Central area of HW dirty white to light brown (pl. 10); FW length  =  12.0–14.0 mm; AA somewhat short, curling strongly upward; sclerotized distal portion of valva curving slightly downward (Venezuela)subalba (Walker)

SPECIES INCLUDED AND MATERIAL EXAMINED

Argentala argoptera, new species

Figures 84D, 85A–D, 87; plate 10

Diagnosis

Superficially, A. argoptera is most similar in wing pattern to A. subcaesia (Prout), from western Colombia. In both, the FW is rich chocolate brown with yellow-orange scales lining the veins (pl. 10). There is a FW fascia beyond the DC—diffuse in argoptera, but more hyaline and clearly defined in subcaesia—and the HW dorsal surface is evenly blackish brown with the white ventral pattern showing faintly through (pl. 10). Wing length provides a means for separating the two species: argoptera ♂ FW length  =  15.0–16.0 mm; subcaesia ♂ FW length  =  13.5–14.5 mm. Based on available material, A. argoptera is the largest member of Argentala. Its FW is also somewhat less elongate than in other species, and its HW is broader. Additionally, the eyes of A. argoptera (fig. 84D) are larger and more bulging that in any other member of Argentala (fig. 84A–C). Finally, A. argoptera is unique within the genus in having the inner surface of Lp2 covered with yellow, rather than white, scales.

Other than genital differences, the most reliable means for species identification in Argentala is to examine the FW and HW ventral surfaces. For example, in A. argoptera the FW ventral surface has a silvery white triangle from the base to about one-third out; all other Argentala taxa exhibit a small, white basal dash in this region. Similarly, the HW of A. argoptera is almost entirely silvery white except for a wide, dark brown band, which begins at the apex, but ends abruptly at vein CuA2. In all other Argentala species, the white area on the HW ventral surface is less extensive; usually the brown band extends well past CuA2, tapering toward the tornus.

The male genitalia of A. argoptera (fig. 85A–D) are distinctive in the following ways: mesal excavation on St8 deeper and more U-shaped than in other Argentala species, most of which have a V-shaped notch; socii/uncus complex wide and squat, not tall as in other Argentala taxa; socii wider and more robust, almost spadelike; apex of aedeagus curving upward more strongly than in other species; and apical tooth of aedeagus sharper and more thornlike.

Description

Male (fig. 84D; pl. 10). Forewing length  =  15.0–16.0 mm. Head: Lp1 covered with bright orange-yellow scales, dorsal surface light yellow; Lp2 with a few yellow-orange scales near junction with Lp1, ventrolateral surfaces then tightly covered with dark chocolate-brown scales, mesal surface with light yellow scales, dorsal surface loosely covered with long, distally pointing, light yellow to cream-colored scales; Lp3 dark brown on ventral surface, cream colored above; front dark chocolate brown in central area, lateral scales light yellow near clypeus, becoming light orange toward antennal bases; occiput dark brown in dorsal half, light yellow to cream colored in lower half; eye extremely large, bulging, surrounded by a thin scaleless area, slightly wider in area of gena; vertex chocolate brown, a few white scales posteriorly, light orange-yellow behind antennal bases; scape and dorsum of antennal shaft dark chocolate brown.

Thorax: Legs dark brown on outer surfaces, cream colored on inner surfaces, except metathoracic tibia mostly cream colored on all surfaces; pleuron entirely cream colored; patagium dark brown, with a few scattered whitish scales anteriorly, and a diffuse, transverse row of whitish scales across middle; tegula relatively small, central area with erect, orange scales, margins fringed with long, hairlike chocolate-brown scales; dorsum dark chocolate brown, with a pair of longitudinal, light orange stripes on either side of midline.

Forewing: (Dorsal) Evenly covered with rich, chocolate-brown ground color (pl. 10); veins, excluding costa but including anal fold, sharply lined with orange-yellow scales; a diffuse fascia present beyond DC, its anterior margin touching M1, its posterior margin touching fork of M3+CuA1; fascia sparsely covered with light brown scales. (Ventral) Ground color light chocolate brown, veins concolorous; silvery white from base to three-fourths out on DC; fascia beyond DC white, ovoid, its anterior margin almost touching radial sector, its posterior margin touching fork of M3+CuA1; outer margin of fascia infiltrated with a short row of brown scales along veins M1 and M2; costa chocolate brown; anal margin light brown.

Hind wing: (Dorsal) Evenly covered with dark chocolate brown, white from ventral surface showing faintly though in basal three-quarters (pl. 10); anal margin a mixture of chocolate-brown and white hairlike scales, whiter in basal two-thirds. (Ventral) Completely silvery white, except a short, wide, chocolate-brown marginal band from apex, ending abruptly at CuA2; fringe brown; anal margin with long, whitish hairlike scales.

Abdomen: Dorsum evenly dark chocolate brown; venter white at base, then covered with long, cream-colored scales until posterior margin of St7; St8 light brown, with a few scattered, cream-colored scales near anterior margin.

Terminalia (fig. 85A–D): Tg8 roughly triangular, widest anteriorly, then gradually narrowing distally; St8 relatively wide, narrowest at anterior margin, wider toward distal margin, then narrowing slightly in distal fourth, lateroposterior angles rounded; anterior margin of St8 smoothly convex, with a rounded, tonguelike mesal fold; posterior margin of St8 with a deep, smoothly U-shaped mesal excavation; socii/uncus complex wide and short, hoodlike; apical notch of uncus small; socii arising from slightly more than halfway out on socii/uncus complex; socii narrow at base, then broad and bladelike, sharply upturned, apices flattened and blunt, rounded; halves of tegumen meeting below socii/uncus complex to form a prominent knob; lower portion of genitalia extremely wide, ventral margin almost horizontal; sides of costa parallel, costa curving sharply inward in distal fourth; valva apices forming heavily sclerotized processes, their distal margins spatulate, serrate, apices passing anterior to socii; aedeagus wide in basal third, then abruptly narrowed, slightly sinuate; apex of aedeagus curving slightly upward, forming a sharp, thornlike ventral process; vesica relatively long, narrow, with a distal appendix, bearing a dense patch of short, spinelike cornuti.

Female. Unknown.

Etymology

This species name, from the Greek argos for “white” and pteron for “wing” or “feather”, refers to the ventral wing surfaces in this taxon, which exhibit by far the most white of any Argentala species (pl. 10). The dorsal wing surfaces of argoptera are uniformly dark.

Distribution

Argentala argoptera is known from the western slope of the Ecuadorian Andes (fig. 87) in cloud forest habitats at elevations between 1200 and 2600 meters. As far as I am aware, only five males have so far been collected—two, including the holotype, from San Francisco de Las Pampas on the northern boundary of Cotopaxi Province (1200 m), one from Otonga Reserve near Las Pampas (2600 m), one approximately 185 km north of that from Cotachachi-Cayapas Reserve in Esmeraldas Province (1550 m), and a fifth from Los Cedros Reserve in Imbabura (1750 m), slightly south of Cotachachi-Cayapas. The close proximity of these localities perhaps indicates a relatively small area of endemism for A. argoptera.

Discussion

Argentala argoptera is the first member of the genus to be discovered from western Ecuador. Future collecting in the cloud forests of southwestern Colombia and northwestern Ecuador will more accurately assess the distribution of this moth; the species undoubtedly occurs in Colombia. Furthermore, even without additional fieldwork, specimens of A. argoptera will perhaps be discovered in personal and institutional collections subsequent to publication of this paper.

Holotype

Male. Ecuador: Cotopaxi: Las Pampas, Casa Cesar Tapia, 1200 m, S00°25.5′, W78°57.5′, 17 Aug 2001, leg. S. Rab Green, M. Tapia & C. Tapia, at light UV/MV. The type is deposited at the AMNH.

Paratypes

Ecuador: Cotopaxi: 1♂, Las Pampas, Casa Cesar Tapia, 1200 m, S00°25.5′, W78°57.5′, 22 Aug 2001, leg. S. Rab Green, Q. Tapia, C. Tapia & I. Tapia, at light UV/MV (AMNH; genitalia slide No. JSM-1818); 1♂, San Francisco de Las Pampas, Otonga Reserve, 2600 m, 22 Mar 1993, leg. Jan Hillman, undisturbed cloud forest (CMNH; genitalia slide no. JSM-1320). Imbabura: 1♂, Los Cedros Reserve, nr. Sanguangal, 60 km NW Quito, 100 km SE Esmeraldas, 1750 m, 23 Aug 1992, leg. A. Spalding, primary forest (BMNH). Esmeraldas: 1♂, 5 km W Río de Cristal near Alto Tambo, Cotachachi-Cayapas Reserve, 1550 m, 7 Dec 1995, leg. Jan Hillman, cloud forest (CMNH).

Other Specimens Examined

None.

Dissected

1♂.

Argentala brehmi, new species

Figures 86, 87; plate 10

Diagnosis

Argentala brehmi is somewhat difficult to recognize because of the existence of two color forms (pl. 10)—the nominate form in which the FW and HW are completely dark above, and a second form with a conspicuous, semihyaline to white fascia in both the FW and HW, as well as a narrow, white triangle in the HW central area, located within the DC. The two forms show closer resemblance on the ventral wing surfaces (pl. 10).

As seems to be the case throughout Argentala, the most effective way to separate the taxa is by study of the wing ventral surfaces. In A. brehmi there is a trait on the HW ventral surface that does not occur elsewhere in the genus; here, the discocellular veins at the distal margin of the discal cell are concolorous with the marginal band (dark blackish brown), forming a small, comma-shaped maculation between the silvery white basal area of the wing and the white fascia beyond the DC (pl. 10). So far, A. brehmi is the only species of Argentala discovered from the eastern slope of the Andes, so its distribution is also diagnostic.

The male genitalia of A. brehmi (fig. 86A, B, D, E) are distinct from other Argentala species in that the mesal excavation on St8 is particularly wide, with acute anterolateral angles and a transverse anterior margin, rather than being U-shaped or V-shaped, and the socii are abruptly constricted below their apices. Females differ from other Argentala taxa for which females are known (mesitana, subalba, subcaesia, and subcoerulea) in exhibiting stronger transverse rugulae on the PVP (fig. 86C). In addition, the posterolateral margins of the PVP, smooth in all other species, are crenulate.

Description

Male (pl. 10). Forewing length  =  13.5–14.5 mm. Head: Lp1 closely covered with yellow-orange scales, dorsal surface white; ventrolateral surfaces of Lp2 tightly covered with blackish brown scales, dorsal surface with looser, white scales, mesal surface a mixture of white and dark brown scales; Lp3 gray-brown, mesal surface bearing short, yellowish spinules; apical tuft cream colored; front blackish brown in central area, bordered on all sides by white to cream-colored scales; occiput blackish brown in dorsal half, with long, white to cream-colored scales in ventral half; eye moderately large, not bulging, surrounded by a narrow scaleless band, but gena (below) broadly scaleless; vertex covered with blackish-brown scales, a few white to cream-colored scales posteriorly, a narrow white stripe behind each antennal base; antennal scape blackish brown, a few white scales below; dorsum of antennal shaft dark brown to blackish brown.

Thorax: Legs gray-brown on outer surfaces, white on inner surfaces, except outer surface of metathoracic legs a mixture of gray-brown and whitish scales; pleuron covered with long, white to cream-colored scales, a few gray scales along anterior margin of mesepisternum; patagium blackish brown, with transverse rows of scattered, white scales anteriorly and across middle; central portion of tegula orange-yellow, broadly fringed with long, hairlike, blackish-brown scales; dorsum blackish brown, with a pair of longitudinal, light yellow-orange stripes on either side of midline.

Forewing: (Dorsal) Ground color dark chocolate brown (pl. 10); veins, excluding costa but including anal fold, thinly lined with yellow-orange scales; fascia beyond DC either extremely faint to diffuse (dark form), or conspicuous, semihyaline, ovoid, its anterior margin touching M1, its posterior margin touching the fork of M3+CuA1. (Ventral) Ground color dark gray to gray-brown; veins not contrasting; a thin white streak behind costa in basal fifth; a silvery white dash between cubitus and anal fold in basal fourth, outer corners extending further distally along veins.

Hind wing: (Dorsal) Ground color dark charcoal gray to blackish brown (pl. 10), white basal area of ventral surface showing faintly through; anterior margin light gray; anal margin lined with a mixture of dark gray and white hairlike scales, whitest near base; basal half of wing either charcoal gray (dark form), or with area of DC from base to discocellular veins white, a few scattered charcoal-colored scales and apparent base of M2 lined with gray, discocellular veins dark charcoal gray. (Ventral) Basal two-thirds silvery white; area of apex broadly dark gray in distal quarter, gray extending around outer margin to between CuA2 and anal fold, projecting toward base near CuA2; discocellular veins and distal portion of radius lined with dark gray scales, forming a comma-shaped maculation; fascia beyond DC white (dark form) or semihyaline, evenly covered with pedicellate white scales; anal angle with scattered dark gray scales near outer margin; fringe gray-brown; anal margin with mostly white, hairlike scales, a few scattered, dark brown scales in distal quarter.

Abdomen: Dorsum dark gray-brown; venter white to cream colored, St8 a mixture of long, white and gray-brown scales.

Terminalia (fig. 86A, B, D, E): Tg8 widest anteriorly, gradually tapered distally to form a blunt mesal process; St8 relatively wide, narrowest anteriorly then gradually widening distally, narrowing again slightly in distal fourth, lateroposterior angles somewhat acute; anterior margin of St8 slightly convex, with a triangular, tonguelike mesal fold; posterior margin of St8 with an extremely wide, U-shaped mesal excavation; socii/uncus complex wide, elongated between tegumen and attachment points of socii, broadly attached to tegumen; apex of uncus represented by a pair of short lobes with a small, deep notch between them; socii arising from two-thirds out on socii/uncus complex; socii narrow at base, then broadly expanded, flattened and bladelike, distal third abruptly narrowed, apices forming shallow spoons; ventral margin of genitalia almost horizontal; inner surface of valva mostly membranous, a small, lightly sclerotized area near middle; inner valva surface sparsely covered with long setae, a brush of setae below apex; sides of costa roughly parallel, costa curving sharply inward in distal fourth; valva apices forming heavily sclerotized, spatulate processes, their distal margins serrate, apices passing anterior to socii; aedeagus wide in basal fourth, then narrowed, sinuate in distal three-quarters; apex of aedeagus recurved, with a blunt, toothlike process below; vesica somewhat long, narrow, with a small, thumblike distal appendix and a patch of short, spinelike cornuti.

Female (pl. 10): Forewing length  =  15.0 mm. Head: Coloring and structure similar to male except labial palpus shorter and narrower, extending upward to middle of front; antenna ciliate.

Thorax: Similar to male.

Forewing: Similar to male, but slightly broader, veins above more faintly lined with yellow-orange scales.

Hind wing: Similar to male, except fringe above and below conspicuously trimmed with white and scattered brown scales between CuA2 and 2A, rest of fringe charcoal gray; wings somewhat broader than in male.

Abdomen: Dorsum gray-brown, with a few scattered white scales, Tg7 covered with short gray scales and a distal tuft of long gray scales; pleural region a mixture of white and gray scales; venter white.

Terminalia (fig. 86C): Ostium displaced anteriorly, PVP forming a scaleless band running the length of St7, its surface covered with transverse striations; Tg7 large, wide, narrowed to form a waist in anterior third; posterior margin of St7 excavated for its entire length to accommodate displaced ostium, forming a huge, wide, U-shaped excavation; Tg8 membranous; AA long and extremely thin, straight; PA large, robust, dorsoventrally elongate; PP long and thin, curving slightly upward; PVP bearing conspicuous, transverse rugulae, posterolateral angles of PVP crenulate; ostium small, opening dorsoventrally compressed; DB flat, sclerotized; DS arising from a triangular, membranous appendix; CB nearly round; signum small, roughly rectangular, surface smooth; paired pockets on right side of CB deeply rugose, inner surfaces coarsely spinose.

Etymology

This species is named in honor of Gunnar Brehm (Friedrich-Schiller-Universität, Jena, Germany), who kindly made his superb collections of Dioptinae from Ecuador and Costa Rica available for this study. Gunnar captured the holotype and one of the three paratypes of Argentala brehmi.

Distribution

Argentala brehmi is the only species in the genus endemic to the eastern slope of the Andes; other taxa are known exclusively from the western slope in Ecuador and Colombia. Argentala subcoerulea is distributed from northwestern Colombia north into Costa Rica. However, A. subcoerulea too is apparently restricted to the Pacific side of the Cordillera Central. All four known examples of A. brehmi were captured at a single locality (fig. 87)—Estación Cientifica San Francisco, in Zamora-Chinchipe Province, southern Ecuador, within a relatively narrow altitudinal range (1800–2040 m). According to Brehm et al. (2005), this site, which they characterized as a global diversity hotspot, is home to the greatest number of geometrid species recorded anywhere on the planet. Their finding undoubtedly applies to many other groups of arthropods.

Discussion

Besides its eastern distribution, the most interesting aspect of brehmi is the existence of two color forms (pl. 10). One is completely dark chocolate brown to blackish brown on the dorsal surface of the FW and HW. In this form, the only markings are the thin lines of orange-yellow scales along the wing veins. The FW fascia beyond the DC is absent or faint in the two available dark-form specimens. The other phenotype exhibits a conspicuous, white fascia in the FW. Here, the HW is dirty white in the area of the DC, and the HW fascia beyond the DC is white, as in the FW. Interestingly, the ventral wing surfaces of the two forms are almost indistinguishable. Other morphological features, including coloration of the head, thorax, and abdomen, as well as genital structure, are identical in the two forms.

This example of divergent wing-pattern phenotypes highlights two features of Argentala: First, other species in the genus, such as A. mesitana, show variation in the amount of white in the FW and HW, a recurring theme throughout the Dioptini. Second, Argentala is unusual in that patterns on the ventral wing surfaces seem to be highly diagnostic, providing more effective means for separating species than the dorsal patterns.

Holotype

Male (pl. 10). Ecuador: Zamora-Chinchipe: Estación Cientifica San Francisco, 3°58′S, 79°04′W, 18 Oct 1999, LF 19.00–19.30 h, T1-4, 2040 m, leg. G. Brehm. The type is deposited at the AMNH.

Paratypes

Ecuador: Zamora-Chinchipe: 1♂, Estación Cientifica San Francisco, Río San Francisco, 3°58.4′S, 79°4.7′W, 1800 m, 9 Nov 2000, leg. G. Brehm, southern bank forest edge (SMNS; genitalia slide no. JSM-1429); 1♂, 3°58′S, 79°4′W, 1886 m, SG2 (10), 21 Oct 2003, LF III, 19.45–20.15 h, leg. N. Hilt & C. Ramenda (SMNS; genitalia slide no. JSM-1427); 1♀, LF I, 18.45–19.15 h (SMNS; genitalia slide no. JSM-1428).

Other Specimens Examined

None.

Dissected

2 ♂♂, 1♀.

Argentala mesitana (Dognin), new combination

Figure 85E–K; plate 10

Polypoetes mesitana Dognin, 1917: 2.

Type Locality

Colombia, Las Mesitas, “prèz Bogotá”.

Type

Holotype ♀, leg. Apollinaire-Marie, 15 Oct 1916 (USNM type no. 30929).

Momonipta felderi Prout, 1918: 413. Revised synonymy (formerly a synonym of subcoerulea Warren).

Type Locality

Colombia, “Bogotá ?”.

Type

Syntype ♂/♀, ex Felder Collection (BMNH).

Discussion

This taxon, described in Polypoetes by Dognin (1917) and retained there by subsequent authors, belongs in Argentala. This is the only Argentala species in which the HW central area shows a whitish yellow, rather than a white or silvery white, cast (pl. 10). The yellow appears on both wing surfaces. My dissections for A. mesitana included the female USNM holotype, as well as a male and a female, both from Río Dagua, Colombia, on loan from the ZMH. The moth appears to be restricted to the western slope of the Colombian Andes, overlapping in distribution, at least partially, with A. subcaesia and A. subcoerulea.

Prout (1918) described felderi as a subspecies of subcoerulea Warren, and subsequent authors (Hering, 1925; Bryk, 1930) followed that proposal. My examination of wing pattern and body coloration in the felderi type (BMNH) suggests instead that Prout's taxon is more properly associated with A. mesitana. I have therefore placed the name felderi Prout as a synonym of A. mesitana. Additional study, including genital dissection, will be required to determine whether felderi deserves elevation to species status, or whether it is truly conspecific with mesitana. There are slight wing-pattern differences between the two.

In addition to the type, there are three females of A. mesitana at the USNM. No examples exist at the BMNH other than two specimens of felderi—the male and female syntypes, both from the Felder Collection. Altogether, this constitutes the known material of A. mesitana.

Distribution

Colombia (BMNH, USNM, ZMH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1116); ♂, Colombia, occ., Río Dagua, leg. 1895, leg. Kalbr., ZMH (genitalia slide no. JSM-1117); ♀, Colombia, Río Dagua, leg. Kalbr., ZMH (genitalia slide no. JSM-1118).

Argentala subalba (Walker), new combination

Plate 10

Chrysauge subalba Walker, 1854: 374.

Type Locality

“Venezuela”.

Type

Holotype ♂, ex Dyson Collection (BMNH).

Discussion

Prout (1918) first moved this species to the Dioptinae from the Pyralidae, where Walker (1854) originally described it, assigning subalba to Momonipta. Hering (1925) regarded that genus to be synonymous with Stenoplastis, where subalba was most recently placed (Bryk, 1930). I here transfer it to Argentala as a new combination.

In addition to the holotype, Argentala subalba is known from two males, both collected at Rancho Grande, Venezuela (AMNH, USNM). I here associate a female in the USNM collection (JSM-1671) with A. subalba based on similarities of wing size and palpus coloring, as well as the fact that it comes from Venezuela (Barinas). That female differs from A. subalba males in showing a diffuse white FW fascia, as well as a diffuse white HW central area; males exhibit neither. However, as is noted above, such wing-pattern features show intraspecific variation in other Argentala taxa, so unless future discoveries suggest otherwise, I regard this to be a female of A. subalba.

Argentala subalba is the smallest member of Argentala, with a FW length ranging between 12.0 and 14.0 mm, as compared to a range of 14.5–16.0 mm for other Argentala species. It is the only member of the genus endemic to Venezuela.

Distribution

Venezuela (AMNH, BMNH, USNM).

Dissected

♂, Venezuela, Rancho Grande nr. Maracay, 6 Jun 1946, New York Zoological Society, AMNH (genitalia slide no. JSM-1017); ♀, Venezuela, Barinas, La Chimenea, 5 km Sur La Soledad, 1500 m, 28–29 May 1975, leg. R.E. Dietz, USNM (genitalia slide no. JSM-1671).

Argentala subcaesia (Prout), new combination

Figures 84A–C, 84E, 84F, 88; plate 10 [EX]

Momonipta subcaesia Prout, 1918: 413 (replacement name for Scotura subcoerulea Dognin, 1909: 225).

Type Locality

Colombia, Antonio, 2000 m.

Type

Syntype ♂, leg. Fassl, 23 Aug 1908 (USNM type no. 30958).

Discussion

Dognin (1909) described subcoerulea in Scotura, but Prout (1918) moved it to Momonipta. Since subcoerulea Dognin (1909) was preoccupied by Momonipta subcoerulea Warren (1901), Prout (1918: 413) proposed the replacement name subcaesia for Dognin's taxon. Dognin's type of subcoerulea (USNM type no. 30958) is therefore the type of subcaesia Prout. Hering (1925) and Bryk (1930) treated Momonipta as a synonym of Stenoplastis. My research further confirms that subcaesia Prout and subcoerulea Warren are congeneric, and I here place them together in Argentala.

The dorsal wing surfaces of A. subcaesia are extremely similar to those of A. argoptera (pl. 10), the only noticeable difference being a better-defined FW fascia in the former. However, clear-cut differences can be found on the ventral wing surfaces; the FW in subcaesia shows a smaller white basal triangle, and the brown band along the HW outer margin is much wider, especially at the apex. Argentala subcaesia (♂ FW length  =  14.5–15.0 mm) is slightly smaller than A. argoptera (♂ FW length  =  15.0–16.0 mm). Their male genitalia provide easy means for separation. Argentala subcaesia shows a male genital feature unique for the genus; the sclerotized valva apices are simple and strongly acute (fig. 88A), rather than serrate and either spatulate or truncate, as occurs in other species.

It is important to note that the entire BMNH series, identified in their collection as “subcaesia Prout” (San Antonio, western Colombia, 5800 ft, leg. M.G. Palmer) is not conspecific with Dognin's type. Those specimens instead represent an undescribed species related to Polypoetes rubribasis in the Persimilis Group. The only verified examples of Argentala subcaesia I have seen are eight specimens at the USNM (4♂♂, 3♀♀, plus the type)—all collected by Fassl near the turn of the 20th century in western Colombia—plus a single Colombian male in the J. Bolling Sullivan Collection.

The type locality for Argentala subcaesia—Antonio, Colombia—called “San Antonio” on most labels, is particularly famous among Fassl's various collecting sites. It is located west of Cali on the road to Buenaventura, in Valle province. According to Gerardo Lamas (personal commun.), who visited the locale, it is properly called Cerro San Antonio, and is located (03°29′N, 76°38′W) at between 2000 and 2200 meters.

Distribution

Colombia (JBSC, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1010); ♂, Colombia, San Antonio, pré Cali, leg. Fassl, USNM (genitalia slide no. JSM-1387, wing slide no. JSM-1389); ♂, Colombia, JBSC (genitalia slide no. JSM-362); ♀, Colombia, Cali, Alto de las Cruces, 2200 m, Mar 1909, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1388).

Argentala subcoerulea (Warren), new combination

Figure 82A, B, E, F; Figure 83A, B; plate 10 [EX]

Tithraustes subcoerulea Warren, 1901: 444.

Type Locality

Panama, Chiriquí.

Type

Holotype ♂ (BMNH).

Discussion

Warren (1901) described subcoerulea in Tithraustes, but Prout (1918) moved it to Momonipta, regarded by Hering (1925) and Bryk (1930) to be a synonym of Stenoplastis. I here transfer the species from Stenoplastis to Argentala.

Although almost all Argentala species exhibit a white basal dash along the anal fold on the FW ventral surface, A. subcoerulea is the only taxon with a corresponding white dash dorsally (pl. 10). In all specimens I have seen, the semihyaline white central area of the HW is unusually large, extending posteriorly well beyond the margin of the DC almost to the anal fold. The FW of A. subcoerulea can be distinguished from those of other Argentala taxa in that the veins on the dorsal surface are almost completely devoid of yellow-orange scales; in A. subcoerulea the FW is uniformly chocolate brown, with only a short, yellow basal streak immediately behind the costa.

Based on study of genitalia, as well as on wing-pattern similarities, this species is most closely related to A. mesitana. The two taxa have similar male genitalia, but females differ in that the posterior margin of the postvaginal plate in A. subcoerulea exhibits a shallow, wide central depression, whereas the PVP in A. mesitana has a V-shaped mesal notch on the posterior margin (fig. 85F).

Argentala subcoerulea is rare in collections, the largest series (3♂♂, 2♀♀) being at INBio. The only example of this species at the BMNH is the male holotype. Study of available material suggests that A. subcoerulea occurs from Chiriquí, Panama, north to Guanacaste Province in Costa Rica. The species is apparently restricted to the Pacific slope of the Cordillera Central. A single female, collected in northwestern Colombia near the Isthmus of Panama (JSM-1014), shows genitalia distinct from Costa Rican material. That specimen represents an as yet undescribed species.

Distribution

Colombia (AMNH); Panama (BMNH); Costa Rica (AMNH, INBio).

Dissected

♂, Costa Rica, Guanacaste Prov., R. F. Cord. Guanacaste, R. San Lorenzo, 1050 m, Jun 1991, leg. C. Alvarado, INBio (genitalia slide no. JSM-1013); ♂, Costa Rica, Cartago, Paraíso, P. N. Tapantí, Est. Quebrada Segundo, 100 N 100 W Inicio de Sendero Pava, 1400 m, Jul 1999, leg. R. Delgado, de Luz, L_N 194450 560500, #57382, INBio (JSM-1771); ♀, Colombia, Mesopotamia, Antioquia, 5000 ft, AMNH (genitalia slide no. JSM-1014); ♀, Costa Rica, Cartago, Paraíso, P. N. Tapantí, Est. Quebrada Segundo, 100 N 100 W Inicio de Sendero Pava, 1400 m, Jul 1999, leg. R. Delgado, de Luz, L_N 194450 560500, #53757, INBio JSM-1772).

POLYPOETES DRUCE, 1885

Figures 89Figure 90Figure 91Figure 92Figure 93Figure 94Figure 95Figure 96Figure 97Figure 98Figure 99Figure 100Figure 101Figure 102Figure 103Figure 104Figure 105Figure 106Figure 107Figure 108Figure 109Figure 110Figure 111Figure 112Figure 113Figure 114Figure 115Figure 116Figure 117Figure 118Figure 119Figure 120Figure 121Figure 122Figure 123Figure 124Figure 125Figure 126Figure 127Figure 128Figure 129Figure 130Figure 131Figure 132Figure 133134; plates 10–14, 37H–M, 38A–F

Figure 89

Polypoetes heads, lateral view (♂♂). A, P. bifenestra, sp. nov.; B, P. villia; C, P. bifenestra; D, P. persimilis; E, P. fenestrata labial palpus (A and B, S. Goodman illustr.; C–E, illustration by J.S. Miller).

i0003-0090-321-1-1-f089.gif

Figure 90

Morphology of Polypoetes. A, ♂ head of P. nubilosa, lateral view; B, head of P. nubilosa, frontal view; C, head of P. nubilosa, posterior view; D, ♂ head of P. etearchus, lateral view; E, head of P. etearchus, frontal view; F, head of P. etearchus, posterior view; G, P. villia ♂ wings; H, P. villa ♀ wings; I, P. persimilis ♂ wings; J, P. etearchus tegula; K, P. nubilosa tegula; L, P. persimilis tegula (illustration by J.S. Miller).

i0003-0090-321-1-1-f090.gif

Figure 91

Scanning electron micrographs of Polypoetes bifenestra, sp. nov. (♂). A, head in frontal view; B, surface of proboscis; C, close-up of proboscis showing alternating ridges; D, labial palpus in mesal view, distal at left; E, apex of Lp3 showing spinules; F, close-up of Lp3 spinules.

i0003-0090-321-1-1-f091.gif

Figure 92

Scanning electron micrographs of Polypoetes bifenestra, sp. nov., and Polypoetes copiosa, sp. nov. (♂♂). A, antenna of P. bifenestra in ventral view (distal at upper left), showing a single flagellomere; B, sensillum styloconicum at distal portion of flagellomere in P. bifenestra; C, head of P. copiosa, lateral view; D, head of P. copiosa, frontal view; E, surface of P. copiosa eye, showing interfacetal setae; F, sensillum styloconicum at distal portion of proboscis in P. copiosa.

i0003-0090-321-1-1-f092.gif

Figure 93

Scanning electron micrographs of Polypoetes copiosa, sp. nov. A, distal portion of ♂ labial palpus, mesal view (distal at left); B, apex of ♂ labial palpus; C, ♂ antenna, ventral view; D, a single ♂ flagellomere, ventral view; E, ♀ antenna, ventral view; F, ♂ FW in ventral view, showing area beyond apex of DC.

i0003-0090-321-1-1-f093.gif

Figure 94

Scanning electron micrographs of Polypoetes copiosa, sp. nov. (♀), and Polypoetes nubilosa (♂). A, P. copiosa segments A8 and A9 in posterior view, showing lateral horns on A8 pleuron surrounding papillae anales; B, P. copiosa, showing lateral horns on A8 pleuron and setose dorsal process above papillae anales; C, labial palpus of P. nubilosa in lateral view (distal at left); D, labial palpus of P. nubilosa in mesal view (distal at left); E, Lp3 of P. nubilosa in mesal view, showing slitlike opening of vom Rath's organ; F, spinules at apex of Lp3 in P. nubilosa.

i0003-0090-321-1-1-f094.gif

Figure 95

Scanning electron micrographs of Polypoetes nubilosa and Polypoetes rufipuncta (♂♂). A, hornlike spinule at apex of Lp3 in P. nubilosa; B, HW dorsal surface of P. rufipuncta, showing fascia beyond apex of discal cell; C, scales in HW fascia of P. rufipuncta; D, scales in HW fascia of P. rufipuncta; E, scales in HW fascia of P. rufipuncta; F, a single fascia scale in P. rufipuncta.

i0003-0090-321-1-1-f095.gif

Figure 96

Genitalia of Polypoetes albiscripta, holotype male (JSM-1085). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f096.gif

Figure 97

Genitalia of Polypoetes approximans (♂ JSM-788, ♀ JSM-789). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ genitalia; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f097.gif

Figure 98

Female genitalia of Polypoetes augustimacula (holotype, JSM-1088). A, genitalia, lateral view (anterior at left); B, Tg7, dorsal view; C, St7, ventral view.

i0003-0090-321-1-1-f098.gif

Figure 99

Genitalia of Polypoetes bistellata (JSM-1091, 1092). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f099.gif

Figure 100

Genitalia of Polypoetes copiosa, sp. nov. (♂ JSM-1641, ♀ JSM-1642). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♀ genitalia; E, ♂ Tg8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f100.gif

Figure 101

Ecuador, showing the known distributions of Polypoetes copiosa, sp. nov., and P. forficata, sp. nov.

i0003-0090-321-1-1-f101.gif

Figure 102

Genitalia of Polypoetes corneola (holotype ♂ JSM-1557, paratype ♀ JSM-1558). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f102.gif

Figure 103

Peru, showing the known distributions of Polypoetes corneola, sp. nov., and P. tulipa, sp. nov.

i0003-0090-321-1-1-f103.gif

Figure 104

Genitalia of Polypoetes deldon (♂ JSM-402, ♀ JSM-403). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f104.gif

Figure 105

Genitalia of Polypoetes forficata, sp. nov. (♂ JSM-1415, ♀ JSM-488). A, ♂ genitalia; B, ♂ St8; C, ♀ genitalia; D, ♂ Tg8; E, aedeagus; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f105.gif

Figure 106

Genitalia of Polypoetes fuliginosa, holotype ♂ (JSM-1113). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f106.gif

Figure 107

Genitalia of Polypoetes integra, holotype ♂ (JSM-1755). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f107.gif

Figure 108

Genitalia of Polypoetes leuschneri, sp. nov. (♂ JSM-1754, ♀ JSM-1753). A ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♀ genitalia; E, ♂ St8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f108.gif

Figure 109

Ecuador, showing the known distributions of Polypoetes bifenestra, sp. nov., P. crenulata, sp. nov., P. leuschneri, sp. nov., P. sumaco, sp. nov., and P. tinalandia, sp. nov.

i0003-0090-321-1-1-f109.gif

Figure 110

Genitalia of Polypoetes nubilosa (♂ JSM-436, ♀ JSM-437). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f110.gif

Figure 111

Male genitalia of Polypoetes selenia (JSM-493). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f111.gif

Figure 112

Genitalia of Polypoetes semicoerulea, holotype ♂ (JSM-1011). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f112.gif

Figure 113

Genitalia of Polypoetes sublucens (♂ JSM-1093, ♀ JSM-1094). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f113.gif

Figure 114

Male genitalia of Polypoetes tulipa, sp. nov. (holotype, JSM-1559). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f114.gif

Figure 115

Genitalia of Polypoetes villia (♂ JSM-434, ♀ JSM-435). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♀ genitalia; E, ♂ Tg8 (illustration by A. Trabka).

i0003-0090-321-1-1-f115.gif

Figure 116

Genitalia of Polypoetes etearchus (♂ JSM-1011, ♀ JSM-802). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♀ genitalia; E, ♂ St8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f116.gif

Figure 117

Genitalia of Polypoetes tinalandia, sp. nov. (holotype ♂ JSM-1575, ♀ JSM-765). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♀ genitalia; E, ♂ St8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f117.gif

Figure 118

Genitalia of Polypoetes wagneri, sp. nov. (♂ JSM-1573, ♀ JSM-1577). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f118.gif

Figure 119

Costa Rica, showing the known distributions of Polypoetes wagneri, sp. nov., and P. etearchus Druce.

i0003-0090-321-1-1-f119.gif

Figure 120

Genitalia of Polypoetes aniplata (♂ JSM-1555, ♀ JSM-1556). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f120.gif

Figure 121

Genitalia of Polypoetes circumfumata (♂ JSM-667, ♀ JSM-668). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♀ genitalia; E, ♂ St8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f121.gif

Figure 122

Genitalia of Polypoetes colana (♂ JSM-1111, ♀ JSM-1097). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ genitalia; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f122.gif

Figure 123

Paratype ♂ genitalia of Polypoetes crenulata, sp. nov. (JSM-1645). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f123.gif

Figure 124

Genitalia of Polypoetes luteivena (♂ JSM-1424, ♀ JSM-669). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f124.gif

Figure 125

Male genitalia of Polypoetes eximia (JSM-840). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f125.gif

Figure 126

Holotype ♂ genitalia of Polypoetes ineldo (JSM-1003). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f126.gif

Figure 127

Holotype ♂ genitalia of Polypoetes jipiro (JSM-1325). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f127.gif

Figure 128

Paratype ♂ genitalia of Polypoetes oteroi, sp. nov. (JSM-528). A, genitalia; B, aedeagus; C, St8; D, Tg8.

i0003-0090-321-1-1-f128.gif

Figure 129

Genitalia of Polypoetes persimilis (♂ JSM-752, ♀ JSM-890). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f129.gif

Figure 130

Genitalia of Polypoetes villiodes (♂ JSM-474, ♀ JSM-475). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♂ Tg8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f130.gif

Figure 131

Male genitalia of Polypoetes aterrima (JSM-1007). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f131.gif

Figure 132

Genitalia of Polypoetes bifenestra, sp. nov. (♂ JSM-754, ♀ JSM-755). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f132.gif

Figure 133

Genitalia of Polypoetes rubribasis (♂ JSM-524, ♀ JSM-525). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f133.gif

Figure 134

Genitalia of Polypoetes sumaco, sp. nov. (♂ JSM-837, ♀ JSM-838). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f134.gif

Polypoetes Druce, 1885a: 159. Type species: Polypoetes deldon Druce, 1885a (by subsequent designation by Kirby, 1892: 414).

Arina Walker, 1856: 1662. Type species: Arina obtusa Walker, 1856 (by monotypy); a junior homonym of Arina Robineau-Desvoidy (Insecta, Diptera).

Diagnosis

Polypoetes exhibits the widest range of morphological variation of any genus in the Dioptinae. As such, it is difficult to characterize. For example, most Polypoetes males exhibit bipectinate antennae, with long rami (fig. 93C, D). In these taxa, the female antennae are also bipectinate, but the rami are short (fig. 93E). In other Polypoetes males, the pectinations are extremely short, giving the antennae a ciliate or subserrate appearance (fig. 92A). Similarly, the labial palpi can be elongate (figs. 89E, 90A, 90D, 92C), often held folded against the front (fig. 89B), or they can be relatively short (fig. 91D) and porrect (figs. 89A, 89C, 89D). The metathoracic tympanum is universally shallow, but the membrane can be large or small. Wing pattern is also variable (pls. 10–14), but in the vast majority of species the FW colors are drab, ranging from brown to dark brown or black, with various small orange-yellow maculations. The FW veins are almost always lined to varying degrees with yellow or orange scales. The HW is frequently white in the central area, with a dark border around the outer margin. By far the most reliable diagnostic features uniting Polypoetes are found in the male and female genitalia.

This morphological diversity in Polypoetes is reflected by the five species groups recognized here (fig. 3; appendix 2). To identify a given Polypoetes species, it is important to first determine the subgroup to which that taxon belongs. Species-group definitions rely heavily on male and female genital characters, and many species are distinguished on that basis, so dissection will usually be required.

The following list of traits provides a means for diagnosing most Polypoetes species: Labial palpi greatly elongate, or short, thin and porrect; Lp3 bearing microscopic, yellowish spinules, most clearly seen on inner surface (figs. 91D–F, 93A, 93B, 94D–F, 95A); male antennae bipectinate, pectinations long (fig. 93C) or less commonly extremely short (fig. 92A); DC longer than one-half FW length (fig. 90G–I); FW usually with an ovoid, hyaline or semihyaline fascia beyond DC (e.g., P. forficata, pl. 12; P. aniplata, pl. 13); FW brown to blackish brown, veins frequently lined with orange or yellow-orange scales; HW broad, frequently with a round, hyaline or semihyaline fascia beyond DC (fig. 95B), its surface covered with short Y-shaped scales (fig. 95C–F); HW fascia conspicuous in Haruspex, Etearchus, Rubribasis, and Persimilis groups; male abdomen with a deep longitudinal groove along Tg8 (e.g., fig. 96B), visible in intact specimens; male Tg8 often longer than St8 (e.g., fig. 123C, D); female St7 large (e.g., figs. 97G, 98C), wide, scaleless, densely covered with long setae (visible in intact specimens).

Redescription

Male. FW length  =  10.5–20.5 mm. Head (figs. 89, 90A–F, 91, 92, 93A–E, 94C–F, 95A): Labial palpus either greatly elongate, extending upward to antennal base or beyond and folded elbowlike over front, or short and porrect, extending upward to below middle of front (Rubribasis and Persimilis groups); Lp1 short and wide, almost straight; Lp2 long and strongly curved, nearly three times as long as Lp1, sometimes only slightly longer than Lp1 (Persimilis and Rubribasis groups); Lp3 short, conical, apex with yellowish brown, microscopic spinules, these absent in Persimilis Group; front with upwardly pointing scales forming a central depression, lateral scales elongate, forming tufts below antennal bases; eye variable in size, ranging from small and completely surrounded by a scaleless band, to extremely large, bulging outward and completely surrounded by scales; antenna bipectinate, rami ranging from long (Haruspex Group; fig. 93C, D) to short (Etearchus Group, some Rufipuncta Group), occasionally extremely short (fig. 92A), subserrate (Rubribasis and Persimilis groups); vertex covered with long, anteriorly directed scales.

Thorax (fig. 90J–L): Epiphysis usually short, less than one-half tibia length, occasionally over one-half tibia length (e.g., P. nubilosa), but never reaching beyond apex of tibia; tegula relatively small, approximately one-half length of mesoscutum, sometimes slightly longer, distal portion rounded, with a weak sulcus below; metathoracic tympanum in a shallow scaleless depression; tympanal membrane usually small, triangular, facing lateroposteriorly, sometimes moderate in size (e.g., P. sublucens), membrane occasionally large (Persimilis Group).

Forewing (figs. 90G–I; pls. 10–14): Broad, triangular, apex often acute; vein Rs1 arising from radial sector before Rs2–Rs4; arrangement of Rs2–Rs4 variable, usually in the pattern [2+3]+4, often 2+[3+4], rarely a trident; stridulatory organ absent; DC much longer than one-half FW length; veins M3 and CuA1 long stalked; pattern variable, ground color brown to dark blackish brown; an ovoid, hyaline to semihyaline fascia immediately beyond DC, bisected by base of M2; fascia variable in size and shape, its anterior margin usually touching base of Rs1–Rs4, its posterior margin touching fork of M3+CuA1; occasionally with a basal dash (e.g., P. bistellata, P. rubribasis), Persimilis Group with a pair of hyaline basal spots; veins invariably lined with orange or yellow-orange scales; ventral surface similar to dorsal one, often with a white basal dash or streak.

Hind wing (fig. 90G–I; pls. 10–14): Broad, outer margin rounded; ground color often darker than FW; veins M3 and CuA1 long stalked; usually with a white central area of varying size and shape; an ovoid to round, hyaline or semihyaline fascia frequently present beyond DC, its anterior margin touching fork of Rs+M1, its posterior margin touching fork of M3+CuA1.

Abdomen: Relatively short, usually widened in distal third; a deep longitudinal groove along midline of Tg8; Tg8 longer than St8, extending beyond it and curving downward.

Terminalia: Tg8 and St8 together forming a large, jawlike structure enclosing genitalia; all features extremely variable; Tg8 long and narrow (e.g., figs. 104B, 105D), much longer than Tg7 and longer than St8, rarely shorter than St8 (Etearchus Group; figs. 116B, 117B, 118D), almost always with a deep middorsal groove (e.g., fig. 120C); anterior margin of Tg8 bearing a pair of small anterolateral apodemes, posterior margin sclerotized, shape extremely variable, sometimes with posterolateral processes; St8 long, shape often roughly quadrate, sometimes greatly widened posteriorly (Persimilis and Rubribasis groups; e.g., fig. 129B); anterior margin of St8 with a short, wide, truncate apodeme (e.g., fig. 102B), posterior margin extremely variable in shape, almost always sclerotized with a U-shaped or V-shaped mesal excavation, occasionally deeply forked (e.g., P. circumfumata; fig. 121E); socii/uncus complex large, extremely wide at base, frequently concave and hoodlike (e.g., fig. 123A), uncus narrowed to a dull point, sometimes strongly bifid (e.g., P. forficata; fig. 105A; P. oteroi; fig. 128A), often with a group of ventral setae near apex; socii large and robust, extending well beyond uncus dorsally, wide at bases, apices highly variable, often bladelike (Haruspex Group; e.g., fig. 97A) or broadly spatulate and laterally compressed (Rubribasis, Persimilis, and Rufipuncta groups; e.g., figs. 123A, 130A), invariably bearing robust, often spinelike, setae on lateral surfaces; tegumen narrow ventrally, wider above, taller than vinculum, occasionally equal in height (Haruspex Group); vinculum narrow, concave, ventral margin of genitalia broadly U-shaped or V-shaped; valva extremely short, fairly wide, membranous, costa simple, valva apex rounded and simple, inner surface often bearing fine setae in distal half (e.g., fig. 102A); BO usually well developed, occupying most of valva, curled anteriorly, BO rarely small, pleats short and sclerotized (e.g., P. villiodes; fig. 130A); transtillar arms short, widest at base, then tapered toward midline, forming a small, anteriorly directed mesal sclerite; aedeagus highly variable in length and width, varying from short and wide (e.g., P. rubribasis; fig. 133C) to long and thin (e.g., P. Persimilis; fig. 129C), invariably expanded and bell shaped at base, apex almost always with a small, toothlike ventral process; vesica short, slightly wider than aedeagus, much less than one-third length of aedeagus; vesica bearing a group of small, spinelike cornuti distally, cornuti sometimes extremely short, their apices bifid (some Haruspex Group species; e.g., figs. 96C, 102C); vesica occasionally bearing deciduous caltrop cornuti (some Rufipuncta Group species).

Female. FW length  =  12.5–22.0 mm. Head: Labial palpus elongate, but shorter than male, extending upward to above middle of front, apex falling well short of antennal base; Lp1 similar in length and width to male; Lp2 long and thin, one and a half times as long as Lp1; Lp3 short, conical, spinules absent; antennae ciliate, or rarely (e.g., P. nubilosa) bipectinate, rami short.

Thorax: Similar to male.

Forewing: Broader and more triangular than male, slightly longer, wing pattern and colors less intense.

Hind wing: Similar to male, but long and broader, outer margin rounder.

Abdomen: Extremely wide, short, truncate distally.

Terminalia: Tg7 large, wide, sometimes partially scaleless, often with a crestlike ridge along midline; St7 heavily sclerotized (e.g., figs. 98C, 100G), scaleless and covered with long setae, surface variously sculpted; posterior margin of St7 forming a pronounced shelf, frequently with a deep mesal excavation, margin often irregularly fluted, bearing large pronglike processes (e.g., fig. 105G); Tg8 heavily sclerotized, forming a rooflike structure over PA (e.g., fig. 104E), posterior margin often bearing various mesal processes (e.g., fig. 102D); pleuron of A8 sclerotized, posterior margin frequently bearing large, bladelike processes (e.g., fig. 94A); PA moderate in size, surface often spiculate (fig. 94B); AA and PP usually long, thin and straight; region below PA frequently deeply infolded, sclerotized, forming a large internal shelf, its surface densely spiculate (Rufipuncta, Persimilis, and Rubribasis groups; e.g., figs. 121D, 122E, 129D); ostium small, narrow and dorsoventrally compressed, or alternatively forming a large, sclerotized funnel (Haruspex Group; e.g., fig. 99E); DB short, lightly sclerotized, rarely long and heavily sclerotized (e.g., P. Persimilis; fig. 129D); CB large, round or almost so, with a narrow, necklike section at base; signum moderate in size, ovoid (e.g., fig. 104E), concave, surface finely dentate to almost smooth, location variable; often a pair of lightly sclerotized pockets in CB membrane near base, their inner surfaces rugulose or spinose (Haruspex and Etearchus groups; e.g., fig. 102D).

Distribution

Polypoetes occurs from Mexico south to Argentina. In Central America species live on both slopes of the Cordillera Central, and in South America they are well represented on both sides of the Andes. Polypoetes species have been recorded at altitudes ranging from 700 to 4200 meters, but most taxa live in cloud forests within a narrower band—between 1000 and 2000 meters. Interestingly, they rarely occur in lowland forests; not a single Polypoetes has been recorded from the Amazon Basin. Similarly, none has been collected in the Guyana Shield. In Brazil, they inhabit the eastern coastal mountains.

Biology

When I began studying the Dioptinae, nothing was known concerning the biology of Polypoetes. More recently, information has begun to accumulate; there are now documented life histories for nine described Polypoetes species (table 4). Nevertheless, this represents less than 15% of the genus. Furthermore, immatures are known for only three of the five Polypoetes species groups—six records are from the Haruspex Group, two from the Rufipuncta Group, and one from the Rubribasis Group. At the very least, these findings form a core of information upon which we can build.

Polypoetes caterpillars exhibit a characteristic color pattern. A pair of yellow longitudinal stripes run along each side of the body; a subdorsal one and a second lateral one passing through the spiracles. On the dorsum are two to four large purple spots. In most species these occur on A1, A3, A5, and A8 (pl. 38A, B, C, F), but in P. haruspex and P. copiosa, only the A1 and A5 spots appear (pl. 37H). The head in all Polypoetes larvae is light reddish brown to yellowish brown, with a series of black spots. The number and arrangement of these spots varies (compare pls. 37I and 38B), thus providing a potentially useful means for species separation. The A10 prolegs of Polypoetes are typical for Notodontidae, being small and held raised above the substrate (e.g., pl. 38B, F), not used for walking. Greatly elongate stemapods on A10, typical of Erbessa (e.g., pl. 37D) and Phaeochlaena, do not occur. Polypoetes pupae (pls. 37J–M, 38D) are exposed and butterflylike, with contrasting markings. They thus resemble those of most other Dioptini, but differ from the pupae of Josiini (pl. 39I).

The host plant list for Polypoetes spans a broad taxonomic spectrum, with a strong trend toward Malvaceae. Larvae of four Haruspex Group species are associated with Malvaceae (table 4). Two adult specimens at the USNM, representing an undescribed species related to P. villia, bear labels stating that they were collected as larvae on “follaje de zapote”, apparently in the state of Cundinamarca, Colombia. According to Gentry (1993), “zapote” refers to plants in the genus Quararibea (Malvaceae). If that genus becomes a verified host, it would be a first for the Dioptinae. Polypoetes haruspex and P. copiosa, sister species, have been recorded from Hackberry (Celtis iguanaea; Celtidaceae). The remaining Haruspex Group host, Psammisia, is in the Ericaceae. Together, these plant families show no obvious phylogenetic affinities (Soltis et al., 2005).

In the Rufipuncta Group, P. circumfumata and P. luteivena were reared in western Venezuela (table 4) on the plant genus Paullinia (Sapindaceae). Paullinia, containing approximately 180 species, includes mostly tropical lianas, often with pinnate leaves (Gentry, 1993). The foliage is rich in alkaloids, and provides the stimulating beverage “guarana” of Amazonian Brazil (Heywood, 1979). Extract of Paullinia is listed as an ingredient in the popular Brazilian soda drink “Guaraná Antarctica”.

The most recent life history discovery for Polypoetes is for P. bifenestra, sp. nov. (pl. 14), from eastern Ecuador—the first record for the Rubribasis Group. In June 2007, larvae of P. bifenestra (pl. 37I) were found by Grant Gentry at Yanayacu Biological Station, feeding on Alchornea grandis (Euphorbiaceae), a novel host-plant family for the Dioptinae. As we continue piecing together the phylogenetic history of host use in Polypoetes, it will be important to find life histories for species in the remaining subgroups—the Etearchus and Persimilis groups.

Discussion

Druce (1885a) erected Polypoetes to include nine Central American species, all of which he described at that time. He characterized the genus by having the labial palpi “long, slender, and curved back on to the head” (1885a: 159). Strangely, such palpi occur in only four of the nine species on his list, and it is these—deldon, eriphus, etearchus, and haruspex—that remain in Polypoetes today. The other five can now be found in Tithraustes, Nebulosa, or Chrysoglossa. By the time of Bryk (1930), 35 years later, Polypoetes contained 44 species. In this paper, the genus is expanded even more. After first removing five species that had been incorrectly placed there by previous authors, I added the members of two important clades—the Rubribasis and Persimilis groups—both of which had previously been subsumed within Stenoplastis. Two species formerly in Xenomigia were then moved to the Persimilis Group. Finally, I here describe 11 Polypoetes as new. This brings the species total to 63, making it the largest genus in the Dioptinae (appendix 2).

Our understanding of Polypoetes taxonomy is in its infancy. Thankfully, the genus exhibits extensive morphological variation, outlined above, and showcased in the species treatments below. Prior to a species-level revision, several problems must be addressed. First, the identities of some species remain unresolved; I have made considerable headway along these lines, having dissected more than 40 Polypoetes types during the course of this research. Second, a preponderance of species occur in the eastern Andes of Peru and Bolivia, areas for which sampling is currently inadequate. Most species of Polypoetes are known from only one or two specimens, the majority of which were collected near the turn of the 20th century. Often only a single sex is available for study. Additional collecting will be an important component of future research.

Many Polypoetes species await description. Even though 11 are described in the current paper, I estimate that, among existing museum material, over 25 additional species of Polypoetes are undescribed. Every collecting trip produces more new taxa. Once a revision has been done, the final species count for Polypoetes will undoubtedly approach 100—roughly a fifth of the dioptine fauna.

My cladistic analysis of 12 Polypoetes exemplars reveals a basic dichotomy within the genus (fig. 3). The taxa divide into two clades, equal in size. One is comprised of the Haruspex Group (nubilosa through copiosa in fig. 3), and the other contains the remaining subgroups—the Etearchus, Rufipuncta, Persimilis, and Rubribasis groups. Synapomorphies supporting this dichotomy are listed in appendix 4. Again, it is important to stress the morphological and taxonomic complexity of Polypoetes. It is hoped that study of character systems from immature stages and DNA will shed more light on these clades.

The Polypoetes species groups proposed here are largely defined on the basis of characters from male and female genitalia. These traits are therefore heavily relied upon in the key below. A few genital traits, such as the configuration of female St7, can be observed in intact specimens, whereas the majority require dissections.

KEY TO POLYPOETES SPECIES GROUPS

1. Labial palpus elongate (figs. 89B, 90A, 90D, 92C), with an elbowlike joint between Lp1 and Lp2, palpus in male extending upward to antennal bases or beyond; male antenna bipectinate (fig. 93C, D), rami usually long, sometimes short; FW veins Rs2–Rs4 either forming a trident (fig. 90H), or in the arrangement [2+3]+4 (fig. 90G)2

Labial palpus relatively short (fig. 89A, C, D), porrect, extending upward to above clypeus but below middle of front; male antenna lacking rami (fig. 92A); FW veins Rs2–Rs4 in the arrangement 2+[3+4] (fig. 90I), rarely forming a trident4

2. Eye small to moderately large (fig. 90A–C), never bulging below ventral margin of head; FW frequently with an orange or white subapical spot (e.g., pls. 12, 13); FW veins Rs2–Rs4 frequently forming a trident, less commonly in the arrangement [2+3]+4; male Tg8 longer than St8 (e.g., fig. 97B, C); female PVP never forming a scoop-shaped structure below PA3

Eye extremely large (fig. 90D), bulging below ventrolateral margin of head (fig. 90E, F); FW never with a subapical spot; FW veins Rs2–Rs4 in the pattern [2+3]+4; male St8 longer than Tg8 (fig. 116B, E; fig. 117B, E; fig. 118B, D); female PVP forming a large, scoop-shaped structure below PA (figs. 116D, 117D, 118E)Etearchus Group

3. Female ostium forming a large, funnel-shaped structure (e.g., figs. 97E, 104E); posterior margins of female A8 pleuron and tergum strongly emarginate, bearing large spinelike or bladelike processes (e.g., fig. 102D); male socii erect, straight or roughly so, their apices acute, often terminating in a pair of small, pointed processes (e.g., figs. 105A, 106A); male vesica never with deciduous cornuti; central area of HW brown or white (pls. 10, 11, 12), rarely yellow (Central and South America)Haruspex Group

Female ostium not forming a funnel, usually dorsoventrally compressed (e.g., figs. 120E, 121D); posterior margins of female A8 not bearing large processes; male socii strongly curved, their apices laterally compressed, often forming large paddle-shaped structures (e.g., figs. 120A, 123A), never acute; male vesica frequently with small, deciduous caltrop cornuti (figs. 120E); central area of HW often light lemon yellow (pl. 13) (South America)Rufipuncta Group

4. Eye large and bulging, gena obscured; male Lp3 short, ovoid (fig. 89D), lacking distal spinules; uncus wide, roughly quadrate (e.g., figs. 125A, 130A), not narrowing distally, apex broadly truncate (e.g., fig. 126A) or bifid (figs. 128A, 129A); female Tg8 forming a small, tentlike structure above PA (e.g., figs. 129D); FW length  =  15.0–22.0 mmPersimilis Group

Eye small (fig. 89A, C), gena broadly scaleless; male Lp3 somewhat elongate (fig. 89C), conical, with long, golden brown distal spinules (fig. 91D–F); uncus wide at base, abruptly narrowing to a blunt point at apex (figs. 131AFigure 132133A), with a set of coarse, ventral setae; female Tg8 forming a large, rooflike structure over PA (figs. 132E, 133E, 134D); FW length  =  10.5–15.5 mmRubribasis Group

1. HARUSPEX GROUP

The Haruspex Group, containing half the described species in Polypoetes, shows a fairly wide range of wing patterns (pls. 10–12), but is united by adult morphology. The Haruspex Group is broadly distributed. Species occur in Central America, from Mexico south to Panama, as well as in South America from Venezuela and Colombia south to Bolivia, Argentina, and southern Brazil. Some members of this clade occur at relatively high altitudes (up to 3000 m for P. fuliginosa; over 3000 m for P. vidua). Wing-pattern characters are often problematic for use in species identifications, but most taxa can be distinguished by their genitalia.

The Haruspex Group is characterized by the following characters: eye moderate to large in size (fig. 89B); male antenna bipectinate, rami fairly long (fig. 93C, D); male uncus extremely wide at base (e.g., fig. 100A), narrowing toward apex, apex simple (e.g., fig. 97A) or bifid (e.g., fig. 96A); socii elongate, upright (e.g., fig. 100A), abruptly narrowing distally, usually with a ventral flange near apex; aedeagus moderate in length, often with a hook-shaped ventral process at apex (e.g., fig. 96C); vesica bearing tiny, thornlike cornuti (e.g., fig. 108C); female St7 with long posterolateral prongs (fig. 100G); female A8 with bladelike or hornlike processes along posterior margin (fig. 94A, B); ostium forming a large, sclerotized funnel (fig. 98A); some species with a sclerotized dorsal ridge between papillae anales (fig. 94B). In some members of the Haruspex Group, the distal scales of each abdominal segment are lighter in color, giving the abdomen a ringed appearance.

KEY TO HARUSPEX GROUP SPECIES

1. Forewing with a small, subapical spot at base of veins Rs2–Rs42

FW without a subapical spot15

2. Subapical FW spot white to creamy white (pls. 11, 12)3

Subapical FW spot orange-yellow (pls. 11, 12)6

3. Forewing with various creamy white markings in basal third4

Basal third of FW gray-brown (pl. 12), concolorous with rest of wing; FW veins thinly lined with creamy white; HW with a single, diffuse, ovoid white fascia beyond DC, rest of HW gray-brown (SE Peru)albiscripta Dognin

4. Forewing with a long white basal streak anterior to anal fold (pl. 12), no additional white markings near base; FW veins gray-brown, concolorous with rest of wing; white central area of HW elongate, somewhat narrow (Argentina)bistellata Dognin

Basal third of FW with more than one white maculation; FW veins lined with light orange-yellow scales; white area of HW round or wide, not elongate5

5. Forewing with a long white basal streak anterior to anal fold (pl. 12), a diffuse white patch within DC, and a tiny white streak posterior to anal fold; white FW fascia a large transverse oval; FW veins M1 and M2 thinly lined with orange-yellow near outer margin; HW with a small, round, white fascia beyond DC, rest of wing gray-brown (SE Peru, N Bolivia)picaria Warren

FW with a small, diffuse, white transverse band near base (pl. 11), extending from anterior margin of DC to 1A+2A, base of anal fold and 1A+2A also white; white FW fascia a narrow transverse band; FW veins M1 and M2 terminating in white, arrow-shaped dashes near outer margin; HW white from base to beyond DC (Colombia S to SE Ecuador)trimacula (Warren)

6. Forewing fascia (dorsal surface) with a sparse covering of brown or blackish-brown scales, fascia appearing diffuse10

FW fascia (dorsal surface) covered with white scales, giving its surface a cellophane-like appearance, fascia strongly defined7

7. Hind wing mostly white, including base and anal margin, except for a wide brown band along outer margin; FW length  =  11.5–14.0 mm9

HW mostly dark brown to blackish gray, including base and anal margin, white area somewhat confined; FW length  =  13.5–14.0 mm8

8. Forewing with a creamy white basal dash anterior to anal fold (pl. 12); white area of HW relatively large, extending toward base; outer portions of FW veins widely lined with ochreous orange; FW length  =  14.0 mmvidua Warren

FW without a white basal dash (pl. 12); white area of HW confined to a round spot distal to DC; outer portions of FW veins thinly lined with orange-yellow; FW length  =  13.5 mmtulipa, sp. nov.

9. Forewing and HW ground color dark blackish brown (pl. 12); FW triangular, outer margin almost straight; HW with a glassy oval within white area, located immediately beyond DC; male genitalia with apex of uncus strongly bifid (fig. 105A); female with a wide, horizontal horn (fig. 105C) arising from posterior margin of A8 pleuron (E Ecuador)forficata, sp. nov.

FW and HW ground color chocolate brown (pl. 11); FW somewhat elongate, outer margin strongly convex; HW without a glassy oval within white area; male genitalia with apex of uncus simple, blunt; female with a long, narrow, upright horn arising from posterior margin of A8 pleuron (N Venezuela)fenestrata Hering

10. Labial palpus segment 1 orange-yellow; FW fascia semihyaline; HW anal margin broadly dark brown to charcoal gray, white area confined to a small spot beyond DC; wing relatively long; FW length  =  13.0–15.5 mm11

Lp1 white; FW fascia opaque, dorsal surface densely covered with brown to blackish-brown scales; HW anal margin white or light yellow; wings short; FW length  =  11.0–14.0 mm12

11. Forewing and HW ground color dark charcoal gray to blackish brown; dorsal surface of FW fascia lightly dusted with blackish-brown scales (pl. 12); HW anal margin silvery white on ventral surface; forked apex of uncus small and delicate (fig. 102A); FW length  =  15.0–15.5 mm (SE Peru)corneola, sp. nov.

FW and HW ground color gray-brown to chocolate brown; dorsal surface of FW fascia covered with white scales (pl. 12); HW anal margin dark brown on ventral surface; forked apex of uncus robust; FW length  =  13.0–14.0 mmintegra Hering

12. Hind wing central area white; HW with tiny, inconspicuous gray-brown streaks at base, marginal band moderately wide13

HW central area light creamy yellow (pl. 11); HW with conspicuous brown streaks at base, anterior margin mostly brown, marginal band extremely wide (E Brazil)obtusa (Walker)/selenia (C. and R. Felder)

13. Foliate posterolateral angles of male St8 rugose, rounded14

Foliate posterolateral angles of male St8 bearing a small, spinelike process (N Venezuela)nigribasalis Hering

14. Large posterolateral processes on female St7 straight or slightly curved (figs. 94A, 94B, 100D); paired, spiculate internal pockets on female CB separate; wing ground color (pl. 11) blackish brown (W Ecuador)copiosa, sp. nov.

Posterolateral processes on female St7 hook shaped; spiculate internal pockets on female CB conjoined; wing color (pl. 11) dark chocolate brown (Costa Rica S to NW Panama)haruspex Druce

15 (1). Forewing fascia elongate, obliquely angled16

FW fascia indistinct or short, not obliquely angled19

16. Forewing dorsal surface with a conspicuous, creamy white basal streak, located along anal fold, streak extending from base to fork of CuA2 or beyond17

FW dorsal surface uniformly dark gray-brown (pl. 12), no markings except for fascia, without a basal streak; HW gray-brown with a faint fascia beyond DC; FW length  =  11.0 mm (SE Peru)mara Hering

17. Hind-wing anal margin thinly or broadly lined with dark brown; some veins within white HW central area lined with dark brown scales; outer margin of FW fascia indented with dark brown along M218

HW anal margin completely white (pl. 12); veins within white HW central area concolorous, not lined with dark brown scales; outer margin of white FW fascia not indented with dark brown along M2; FW length  =  11.5 mm (Bolivia)exclamationis Hering

18. Hind wing mostly gray-brown (pl. 12), dirty creamy white in basal third, a diffuse, creamy white fascia beyond DC; FW veins faintly lined with light orange-yellow scales; uncus terminating in a large, lobate process, its apex indented; socii slightly spatulate, without a second process below apex; FW length  =  12.0–12.5 mm (N Bolivia, SE Peru)fuliginosa Dognin

HW mostly creamy white (pl. 12), cubitus and 2A lined with brown scales; FW veins brown, concolorous with wing; uncus terminating in a small, truncate process; socii acute, with a small spinose process below apex; FW length  =  10.5 mm (E Peru)marginifer Dyar

19. Hind-wing dorsal surface with a large white central area, white extending basally into DC; HW outer margin brown to dark brown24

HW dorsal surface completely brown or almost so, no white in DC20

20. Hind-wing dorsal surface uniformly dark brown, without a fascia beyond DC; FW ground color slightly lighter than HW, not strongly contrasting21

HW dorsal surface with a diffuse, semihyaline fascia immediately beyond DC (pl. 10); FW also with a diffuse fascia beyond DC; FW ground color olive brown, HW contrasting dark brown; FW length  =  12.0–13.0 mm (Guatemala)deldon Druce

21. Forewing without a fascia beyond DC; FW uniformly dark olive brown, veins lined with ochreous orange; HW dark brown23

FW with a fascia beyond DC, especially visible on ventral surface22

22. Forewing with a diffuse, poorly delineated fascia beyond DC (pl. 11); FW ground color dark chocolate brown, veins lined with orange-yellow scales; HW ventral surface mostly silvery white except for a wide, dark brown marginal band; FW length  =  13.0–15.0 mm (W Ecuador)leuschneri, sp. nov.

FW with a prominent, semihyaline fascia beyond DC, vein M2 black as it passes through (pl. 11); FW ground color blackish brown, veins mostly concolorous, with a few scattered yellow scales near outer margin; HW ventral surface silvery white along anal margin; FW length  =  13.0 mm (E Colombia)semicoerulea Dognin

23. Hind-wing ventral surface mostly silvery white except for a wide, dark brown marginal band from apex to CuA2 (pl. 11); FW ventral surface white in basal third, completely dark brown in distal two-thirds; FW apex acutely angled; FW length  =  14.0–15.0 mm (E Colombia)sublucens Dognin

HW ventral surface dark brown except for a diffuse patch of white scales along anterior margin near base (pl. 11); FW ventral surface dark brown (pl. 11), a small subapical patch of creamy white scales at base of Rs2–Rs4; FW apex not acutely angled; FW length  =  9.0–12.0 mm (E Peru)tenebrosa Warren

24. Forewing dorsal surface evenly dark brown, basal third without markings; a faint fascia beyond DC, fascia rarely well defined; HW outer margin broadly banded with blackish brown25

FW dorsal surface light gray-brown to olive brown, basal third with diffuse, whitish streaks in DC and along anal fold; FW fascia white; HW outer margin broadly banded with light gray to charcoal gray28

25. Ventral surface of HW silvery white, with a wide, dark brown marginal band, widest at apex, narrowing abruptly before anal fold; HW dorsal surface broadly gray-brown along anal margin (pl. 10); FW length  =  11.5–15.5 mm26

Ventral surface of HW white, with an extremely wide dark brown marginal band, widest at apex, evenly tapered to tornus; HW dorsal surface with a narrow brown band along anal margin; FW length  =  11.5–12.5 mm27

26. Eye extremely large, bulging below ventrolateral margin of head (frontal view), gena completely obscured; apex of uncus narrowing to a blunt point (W Colombia)subcandidata Dognin

Eye moderately large, not bulging below ventrolateral margin of head (frontal view), gena comprising a narrow scaleless band below eye; apex of uncus truncate (Costa Rica and Panama)approximans (Warren)

27. Forewing fascia large (pl. 11), diffuse, dorsal surface sparsely covered with brown scales; HW anal margin narrowly banded with a mix of brown and white scales (Argentina)suffumosa Dognin

FW fascia small and round, well defined (pl. 11), dorsal surface white; HW anal margin broadly banded with brown scales (Bolivia)prodromus Hering

28. Dorsum of thorax with a pair of creamy white longitudinal lines on either side of midline; FW without a diffuse submarginal line29

Dorsum of thorax with a pair of orange longitudinal lines on either side of midline; FW with a diffuse, light brown submarginal line30

29. Forewing light gray-brown to olive gray (pl. 11), veins lined with creamy white to yellowish white scales, fascia diffuse; HW mostly white, outer margin with a wide, gray-brown band from apex to tornus, anal margin white; FW length  =  12.5–16.5 mm (W Ecuador)nubilosa (Warren)

FW chocolate brown, veins lined with light orange scales, fascia large, white (pl. 11); HW mostly gray-brown, anal margin broadly gray-brown, white central area narrow, a large, round semihyaline fascia immediately beyond DC; FW length  =  21.0 mm (Colombia)augustimacula (Dognin)

30. Forewing veins orange to ochreous orange (pl. 11); FW with a small, diffuse, transverse whitish band in basal third between cubitus and 1A+2A; posterior margin of male St8 heavily sclerotized, bifid (fig. 115C); female signum large and smooth, triangular (fig. 115D); FW length  =  16.5–19.5 mm (Costa Rica and Panama)villia Druce

FW veins light yellowish brown to tan (pl. 11); FW base with a faint, whitish dash along anal fold, without a small transverse band; posterior margin of male St8 not sclerotized, simple, bearing long spinelike setae; signum small and dentate, ovoid; FW length  =  13.0–16.5 mm (Mexico S to Nicaragua)eriphus Druce

SPECIES INCLUDED AND MATERIAL EXAMINED

Polypoetes albiscripta Dognin

Figure 96; plate 12

Polypoetes albiscripta Dognin, 1903: 271.

Type Locality

“Perou”.

Type

Syntype ♂ (USNM type no. 30921).

Discussion

Polypoetes albiscripta belongs in a subclade of the Haruspex Group along with 11 other Andean species. In all of these, the male uncus bears a bifid apical process (table 5; fig. 96A), and the vesica of the aedeagus is covered with extremely short, minutely forked cornuti, a trait unique in the Dioptinae. These taxa occur at mid to high elevations (1000–3000 m). Genital characters further demonstrate the existence of a three-taxon clade comprising P. albiscripta, P. corneola, and P. integra, a relationship outlined during discussion of the latter.

Table 5

Species of the Haruspex Group (Polypoetes) bearing a bifid process at the apex of the male uncus

i0003-0090-321-1-1-t05.gif

All verified specimens of P. albiscripta have been collected in the vicinity of Cuzco, Peru, at an elevation of approximately 3000 meters. A USNM series (2♂♂, 2♀♀) captured at Machu Picchu by Gates Clarke (JSM-1086) exhibits a whiter HW central area than the type, but such pattern variation occurs throughout Polypoetes.

Distribution

Peru (BMNH, USNM, ZMH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1085); ♂, Peru, Cuzco, 3000 m, BMNH (genitalia slide no. JSM-867); ♀, Cuzco, Machu Picchu, 2885 m, 5 Feb 1959, leg. J.F.G. Clarke, USNM (genitalia slide no. JSM-1086).

Polypoetes approximans (Warren)

Figure 97; plates 10, 37K, 38A

Tithraustes approximans Warren, 1901: 443–444.

Type Locality

Panama, Chiriquí.

Type

Holotype ♀ (BMNH).

Discussion

Establishing the identity of P. approximans has been problematic. The female type exhibits genitalia (JSM-1142) precisely the same as those of Costa Rican females from Puntarenas and Orosí (JSM-789, 850; fig. 97E–G). Two INBio males (JSM-787, 788; fig. 97A–D) are apparently conspecific; their wing pattern and body color match the approximans type exactly. I now feel fairly confident that this material represents P. approximans. A problem arises in determining the status of two species with which it has consistently been confused in collections—satanas Hering and subcandidata Dognin.

After numerous dissections, I conclude the following: (1) P. approximans is restricted to Central America, occurring from Panama north to Costa Rica; (2) P. subcandidata, a valid species and possibly the sister taxon to P. approximans, is endemic to Colombia; (3) satanas Hering is a junior synonym of subcandidata. Although in wing pattern and genitalia, P. approximans and P. subcandidata are extremely similar, the two can be separated by eye size. In P. approximans the eye is moderately large and the gena is narrowly scaleless below. In P. subcandidata, on the other hand, the eye is extremely large, bulging outward so that the gena is completely obscured.

Polypoetes sublucens (pl. 10), used as an exemplar in the current study, is also closely related to these; its genitalia (fig. 113) are similar in all respects to those of P. approximans (fig. 97) and P. subcandidata. Its wing pattern differs by having the FW dorsal surface completely dark, without a fascia, and the HW dorsal surface dark, without a white central area.

The immature stages of Polypoetes approximans have been documented as part of the ongoing ACG caterpillar inventory in Costa Rica (Janzen and Hallwachs, 2008). The caterpillars show prominent blackish dorsal spots on abdominal segments A1, A3, A5, and A8 (pl. 38A), and the pupae are boldly patterned (pl. 37K), similar to other Polypoetes. The larvae feed on Pachira aquatica, in the Malvaceae (table 4).

Distribution

Panama (BMNH, ZMH); Costa Rica (BMNH, INBio).

Dissected

Holotype ♀ (genitalia slide no. JSM-1142); ♂, Costa Rica, Alajuela, Finca San Gabriel, 16 km E Quebrada Grande, 630 m, 12 Mar 1983, leg. D.H. Janzen and W. Hallwachs, INBio (genitalia slide no. JSM-787); ♂, Costa Rica, Guanacaste, 4 km E Casetilla, Rincón National Park, 750 m, 11 Apr 1983, leg. D.H. Janzen and W. Hallwachs, INBio (genitalia slide no. JSM-788); ♀, Costa Rica, Puntarenas, Estación La Casona, Monteverde, A.C. Arenal, 1520 m, Dec 1993, leg. N.G. Obando, L N 253250_449700, #2605, INBio (genitalia slide no. JSM-789); ♀, Costa Rica, Orosí, 1200 m, leg. Fassl, BMNH (genitalia slide no. JSM-850).

Polypoetes augustimacula (Dognin), new combination

Figure 98; plate 11

Phaeochlaena augustimacula Dognin, 1902: 475.

Type Locality

Colombia, Popayán.

Type

Holotype ♀ (USNM type no. 30976).

Discussion

This unusual species was originally described in Phaeochlaena (Dognin, 1902), but was later moved to Tithraustes (Prout, 1918), where it has remained ever since (Bryk, 1930). In fact, augustimacula belongs in Polypoetes as a new combination. The moth is striking in being one of the largest Polypoetes species; the female type, the only known specimen of P. augustimacula (pl. 11), has a FW length of 22.0 mm. Its genitalia—with a large, funnel-shaped ostium and prominent, hornlike lateral processes on the A8 pleuron (fig. 98)—indicate membership in the Haruspex Group.

Distribution

Colombia (USNM).

Dissected

Holotype ♀ (genitalia slide no. JSM-1088).

Polypoetes bistellata Dognin

Figure 99; plate 12 [EX]

Polypoetes bistellata Dognin, 1902: 476.

Type Locality

Argentina, Tucumán.

Type

Holotype ♂ (USNM type no. 30922).

Discussion

Polypoetes bistellata is well represented in the collections of the Fundación Miguel Lillo and the USNM, but is known from merely a handful of specimens elsewhere. All the material I have seen was collected in the vicinity of Tucumán. Males of P. bistellata exhibit a forked uncus (fig. 99A), characteristic of the Haruspex Group subclade to which P. forficata belongs (table 5; fig. 105A). Females possess a large, funnel-shaped ostium (fig. 99E).

Distribution

Argentina (BMNH, FML, NMW, USNM, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1114); ♂, Argentina, Tucumán, R. Schreiter Coll., USNM (genitalia slide no. JSM-1091); ♀, Argentina, Tucumán, R. Schreiter Coll., USNM (genitalia slide no. JSM-1092).

Polypoetes copiosa, new species

Figures 92C–F, 93, 94A, 94B, 100, 101, 357, 359; plate 11 [EX]

Diagnosis

The habitus of this species is unremarkable (pl. 11). Polypoetes showing a similar wing pattern—a brown FW with light-colored veins, a light brown basal third, and a small orange-yellow subapical spot, as well as a HW with a white to whitish yellow central area and a blackish-brown outer margin—occur in two different species groups. For example, compare the wings of P. copiosa with those of P. forficata (pl. 12), another member of the Haruspex Group, as well as with P. colana (pl. 13) in the Rufipuncta Group. Similarities abound. The wings of P. copiosa are barely distinguishable from those of P. haruspex (pl. 11); genital morphology must be examined to separate the two species.

The long, divergent socii of the male genitalia (fig. 100A), and the funnel-shaped female ostium (fig. 100D), place P. copiosa firmly within the Haruspex Group. Among other traits, the long pleural prong on female A8 (fig. 94A, 94B, 100D), as well as the configuration of male Tg8 (fig. 100E), confirms that this species belongs in a close-knit clade with five Haruspex Group species—fenestrata, haruspex, nigribasalis, obtusa, and selenia. At this level, finding features to distinguish P. copiosa from its relatives becomes problematic. One must compare the size and shape of various prongs and processes in females, as well the shape of the distal margin of male Tg8.

Description

Male (pl. 11). Forewing length  =  11.0–12.0 mm. Head (fig. 92C–F, 93A–D): Labial palus greatly elongate, folded elbowlike over front, apex extending posteriorly to well beyond antennal base; Lp1 short, curving slightly upward, creamy white, with a loose fringe of longer scales below; Lp2 extremely long, over two and a half times as long as Lp1, curving gradually upward, lateral surface covered with charcoal-gray to gray-brown scales, dorsal and ventral surfaces creamy white; apex of Lp2 bearing a tuft of long, buff to cream-colored scales on dorsal surface, this tuft partially obscuring Lp3; Lp3 short and conical, light gray, apex sclerotized, acute; mesal surfaces of Lp2 and Lp3 mostly scaleless, bearing thin distal spinules; central portion of front covered with charcoal-gray, upwardly pointing scales, lateral margins of front bearing long, creamy white, upwardly pointing scales, these converging between antennal bases to form a pair of short triangular tufts; occiput charcoal gray in upper third, creamy white in ventral two-thirds; eye small, completely surrounded by a scaleless band, gena broadly scaleless; eye with a covering of short setae; vertex covered with long, charcoal-gray to blackish-gray scales, a few white scales between antennal bases, areas behind antennal bases creamy white; antenna bipectinate, rami relatively long; scape charcoal gray, creamy white on ventral surface; dorsum of antennal shaft covered with appressed, glossy gray scales.

Thorax: Legs, including spurs, white to creamy white, outer surfaces gray-brown; pleuron covered with long, bifid white and hairlike cream-colored scales, meso-eucoxa gray; patagium covered with long, erect white scales, a group of blackish gray scales near midline; tegula relatively long, ventral angle bearing long white scales, upper portion covered with erect, light orange scales becoming lighter distally, lateral margins of tegula trimmed with hairlike, gray to charcoal-gray scales; dorsum charcoal gray to blackish gray, with a pair of creamy white longitudinal bands on either side of midline; tympanum small, cavity shallow, barely concave; tympanal membrane small, ovoid, facing laterally.

Forewing: (Dorsal) Ground color dark gray-brown to black, lighter and more sparsely scaled in basal third (pl. 11); veins, including anal fold but excluding costa, lined with cream-colored scales in basal third, lined with light orange to orange scales in distal two-thirds; a diffuse, sparsely scaled, ovoid fascia located immediately beyond distal margin of DC, its anterior margin touching M1, its posterior margin touching fork of M3+CuA1; an irregular, roughly ovoid, light orange subapical spot formed near fork of Rs3+Rs4, its anterior margin touching Rs2, its posterior margin extending well beyond Rs4. (Ventral) Ground color evenly charcoal gray, veins not lined with lighter scales; basal third from subcosta to anal fold white to grayish white; fascia beyond DC covered with white scales; orange subapical spot slightly larger than on dorsal surface.

Hind wing: (Dorsal) Intense white to creamy white, a few gray scales near base (pl. 11); outer margin with a wide, blackish gray to black band, band slightly narrower near M2; anterior margin light gray; anal margin white from base to black outer band. (Ventral) Similar to dorsal surface, except anterior margin creamy white to buff colored.

Abdomen: Dorsum glossy dark gray-brown to charcoal gray, posterior margin of terga 2–7 sparsely trimmed with long, creamy white scales, dorsolateral regions of abdominal base bearing a mixture of white and gray scales; pleuron buff colored; venter creamy white; A8 almost entirely glossy gray-brown except for a longitudinal ventral band of white.

Terminalia (fig. 100A–C, E): Tg8 almost 3 times as long as Tg7, extremely narrow, slightly wider anteriorly, anterior margin bearing small lateral apodemes, distal half with a middorsal groove; posterior margin of Tg8 heavily sclerotized, posterolateral angles expanded to form an elaborate, fluted structure; St8 long, slightly shorter than Tg8, roughly quadrate, much wider than Tg8 but narrower than St7; anterior margin of St8 convex, with a tonguelike mesal fold, lateral margins parallel, posterior margin heavily sclerotized, with a wide U-shaped mesal excavation bearing a submarginal ridge, posterolateral angles of St8 deeply notched, forming spoon-shaped structures, their surfaces slightly rugose; socii/uncus complex extremely wide, robust, with a broad attachment to tegumen; uncus broadly expanded at base, narrowing distally, apex truncate, bearing a few coarse setae on dorsum; socii extremely wide at bases, abruptly tapered distally, apices slightly expanded, emarginate, forming small, acute C-shaped processes, their lateral surfaces bearing coarse, spinelike setae; tegumen short and wide, slightly shorter than vinculum; arms of vinculum short, narrow, concave, the two together forming a broad U-shaped ventral structure; saccus comprising a wide, lightly melanized, horseshoe-shaped sclerite, folded upward over valva bases; valva short and wide, mostly membranous; BO large, with numerous pleats, comprising over one-half of valva, lateral margins curled anteriorly; inner surface of valva bearing a membranous ridge, extending from transtillar arms to near apex; costa short, moderately wide at base, tapered distally, upper margin gently convex, costa falling short of valva apex; apex membranous, broadly lobate, bearing fine setae on inner surface; inner surface of valva immediately below apex rugulose; valva bases wide; juxta absent; transtillar arms narrow, meeting at midline to form a narrow, elongate sclerite above aedeagus; aedeagus relatively long and narrow, greatly expanded in basal third with opening of DES oriented dorsally; a tiny, nipple-shaped dorsolateral process near apex, apex itself with a small, hook-shaped ventral process; vesica moderately large, opening dorsally, bearing numerous, evenly spaced, short spinelike cornuti.

Female. Forewing length  =  11.5–13.5 mm. Labial palpus folded elbowlike against front, but shorter than in male, apex reaching to immediately below antennal base; antenna bipectinate in basal two-thirds, distal third simple, rami extremely short (fig. 93E); wings significantly longer and broader than male, pattern similar, ground color slightly lighter gray-brown; abdominal dorsum with more cream-colored scaling than male.

Terminalia (100D, F, G): Tg7 long and wide, gradually tapered toward distal margin, anterior margin simple, posterior margin convex with a small mesal excavation, lateral margins of Tg7 with ridgelike flanges at halfway point; St7 extremely wide, surface setose in distal two-thirds, more densely setose near posterior margin; anterior margin of St7 gently convex, lateral margins constricted in anterior third, with small flanges at constriction point; posterior margin of St7 with a deep, U-shaped mesal excavation, posterolateral angles greatly expanded, margins coarsely serrate, each side bearing a prominent, spinelike process; Tg8 sclerotized, relatively wide, emarginate posteriorly; A8 pleuron bearing a large, sclerotized, hornlike process along posterior margin, this pointing dorsoposteriorly; AA short, narrow; PA large, slightly triangular, their surfaces sclerotized, densely spiculate; PP elongate, thin, straight; membrane below PA infolded; DB short, heavily sclerotized, ostium forming an expanded, funnel-shaped structure, its surface spiculate and minutely rugose; junction of DB and CB bearing a small, membranous lateral appendix; CB almost round, with a narrower, quadrate section at base; signum roughly ovoid, with an anterior fold, its internal surface minutely dentate; signum located laterally on left side; right side of CB bearing a pair of small, sclerotized, widely separated, internal pockets, their surfaces coarsely rugose; DS attached to narrowed quadrate region of CB on right side.

Etymology

The name for this species is derived from the Latin word copiosus, “abundant”. It refers to the fact that, while collecting in western Ecuador (J.S. Miller and E. Tapia, during March 2006), numerous adults of P. copiosa were observed at two locations—Cristal and Otongachi—flying in mid to late afternoon in close proximity to the branches of their host plant, Celtis iguanaea. A search of C. iguanaea foliage at these sites revealed huge numbers of eggs and larvae. It is not known whether Polypoetes copiosa is abundant every year at all times of the year, or whether these observations were instead the result of a sporadic, almost outbreak-type situation.

Distribution

Polypoetes copiosa shows a fairly restricted distribution along the foothills of the Andes in western Ecuador (fig. 101). Specimens have been collected as far south as Río Las Juntas (Los Ríos Province) and Balsapamba (Bolívar Province), sites less than 25 km apart. The northernmost limit is Tinalandia and La Unión del Toachi, both in Pichincha Province. Additional collecting will undoubtedly extend this range north and south. Polypoetes copiosa also appears to occur within a narrow altitudinal band, between 700 and 900 meters.

Biology

As in P. haruspex from Central America (see below), caterpillars of P. copiosa feed on Celtis iguanaea, a spiny liana in the Celtidaceae, the sister family to the Cannabinaceae. Celtis, or hackberry, a genus containing approximately 50 species, is relatively diverse in the Old World and in temperate North America, but only two species are known from Andean South America (Gentry, 1993). Although C. iguanaea has been recorded on both sides of the Ecuadorian Andes (Jorgensen and Leon-Yanez, 1999), P. copiosa is restricted to the Pacific slope. The famous “snout butterflies”, the nymphalid subfamily Libytheinae, include 12 species worldwide (Ackery et al., 1999) placed in two genera. All libytheines are restricted to feeding on Celtis (Ackery, 1988).

Polypoetes copiosa is unusual for the Dioptinae in that it lays eggs in masses. A brief survey at Otongachi revealed five masses, ranging in size from 25 to 110 eggs. Furthermore, first instar larvae feed communally in a single cluster on the underside of the leaf, near its apex. Later instars feed in loose groups, never eating the leaf midvein. Final instar caterpillars feed alone along the leaf's edge.

Discussion

Three species form an extremely tight subclade within Polypoetescopiosa (Ecuador), haruspex (Panama and Costa Rica), and nigribasalis (Venezuela). I found a single character, on male St8, for distinguishing P. nigribasalis from the others (see species key). Morphological differences between P. copiosa and P. haruspex are so subtle that I was at first hesitant to describe a new taxon. An alternative would be to recognize a single species, haruspex, ranging from Costa Rica south to Ecuador, with a second species, nigribasalis occurring across northern Venezuela. However, after finding consistent characters in the female genitalia for distinguishing Ecuadorian and Central American material, I decided to erect copiosa as new. Males of the two are essentially impossible to separate based on morphology—they present prime candidates for bar-coding.

Females of P. copiosa and P. haruspex differ in two traits: First, the prominent posterolateral processes on St7 are straight or slightly curved in copiosa, but are hook shaped in haruspex. Additionally, in both species the corpus bursae bears a pair of spiculate invaginations in addition to the signum. These pockets are conjoined in haruspex, but separate in copiosa. In both sexes, P. copiosa generally shows a darker charcoal-gray FW ground color compared to that of P. harupex, which is brown. However, specimens of both species tend to intergrade. Hopefully, future research will identify additional traits, perhaps from DNA or immatures, for separating these taxa.

Based on our current knowledge, P. copiosa, endemic to western Ecuador, and P. haruspex, from the Pacific side of the Cordillera Central in Central America, are allopatric. However, additional sampling, particularly along the western Andes of Colombia, is needed to confirm these distributions. A single USNM specimen, collected by R.E. Dietz (February 1969) near Villavicencio in central Colombia on the eastern side of the Andes (genitalia slide no. JSM-1644) represents a fourth, as yet undescribed, species in this clade, closely related to copiosa, haruspex and nigribasalis.

Having observed that P. copiosa is common, it is interesting that, other than the large series of AMNH material collected between 1993 and 2006, the species is known from only two additional collections, each represented by a single individual. One of those is at the LACM (leg. J. Donahue, Tinalandia, 1980), while the other—a BMNH male—was caught by M. de Mathan in the summer of 1893. These two specimens undoubtedly came from light-trap samples.

Observations of this kind provide support for the theory that Dioptinae, although rare in collections, are not uncommon in their habitats. Rather, the species are regionally abundant, occurring in close proximity to their host plants. They require special focus to collect; day-flying dioptines have been virtually ignored by the vast army of butterfly collectors working in the Neotropics over the past 200 years.

Holotype

Female. Ecuador: Bolívar: Cristal, N bank Río Cristal, 0.7 km S Balsapamba, 01°45.8′S, 79°10.5′W, 800 m, 15 Mar 2006, day, along river's edge, leg. J.S. Miller & E. Tapia. The type is deposited at the AMNH.

Paratypes

Ecuador: Pichincha: 1♂, 5♀♀, Otongachi, La Unión del Toachi, 00°19.3′S, 78°57.1′W, 933 m, 16 Mar 2006, day-coll., leg. J.S. Miller & E. Tapia, (AMNH; female genitalia slide Nos. JSM-1642, 1643); 2♀♀, leg. E. Tapia (AMNH); 1♀, leg. J.S. Miller & E. Tapia, ex larva on Celtis iguanaea (Celtidaceae) (AMNH). Bolívar: 6♂♂, Cristal, N bank Río Cristal, 0.7 km S Balsapamba, 01°45.8′S, 79°10.5′W, 800 m, 15 Mar 2006, day, along river's edge, leg. J.S. Miller & E. Tapia (AMNH; genitalia slide Nos. JSM-1640, 1641).

Other Specimens Examined

Ecuador: Pichincha: 1♂, Tinalandia, 700 m, 20 May 1993, leg. E. Tapia, day-coll. (AMNH; genitalia slide no. JSM-1417); 1♀, Tinalandia, 17 km W Santo Domingo de los Colorados, 2 Jul 1980, leg. Julian P. Donohue (LACM); 1♂, 1♀, Toachi, S 00°19.3′, W 78°57.3′, 800 m, 23 Feb 2003, leg. S. Rab Green & M. Tapia, at light UV/MV, western cloud forest, disturbed (AMNH). Los Ríos: 1♂, La Chima, Río de las Juntas, pr. Babahoyo, Jun–Jul 1893, leg. M. de Mathan (BMNH; genitalia slide no. JSM-483).

Dissected

4♂♂, 2♀♀.

Polypoetes corneola, new species

Figures 102, 103; plate 12

Diagnosis

This taxon could potentially be confused with two other Polypoetes species with which it is sympatric—P. albiscripta and P. integra (pl. 12). In all three, the FW bears a large, almost quadrate fascia beyond the DC, as well as a tiny, whitish yellow, irregular subapical spot at the junction of Rs2–Rs4. The HW is dark with a white area that tends to be confined to an ovoid region beyond the DC, though in females this can extend toward the wing base. Furthermore, all three species exhibit similar coloring on the labial palpi: Lp1 yellow-orange; Lp2 dark brown laterally, creamy white on the dorsal and ventral surfaces; Lp3 obscured by a distal tuft of brown to cream-colored scales.

Polypoetes corneola (FW length  =  15.0–15.5 mm) can be separated from P. albiscripta (FW length  =  12.5–14.5 mm) by its larger size (pl. 12). Furthermore, the FW veins are lined with orange-yellow in P. corneola, but with white in P. albiscripta. Polypoetes integra differs from P. corneola in being smaller (FW length  =  13.0–14.0 mm), and in having a lighter FW and HW ground color (pl. 12). Although the male and female genitalia of these species show fundamental similarities, all three can be separated by morphological differences. For example, male St8 is narrower in P. corneola (fig. 102B) than in the other two (figs. 96D, 107B).

Description

Male (pl. 12). Forewing length  =  15.0 mm. Head: Labial palpus extremely long, curving upward to well beyond antennal base, folded elbowlike over front; Lp1 relatively short, widest near middle, lateral surface loosely covered with light yellow-orange scales, mesal surface with a mixture of white and yellow-orange scales, dorsal surface white; Lp2 more than twice as long as Lp1, bowed slightly outward, lateral surface tightly covered with glossy, dark slate-gray to blackish-gray scales, mesal surface sparsely covered with short white scales, dorsal surface clothed with cream-colored scales; distal third of Lp2 scaleless on mesal surface, covered with spicules, dorsal surface with a tuft of long scales extending beyond Lp3; Lp3 short, conical, glossy dark gray, mesal surface scaleless, covered with short spicules; front covered with long, upwardly pointing scales, scales longest above, forming a pair of dorsal tufts between antennal bases; central area of front glossy slate gray to dark brown, lateral portion creamy buff to light yellow; lower three-quarters of occiput white to light yellow, dorsal fourth blackish gray; eye moderately large, completely surrounded by a scaleless region, this narrow above and on sides, gena broadly scaleless; eye evenly covered with short setae; vertex covered with long, anteriorly pointing, black to blackish-gray scales, a few long, light yellow scales near midline; a narrow band of white to light yellow scales behind each antennal base; antenna bipectinate, rami moderately long; scape glossy gray black, a few whitish scales on venter; dorsum of antennal shaft glossy gray black.

Thorax: Inner surfaces of legs white to whitish gray, outer surfaces glossy bluish gray to dark gray; tibial spurs white to buff colored; tarsi buff colored on inner surfaces, gray laterally; pleuron covered with long, hairlike white scales mixed with shorter dark gray scales; patagium dark gray to coppery, a few scattered long white scales anteriorly; tegula relatively short, covered with erect, hairlike scales, longest toward apex, scales orange in central portion, fringed with dark charcoal gray laterally; dorsum blackish gray, with a pair of orange-yellow stripes on either side of midline; tympanum relatively small, open, comprising a shallow scaleless depression; tympanal membrane moderate in size, ovoid, facing lateroposteriorly.

Forewing: (Dorsal) Ground color blackish gray to dark coppery gray, more sparsely scaled in basal third (pl. 12); veins, excluding costa but including anal fold, sparsely lined with orange-yellow scales; veins Rs2–Rs4 in the arrangement [2+3]+4; a large, transverse oval fascia immediately beyond distal margin of DC, located between M1 and fork of M3+CuA1, its surface sparsely covered with short, fork-shaped and small, paddle-shaped blackish gray scales; base of vein M2 lined with blackish scales as it passes through fascia; a small, diffuse, light orange subapical spot formed at base of Rs2–Rs4. (Ventral) Similar to dorsal surface, except: veins concolorous with ground color; a white basal dash behind cubitus; Sc white near base; surface of ovoid fascia glassy, evenly covered with short, erect, white scales; subapical spot larger, ovoid, more evenly covered with orange scales; fringe dark coppery gray.

Hind wing: (Dorsal) Ground color black to blackish gray, basal half lighter, more sparsely scaled (pl. 12); a relatively small, round, white central area formed near lateroposterior angle of DC, extending slightly behind cubitus, and joining a translucent fascia beyond DC; surface of fascia glassy, sparsely covered with white scales; fascia rectangular, its anterior margin touching base of Rs+M1, its posterior margin touching base of M3+CuA1; fringe coppery gray; anal margin fringed with long, light gray scales. (Ventral) White from base to distal margin of DC; surface of fascia beyond DC glassy, sparsely covered with white scales; a wide, black to charcoal-gray band along outer margin from apex to tornus; anal margin broadly covered with a mixture of white and dark gray scales.

Abdomen: Dorsum dark charcoal gray to dark brown, posterior margins of terga 2–7 sparsely fringed with long white scales; pleural region with a mixture of charcoal gray and white scales; venter white.

Terminalia (fig. 102A–C, E): Tg8 long, narrow, widest in anterior third, gradually narrowed in distal two-thirds, dorsum with a wide groove along midline; anterior margin of Tg8 with a pair of small, narrow apodemes at lateral angles, posterior margin with long, sclerotized digitate processes at lateral angles; St8 longer than Tg8, slightly wider, its lateral margins bowed gently outward at halfway point, then narrowing distally; anterior margin of St8 forming a broad, rounded apodeme with a triangular fold; posterior margin of St8 bearing an extremely long, sclerotized mesal fork, its dorsum with a short groove along midline; socii/uncus complex broad and short, heavily sclerotized, extremely wide at base; uncus forming a small narrow mesal process, forked at its apex; socii greatly elongate, heavily sclerotized, wide at bases then tapered to a point distally, each with a bladelike subapical flange, lateral surfaces bearing long, coarse setae; tegumen short, expanded below junction with socii/uncus complex; vinculum approximately equal in height to tegumen, narrow, ventral margin of genitalia broadly U-shaped; valva short and wide, inner surface coarsely setose; BO relatively large, occupying almost one-third of valva, curled anteriorly; costa short, wide; valva apex lightly sclerotized, bearing a blunt, densely setose process; basal sclerites at valva bases wide, triangular; ventral margin of genitalia broadly convex; saccus forming an extremely large, thin plate, folded upward to junction of transtillar arms; transtillar arms wide at bases, abruptly narrowed, meeting at midline to form an elongate, tubular, anteriorly projecting structure; aedeagus moderately long, mostly straight, wider at base; apex of aedeagus boat shaped, terminating in a hook-shaped tooth; vesica relatively small, distal portion covered with short, thornlike cornuti, some of these minutely bifid.

Female. Forewing length  =  15.5 mm. Head, thorax, and wings similar to male except: labial palpus shorter and thinner, apex falling well short of antennal base; Lp2 without an apical tuft; antennae ciliate; FW veins lined with light yellow scales; subapical spot larger, lighter; HW with a much more extensive white central area, extending from near base to beyond fork of M3+CuA1; abdominal dorsum dark brown, terga on A2–A7 sparsely fringed with white scales; St 7 scaleless, densely setose, heavily sclerotized, dark brown in anterior half, yellow-brown posteriorly.

Terminalia (fig. 102D): Tg7 large, sclerotized, anterior margin simple, posterior margin convex; St7 extremely large and wide, surface of anterior half wrinkled, sparsely covered with coarse setae, posterior half smooth, densely setose; anterior margin of St7 broadly convex, posterior margin of St7 coarsely serrate, with a deep, U-shaped mesal excavation, each posterolateral angle bearing a curved, hornlike process; Tg8 heavily sclerotized, midline membranous, dividing tergum into two halves; Tg8 contiguous with sclerotized A8 pleuron, posterior margin bearing a pair of broad, bladelike horns; AA short, thick; PA large, robust, sclerotized, surface densely spiculate, a melanized, spiculate dorsal ridge present between lobes; PP longer than AA, sclerotized, thick, apices spatulate; ostium large, sclerotized, funnel shaped; DB extremely short, with a small lateral appendix on right side; CB a large transverse oval, surface strongly wrinkled, with a wide, coriaceous section at its base; signum large, almost round, located laterally on left side, with a raised anterior ridge, surface denticulate; a pair of large, strongly rugose pockets located laterally on right side of CB, their surfaces coarsely spiculate; DS attached at junction of CB and DB.

Etymology

This name is taken from the Latin corneolus, meaning “horny”, in reference to the genitalia of this species, in both sexes of which horns abound. Males possess paired horns on the distal margins of Tg8 and St8, in addition to a pair of small horns on the apex of the uncus. Females bear hornlike structures on the lateral angles of St7, as well as a pair of broad horns along the posterior margin of the A8 pleuron.

Distribution

Polypoetes corneola is known exclusively from the type locality, in the Cosñipata Valley of southeastern Peru (fig. 103). The elevation at which this species was collected (2300 m) corresponds with the relatively high altitudes recorded for its relatives within the Haruspex Group, such as P. albiscripta, which occurs in the same region of Peru between 2900 and 3000 meters.

Discussion

Polypoetes corneola belongs in a clade of 12 Haruspex Group species (table 5) in which there is a fork at the apex of the uncus, and the vesica bears short, minutely bifid cornuti. The genitalia of P. corneola are extremely similar to those of P. albiscripta and P. integra. All the various teeth and horns present in the male genitalia of P. corneola (fig. 102) have their homologues in P. albiscripta (fig. 96) and P. integra (fig. 107). Within this three-species clade, P. corneola and P. albiscripta, both of which occur in the region east of Cuzco, show synapomorphies indicating a possible sister-species relationship.

Both known specimens of P. corneola were collected within a few minutes of each other at precisely the same locality, along the gravel road running through the Cosñipata Valley from Cuzco down to Pilcopata. This road is cut into an extremely steep slope, high above the Río Pilcopata. The female was captured in a misty rain, sitting on the flowers of a white Asteraceae, while the male was collected as it flew from a roadside shrub only a few meters away.

Holotype

Male (pl. 12). Peru: Cuzco: Cosñipata Valley, Pillahuata-Pilcopata Rd., 2300 m, S13°08′58″, W71°35′07″, 23 Oct 2005, leg. J.S. Miller, day collecting (genitalia slide no. JSM-1557). The type is deposited at the AMNH.

Paratypes

Peru: Cuzco: 1♀, Cosñipata Valley, Pillahuata-Pilcopata Rd., 2300 m, S13°08′58″, W71°35′07″, 23 Oct 2005, leg. J.S. Miller, day collecting, on Compositae flowers (AMNH; genitalia slide no. JSM-1558).

Other Specimens Examined

None.

Dissected

Holotype ♂, Paratype ♀.

Polypoetes deldon Druce

Figure 104; plate 10

Polypoetes deldon Druce, 1885a: 160, pl. 14, fig. 24.

Type Locality

Guatemala, Cerro Zunil, 4000 ft.

Type

Syntype ♂, leg. Champion (BMNH).

Discussion

Kirby (1892) assigned P. deldon as the type species for Polypoetes because Druce (1885a), who described the genus, did not designate a type. Based on similarities of wing pattern and genitalia, P. deldon (fig. 104; pl. 10) is closely related to P. approximans (fig. 97; pl. 10) from Costa Rica and Panama, as well as to P. subcandidata (pl. 10) and P. sublucens (fig. 113; pl. 11), both from Colombia. Subtle shape differences in male Tg8, the aedeagus and the female DB can be used to separate them.

A wing-pattern feature unique to P. deldon is the presence of a small, diffuse white area in the HW, located immediately beyond the DC. Other taxa either show an entirely dark HW, or a large white HW central area. The FW length of P. deldon (12.0–13.0 mm) is shorter than in the other species mentioned (14.0–15.0 mm). There are nine males and one female of P. deldon at the BMNH, all collected by Champion prior to publication of the Biologia Centrali-Americana in 1885. No other examples are known.

Distribution

Guatemala (BMNH).

Dissected

♂, Guatemala, Pantaleon, 1700 ft, leg. Champion, BMNH (genitalia slide no. JSM-402); ♀, Guatemala, Cerro Zunil, 4–500 ft, leg. Champion, BMNH (genitalia slide no. JSM-403).

Polypoetes eriphus Druce

Plate 11

Polypoetes eriphus Druce, 1885a: 160.

Type Locality

Guatemala, Panimá.

Type

Syntype ♂, leg. Champion (BMNH).

Polypoetes cethegus Schaus, 1889: 192. Revised synonymy; formerly a synonym of etearchus Druce (Bryk, 1930).

Type Locality

Mexico, Coatepec.

Type

Syntype ♂/♀ (USNM).

Polypoetes draudti Hering, 1925: 514. New synonymy.

Type Locality

Mexico, Misantla.

Type

Syntype ♂/♀, Apr 1912 (ZMH).

Discussion

Several morphological features of P. eriphus suggest that it may be improperly placed in the Haruspex Group. For example, the male labial palpi are shorter and thinner than in most species of the group. The male genitalia are unusual as well, with St8 bearing a series of unique, long, spinelike bristles along its posterior margin. Nevertheless, based on the presence in females of a large, funnel-shaped ostium and large, bladelike processes on the A8 pleuron, I have provisionally placed P. eriphus in the Haruspex Group. It does not show closer affinities elsewhere in Polypoetes.

Someone long ago re-attached the abdomen of the male P. eriphus syntype with glue. This leads one to doubt whether it was properly re-associated. My subsequent dissection (JSM-1145) suggests that it is the correct abdomen.

Study of types, including genital dissections, shows that cethegus Schaus, formerly regarded as a synonym of etearchus Druce (Etearchus Group), is instead conspecific with P. eriphus. My examination of the female type of draudti Hering at the ZMH (March 2005), shows that it should be newly recognized as a synonym of eriphus.

Distribution

Mexico (AMNH, BMNH, USNM, ZMH); Guatemala (BMNH, ZMH); Nicaragua (SMNS).

Dissected

Syntype ♂ (genitalia slide no. JSM-1145); ♂ syntype of cethegus Schaus, Mexico, Coatepec, USNM (genitalia slide no. JSM-1081); ♀, Mexico, Jalapa, AMNH (genitalia slide no. JSM-1082).

Polypoetes exclamationis Hering

Plate 12

Polypoetes exclamationis Hering, 1925: 515.

Type Locality

Bolivia, Mapiri.

Type

Holotype ♂ (ZMH).

Discussion

This taxon is known exclusively from the ZMH holotype (pl. 12). The unique combination of white patterning on the FW and HW provide excellent means for identifying P. exclamationis. The species is particularly unusual in lacking a subapical FW spot, and in having a broad white HW central area. The presence of a bifid uncus confirms the position of P. exclamationis within the Haruspex Group, along with species such as P. forficata, P. corneola and others (table 5). The labial palpus of P. exclamationis bears a loose fringe of long, bristlelike scales ventrally, suggesting placement of this species within a smaller subclade that includes P. fuliginosa, P. mara, P. marginifer, and P. picaria. All are Andean taxa endemic to Bolivia and southeastern Peru. The configuration of male Tg8 and the valvae suggest a particularly close relationship between P. exclamationis and P. picaria.

Mapiri, the type locality for P. exclamationis, is an historically famous Bolivian collecting site, located northwest of La Paz (15°28′S, 67°49′W). The elevation at that location is roughly 1000 meters. Additional dioptine species have been captured there.

Distribution

Bolivia (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1756).

Polypoetes fenestrata Hering

Figures 89E; plate 11

Polypoetes fenestrata Hering, 1925: 516.

Type Locality

Bolivia, Río Songo, Yungas, 1200 m.

Type

Syntype ♂/♀, 1895–1896, leg. Garlepp (ZMH).

Discussion

Polypoetes fenestrata is a close relative of another Hering taxon, P. nigribasalis from Venezuela (pl. 11). Their similarities are addressed in my discussion of the latter (below). Although these two species are superficially similar to a newly described Ecuadorian taxon, P. forficata, they show strong differences in genital morphology. The only specimens of P. fenestrata I have seen consist of type material, which totals four specimens—one male and two females at the ZMH (all collected by Garlepp on the Río Songo, Bolivia), as well as a female BMNH paratype. The BMNH specimen, also collected by Garlepp, is from Toreobito, Bolivia.

Distribution

Bolivia (BMNH, ZMH).

Dissected

♂ Syntype (genitalia slide no. JSM-1413).

Polypoetes forficata, new species

Figures 101, 105; plates 12, 37I, 37L

Diagnosis

The two species with which P. forficata could most easily be confused are P. fenestrata (Río Songo, Bolivia) and P. nigribasalis (Mérida, Venezuela). These are slightly smaller moths (pl. 11); both have male FW lengths of approximately 12.0 mm, whereas the FW of P. forficata males ranges between 12.0 and 14.0 mm. Wing shape also differs. The FW of P. forficata is more triangular and less elongate, and the HW is fuller. Polypoetes forficata can also be distinguished by the presence of a semihyaline HW fascia beyond the DC, in addition to a FW fascia. Other similar-appearing Polypoetes species show only the FW fascia. These taxa can easily be separated from P. forficata by comparison of male genital morphology. None of them exhibit a forked uncus (fig. 105A), the trait giving forficata its name.

Description

Male (pl. 12). Forewing length  =  12.0–14.0 mm. Head: Labial palpus extremely long, extending upward to well beyond antennal base, folded elbowlike over front; Lp1 short, ovoid, closely covered with light yellowish to cream-colored scales; Lp2 much longer than Lp1 and Lp3, bowed gently outward near middle, with light yellowish to cream-colored scales on mesal and dorsal surfaces, blackish brown laterally, dorsal surface bearing an apical tuft extending beyond Lp3; Lp3 extremely short, blackish brown, mesal surface covered with short spines; central portion of front covered with dark brown, upwardly pointing scales; lateral portions of front with long, upwardly pointing, cream-colored scales, longest dorsally, forming a pair of tufts between antennal bases; lower three-quarters of occiput light yellow to cream colored, upper fourth blackish brown; eye relatively small, completely surrounded by a thin, scaleless region above and on sides, gena broadly scaleless; eye evenly covered with short setae; vertex covered with dark brown to blackish brown, anteriorly pointing scales, a few scattered cream-colored scales; a whitish to cream-colored stripe behind each antennal base; antenna bipectinate, rami moderately long; scape dark brown to blackish brown dorsally, whitish to cream colored below; dorsum of antennal dark brown, loosely lined on each side with a row of cream-colored scales.

Thorax: Inner surfaces of legs covered with whitish to cream-colored scales, outer surfaces brown to dark brown; pleuron covered with long white to cream-colored scales; patagium dark brown to blackish brown, with a loose array of cream-colored scales anteriorly, and a few orange scales posteriorly; tegula relatively small, covered with erect, hairlike scales, longest toward apex, scales orange in central portion, fringed with dark brown laterally; dorsum dark brown to blackish brown, with a pair of yellow-orange longitudinal stripes on either side of midline; tympanum relatively small, open, comprising a shallow, scaleless depression; tympanal membrane moderate in size, ovoid, facing lateroposteriorly.

Forewing: (Dorsal) Ground color dark brown to blackish brown, lighter in basal third (pl. 12); wing veins, excluding costa but including anal fold, lined with orange to yellow-orange scales; a large, ovoid fascia beyond distal margin of DC, located between M1 and fork of M3+CuA1; surface of fascia glassy, sparsely covered with white and hyaline, paddle-shaped scales; a small, almost round, orange subapical spot formed near base of Rs2–Rs4, extending slightly beyond Rs2 anteriorly and beyond Rs4 posteriorly; fringe dark brown to blackish brown. (Ventral) Similar to dorsal surface, except: veins not lined with orange; basal third covered with white scales, white region with a wedge, posterior to CuA1, extending toward outer margin; subapical spot with an additional tiny patch of orange scales located anterior to M1.

Hind wing: (Dorsal) Central area immaculate white, with scattered dark brown scales near base (pl. 12); a wide, blackish brown band along outer margin, extending from apex to tornus, slightly wider near apex; anterior margin lined with light brown; anal margin white, fringed with long, whitish scales; an ovoid, hyaline fascia beyond DC, extending from base of Rs+M1 anteriorly, to short of M3+CuA1 posteriorly. (Ventral) Similar to dorsal surface, except anterior margin white; blackish brown marginal band thinner near tornus.

Abdomen: Dorsum brown to dark brown, becoming cream-colored toward pleuron; posterior margin of each tergum with a thin, transverse band of light yellowish to cream-colored scales; venter mostly whitish near base, becoming cream-colored distally.

Terminalia (fig. 105A, B, D, E). Tg8 long, extremely thin, narrowest anteriorly, slightly wider posteriorly, anterior margin of Tg8 with lateral angles greatly elongate, acute, posterior margin lightly sclerotized, with a shallow mesal depression; St8 as long as Tg8, roughly rectangular, slightly wider posteriorly; anterior margin of St8 with a small, triangular fold, apodeme apparently absent; a sclerotized flange along posterior margin of St8, slightly expanded at lateral angles, with a shallow U-shaped mesal excavation; socii/uncus complex large, heavily sclerotized, triangular, extremely wide at base; uncus long, forming a thin, scissorlike process at apex; socii a pair of greatly elongate arms, wide at base, acute at apex, with a small bladelike, subapical flange, a set of long setae on lateral surfaces; tegumen short, slightly expanded at junction with socii/uncus complex; vinculum short, relatively narrow; valva short, wide, mostly membranous, inner surface setose; BO relatively large, curled anteriorly, occupying over one-third of valva; valva apex mostly membranous, slightly expanded; costa short, wide, curved gently outward near middle of valva; basal sclerites at valva bases wide, slightly concave; lower margin of saccus horizontal, with a triangular sclerite extending upward to cover valva bases; transtillar arms wide at bases, abruptly narrowed, arching downward to meet at midline; aedeagus long, widest at base, slightly constricted in basal third; apex of aedeagus boat shaped, terminating in a small, hook-shaped tooth; vesica relatively small, distal half sparsely covered with small, thornlike cornuti, some of these minutely bifid, a few trifid.

Female. Forewing length  =  13.5–15.0 mm. Head, thorax, and wings similar to male except: labial palpus shorter, thinner, reaching upward to immediately short of antennal base; Lp2 without an apical tuft; antenna ciliate.

Terminalia (fig. 105C, F, G): Tg7 large, sclerotized, broadly rounded along posterior margin; St7 large, much wider than St6, abruptly narrower in anterior quarter, surface covered with coarse setae in posterior half; lateral margins of St7 expanded, each side bearing a prominent, sclerotized, thornlike process; posterior margin of St7 heavily sclerotized, with a deep, U-shaped mesal excavation, on either side of which is a pair of large, triangular processes; Tg8 heavily sclerotized, posterior margin complex, rooflike, a pair of small, mesal processes formed at midline, each side with a large, smooth expansion laterally, and an extremely robust, sclerotized process near pleuron; AA relatively short; PA large, robust, sclerotized, surface coarsely spiculate, a melanized dorsal ridge present between lobes; PP longer than AA; ostium large, sclerotized, funnel shaped; DB short, membranous, with complex folds and a small lateral appendix on right side; CB relatively small, membranous, ovoid; signum small, ovoid, located ventrally, surface concave, almost smooth; a pair of large, rugose, lightly sclerotized areas near base of CB dorsally, their surfaces coarsely spiculate; DS attached at junction of CB and DB.

Etymology

The name is from the Latin word for “scissors shaped” (masculine, forficatus), in reference to the strongly bifid uncus of the male genitalia in this taxon, a trait that distinguishes it from most other Polypoetes species, but also establishes P. forficata as a member of a fascinating subclade of the Haruspex Group (table 5).

Distribution

So far, Polypoetes forficata is known exclusively from a small region of eastern Ecuador (fig. 101) near the towns of Baeza and Cosanga, in a narrow elevational band between approximately 1800 and 2200 meters. Material extremely similar in appearance to P. forficata has been collected at lower elevations in eastern Ecuador (AMNH, 500 m; CMNH, 900 m), but upon dissection these prove to represent an undescribed species.

Biology

Polypoetes forficata has been reared at Yanayacu Biological Station, Cosanga, Ecuador (Dyer et al., 2009). The larvae (fig. 37I) feed on Psammisia (Ericaceae), a plant genus containing approximately 50 species. At Yanayacu, the plants are common along streams in the cloud forest, and can also be seen growing in wet spots beside gravel roads. They bear drooping pink or brilliant red flowers (see Dyer et al., 2009). The pupae of P. forficata (pl. 37L) are typical of Polypoetes.

Discussion

Polypoetes forficata belongs to a taxonomically challenging group of Andean species, distributed from Bolivia north to western Venezuela, many of which are undescribed. In all these taxa, the wings show the same basic pattern: The FW ground color is dark brown to blackish brown, slightly lighter in the basal third; the FW veins are thinly lined with yellow-orange scales, there is a light-colored or semihyaline fascia beyond the DC, and a small, orange subapical FW spot near the fork of Rs2–Rs4; the HW is white with a wide, blackish-brown border along the outer margin. Coloration of the head and thorax does not seem to provide useful characters for separation. By far the most reliable means for distinguishing these species is by study of male and female genital characters. There, the differences are clear.

For example, I had initially identified the AMNH specimens of forficata as Polypoetes fenestrata Hering, known from Bolivia. Not until the ZMH type of fenestrata was dissected (March 2005) did it become clear that material from Baeza and Cosanga was undescribed. Subsequently, Polypoetes specimens from other Ecuadorian localities were studied by dissection. In each case, although their wing pattern was hardly distinguishable from that of P. forficata, genital morphology differed. To my knowledge, there are at least four Polypoetes from Ecuador exhibiting the same general appearance as P. forficata. One of these, P. copiosa, is newly described above. The other three, all undescribed members of the Haruspex Group, are listed here along with their genitalia slide numbers for future reference: The first occurs at Tinalandia, Pichincha Province, in western Ecuador (AMNH ♂, JSM-1563); a second (CMNH; ♂, JSM-1416) is from Coca River canyon, Napo Province, but at a lower elevation (900 m) than that of P. forficata; finally, an AMNH female from Tena (JSM-1423), not far from Cosanga but again at a lower elevation (500 m), exhibits genital morphology very different from that of P. forficata.

Holotype

Male (pl. 12). Ecuador: Napo: Yanayacu Biol. Stn., 5 km W Cosanga on Cosanga-Río Alíso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 1 Mar 2006, leg. J.S. Miller & E. Tapia, day collecting. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 1♀, Yanayacu Biol. Stn., 5 km W Cosanga on Cosanga-Río Alíso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 2 Mar 2006, leg. J.S. Miller & E. Tapia, day collecting (AMNH); 1♂, 1♀, Baeza, nr. Río Quijos, 6200 ft, 31 Oct 1988, leg. J.S. Miller, shrub flowers (AMNH; ♂ genitalia slide no. JSM-484, ♀ genitalia slide no. JSM-488); 2♂♂, nr. Río Quijos, 5800 ft, 28 May 1993, leg. J.S. Miller & E. Tapia, day-collecting (AMNH; genitalia slide no. JSM-1415); 1♂, W bank of Río Quijos, 0°26′S, 77°53′W, 1750 m, 3 Mar 2006, day collecting, leg. J.S. Miller & E. Tapia (AMNH); 1♂, Yanayacu Biological Station, S 00°35.9′ W77°53.4, 2163 m, 8 Sep 2002, reared by Dyer et al., #B 1194 (AMNH).

Other Specimens Examined

None.

Dissected

2♂♂, 1♀.

Polypoetes fuliginosa Dognin

Figure 106; plate 12

Polypoetes fuliginosa Dognin, 1904: 119.

Type Locality

Bolivia, Yungas de la Paz, 1000 m.

Type

Holotype ♂ (USNM type no. 30923).

Discussion

Other than the holotype, I was able to locate only three specimens of P. fuliginosa: a USNM male (without abdomen) collected at 2280 meters in Cuzco, Peru (J.B. Heppner); and two Peruvian males at the BMNH collected by Garlepp—one from Cuzco and the other from Challabamba (3000 meters). Polypoetes fuliginosa belongs in a subclade within the Haruspex Group containing high-altitude species in which the FW bears a whitish basal streak, and the FW fascia is elongate, obliquely angled (pl. 12). Additional white FW markings can be used to separate these taxa (see Haruspex Group species key). This species also exhibits a bifid uncus (fig. 106A; table 5) and short, bifid cornuti on the male aedeagus (fig. 106C).

Distribution

Bolivia (USNM); Peru (BMNH, USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1113).

Polypoetes haruspex Druce

Plates 11, 37H, 37J

Polypoetes haruspex Druce, 1885a: 161.

Type Locality

Panama, Volcán de Chiriquí, 2–3000 ft.

Type

Syntype ♀, leg. Champion (BMNH).

Discussion

Polypoetes haruspex is endemic to Central America, whereas its sister species—P. copiosa—is known from western Ecuador. The two are extremely difficult to separate, but means for doing so, mostly involving female genitalia, are detailed in the description for copiosa (above). The haruspex syntype, at the BMNH, is a female with labels typical of Druce types. Additional members of the Haruspex Group, including nigribasalis, fenestrata, and selenia/obtusa—together with haruspex and copiosa—form a tightly knit subclade. All exhibit roughly the same small size, wing pattern, and body coloration. Their genital morphology is also extremely similar. Many dissections, across large series, will be required to fully revise the taxonomy of this difficult group. As uniform as they are morphologically, these taxa are widely separated geographically. For example, a distance of over 4800 kilometers separates P. fenestrata (Bolivia) and P. haruspex.

Janzen and Hallwachs (2008) discovered the immature stages of Polypoetes haruspex (pl. 37H, J) in Costa Rica. The larvae feed on hackberry, Celtis iguanaea (table 4). Elicio Tapia and I subsequently discovered P. copiosa, sp. nov., feeding on this same plant species in Ecuador.

In Costa Rica, Vitor Becker (personal commun.) observed a calling female of P. haruspex, perched under a leaf at the tip of a branch approximately 4 meters above the ground, with dozens of males fluttering around it. This is the first verified observation of calling behavior in the Dioptinae.

Distribution

Panama (BMNH, USNM, ZMH); Costa Rica (INBio, BMNH, USNM, VOB).

Dissected

♂, Costa Rica, Turrialba, 600 m, 5 Aug 1971, leg. V.O. Becker, VOB (genitalia slide no. JSM-1101); ♀, Panama, Volcan de Chiriquí, 2000–3000 ft, leg. Champion, BMNH (genitalia slide no. JSM-487).

Polypoetes integra Hering

Figure 107; plate 12

Polypoetes integra Hering, 1925: 516.

Type Locality

Peru, Callanga, 1500 m, (pr. Cuzco).

Type

Holotype ♂, leg. Garlepp, 1898 (ZMH).

Discussion

I know Polypoetes integra from two specimens—the male holotype and a BMNH female. Interestingly, Garlepp collected both examples over 100 years ago, one in Bolivia and the other in southeastern Peru. Numerous synapomorphies of the male and female genitalia confirm that P. integra belongs in a close-knit clade with two additional Haruspex Group species—P. albiscripta Dognin and P. corneola, sp. nov. In all three taxa, males bear a pair of elongate, hornlike processes on Tg8 and St8 (fig. 96B, D; fig. 102B, E; fig. 107B, D). Configurations of their socii and valvae are nearly identical. Females show a pair of large, bladelike processes on the posterior margin of A8 (e.g., fig. 102D), and exhibit similarities in shape of the CB.

These three taxa occur together in the vicinity of Cuzco, Peru, but P. integra has also been recorded from Bolivia. The others almost certainly occur there as well.

Distribution

Peru (ZMH); Bolivia (BMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1755); ♀, Bolivia, Yungas de la Paz, 1000 m, Oct 1899, leg. Garlepp, BMNH (genitalia slide no. JSM-868).

Polypoetes leuschneri, new species

Figures 108, 109; plate 11

Diagnosis

Polypoetes species in which the FW and HW dorsal surfaces are uniformly dark brown include P. leuschneri, P. sublucens, and P. tenebrosa, members of the Haruspex Group. Polypoetes leuschneri (pl. 11) could not be confused with P. tenebrosa (pl. 11), from Peru, because it is much smaller and lacks silvery white markings on the FW and HW ventral surfaces. Genital structure suggests that P. tenebrosa is distantly related to P. leuschneri and P. sublucens, whereas that the latter two are extremely close.

Wing venation provides a useful means for separating P. leuschneri and P. sublucens: In the latter, FW veins Rs2–Rs4 appear in the arrangement typical of most Polypoetes species—[2+3]+4. In P. leuschneri, on the other hand, these veins arise together at the terminus of the radial sector, forming a trident. Numerous genital differences distinguish the two species. For example, the socii differ in shape: P. leuschneri has long socii with spatulate apices (fig. 108A), whereas in P. sublucens the socii are short and their apices are broadly flanged (fig. 113A).

Description

Male (pl. 11). Forewing length  =  13.0–14.5 mm. Head: Labial palpus greatly elongate, folded elbowlike over front, apex extending posteriorly to well beyond antennal base; Lp1 short and wide, curving slightly upward, lemon yellow, dorsal surface light yellow, with a loose fringe of slightly longer scales below; Lp2 extremely long, over two and a half times as long as Lp1, curving gradually upward, lateral and ventral surfaces tightly covered with short, dark brown scales, dorsal surface sparsely lined with creamy white to light yellow scales, mesal surface mostly scaleless, a few scattered cream-colored scales near base; apex of Lp2 bearing a tuft of light gray-brown scales on dorsal surface, this tuft partially obscuring Lp3; Lp3 short and conical, acute at apex, lateral surface gray-brown, inner surface scaleless, covered with short yellowish-brown spinules; central portion of front covered with dark brown, upwardly pointing scales, lateral margins of front bearing long, light yellow to lemon yellow, upwardly pointing scales, these converging between antennal bases to form a pair of short triangular tufts; occiput dark brown in upper half, creamy white in ventral half; eye large, bulging gently outward, surrounded by an extremely narrow scaleless band, gena narrow; eye with a sparse covering of short setae; vertex covered with long, anteriorly pointing, dark brown scales, areas behind antennal bases creamy white; antenna bipectinate, rami moderately long; scape dark brown; dorsum of antennal shaft covered with appressed, bronzy brown scales.

Thorax: Legs white to creamy white on inner surfaces, outer surfaces gray-brown to bronzy brown; pleuron covered with white trifid scales, and creamy white hairlike scales; patagium dark brown, with a scattering of creamy white scales; tegula relatively long, ventral angle cream colored, central area of upper portion yellow-orange, margins fringed with dark brown hairlike scales; dorsum dark brown, with a pair of wide, diffuse lemon yellow to yellow-orange longitudinal bands, one on either side of midline; tympanum small, cavity shallow, barely concave; tympanal membrane small, roughly triangular, facing lateroventrally.

Forewing: (Dorsal) Ground color dark chocolate brown (pl. 11); veins, including anal fold and midline of DC, but excluding costa, thinly lined with yellow-orange scales; a diffuse, poorly defined fascia beyond DC, its surface sparsely covered with brown scales, fascia confined between base of Rs1–Rs4 and M3+CuA1; veins Rs2–Rs4 arising together to form a trident. (Ventral) Ground color brown, veins not lined; basal third from subcosta to anal fold silvery white; fascia beyond DC ovoid, covered with white scales.

Hind wing: (Dorsal) Ground color blackish brown, slightly darker than FW (pl. 11); without markings of any kind; white basal areas from ventral surface showing faintly through above. (Ventral) Ground color silvery white; outer margin with a wide, blackish-brown band from apex to slightly beyond CuA2, there terminating abruptly; inner margin of brown band excavated between M2 and fork of M3+CuA1; fringe along tornus dark brown.

Abdomen: Dorsum dark brown with a coppery luster; venter white to creamy white.

Terminalia (fig. 108A–C, E): Tg8 roughly two and a half times as long as Tg7, extremely narrow anteriorly, becoming wider posteriorly, dorsum with a shallow middorsal groove; anterior margin of Tg8 concave, bearing small, straplike apodemes at lateral angles, posterior margin bearing large, flangelike folds at lateral angles and a wide, irregular keel-shaped mesal process; St8 wider and slightly longer than Tg8, its lateral margins roughly parallel; anterior margin of St8 bearing a wide, short mesal process with a triangular mesal fold, posterior margin with a deep, U-shaped mesal excavation, flanked on either side by long, triangular sclerotized processes; socii/uncus complex extremely wide, robust, with a broad attachment to tegumen; uncus broadly expanded at ventrolateral angles, abruptly narrowing distally, apex blunt, bearing hairlike setae on dorsum; socii extremely wide a bases, abruptly narrowed distally, apices spatulate, each socius with a short, flangelike process on mesal surface below apex, mesal surfaces bearing coarse setae; tegumen much shorter than vinculum, each arm moderately wide; vinculum nearly three times as tall as tegumen, arms wide, convex, forming a broad U-shape ventrally; saccus comprising a wide, lightly sclerotized triangle, folded upward; valvae short and wide, roughly triangular, mostly membranous; BO large, comprising majority of valva, curled anteriorly, expanded at ventrolateral angles; inner surface of valva densely setose; costa extremely short, poorly defined; apex membranous, bearing a dense tuft of setae; valva base wide; juxta absent; transtillar arms extremely wide at bases, narrowing abruptly, meeting to form a tubular mesal sclerite above aedeagus; aedeagus long and narrow, curving slightly upward near middle, slightly constricted; base of aedeagus somewhat widened; apex of aedeagus bearing a thin, straplike dorsal sclerite and a large, coarsely dentate ventral sclerite, the latter bending sharply upward at almost 90°, these sclerites extending onto vesica; vesica relatively small, curling anteriorly, bearing a distal group of short, spinelike cornuti.

Female. Forewing length  =  13.5–15.0 mm. Body and wings similar to male, except: labial palpus shorter, reaching to immediately below antennal base; antenna ciliate; outer margin of FW more convex than in male; pattern similar, but ground color generally lighter.

Terminalia (fig. 108D, F, G): Tg7 broad, longer than Tg6, anterior margin simple, posterior margin broadly rounded at lateral angles; a transverse groove near midpoint of Tg7, forming ridgelike structures near lateral margins; St7 wide, scaleless, surface setose, anterior margin broadly U-shaped, emarginate, curving posteriorly to form sclerotized lateral processes; posterolateral margins of St7 rounded, each side bearing a sclerotized posterior prong, posterior margin with a deep, asymmetrical, U-shaped mesal excavation; Tg8 sclerotized, wide, posterior margin with a pair of short, spinelike mesal processes; AA short, acute; A8 pleuron membranous; PA large, surface densely spiculate, posterior margins slightly concave, each lobe with a lightly sclerotized lateral ridge in ventral third; PP thin, moderately long, curving gently upward, apices minutely club shaped; area between PA and ostium broadly membranous; DB sclerotized, forming a large, funnel-shaped structure, its surface striate; ostium asymmetrical, twisted to left side; junction of DB and CB constricted, with a small patch of internal denticles; CB an upright oval, its surface membranous, minutely striate, basal third abruptly narrower, its surface smooth, lightly sclerotized; signum small, irregular, slightly concave, its inner surface bearing a few minute denticles; DS attached to dorsum of sclerotized basal portion of CB on right side.

Etymology

This species is named in honor of Ron Leuschner, who has been avidly collecting Lepidoptera for over 60 years. His collecting efforts in the Neotropics, especially in Ecuador, Peru, and Amazonian Brazil, provided invaluable material for this study. Ron is a former president of the Lepidopterists' Society, and is currently a research associate of the Los Angeles County Museum.

Distribution

Polypoetes leuschneri is endemic to the Pacific slope of the Ecuadorian Andes (fig. 109). Almost all existing specimens were collected at a single site—Tinalandia (Pichincha), west of Quito, at approximately 700 meters elevation. However, a single example from the CMNH (JSM-1754) was captured in Azuay Province. Not only does this specimen extend the altidudinal limits of P. leuschneri up to 1200 meters, but it also expands the geographical range southward roughly 400 km. Thorough sampling will probably reveal that P. leuschneri occurs along the foothills of the Andes for nearly the entire length of Ecuador. In all probability, the moth also lives in southwestern Colombia.

Discussion

Polypoetes leuschneri belongs in a well-defined subclade of the Haruspex Group that includes P. approximans, P. subcandidata, and P. sublucens (pls. 10, 11). In all these, male Tg8 bears a lobelike central process on its posterior margin (figs. 97C, 108B, 113B), and the posterior margin of St8 is broadly concave with acute processes at the posterolateral angles (figs. 97B, 108E, 113D). At the apex of the aedeagus in this clade, narrow dorsal and ventral sclerites extend onto the vesica. The ventral sclerite is dentate, forming an elbowlike bend (fig. 108C). A fifth member of the group, as yet undescribed, is known from a single male collected at San Rafael Falls (pl. 41A) in Sucumbíos Province, eastern Ecuador (leg. J.S. Miller, 29 Oct 1988).

Two members of this clade—P. approximans and P. subcandidata—exhibit white on the HW dorsal surface, quickly setting them apart. Means for separating the remaining taxa, P. leuschneri and P. sublucens, are outlined in the diagnosis (above), as well as in the species keys. The various taxa in this group can be readily separated by their uncus shapes, by the shape of their socii, and by differences in structure of the lateral processes on female St7 (e.g., fig. 97G, 108G). Of the four described members of this “sublucens subclade”, P. leuschneri is the only one in which the scales around the perimeter of the front are yellow, rather than being buff colored to creamy white.

A feature of the female genitalia in P. leuschneri is worthy of note: the large, funnel-shaped ostium of the DB is asymmetrical (fig. 108D), with the opening itself being twisted slightly to the left. The corresponding excavation on St7, where the ostium emerges, is also asymmetrical (fig. 108G). Asymmetry also occurs in females of P. sublucens (fig. 113E), the apparent sister species of P. leuschneri, but not in P. approximans (fig. 97E). Females are unknown for the fourth member of this subclade—P. subcandidata. While not uncommon within the Noctuoidea, female asymmetry is rare in the Dioptinae. The only other occurrence is in Momonipta onorei, a taxon far removed from Polypoetes on the dioptine cladogram (fig. 3).

Although nothing is known concerning the biology of P. leuschneri, its close relationship with P. approximans from Costa Rica is intriguing. Since larvae of P. approximans feed on Pachira aquatica (table 4), a genus in the Malvaceae, future attempts to find the host plant of leuschneri should focus on Pachira and its relatives.

Holotype

Male. Ecuador: Pichincha: Tinalandia, 600 m, 16 km E Santo Domingo de los Colorados, 18–22 Apr 1990, leg. Brian Harris (LACM). The type is deposited at the LACM.

Paratypes

Ecuador: Pichincha: 1♂, Tinalandia, 600 m, 16 km E Santo Domingo de los Colorados, 18–22 Apr 1990, leg. Brian Harris (LACM); 7♂♂, 3♀♀, Santo Domingo de los Colorados, 700 m, 22 Sep 1970, leg. R.E. Dietz IV (EMEC; male genitalia slide no. JSM-1321); 1♂, Tinalandia, 700 m, 19 May 1985, leg. C.V. Covell Jr. (AMNH); 7♂♂, 2♀♀, Tinalandia, 17 km SE Santo Domingo de los Colorados, 3000 ft, 16–22 Oct 1988, black light, leg. J.S. Miller (AMNH; ♂ genitalia slide no. JSM-441, ♀ genitalia slide Nos. JSM-442, JSM-1753).

Other Specimens Examined

Ecuador: Azuay: 1♂, 18 km SE Jesús María, 1200 m, 10 Nov 1987, wet forest habitat, leg. J. Rawlins, C. Young & R. Davidson (CMNH; genitalia slide no. JSM-1754).

Dissected

4♂♂, 2♀♀.

Polypoetes mara Hering

Plate 12

Polypoetes mara Hering, 1925: 517.

Type Locality

Peru, Vilcanota, 3000 m, “pr. Cuzco”.

Type

Holotype ♂, leg. O. Garlepp, 1898 (ZMH).

Discussion

The only known example of P. mara is the ZMH holotype (pl. 12). Its head and body are completely dark chocolate brown, with no markings of any kind. The wing ventral surfaces differ from the dorsal surfaces in exhibiting a light yellow FW streak from the base, behind the cubital vein, and in having two light yellow HW streaks from the base, one within the DC, the other behind the cubitus. The labial palpi of P. mara are unusual in being covered with erect, bristlelike scales, especially along their ventral surfaces. This trait is shared with at least four additional members of the Haruspex Group—P. exclamationis, P. fuliginosa, P. marginifer, and P. picaria (pl. 12)—all of which are endemic to the eastern Andes of Peru and Bolivia. Within this clade, the male genitalia of P. mara are unusual in that the uncus is broadly tapered at its apex, rather than forming a narrow process with a bifid apex (e.g., fig. 106A). This tapered uncus, as well as the shape of Tg8, St8 and the valvae, suggests a possible sister-group relationship between P. mara and P. marginifer.

Distribution

Peru (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1758).

Polypoetes marginifer Dyar

Plate 12

Polypoetes marginifer Dyar, 1913: 649.

Type Locality

Peru, Tincochaca, 7000 ft.

Type

Holotype ♂, “Yale Peruv Exp”, 10 Aug 1911 (USNM type no. 15650).

Discussion

I know Polypoetes marginifer exclusively from the holotype (pl. 12). As noted above, similarities in male genitalia ally P. marginifer with four species—P. exclamationis, P. fuliginosa, P. mara, and P. picaria—all high altitude Polypoetes from Bolivia and eastern Peru.

Earlier workers on the Dioptinae somehow missed the name marginifer; it does not appear in Bryk (1930), Hering (1925) or Prout (1918). Dyar, who was extremely active in many other moth groups, such as the Limacodidae (see Epstein, 1996), described this one species of Dioptinae. A long, handwritten note on the pin of the P. marginifer type, partly in English and partly in French, explains wing-pattern differences between it and P. fuliginosa (pl. 12). Polypoetes marginifer differs mainly in being smaller, and in having a much larger white central area of the HW; dark scales are restricted to a narrow band around the margin.

Distribution

Peru (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1115).

Polypoetes nigribasalis Hering

Plate 11

Polypoetes nigribasalis Hering, 1925: 516.

Type Locality

Venezuela, Mérida.

Type

Holotype ♂, leg. Bricenno (ZMH).

Polypoetes clarata Hering, 1925: 516. New synonymy.

Type Locality

Venezuela, Cucuta.

Type

Holotype ♂; not seen (in Bastelberger Collection, Senckenberg Museum).

Discussion

It is my determination that P. nigribasalis and P. clarata, both described by Hering (1925) and both from Venezuela, are synonyms. I have chosen nigribasalis as the valid name because its type (ZMH) is more accessible than the type of clarata, which is supposedly in the Bastelberger Collection at the Senckenberg Museum, but which I have been unable to locate.

My identification of clarata is based on comparison of available specimens, collected at the type locality, with the figure in Hering (1925). I dissected two Venezuelan males—one from Rancho Grande (JSM-482) and one from Cucuta (JSM-1095)—as well as a female from Portachuelo Pass, near Rancho Grande. All match the figure of P. clarata (Hering, 1925: fig. 69f) with precision. Comparison of their genitalia with those of the P. nigribasalis holotype (JSM-1412) shows that nigribasalis and clarata constitute a single taxon.

Polypoetes nigribasalis belongs in a clade with P. fenestrata (Bolivia), P. haruspex (Central America), P. copiosa (western Ecuador), and P. selenia/obtusa (Brazil). All of these species (pl. 11) show similarities in size, body coloration and wing pattern, as well as in features of the labial palpi and front. Their genitalia are similar, but males exhibit differences in the shape of the distal margins of Tg8 and St8, as well as in the shape of the uncus.

Distribution

Venezuela (IZA, USNM, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1412); ♂, Venezuela, Aragua, Rancho Grande, 1100 m, 15 Aug 1950, leg. F. Fernandez Yepez, IZA (genitalia slide no. JSM-482); ♂, Cucuta, Venezuela, Collection Wm. Schaus, USNM (genitalia slide no. JSM-1095); ♀, Venezuela, Aragua, Portachuelo Pass, 1100 m, Aragua, 1–7 Aug 1967, leg. R.W. Poole, USNM (genitalia slide no. JSM-1096).

Polypoetes nubilosa (Warren)

Figures 90A–C, 90K, 94C–F, 95A, 110; plate 11 [EX]

Phaeochlaena nubilosa Warren, 1900: 128.

Type Locality

Ecuador, Chimbo, 1000 ft.

Type

Holotype ♂, leg. Rosenberg, Jul 1897 (BMNH).

Discussion

Polypoetes nubilosa, a common Polypoetes species, is endemic to midelevations along the western slope of the Ecuadorian Andes. This taxon is often represented by large series in museum collections; I have collected P. nubilosa in huge numbers at Tinalandia, Ecuador, flying along trails during the day. Occasionally, the moths are attracted to lights. The species is notable for its narrow, Y-shaped male Tg8 (fig. 110C).

Caterpillars of P. nubilosa were reared on balsa, Ochroma pyramidale (Malvaceae), by A. Barragán and G. Onore (Ecuador, Cotopaxi, La Mana Guasaganda, 500 m, 1995). This is the only species of Dioptinae so far discovered on balsa, but additional members of the Haruspex Group are associated with Malvaceae (table 4).

Distribution

Ecuador (AMNH, BMNH, CMNH, LACM, USNM).

Dissected

♂, Ecuador, Pichincha, Tinalandia, 17 km SE Santo Domingo de los Colorados, 3000 ft, blk. lt., 22 Oct 1988, leg. J.S. Miller, AMNH (genitalia slide no. JSM-436); ♀, Ecuador, Pichincha, Tinalandia, 17 km SE Santo Domingo de los Colorados, 3000 ft, blk. lt., 17 Oct 1988, leg. J.S. Miller, AMNH (genitalia slide no. JSM-437).

Polypoetes obtusa (Walker)

Plate 11

Arina obtusa Walker, 1856: 1663.

Type Locality

“Brazil”.

Type

Syntype ♂; not seen (BMNH).

Discussion

I was unable to locate Walker's type of obtusa, cited by him as being “in Mr. Saunders' collection”. However, a series of moths at the BMNH, identified as P. obtusa (4♂♂, 10♀♀), corresponds to Walker's description. They also match the wing pattern of P. obtusa as figured in Hering (1925: fig. 69e). Dissections from the BMNH series (JSM-491, 492) suggest that P. obtusa is closely related to the Venezuelan species P. nigribasalis Hering. Furthermore, the genitalia of material identified at the BMNH as P. selenia (pl. 11) are identical with specimens of P. obtusa—both moths are from Castro, Paraná, Brazil—and their wing patterns are the same. I was unable to find key characters for separating the two. Thus, selenia C. and R. Felder (1874) may be a junior synonym of obtusa Walker (1856). I leave resolution of this issue to future species-level revisionary work.

Distribution

Brazil (BMNH, NMW, VOB).

Dissected

♂, Brazil, Paraná, Castro, leg. E.D. Jones, BMNH (genitalia slide no. JSM-491); ♀, Brazil, Espirito-Santo, ex coll. Fruhstorfer, BMNH (genitalia slide no. JSM-492).

Polypoetes picaria Warren

Plate 12

Polypoetes picaria Warren, 1904: 18.

Type Locality

Peru, Marcapata, 10,800 ft.

Type

Syntype ♂/♀, leg. Ockenden (BMNH).

Astyochia punctata Druce (see Prout, 1918: 411).

Type Locality

Bolivia, La Paz, 1000 m, leg. Garlepp.

Type

Syntype ♂ (BMNH).

Polypoetes cryptophleps Hering, 1925: 516.

Type Locality

Peru, Vilcanota, 3000 m, “pr. Cuzco”.

Type

Syntype ♂ (ZMH).

Discussion

Polypoetes picaria, endemic to eastern Peru and northern Bolivia at an altitude of approximately 3000 meters, belongs in a small clade of four species along with P. mara and others (see above). Hering (1925: 516) described cryptophleps as a subspecies of picaria, and Bryk (1930) placed the former in synonymy. I have not dissected Hering's type, but my dissection of a USNM specimen matching the wing pattern of P. cryptophleps shows that its male genitalia are identical with those of picaria, supporting its status as a synonym.

Not having dissected the syntype of punctata Druce, I follow Prout (1918: 411) and subsequent authors in treating it as being conspecific with picaria. The respective types differ only in that punctata (FW length  =  10.0 mm) is somewhat smaller than picaria (FW length  =  11.5 mm). The former is from a lower altitude (1000 m), so further research regarding the status of punctata is warranted.

The MUSM collection in Lima contains three specimens of an undescribed Peruvian species whose wing pattern and male genitalia align it with P. picaria. Label data are as follows: ♂, Peru, Junín, Cordillera de Vilcabamba, 2015–2050 m, 1133/7338, 21–30 Jun 1997, leg. A. Sanchez (genitalia slide no. JSM-1571).

Distribution

Peru (BMNH, USNM, ZMH); Bolivia (BMNH, USNM).

Dissected

♂, Bolivia, Yungas la Paz, BMNH (genitalia slide no. JSM-543); ♂, Peru, 3000 m, 1903, USNM (genitalia slide no. JSM-1120); ♀, Peru, 3000 m, 1903, USNM (genitalia slide no. JSM-1119).

Polypoetes prodromus Hering

Plate 11

Polypoetes prodromus Hering, 1925: 515.

Type Locality

Bolivia, Rio Tanampaya (La Paz).

Type

Holotype ♂, leg. Garlepp, 1894 (ZMH).

Discussion

Only two specimens of Polypoetes prodromus are known: the ZMH holotype (pl. 11) and a male at the BMNH. The presence of a bifid process at the apex of the uncus demonstrates membership in a subclade of the Haruspex Group (table 5). Within this group, the position of P. prodromus is unresolved. The posterior margins of male segment 8 are simple, without excavations or processes, thus providing few additional hints regarding the affinities of this taxon.

Distribution

Bolivia (NMHL, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1757).

Polypoetes selenia (C. and R. Felder)

Figure 111; plate 11

Stenoplastis selenia C. and R. Felder, 1874: pl. 105, fig. 17.

Type Locality

Brazil, Brasilia.

Type

Syntype ♀ (BMNH).

Discussion

The female syntype of P. selenia is in horrible condition. A series of identified material, also at the BMNH, corresponds closely with the type. Based on study of those, P. selenia may be a junior synonym of P. obtusa Walker (1856); the male genitalia of so-called “selenia” (fig. 111) are indistinguishable from those of P. obtusa Walker (1856)—the aedeagus in both shows an unusual dorsal process near its apex (fig. 111C), in addition to the typical ventral tooth. The moths are identical in wing pattern as well. Both sets of specimens were collected at Castro, Paraná. The moth figured by C. and R. Felder (1874: pl. 105, fig. 17) differs from the selenia type in lacking a subapical FW spot; the type shows a distinct, orange spot near the FW apex. This ambiguous situation cannot be resolved until the respective types are dissected, which I leave for future work.

Within the Haruspex Group, obtusa/selenia belongs in a clade that includes P. haruspex (Central America), P. nigribasalis (Venezuela), P. copiosa (Ecuador), and P. fenestrata (Bolivia).

Distribution

Brazil (BMNH).

Dissected

♂, Brazil, Paraná, Castro, BMNH (genitalia slide no. JSM-493); ♀, Brazil, Paraná, Castro, E.D. Jones Coll., BMNH (genitalia slide no. JSM-494).

Polypoetes semicoerulea Dognin

Figure 112; plate 11

Polypoetes semicoerulea Dognin, 1910b: 159.

Type Locality

Colombia, San Antonio, “près Cali”, 1800 m.

Type

Syntype ♂, leg. Fassl, Feb 1909 (USNM type no. 30927).

Discussion

This species is unusual in exhibiting uniformly black wings (pl. 11), the only marking being a semihyaline, transverse ovoid FW fascia beyond the DC. Polypoetes semicoerulea could potentially be confused with P. leuschneri, sp. nov. (pl. 11), but is distinguished by a larger and more hyaline FW fascia. It also shares wing-pattern similarities with P. bifenestra (pl. 14), a member of the Rubribasis Group. However, these can easily be separated because members of the Rubribasis Group possess short labial palpi (fig. 89A, C) and subserrate male antennae (fig. 92A), whereas P. semicoerulea shows traits typical of the Haruspex Group—elongate palpi and bipectinate male antennae. The species with which Polypoetes semicoerulea would most likely be confused is Argentala subcaesia (Prout) (pl. 10). Again, however, basic morphological differences distinguish the two. For example, Argentala males possess subserrate antennae (fig. 82A, B).

The two male syntypes, both at the USNM, are the only specimens of semicoerulea I have seen. Discovery of females may provide characters to further elucidate the phylogenetic position of this taxon.

Distribution

Colombia (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1011).

Polypoetes subcandidata Dognin

Plate 10

Polypoetes subcandidata Dognin, 1910b: 159.

Type Locality

Colombia, Juntas, Dagua, 300 m.

Type

Syntype ♂, leg. Fassl, May 1909 (USNM type no. 30926).

Polypoetes satanas Hering, 1925: 514; fig. 69d. New synonymy.

Type Locality

Colombia, Las Jimenez, 2400 ft.

Type

Holotype ♂; not seen (in the Bastelberger Collection, Senckenberg Museum).

Discussion

Polypoetes subcandidata belongs in a difficult species complex that includes P. approximans and P. sublucens. In all three, the FW ground color is dark brown, and there is a faint FW fascia beyond the DC. The HW dorsal surface of P. sublucens is blackish brown (pl. 11), whereas in P. approximans and P. subcandidata the central area is white (pl. 10). Differences in genital morphology are extremely subtle. For example, the only discernible difference between P. subcandidata and P. sublucens is that the uncus of P. sublucens (fig. 113A) is more acute at its apex.

After considerable study, accompanied by hours of confusion, I have retained all three as valid species. The only taxonomic change made here is to place satanas Hering (1925) in synonymy with subcandidata Dognin. This is done without having seen Hering's type, supposedly in the Senckenberg Museum, Frankfurt. I do not generally endorse such practice, and have not done it elsewhere in this paper. However, the moth Hering figured as P. satanas (1925: fig. 69d) is a precise match with the type of P. subcandidata, and both are from western Colombia. I therefore feel comfortable in making this proposal.

As is noted in the discussion for P. approximans (above), it can be easily separated from P. subcandidata by differences in eye size, the eyes of P. subcandidata being significantly larger.

Distribution

Colombia (AMNH, JBSC, USNM, ZMH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1089); ♂, Colombia, Valle, Anchicaya, 650 m, 3 Feb 1989, leg. J. Bolling Sullivan, JBSC (genitalia slide no. JSM-363); ♂, Colombia, AMNH (genitalia slide no. JSM-364).

Polypoetes sublucens Dognin

Figure 113; plate 11 [EX]

Polypoetes sublucens Dognin, 1909: 225.

Type Locality

Colombia.

Type

Syntype ♂, leg. Fassl (USNM type no. 30925).

Discussion

The male and female genitalia of Polypoetes sublucens (fig. 113), from eastern Colombia, show numerous synapomorphies with those of P. approximans (fig. 97), P. subcandidata, and P. leuschneri (fig. 108). These four species form a tightly knit subclade of the Haruspex Group. Within it, Polypoetes sublucens and P. leuschneri exhibit a dark brown HW dorsal surface (pl. 11); the other two show a large white central area (pl. 10). Characteristics for separating P. sublucens and P. leuschneri are outlined in the species description of the latter.

Polypoetes sublucens is the only taxon within this subclade endemic to the eastern side of the Andes; all the others are western. However, a single AMNH specimen from San Rafael Falls in eastern Ecuador (00°06′13.7″S, 77°35′16.2″W; pl. 41A) represents an as yet undescribed species. Here, the FW and HW are completely dark (almost black) above, and there is no FW fascia. It thus corresponds closely with P. sublucens. In the San Rafael moth, the FW veins are conspicuously bright yellow against the dark ground color. Ventrally, the white markings are similar to the sublucens type. Its genitalia, however (JSM-1123), differ from sublucens and from all other Polypoetes.

Distribution

Colombia (BMNH, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1090); ♂, Colombia, leg. Fassl, USNM (genitalia slide no. JSM-1093); ♂, Colombia, Valle, San Antonio, 2000 m, 20 Sep 1908, leg. Fassl, USNM (genitalia slide no. JSM-1566); ♀, Colombia, Valle, San Antonio, Cali, leg. Fassl, USNM (genitalia slide no. JSM-1094); ♀ Syntype, Colombia, Río Agnatal, 1600 m, 18 Jul 1908, leg. Fassl, USNM (genitalia slide no. JSM-1567).

Polypoetes suffumosa Dognin, revised status

Plate 11

Polypoetes suffumosa Dognin, 1902: 476.

Type Locality

Argentina, Tucumán.

Type

Syntype ♂, leg. P. Girard (USNM type no. 30939).

Discussion

This species, described in Polypoetes by Dognin (1902) but inexplicably assigned to Tithraustes by Prout (1918: 409)—where it has remained (Hering, 1925; Bryk, 1930)—is here transferred back to Polypoetes; P. suffumosa exhibits the typical characters of Polypoetes, including the presence of extremely long, elbowed labial palpi in males. Polypoetes suffumosa is known exclusively from Argentina, with the vast majority of material in collections, including the type, having been captured at or near Tucumán. However, three specimens at the FML were collected at Pto. Bemberg, Iguazú, in the northeastern region of Argentina near its borders with Brazil and Paraguay. I did not dissect these to determine whether they differ from nominate suffumosa.

A single USNM specimen from Chiriquí, Panama, is almost identical in appearance to P. suffumosa. However, its male genitalia (JSM-1572) reveal it to be an undescribed taxon, the apparent sister species of P. suffumosa.

Distribution

Argentina (AMNH, BMNH, FML, MNHN, USNM, ZMC).

Dissected

Syntype ♂ (genitalia slide no. JSM-926); ♂, Argentina, Tucumán, FML (genitalia slide no. JSM-463); ♀, Argentina, Tucumán, Dognin Coll., USNM (genitalia slide no. JSM-1390).

Polypoetes tenebrosa Warren

Plate 11

Polypoetes tenebrosa Warren, 1907: 199.

Type Locality

Peru, Carabaya, Oconeque, 7000 ft.

Type

Holotype ♂, leg. G. Ockenden, “dry s.”, Jul 1904 (BMNH).

Discussion

Polypoetes tenebrosa (pl. 11) is one of the smallest species in the genus (FW length  =  9.0–12.0 mm). It resembles two other Haruspex Group taxa—P. sublucens and P. leuschneri (pl. 11)—in that the FW and HW dorsal surfaces are completely dark, and the wing veins are lined with yellow-orange. However, a glance at the wing ventral surfaces quickly separates P. tenebrosa from these others; both P. sublucens and P. leuschneri show bold silvery white basal markings on the FW and HW (pl. 11), whereas the ventral surfaces in P. tenebrosa (pl. 11) are brown. Finally, a synapomorphy appearing in a subset of Haruspex Group species (table 5), presence of a forked apical process on the uncus (e.g., fig. 114A), is well developed in P. tenebrosa but does not occur in either P. sublucens (fig. 113A) or P. leuschneri (fig. 108A).

I know Polypoetes tenebrosa from four BMNH males (including the holotype), as well as from a single female in the ZMH collection. George R. Ockenden collected all of this material on the same date in 1904, and at the same locality in southeastern Peru. Ockenden was born in Brighton, England, in 1868 (see obituary in Hartert, 1907), leaving London in 1900 to collect butterflies, moths, birds, reptiles, and mammals in Peru. His remarkable Lepidoptera collections, the bulk of which are at the BMNH, were an invaluable resource for this research. Ockenden remained in Peru until his death in 1906, at the age of 40, which resulted from typhoid fever contracted during an expedition near Tirapata.

Distribution

Peru (BMNH, ZMH).

Dissected

♂, Peru, Oconeque, Carabaya, 7000 ft, dry season, Jul 1904, leg. G. Ockenden, BMNH (genitalia slide no. JSM-495).

Polypoetes trimacula (Warren)

Plate 11

Stenoplastis trimacula Warren, 1904: 18.

Type Locality

Colombia, Río Dagua.

Type

Holotype ♂, leg. W. Rosenberg (BMNH).

Discussion

Polypoetes trimacula (pl. 11) bears a striking resemblance to Polypoetes pellucida (pl. 14) in the Rubribasis Group, but belongs instead in the Haruspex Group. The two can easily be separated because P. trimacula has long labial palpi and pectinate male antennae, whereas P. pellucida possesses short labial palpi and ciliate male antennae, characteristics of the Rubribasis Group.

The male genitalia of P. trimacula are unusual for Polypoetes; the uncus is completely absent, the long thin socii are simple, and Tg8/St8 are unlike other members of the genus. However, I have placed this species in the Haruspex Group because of its large, funnel-shaped ostium of the female genitalia.

A USNM female from Loja, southern Ecuador, is indistinguishable from P. trimacula (FW length  =  12.0–13.5 mm), except that its wings are slightly longer (FW length  =  14.0 mm). Based on its disjunct locality, this may represent an undescribed species. Anton Fassl collected all confirmed examples of P. trimacula (8♂♂, 2♀♀) in central Colombia.

Distribution

Colombia (BMNH, USNM, ZMH); Ecuador (USNM).

Dissected

♂, Colombia, Cañon del Tolima, 1700 m, Oct 1909, leg. Fassl, BMNH (genitalia slide no. JSM-542); ♂, Colombia, Cañon del Tolima, 1700 m, Oct 1909, leg. Fassl, USNM (genitalia slide no. JSM-1124); ♀, Colombia, El Eden, Quindiu, 2600 m, Sep 1909, leg. Fassl, USNM (genitalia slide no. JSM-1125).

Polypoetes tulipa, new species

Figures 103, 114; plate 12

Diagnosis

The wing pattern of this species (pl. 12) is similar P. exclusa (pl. 13), from Colombia. Polypoetes tulipa differs in that the FW fascia beyond the DC is larger, and the HW central area is white, rather than being light yellow as in P. exclusa. Their male genitalia differ markedly, indicating placement in different species groups of Polypoetestulipa in the Haruspex Group, and exclusa in the Rufipuncta Group (appendix 2).

Description

Male (pl. 12). Forewing length  =  13.5 mm. Head: Labial palpus greatly elongate, curving upward to antennal base, folded elbowlike over front; Lp1 moderately long, curved slightly upward, all surfaces loosely covered with white scales; Lp2 elongate, over twice as long as Lp1, bowed gently outward, dorsal, ventral, and mesal surfaces white, lateral surface with a longitudinal stripe of gray-brown scales, stripe narrow at base, widest near apex; apex of Lp2 scaleless on mesal surface, finely spiculate, dorsal surface bearing a tuft of white to light brown scales extending beyond Lp3; Lp3 short, conical, gray-brown to light brown, mesal surface spiculate; front covered with upwardly pointing scales, central portion brown, lateral areas beige to creamy white; lateral scales of front longest above, forming a pair of whitish to beige tufts between antennal bases; occiput brownish black in upper half, white to cream colored in lower half; eye moderately large, surrounded by a scaleless band, this narrowest posteriorly, wider anteriorly and dorsally, gena broadly scaleless; eye evenly covered with short setae; vertex covered with long, anteriorly pointing, blackish-brown scales, a few scattered, long white scales; antenna bipectinate, rami moderately long; scape glossy blackish brown, inner surface white; dorsum of antennal shaft glossy dark gray, trimmed on each side with a row of white scales.

Thorax: Inner surfaces of legs white to creamy white, outer surfaces glossy gray-brown; spurs creamy white; tarsi cream colored on inner surfaces, light gray-brown laterally; pleuron covered with long, white scales and a few shorter gray scales; patagium with long, erect blackish-brown scales, lined anteriorly and posteriorly with long white scales; tegula moderately long, central portion orange-yellow, fringed laterally with hairlike, dark coppery brown scales; dorsum blackish brown, with a pair of diffuse, orange-yellow stripes on either side of midline; tympanum relatively small, open, comprising a shallow scaleless depression; tympanal membrane moderate in size, roughly triangular, facing lateroposteriorly.

Forewing: (Dorsal) Ground color uniformly blackish brown (pl. 12); veins, excluding costa but including anal fold, lined with yellow-orange to light yellow scales; veins Rs2–Rs4 arising close together in the arrangement 2+[3+4]; a large, slightly transverse, ovoid fascia immediately beyond DC, its anterior margin falling short of base of radial sector, its posterior margin touching fork of M3+CuA1, fascia widest posteriorly; surface of fascia glassy, covered with pedicellate white scales; base of veins M1 and M2 sparsely lined with light yellow and dark brown scales as they pass through fascia; a conspicuous, orange-yellow, broadly trident-shaped subapical spot formed at the bases of Rs2–Rs4; fringe dark coppery gray. (Ventral) Similar to dorsal surface except: ground color dark charcoal gray; veins not lined with orange; a white triangle in basal third, extending from anterior margin of DC to anal fold, its lateroposterior angle extended distally; Sc white in basal third; surface of translucent fascia covered with erect, paddle shaped white scales.

Hind wing: (Dorsal) Ground color blackish gray from base, outer margin broadly banded with black from apex to tornus (pl. 11); a white, roundish central area formed in distal portion of DC, extending from base of Rs+M1 anteriorly to anal fold posteriorly, white area contiguous with a translucent fascia immediately beyond DC; surface of fascia glassy, covered with erect, pedicellate white scales; fringe glossy gray-brown; anal margin trimmed with long gray scales. (Ventral) Silvery white from base, extending out to wide, blackish gray band along outer margin; white area encompassing translucent fascia beyond DC; surface of fascia covered with erect, pedicellate white scales; anal margin fringed with a mixture of white and dark gray hairlike scales.

Abdomen: Dorsum dark gray, venter white.

Terminalia (fig. 114): Tg8 long and narrow, sides almost parallel, slightly expanded near middle; anterior margin of Tg8 strongly concave, with long, thin apodemes at lateral angles; posterior margin of Tg8 sclerotized, expanded slightly at lateral angles, curled downward, dorsum with a short, shallow groove along midline; St8 wider and slightly longer than Tg8, roughly rectangular; anterior margin of St8 convex, with a small triangular fold, posterior margin sclerotized, with short, broad flanges near lateral angles, a shallow mesal excavation; socii/uncus complex large, heavily sclerotized, triangular, extremely wide at base; uncus long, forming a scissorlike process at apex; socii a pair of extremely long arms, wide at base, acute at apex, with a small subapical flange, a set of long, coarse setae on lateral surfaces; tegumen short, slightly expanded at junction with socii/uncus complex; vinculum short, narrow; valva short, wide, mostly membranous, inner surface coarsely setose; BO relatively large, curled anteriorly, occupying over one-third of valva; valva apex mostly membranous, slightly expanded; costa short, extremely wide at valva base, much narrower toward apex; basal sclerites at valva bases wide; lower margin of saccus horizontal, with a triangular sclerite extending upward to cover valva bases; transtillar arms wide at bases, abruptly narrowed, arching downward, meeting at midline to form an elongate, narrow sclerite; aedeagus long, widest at base, slightly constricted in basal third; apex of aedeagus boat shaped, terminating in a small, hook-shaped tooth; vesica relatively small, distal half evenly covered with small, thornlike cornuti, some of these minutely bifid, a few trifid.

Female. Unknown.

Etymology

This name is from the Latin word for “tulip”, and refers to the orange, tulip-shaped subapical spot in the FW, formed at the base of veins Rs2–Rs4.

Distribution

Since only a single specimen of P. tulipa is known, it is premature to speculate on its distribution. The moth was collected in southeastern Peru (fig. 103), along a scenic portion of the road descending from Pillahuata (2400 m) to Pilcopata (600 m), at an altitude of 1600 meters.

Discussion

Polypoetes tulipa belongs in the “forked uncus” subclade within the Haruspex Group (table 5). Comparing the morphology of known taxa, P. tulipa is the apparent sister species of P. forficata, sp. nov., from Ecuador (pl. 12); male genitalia in the two are similar in almost every respect, including the size and shape of their uncus forks (figs. 105A, 114A). Polypoetes tulipa and P. forficata can best be separated by the shape of Tg8 (figs. 105D, 114D)—which is extremely narrow, almost straplike in forficata—as well as by the shape and width of the valval costa (figs. 105A, 114A), which is wide at its base in tulipa.

A single male, collected by Brian Harris (Smithsonian Institution), is nearly identical to the holotype of P. tulipa in size and wing pattern. This specimen was captured further south, on the eastern slope of the Bolivian Andes. Its wings show yellowish white, rather than immaculate white markings, and differ in another important aspect; the FW fascia is smaller, not extending anteriorly beyond vein M1. In P. tulipa this fascia extends almost to the radial sector. The Bolivian male exhibits genital morphology extremely similar to that of P. tulipa, differing most noticeably in valva shape. I conclude that the USNM example represents an undescribed species, closely related to P. tulipa. This finding strengthens the argument that species diversity for Andean Polypoetes remains largely undiscovered. Label data for the undescribed taxon are as follows: Bolivia, La Paz, Cumbre Alto Beni, 1500–1700 m, 15°40.522′S, 67°29.348′W, road to radio tower, 12–15 Apr 2003, diurnal, leg. Brian Harris (USNM; genitalia slide no. JSM-1831).

Holotype

Male (pl. 12). Peru: Cuzco: Cosñipata Valley, Pillahuata-Pilcopata Rd., Puente Unión, 4 km W Río San Pedro, 1650 m, S13°04′03″, W71°34′02″, 27 Oct 2005, leg. J.S. Miller, 4:30 p.m. (genitalia slide no. JSM-1559). The type is deposited at the AMNH.

Paratypes

None.

Other Specimens Examined

None.

Dissected

Holotype.

Polypoetes vidua Warren

Plate 12

Polypoetes vidua Warren, 1909: 72.

Type Locality

Peru, Limbani, Carabaya, 10,000 ft.

Type

Syntype ♀, leg. Ockenden, wet season, Nov 1901 (BMNH).

Discussion

The only specimens of P. vidua I was able to locate are the male and female syntypes. Neither was dissected. Data for the female are listed above, while the male (pl. 12) is as follows: Peru (SE), Agualani, 9000 ft, Mar 1904, leg. Ockenden, Rothschild Bequest B.M. 1939-1 (BMNH).

Based on superficial study of that material, P. vidua belongs in the Haruspex Group; its wings are similar to those of P. bistellata (pl. 12) from Argentina, and to P. exclamationis (pl. 12) from Bolivia. I predict that dissection will reveal P. vidua to belong in the bifid-uncus subgroup of Polypoetes (table 5).

Distribution

Peru (BMNH).

Dissected

None.

Polypoetes villia Druce

Figures 89B, 90G, 90H, 115; plates 11, 38B [EX]

Polypoetes villia Druce, 1897: 409, pl. 78, fig. 55.

Type Locality

Panama, Chiriquí (♂).

Type

Syntype ♂/♀, leg. Trotsch, 1886 (ZMH).

Polypoetes denigrata Hering, 1928: 272, pl. 8, fig. 3. New synonymy.

Type Locality

Costa Rica, Orosí.

Type

Holotype ♂, leg. Fassl (ZMH).

Phaeochlaena longipalpis Warren, 1901: 442.

Type Locality

Panama, Chiriquí.

Type

Syntype ♂ (BMNH).

Discussion

Material identified as Polypoetes villia is common in collections, but resolving the identity of this taxon and its associated names—longipalpis and denigrata—has proved to be difficult. Dissections confirm the existence of three cryptic species, all of which co-occur in Costa Rica, but my attempts to associate each of those with an available name have met with frustration. I have been able to establish the following:

Hering (1928) described Polypoetes denigrata subsequent to his contribution in Seitz (1925). My studies suggest that the P. denigrata holotype female, from Orosí, Costa Rica, is conspecific with the female syntype of P. villia Druce, collected at Chiriquí. Both types are housed in the ZMH collection, and during a visit to that museum (February 2005) I was able to examine each in detail. Comparison of the sclerites surrounding the ostium, visible in intact specimens, reveals them to be alike in all respects. The FW ground color of the P. denigrata type is darker than most P. villia, but the latter seems to show considerable intraspecific color variation. I here place denigrata Hering in synonymy.

The male syntype of P. longipalpis (Warren), formerly regarded as a synonym of P. villia (Bryk, 1930), was captured at Chiriquí, the type locality for P. villia. The socii of the longipalpis type (JSM-1146) are striking because each arm possesses a long, digitate process, arising from the bladelike distal margin, thus giving the socii an “antlered” appearance. This modification is absent in most males identified as P. villia (fig. 115A). An AMNH male from Chiriquí (JSM-1570) does not exhibit antlered socii. Thus, it is confirmed that at least two species co-occur in Chiriquí. The question remains: does the syntype male of P. villia (ZMH) bear antlered socii? Unfortunately, that specimen is missing its abdomen, so the question cannot be resolved.

In summary, genital differences demonstrate the existence of three species in the villia complex. Having established denigrata as a synonym of villia, two available names remain—villia and longipalpis. At present, it is impossible to resolve whether those refer to the same or to different taxa. My solution for the time being is to apply the oldest name, villia, to all available material until revisionary study can be brought to bear on this problem.

In 1996, Valerie Giles (AMNH) discovered larvae of Polypoetes villia (pl. 38B) in Monteverde, Costa Rica (1300–1500 m), feeding on Malvaviscus arboreus, a liana in the Malvaceae. More recently, P. villia was found in association with M. palmanus at the Area de Conservación Guanacaste (Janzen and Hallwachs, 2008). Four species of Dioptinae are now known to be associated with the Mallow family (table 4).

My studies have uncovered at least three undescribed South American Polypoetes species related to P. villia. The first comes from a series of specimens at the USNM, apparently collected as larvae and reared on Quararibea (Malvaceae; table 4). Slide label data for this taxon are as follows: ♂, Colombia, Cundinamarca, Cachipay, 21 Nov 1973, leg. L. Nuñez, “follaje de zapote”, USNM (genitalia slide no. JSM-1568); ♀, Colombia, Cundinamarca, Cachipay, 21 Nov 1973, leg. L. Nuñez, “follaje de zapote”, USNM (genitalia slide no. JSM-1569). The other two undescribed species—one from Venezuela and one from Bolivia—are in the collections of the IZA (Maracay) and MNHN (Paris).

Distribution

Panama (AMNH, BMNH, LACM, MNHN, USNM, ZMH); Costa Rica (AMNH, BMNH, CUIC, FNHM, INBio, LACM, NMW, UCB, USNM, VOB).

Dissected

♂ syntype of longipalpis Warren (genitalia slide no. JSM-1146); ♂, Panama, May 1907, Wm Schaus Collection, USNM (genitalia slide no. JSM-1126); ♂, Panama, Chiriquí, South of Fortuna dam, behind the “Vivero”, 82°15′W, 8°43′N, 1400 m, 18 Feb 1998, leg. S. Rab Green, V. Giles, UV/MV, 7pm–2am, AMNH (genitalia slide no. JSM-1570); ♂, Costa Rica, Puntarenas, Monteverde, 1400 ft, 26 Mar 1960, leg. C.W. Palmer, AMNH (genitalia slide no. JSM-149); ♂, Costa Rica, Puntarenas, Monteverde, Pensión Quetzal, 10°18′28″–84°48′56″, 1380 m, 14–21 Apr 1990, leg. T. McCabe, AMNH (genitalia slide no. JSM-434); ♂, Costa Rica, Cartago, P. N. Tapantí, 1250 m, INBio (genitalia slide no. JSM-805); ♂, Costa Rica, San José, Heredia, El Angel Waterfall, 1350 m, 8.2 km downhill Vara Blanca, 5 Aug 1981, leg. D.H. Janzen and W. Hallwachs, INBio (genitalia slide no. JSM-192; wing slide JSM-202); ♀, Costa Rica, Puntarenas Monteverde, 4600 ft, 1 Jan 1962, leg. C.W. Palmer, AMNH (genitalia slide no. JSM-435); ♀, Costa Rica, Puntarenas, Monteverde, 4600 ft, 23 Feb 1962, leg. C.W. Palmer, AMNH (wing slide no. JSM-180; genitalia slide no. JSM-1127).

2. ETEARCHUS GROUP

The three Etearchus Group species show essentially the same wing pattern (pl. 12). There is a characteristic semihyaline, transverse ovoid FW fascia immediately beyond the DC, and within the DC a faint, thinly scaled basal streak. The HW exhibits a large, white, semitransparent central area surrounded by a wide, dark brown to blackish brown marginal band, and the anal margin is broadly gray.

This species group is mostly Central American, with two of three species known from Costa Rica and Panama. The third, P. tinalandia, is from western Ecuador. No Etearchus Group taxa have been discovered on the eastern slopes of the Andes.

Male antennae in the Etearchus Group are bipectinate, but the pectinations are unusually short. Diagnostic characteristics of the genitalia are as follows: male St8 large and robust, distal margin strongly bifid (figs. 116E, 117E, 118B); socii much longer than uncus, emarginate (figs. 116AFigure 117118A); uncus broad, simple; female Tg7 large, quadrate, with lateroposterior processes (figs. 116F, 117F); St7 large, swollen (figs. 116G, 117G); ostium somewhat flattened (figs. 116D, 117D, 118E), not funnel shaped; a large, spiculate plate present below PA.

KEY TO ETEARCHUS GROUP SPECIES

1. Lateral margins of female Tg8 roughly parallel (figs. 116F, 117F), lateroposterior margins excavated, with crestlike ridges converging on a broadly rounded mesal process; apices of male socii abruptly narrowed (figs. 116A, 117A); female St7 with an abruptly raised central area (figs. 116G, 117G)2

Lateral margins of female Tg8 diverging distally, lateroposterior margins bearing large, triangular processes, mesal process absent; apices of socii strongly curled (fig. 118A); female St7 broadly convex, without a raised central area (E Costa Rica)wagneri, sp. nov.

2. Uncus broad at apex (fig. 116A), forming a short, blunt mesal process; valva apex bearing fine setae (fig. 116A); ridges on lateroposterior angles of male Tg8 strongly emarginate (fig. 116B), with minute striae; lateral margins of female St7 gently excavated (fig. 116G); DB U-shaped (fig. 116D) (NW Panama and SW Costa Rica)etearchus Druce

Uncus narrow at apex (fig. 117A), forming a long, subacute mesal process; valva apex bearing robust setae (fig. 117A); ridges on lateroposterior angles of male Tg8 rugose (fig. 117B); lateral margins of female St7 deeply excavated (fig. 117G); DB sinuate (fig. 117D) (W Ecuador)tinalandia, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Polypoetes etearchus Druce

Figures 90D–F, 90J, 116, 119; plate 12 [EX]

Polypoetes etearchus Druce, 1885a: 160, pl. 14, fig. 24.

Type Locality

Panama, Volcan de Chiriquí, 2000–3000 ft.

Type

Syntype ♂ (BMNH).

Discussion

Ten Costa Rican Polypoetes specimens, all of which I had at first assumed to be examples of P. etearchus, were dissected for this study. Surprisingly, their genitalia demonstrated the existence of two species. Furthermore, it became apparent that the vast majority of material in museum collections is not P. etearchus, but instead represents an unrecognized species, here described as P. wagneri (below). Polypoetes etearchus is in fact relatively rare—I have seen only a handful of specimens—and appears to be restricted in distribution, occurring in southwestern Costa Rica and northwestern Panama (fig. 119). The new species, P. wagneri, on the other hand, occurs widely in Costa Rica (fig. 119) but has not been recorded from Panama. I examined the male type of P. etearchus at the BMNH, but did not dissect it. However, the genitalia of a female from the type locality, Chiriquí (JSM-1576), correspond perfectly with a Costa Rican female (JSM-802) captured in Puntarenas Province, thus confirming the existence of P. etearchus in Costa Rica.

Bryk (1930) listed P. cethegus Schaus as a synonym of etearchus, following Prout (1918) and Hering (1925). Examination of the types for these taxa shows that they are not conspecific. The name cethegus instead appears to be a synonym of eriphus Druce (appendix 2).

Male and female genitalia (JSM-1083, 1084) reveal that material from Mexico (AMNH, NMW) and Guatemala (LACM) represents a fourth, as yet undescribed species in the Etearchus Group. This taxon is smaller and drabber than the others.

Distribution

Panama (BMNH, USNM, ZMH); Costa Rica (AMNH, BMNH, USNM).

Dissected

♂, Costa Rica, Puntarenas, 35 km NE San Vito, nr Las Alturas Field Station, 1540 m, 3 Aug 1992, leg. A. Sourakov, AMNH (genitalia slide no. JSM-1110); ♀, Costa Rica, Puntarenas, 35 km NE San Vito, nr Las Alturas Field Station, Tajo Bella Vista, 1540 m, 23 Mar 1991, leg. J.S. Miller, at light, AMNH (genitalia slide no. JSM-802); ♀, Panama, Chiriquí, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1576).

Polypoetes tinalandia, new species

Figures 109, 117; plate 12

Diagnosis

Slight differences in wing coloring between the three Etearchus Group species (pl. 12) include the following: The FW and HW ground color tends to be lighter and browner in P. etearchus, whereas it is blackish gray to black in P. tinalandia and P. wagneri; the wing veins are thinly lined with light brownish orange scales in P. tinalandia, but are more boldly marked with light orange in P. etearchus and P. wagneri. These differences are subtle and difficult to evaluate without the luxury of having specimens of all three taxa sitting side by side for comparison.

Perhaps the best wing-pattern feature for separating P. tinalandia from the other two is that the stem of HW vein Rs+M1 is lined with dark gray scales, making it stand out against the white central area. In P. etearchus and P. wagneri, on the other hand, the confluence of these veins is white, like the central area. The most reliable means for identification comes from genital morphology, which provides unambiguous features for separating all three taxa (figs. 116Figure 117118).

Description

Male. Plate 12. Forewing length  =  14.0–14.5 mm. Head: Labial palpus elongate, held elbowlike over front, curving upward to immediately short of antennal base; Lp1 relatively short, wide, closely scaled with light orange-yellow scales; Lp2 greatly elongate, over twice as long as Lp1, curving gently outward (more strongly near its apex); lateral surface of Lp2 closely scaled with gray-brown, mesal surface almost bare, sparsely scaled with white, dorsal surface with a few scattered light yellow scales, a distal tuft of long gray scales extending beyond apex of Lp3; Lp3 short, conical, gray-brown laterally, bare on mesal surface; mesal surfaces of Lp2 and Lp3 bearing long, yellowish-brown spinules, these more dense on Lp3; scales of front long, pointing dorsomedially, central portion gray, lateral scales longer, whitish in ventral third, creamy white to yellowish buff in dorsal two-thirds, forming short tufts below antennal bases; occiput gray-brown in dorsal fifth, buff colored below that, creamy white in lower half; eye extremely large, bulging outward, surrounded by scales except for a narrow scaleless band along anterior margin; eye with a sparse covering of extremely short setae; vertex covered with long, forward pointing, steely gray scales; a narrow band of white behind each antennal base; antenna bipectinate, rami relatively short; scape gray-brown on upper surface, narrowly white below; dorsum of antennal shaft tightly covered with short, steely gray to gray-brown scales.

Thorax: Inner surfaces of legs white to cream colored, outer surfaces glossy gray-brown; spurs creamy white with a few gray scales laterally; pleuron covered with long, light gray and buff colored scales, a lower layer of shorter white scales; patagium steely gray, with a transverse row of long white scales anteriorly; central portion of tegula with erect, bright orange scales, margins fringed with long, hairlike gray-brown scales; dorsum gray, with a diffuse longitudinal stripe of long, whitish to buff-colored scales on each side of midline; tympanum relatively small, “open”, tympanal cavity comprising a shallow scaleless depression; tympanal membrane moderately large, ovoid, facing posterolaterally.

Forewing: (Dorsal) Ground color dark gray-brown to blackish brown, lighter gray in basal third (pl. 12); veins, excluding costa but including anal fold, thinly lined with light orange to ochreous orange scales; basal two-thirds of DC forming a thinly scaled streak, this bisected by a line of whitish orange scales; a transverse, ovoid, semihyaline fascia immediately beyond DC, its anterior margin touching base of radial sector, its posterior margin extending beyond fork of M3+CuA1; veins M1 and M2 dark brown as they pass through fascia; surface of fascia thinly scaled with elongate and short, dark gray-brown scales, their vertices notched. (Ventral) Similar to dorsal surface, except veins concolorous, not lined with orange scales; a short white dash at base; surface of fascia covered with pedicellate white scales.

Hind wing: (Dorsal) Central area translucent white (pl. 12), anterior margin of white area extending to Sc+R, extending posteriorly to posterior margin of DC, angled posteriorly at CuA2; outer margin broadly banded with gray black, band widest near apex, narrowest at fork of M3 and CuA1; marginal band converging with gray anal margin; radius, along anterior margin of DC and extending out to fork of Rs+M1, lined with gray scales; a broad gray area between cubitus and anal margin, its leading edge suffused with white scales; anal margin fringed with long gray scales. (Ventral) Similar to dorsal surface, except region between cubitus and anal margin whiter; anterior margin with a narrow white streak in basal half.

Abdomen: Dorsum slate gray to light brown, with a slight bluish iridescence; a diffuse, short, cream-colored stripe on A7 pleuron; venter white near base, creamy white to buff distally.

Terminalia (fig. 117A–C, E): Tg8 elongate, over three times as long as Tg7; Tg8 tapered toward distal margin, arching strongly upward, with a wide, shallow groove along midline, anterior margin with a short, rounded apodeme on each lateral angle, lateroposterior margins rugose, with elongate ridgelike crests, these converging distally on a large, broadly rounded, mesal apodeme; St8 extremely large, longer and wider than Tg8, slightly narrower posteriorly; surface of St8 strongly convex, arching upward, anterior margin with a relatively long, wide, somewhat tapered, mesal apodeme, its anterior margin slightly concave; posterior margin of St8 forked, each prong robust, elongate and heavily sclerotized, curving upward; socii/uncus complex extremely wide, triangular in shape, with a wide attachment to ring; uncus wide at base, gradually tapered to a narrow point at apex; socii extremely robust, long, extending upward well beyond apex of uncus, apices narrowly spatulate, inner surfaces flat and smooth, with ridgelike margins, lateral surfaces expanded outward, densely covered with spinelike setae; tegumen slightly shorter than vinculum, narrow below, wider at junction with socii/uncus complex; vinculum wide, convex, joining below to form a U-shaped ventral margin; saccus extremely large, extending upward over valva bases almost to transtilla, upper margin triangular, posterior surface of saccus with a wide, elongate ridge between valva bases below; valva extremely short, mostly membranous; BO relatively large, occupying over three-fourths of valva, curled anteriorly; costa short, moderately wide; valva apex lightly sclerotized, minutely rugose, area below apex densely covered with robust spinelike setae; aedeagus elongate, widest at base, constricted near middle; apex of aedeagus with a tiny, sclerotized lateral tooth; vesica narrow, approximately half as long as aedeagus, bearing a tight group of short, spinelike cornuti distally and a second set of longer, more widely spaced cornuti beyond those.

Female. Forewing length  =  14.5–15.0 mm. Body and wing characters similar to male, except: labial palpus shorter, extending upward to short of antennal bases; antenna ciliate; wings longer than male, ground color slightly lighter; abdomen wider; St7 completely scaleless, surface densely covered with setae, central portion forming a raised, U-shaped structure, with lateral furrows; Tg7 heavily sclerotized, scaleless, setose along posterior margin, with a raised ridge along midline.

Terminalia (fig. 117D, F, G): Tg7 extremely large, quadrate, heavily sclerotized in posterior three-fourths, anterior margin simple, lateral margins slightly excavated near middle, lateroposterior angles expanded, posterior margin bearing a wide, diffuse, transverse row of setae; St7 extremely large, central portion densely covered with setae, with a sharply raised, V-shaped area, its anterior angle forming a knoblike structure, lateral areas scaleless, deeply furrowed; anterior margin of St7 simple, lateral margins deeply excavated near middle, posterior margin irregular, sclerotized, with a shallow, V-shaped mesal excavation; Tg8 sclerotized, moderately wide, forming a rooflike structure over PA, posterior margin with a small mesal excavation; Tg8 contiguous with sclerotized A8 pleuron, posterior margin simple; AA elongate, thin, roughly straight; PA moderately large, mostly membranous, surface minutely spiculate, posterior margin simple; PP slightly shorter than AA, thin, curving slightly downward distally; area above ostium and below PA infolded to forming a large, sclerotized shelf, its dorsal surface broadly concave, covered with fine spicules; posterior margin of shelf simple, with a small mesal notch; ostium relatively large, comprising a complex set of lightly sclerotized folds; DB moderately long, membranous, dorsoventrally compressed; CB large, almost round, surface membranous, a long, narrow section posteriorly, this flattened, with several folds; signum small, ovoid, slightly concave, located dorsally, surface finely spiculate; a pair of denticulate pockets in CB membrane ventrally; DS attached at junction of DB and narrowed basal section of CB.

Etymology

The name of this species, a noun in apposition, refers to the type locality, Tinalandia, Ecuador. Tinalandia, a wildlife preserve located approximately 17 km ESE of Santo Domingo de los Colorados at an altitude of 700 meters, is one of the last accessible remnants of midelevation forest in western Ecuador. It has long been a famous destination for entomologists and bird watchers. I visited there four times—in October 1988, May 1993, March 2006, and January 2009. Specimens of P. tinalandia were captured on two of those occasions. Tina Tarnopol Frankfurter (1908–1996), a Russian who moved to Ecuador in the mid-1930s, owned and ran Tinalandia for over 50 years. A colorful character and true pioneer, she left Quito to build her dream establishment in the forest above the Río Toachi. Today, Tinalandia includes scenic trails, wonderful accommodations, and a jungle-style golf course. I had the opportunity to meet Tina on my first two visits. During a recent trip, I visited her gravesite, which sits along with that of her husband, who died in 2002, atop a hill overlooking the land she loved. A brief history of Tinalandia is provided at:  www.tinalandia.com.

Distribution

Polypoetes tinalandia, the only South American member of the Etearchus Group, occurs on the Pacific slope of the Ecuadorian Andes in Pichincha Province (fig. 109). The species has been collected at two localities—Tinalandia and La Unión del Toachi—less that 15 km apart. Additional sampling at elevations between 500 and 1000 meters along the western foothills of the Andes of Colombia and Ecuador will likely provide additional records.

Discussion

Polypoetes tinalandia exhibits the following autapomorphic traits, setting it apart from P. etearchus and P. wagneri: apex of male valva finely rugulose (fig. 117A); a group of robust, spinelike setae on inner surface of valva near apex; lateral margins of female St7 deeply excavated, St7 with a raised, knoblike central process near anterior margin; DB sinuate (fig. 117D).

Holotype

Male (pl. 12). Ecuador: Pichincha: Tinalandia, 700 m, 20 May 1993, leg. J.S. Miller, day-coll. in forest understory (genitalia slide no. JSM-1575). The type is deposited at the AMNH.

Paratypes

Ecuador: Pichincha: 1♂, Tinalandia, 700 m, 19 May 1993, leg. J.S. Miller, L.D. Otero & E. Tapia, day collecting (AMNH; JSM-764); 1♀, Tinalandia, 17 km SE Sto. Domingo de Los Colorados, 3000 ft, 18 Oct 1988, leg. J.S. Miller (AMNH; JSM-765); 1♀, Tinalandia, 700 m, 18 May 1993, leg. J.S. Miller, at light (AMNH); 1♀, Tinalandia, 700 m, 27–30 June 1980, leg. C.V. Covell Jr. (USNM); 2♂♂, Otongachi, La Unión del Toachi, 00°19.3′S, 78°57.1′W, 933 m, 3 Aug 2005, leg. G. Onore (AMNH); 1♀, Tinalandia, 600 m, 5–11 May 1990, leg. R.H. Leuschner (LACM); 1♂, Hac. Gomez, 32 km E Santo Domingo, 3.8 air km E Unión del Toachi at Río El Transito, 900 m, 18 Aug 1988, leg. S. McKamey (LACM).

Other Specimens Examined

None.

Dissected

Holotype, 1♂, 1♀.

Polypoetes wagneri, new species

Figures 118, 119; plate 12

Diagnosis

The two species co-occurring in Costa Rica—P. wagneri and P. etearchus (pl. 12)—differ in that the FW ground color of P. etearchus is light brown, whereas that of P. wagneri is dark brown to black. The FW veins in P. etearchus are finely lined with ochreous, almost brown, scales; they do not stand out, thus giving the wing a somewhat monotone appearance. In P. wagneri, on the other hand, the FW veins are more boldly lined with orange, giving the wings a brighter look.

Distinguishing P. wagneri and P. tinalandia (pl. 12) is more difficult because both show a blackish FW ground color. A subtle difference between them involves the stem of HW vein Rs+M1, which is lined with gray scales where it connects with the DC in P. tinalandia, but is white in P. wagneri, showing only a small tooth of black near the fork of Rs and M1. Geographical distribution provides an obvious clue; P. tinalandia is endemic to Ecuador whereas P. wagneri has not been collected outside Costa Rica. By far the most reliable way to identify them is to examine their genitalia.

Description

Male. Forewing length  =  13.5–15.5 mm. Head: Labial palpus elongate, held elbowlike over front, curving upward to immediately short of antennal base; Lp1 relatively short, wide, closely scaled with orange-yellow scales; Lp2 greatly elongate, over twice as long as Lp1, curving gently outward, more strongly distally; lateral surface of Lp2 closely scaled with glossy gray-brown, mesal surface sparsely scaled with creamy white, dorsal surface with a few scattered long, light yellow scales, a distal tuft of long gray scales extending beyond apex of Lp3; Lp3 short, conical, gray-brown laterally, bare on mesal surface; mesal surfaces of Lp2 and Lp3 bearing long, yellowish-brown spinules, these more dense on Lp3; scales of front long, pointing dorsomedially, central portion gray to light gray, lateral scales longer, creamy white to light orange or buff, forming short tufts below antennal bases; occiput gray in dorsal fifth, creamy white in lower four-fifths; eye extremely large, bulging outward, surrounded by scales except for a narrow scaleless band along anterior margin; eye with a sparse covering of extremely short setae; vertex covered with long, forward pointing, steely gray scales, sometimes with a few long, buff-colored scales mixed in; a narrow band of white behind each antennal base; antenna bipectinate, rami short; scape gray-brown on upper surface, with scattered white to buff scales below; dorsum of antennal shaft tightly covered with short, glossy gray-brown scales.

Thorax: Inner surfaces of legs white to cream colored, outer surfaces glossy gray-brown; spurs creamy white with gray scales laterally; pleuron covered with long, buff and white scales; patagium gray with a few long buff-colored scales, a transverse row of long white scales anteriorly; central portion of tegula with erect, bright orange scales, margins fringed with long, hairlike gray-brown scales; dorsum gray, with a wide, diffuse longitudinal stripe of long, buff-colored to light orange scales on each side of midline; tympanum relatively small, “open”, tympanal cavity comprising a shallow scaleless depression; tympanal membrane moderately large, ovoid, facing posterolaterally.

Forewing: (Dorsal) Ground color dark brown to charcoal gray or blackish brown (pl. 12), lighter gray in basal third; veins, excluding costa but including anal fold, sharply lined with light orange to ochreous orange scales; basal two-thirds of DC forming a thinly scaled streak, this bisected by a line of whitish orange scales; a transverse, ovoid, semihyaline fascia immediately beyond DC, its anterior margin extending to base of radial sector, sometimes almost to R1, its posterior margin extending to fork of M3+CuA1; veins M1 and M2 a mixture of dark gray and ochreous orange scales as they pass through fascia; surface of fascia thinly scaled with elongate and short, dark gray-brown scales, their vertices notched. (Ventral) Similar to dorsal surface, except veins concolorous, not lined with orange scales; a short white dash at base; surface of fascia covered with pedicellate white scales.

Hind wing: (Dorsal) Central area translucent white (pl. 12), anterior margin of white area extending to Sc+R, extending posteriorly to posterior margin of DC, angled posteriorly at CuA2; outer margin broadly banded with gray black, band widest near apex, narrowest at fork of M3 and CuA1; marginal band converging with gray anal margin; a broad gray to dark gray area between cubitus and anal margin; anal margin fringed with long, light gray scales. (Ventral) Similar to dorsal surface, except region between cubitus suffused with white scales; anterior margin completely dark gray, without a white streak in basal half (as in tinalandia).

Abdomen: Dorsum slate gray to gray-brown with a slight bluish iridescence; venter white to creamy white.

Terminalia (fig. 118A–D): Tg8 elongate, over three times as long as Tg7, wide; Tg8 wider toward distal margin, arching strongly upward; anterior margin with a short, wide apodeme on each lateral angle, lateroposterior margins bearing large, triangular processes, mesal process truncate, dorsally concave, edges emarginate; St8 extremely large, longer than Tg8, slightly wider posteriorly; surface of St8 strongly convex, arching upward, anterior margin with a wide, somewhat tapered, mesal apodeme, its anterior margin transverse; posterior margin of St8 forked, each prong robust, elongate and heavily sclerotized, curving upward; socii/uncus complex extremely wide, triangular in shape, fused to tegumen; uncus wide at base, gradually narrowed to a short, broad process at apex; socii extremely long and wide, heavily sclerotized, extending dorsally well above apex of uncus, apices slightly flattened, with a strong lateral curl, a ridgelike ventral crest forming a prominent elbow two-thirds from base; inner surfaces of socii smooth, lateral surfaces bearing robust, spinelike setae; tegumen shorter than vinculum, narrow below, wide at junction with socii/uncus complex; vinculum wide, convex, joining below to form a U-shaped ventral margin; saccus large, extending upward to well above valva bases, upper margin triangular; valva extremely short, wide, mostly membranous; BO large, occupying two-thirds of valva, curled anteriorly; costa short, wide, curving upward over apex; valva apex wide, smoothly sclerotized, area below apex sparsely covered with short, thin, spinelike setae; aedeagus elongate, expanded at base, sides roughly parallel in distal two-thirds; apex of aedeagus with a tiny, sclerotized lateral tooth; vesica short, wider than aedeagus, bearing a tight clump of spinelike cornuti.

Female. Forewing length  =  15.5–16.0 mm. Body and wing characters similar to male, except: labial palpus shorter, apex falling well short of antennal base; antenna ciliate; wings longer than male, ground color slightly lighter; abdomen wider; St7 completely scaleless, surface densely covered with setae, with a wide, transverse groove along anterior margin; Tg7 heavily sclerotized, scaleless, setose along posterior margin, with a raised ridge along midline.

Terminalia (fig. 118E): Tg7 extremely large, wide, heavily sclerotized in posterior four-fifths; anterior margin of Tg7 simple, lateral margins slightly excavated near middle, lateroposterior angles greatly expanded to form triangular, rugose processes, posterior margin irregular, bearing a wide, diffuse row of setae; St7 extremely large, trapezoidal, slightly narrower posteriorly, completely covered with setae except near lateral margins, central portion gently raised, with a shallow, transverse groove along anterior margin, but without a sharply raised, V-shaped area (as in etearchus, tinalandia); anterior margin of St7 simple, posterior margin roughly transverse, crenulate, with rounded, sclerotized lateral angles; Tg8 sclerotized, wide, forming a rooflike structure over PA, posterior margin with occasional striations, sparsely lined with long setae; Tg8 contiguous with sclerotized A8 pleuron, posterior margin with a lateral notch; AA elongate, thin, gently curving downward; PA moderately large, mostly membranous, surface minutely spiculate, posterior margins triangular; PP shorter than AA, thin, straight; area below Tg8 and PA greatly infolded, large, melanized, surface minutely spiculate; area above ostium infolded to forming a large, wide shelf, its dorsal surface broadly concave, covered with fine spicules; posterior margin of shelf with several longitudinal striae; ostium short, wide, lightly sclerotized; DB short, sclerotized, dorsoventrally compressed, bulbous at base; CB large, ovoid, membranous, gradually narrowed anteriorly, a long, narrow, sclerotized S-shaped section posteriorly; signum small, heart shaped, slightly concave, located ventrolaterally on left side, surface minutely spiculate; a pair of coarsely denticulate, elongate pockets in CB membrane, located laterally on right side; DS attached near ostium, at base of S-shaped narrow region of CB.

Etymology

This species is named in honor of David Wagner (University of Connecticut, Storrs), one of the world's leading experts on microlepidoptera systematics, and on Lepidoptera life histories in general. Dave spearheaded an ongoing biodiversity survey of Costa Rican Lepidoptera (INBio-OET-ALAS transect). It was he, along with, Jadranka Rota, who collected the holotype of P. wagneri.

Distribution

This species is known exclusively from Costa Rica, but within the country, P. wagneri appears to be relatively widespread (fig. 119). Dissections confirm that it occurs at sites in the Caribbean drainage within the provinces of Alajuela, Cartago, Guanacaste, and Heredia, at elevations between 700 and 1300 meters. The other Central American Etearchus Group species, P. etearchus, shows a more restricted distribution. It has been recorded exclusively from the Pacific drainage of the Cordillera de Talamanca in southwestern Costa Rica and northwestern Panama (fig. 119).

Many examples of P. wagneri come from the William Schaus Collection (USNM). These were captured at Juan Viñas (1300 m) and Sítio (1100 m), historically well-known sites located close together on the south-facing slopes of Volcán Irazu and Volcán Turrialba. These are the two highest volcanoes in Costa Rica, with summits of over 3200 meters (DeVries, 1997). Additional study will be required to more fully understand the distribution of P. wagneri. Collecting in Bocas del Toro, Panama, near the Costa Rican border, an area for which little is known, will be particularly important.

Discussion

Morphological differences in the terminalia provide the only reliable means for identifying P. wagneri and P. etearchus. Interestingly, males and females can be separated without dissection. Female St7 is scaleless in these species, instead being densely covered with setae. Thus, differences in configuration between P. etearchus and P. wagneri, outlined in the species key (above), can be discerned on intact specimens with the aid of a stereomicroscope. For males, removing the terminal scales of the abdomen with a fine paintbrush reveals differences in the shape of Tg8.

The type series of P. wagneri includes moths from two sets of collectors—Wagner/Rota and Brehm—but all were captured at essentially the same location (10°16′N, 84°05′W).

Holotype

Male (pl. 12). Costa Rica: Heredia: 16 km SSE La Virgen, 10°16′N, 84°05′W, 1050–1150 m, 15 Mar 2001, leg. D. Wagner & J. Rota, INBio-OET-ALAS transect. The holotype is deposited at the AMNH.

Paratypes

Costa Rica: Heredia: 1♂, 16 km SSE La Virgen, 10°16′N, 84°05′W, 1050–1150 m, 15 Mar 2001, leg. D. Wagner & J. Rota, INBio-OET-ALAS transect (AMNH); 1♂, 18 Mar 2001 (AMNH); 1♂, 19 Mar 2001 (AMNH; genitalia slide no. JSM-1573); 1♂, 20 Mar 2001 (AMNH); 2♂♂, NP Braulio Carrillo, 10°15.9′N, 84°05.1′W, 1115 m, 22 May 2003, leg. Gunnar Brehm, rainforest, blacklight 30W, Ms b(6), 19.30–20.30 h (SMNS); 2♂♂, 23 May 2003 (SMNS; genitalia slide no. JSM-1574).

Other Specimens Examined

Costa Rica: Guanacaste: Est. Pitilla, 9 km S Santa Cecilia, 700 m, L N 330200_380200, leg. C. Moraga, #3158 (INBio; genitalia slide no. JSM-1579). Alajuela: 2♂♂, 7.7 km N Jct. Rts. 126(9) & 120 on road to Puerto Viejo, gravel pit, 7 Mar 1991, leg. J.S. Miller (AMNH; genitalia slide no. JSM-1578). Cartago: 6♂♂, Juan Viñas, May–June, Wm. Schaus Collection (USNM; JSM-1109); 1♂, 1♀, Sítio, May, Wm. Schaus Collection (USNM); 1♂, Sítio, Feb, Wm. Schaus Collection (USNM); 1♀, Sítio, Jan, Wm. Schaus Collection, Acc. 4960 (USNM; genitalia slide no. JSM-1577); 1♂, Turrialba, 2–5 Nov 1967, leg. E.L. Todd (USNM); 2♂♂, Turrialba, 14–17 May 1974, leg. E. Giesbert (LACM).

Dissected

5♂♂, 1♀.

3. RUFIPUNCTA GROUP

The Rufipuncta Group is strictly South American. Its 11 included species are distributed from Colombia and Venezuela south to Bolivia. Two taxa (P. dynastes and P. rufipuncta) are known from southeastern Brazil.

The male genitalia of most Rufipuncta Group species are unusual because the vesica bears deciduous caltrop cornuti (fig. 120E). Although such cornuti are widespread in the Notodontidae (Holloway, 1983; Miller, 1991; Kitching and Rawlins, 1999) and can be found in many genera of the Dioptinae (documented throughout the current work), in Polypoetes they occur only within the Rufipuncta Group. Furthermore, they are not found in any of the other six genera in Clade 5 (fig. 7). These structures undoubtedly evolved in Polypoetes through convergence. Within the Rufipunta Group, deciduous caltrop cornuti occur in at least six of the 11 species, defining a subclade that includes aniplata, circumfumata, colana, crenulata, dynastes, and nox. In P. aniplata the deciduous cornuti are relatively large (fig. 120E), whereas in other members of the clade they are small and delicate, and can easily go unnoticed during the dissection process.

In some Rufipuncta Group species, the male antennae are bipectinate, but the pectinations are extremely short, e.g., in P. aniplata and P. albicuneata. Nevertheless, the group is unified by genital morphology. Genital traits for the Rufipuncta Group can be summarized as follows: male uncus large, concave, hoodlike (figs. 120AFigure 121Figure 122Figure 123124A); socii laterally compressed; a striate plate present in manica above aedeagus; vesica bearing small, deciduous caltrop cornuti (fig. 120E, 123B) in addition to short spinelike ones (e.g., fig. 121C); lateral margins of female Tg7 excavated (figs. 121F, 122F, 124F); female St7 without lateral prongs (figs. 121G, 122G, 124G); ostium dorsoventrally compressed (e.g., fig. 120E), not funnel shaped; Tg8 rooflike (figs. 120E, 121D, 122E, 124D); lateral margins of A8 lacking processes.

KEY TO RUFIPUNCTA GROUP SPECIES

1. Forewing with an orange subapical spot, located at junction of veins Rs2–Rs44

FW without a subapical spot2

2. Dorsal surface of HW with a white or whitish yellow marking; posterior margin of male Tg8 not crenulate3

Dorsal surface of HW uniformly gray black (pl. 13); posterior margin of male Tg8 (fig. 123C) strongly crenulatecrenulata, sp. nov.

3. Hind wing almost entirely white, outer margin blackish brown (pl. 13); FW veins lined with light yellow and cream colored scales; lateral margins of male Tg8 parallel, tergum wide; female St7 without a crest along midline (Colombia)albicuneata (Dognin)

HW mostly blackish brown (pl. 12), a whitish yellow spot located beyond DC; FW veins lined with orange scales; male Tg8 strongly tapered distally (fig. 124E), tergum narrow; female St7 (fig. 124G) with a large, sclerotized crest along midline (Colombia, Venezuela)luteivena (Walker)

4. Dorsal surface of HW with a light yellow or white central area (pl. 13), various in shape and size5

HW dorsal surface gray to blackish gray (pl. 13), no white marking, white area on ventral surface showing faintly through (Colombia, Venezuela)nox Druce

5. Forewing with an ovoid fascia beyond DC, sometimes diffuse, always exhibited clearly on ventral surface; HW central area light yellow; FW base concolorous with rest of wing6

FW without a fascia beyond DC, on dorsal or ventral surfaces; HW central area white; FW basal fourth lighter in color than rest of wing (E Peru, Bolivia)colana Druce

6. Forewing fascia clearly delimited above, hyaline, forming a windowlike maculation8

FW fascia diffuse, surface semihyaline, sparsely covered with dark brown scales, not forming a windowlike maculation7

7. Hind wing mostly lemon yellow, base, anterior margin and anal margin concolorous with light lemon yellow central area; valva short (fig. 121A); socii long and narrow, apices spatulate (Venezuela)circumfumata (Warren)

HW mostly brown, base, anterior margin and anal margin brown with scattered yellow scales, lemon yellow central area relatively small; valva long, socii short and wide, apices broadly angulate (Colombia)exclusa Hering

8. Posterolateral margins of female Tg8 forming large, triangular, lobate structures; FW length  =  12.5–14.0 mm9

Posterolateral margins of female Tg8 gently convex, not forming triangular lobate structures; FW length  =  14.0–17.0 mm10

9. Female St7 as wide as St6, surface of St7 coarsely setose, U-shaped excavation on posterior margin wide; CB almost round (Colombia)intersita Hering

Female St7 narrower than St6, surface of St7 finely setose, U-shaped excavation on posterior margin narrow; CB a transverse oval (SE Brazil)rufipuncta Schaus

10. Light yellow area of HW extending to anal margin; FW veins delicately lined with light yellow-orange scales (Brazil, E Ecuador)dynastes Hering

HW anal margin dark brown with a suffusion of light yellow scales; FW veins boldly lined with orange scales (SE Peru, Bolivia)aniplata Warren

SPECIES INCLUDED AND MATERIAL EXAMINED

Polypoetes albicuneata (Dognin), new combination

Plate 13

Scotura albicuneata Dognin, 1910b: 159.

Type Locality

Colombia, Mont Vitaco, “près San Antonio”, 2500 m.

Type

Syntype ♂, leg. Fassl, Jan 1909 (USNM type no. 30959).

Discussion

Prout (1918: 412) moved this species from Scotura, where it was described (Dognin, 1910b), to Momonipta because males supposedly possess ciliate antennae. Subsequent authors essentially left it there (Hering, 1925; Bryk, 1930), though they considered Momonipta to be a synonym of Stenoplastis. Close study reveals that the male antennae of P. albicuneata bear extremely short pectinations; they are not ciliate. The labial palpi of P. albicuneata are elongate and exhibit short spinules on their mesal surfaces in the distal third, a character of Polypoetes (e.g., figs. 94F, 95A). The new combination Polypoetes albicuneata (Dognin) is here proposed. Other taxa of the Rufipuncta Group in which the male antennal pectinations are short include aniplata, crenulata, dynastes, and rufipuncta.

Certain features of the male and female genitalia in P. albicuneata suggest those of Rubribasis Group species, such as P. bifenestra and P. sumaco (figs. 132, 134). Examples include: female Tg8 robust, rooflike; male Tg8 elongate, with a deep dorsal groove; uncus hoodlike; socii broadly spatulate; aedeagus short; vesica with a distal brush of setae. However, members of the Rubribasis Group exhibit short labial palpi and their male antennae are subserrate, lacking pectinations (fig. 92A). I here provisionally place P. albicuneata in the Rufipuncta Group, until evidence from additional character systems proves otherwise.

Polypoetes albicuneata is another of the many dioptine taxa known exclusively from Colombian material collected by the great naturalist Anton Fassl, near the turn of the 20th century. The entire series consists of four examples at the USNM (2 ♂ Syntypes, 1♂, 1♀), as well as two males at the BMNH.

Distribution

Colombia (BMNH, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1012); co-type ♂, Colombia, “Vitacoberge”, 2500 m, Jan 1909, leg. Fassl, USNM (male genitalia slide no. JSM-526); ♀, Colombia, 21 Aug 1908, leg. Fassl, USNM (genitalia slide no. JSM-527).

Polypoetes aniplata Warren

Figure 120; plate 13

Polypoetes aniplata Warren, 1906: 412.

Type Locality

Bolivia.

Type

Holotype ♀ (USNM type no. 9168).

Discussion

Polypoetes aniplata occurs on the eastern slope of the Andes, at elevations between 1400 and 1800 meters, from southern Peru south to northern Bolivia. The moth is quite rare. Ancient material in the USNM (♀ holotype, 1 additional ♀) and BMNH (3♂♂, 1♀) collections, is from Bolivia. The Peruvian examples (AMNH), were collected more recently. Porion captured one of those (December 1979) at km 160 on the road from Cuzco to Manu at 1200 meters. I collected the other two, a male and female, along the same road in October 2005.

Based on similarities of genitalia and wing pattern, this species is closely related to P. dynastes (pl. 13) from southeastern Brazil. Superficially, P. aniplata differs in having the HW anal margin dark gray-black, suffused with lemon yellow, instead of being completely lemon yellow. The figure of this species in Hering (1925: fig. 69e) is slightly inaccurate; in the type and in all the material I have identified as P. aniplata, the ovoid fascia immediately beyond the FW DC is hyaline, rather than being yellow as shown there.

Distribution

Bolivia (BMNH, USNM); Peru (AMNH).

Dissected

♂, Peru, Cuzco, Cosñipata Valley, Río San Pedro, San Pedro Lodge, S13°01′21″, W71°29′52″, 1400 m, 27 Oct 2005, leg. J.S. Miller, 4:00 p.m., AMNH (genitalia slide no. JSM-1555); ♀, Peru, Cuzco, Cosñipata Valley, Pillahuata-Pilcopata Rd., Puente Unión, 4 km W Río San Pedro, S13°04′03″, W71°34′02″, 1650 m, 27 Oct 2005, leg. J.S. Miller, 1:30 p.m., AMNH (genitalia slide no. JSM-1556); ♀♀, Bolivia, Coroico, 1800 m, USNM (genitalia slide no. JSM-1087).

Polypoetes circumfumata (Warren)

Figure 121; plate 13, 38F

Phaeochlaena circumfumata Warren, 1901: 443.

Type Locality

Venezuela, Cucuta.

Type

Syntype ♂ (BMNH).

Discussion

Polypoetes circumfumata is similar in wing pattern to P. nigribasalis (pl. 11), also from western Venezuela. However, the two taxa differ in size (circumfumata FW length  =  15.0 mm; nigribasalis FW length  =  12.0 mm), and their genital morphology is dramatically different. I have placed them in different species groups within PolypoetesP. nigribasalis in the Haruspex Group, and P. circumfumata in the Rufipuncta Group. Polypoetes circumfumata appears to vary in the amount of yellowish white along the HW anal margin; in some specimens this area is mostly light, whereras in others it is dark.

The AMNH specimens of P. circumfumata are from a series reared in Mérida, Venezuela, by L.D. Otero on Paullinia macrophylla (Sapindaceae). The identity of these (JSM-667, JSM-668) was confirmed by comparison of male genital morphology with that of the type (JSM-1143). Otero also reared Polypoetes luteivena (pl. 38C, D), another Rufipuncta Group member, on Paullinia macrophylla. Polypoetes circumfumata and P. luteivena are similar in general appearance (pl. 13), but the latter lacks an orange subapical FW spot, and shows less light yellow in the HW. Ignoring wing pattern, P. circumfumata and P. nox (pl. 13) share nearly identical male genitalia; on those grounds alone, they might be considered conspecific.

Distribution

Venezuela (AMNH, BMNH, IZA, OUMNH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1143); ♂, Venezuela, Mérida, Carretera vía La Mesa, 1.8 km del Cruce en. Carr. via Jají, 1560 m, 28 Mar 1993, leg. L.D. Otero, D93-09, AMNH (genitalia slide no. JSM-667); ♀, Venezuela, Mérida, Carretera vía La Mesa, 1.8 km del Cruce en. Carr. via Jají, 1560 m, 28 Mar 1993, leg. L.D. Otero, D93-10a, AMNH (genitalia slide no. JSM-668).

Polypoetes colana Druce

Figure 122; plate 13

Polypoetes colana Druce, 1893: 296.

Type Locality

E Peru.

Type

Syntype ♂, leg. Whitely (BMNH).

Polypoetes evanescens Hering, 1925: 516. New synonymy.

Type Locality

Bolivia, “Corvico & Bueyes”.

Type

Syntype ♂/♀ (ZMH).

Discussion

The identity of Polypoetes colana is here firmly established. Dissections of a BMNH syntype and four additional specimens (2♂♂, 2♀♀) show that P. colana occurs in southern Peru and northern Bolivia, on the eastern slope of the Andes.

The male and female paratypes of P. evanescens Hering (1925) dissected here (JSM-1111, JSM-1112) exhibit genitalia and wing pattern exactly matching the type of P. colana, thus confirming P. evanescens as a newly recognized synonym of colana Druce. A third paratype—from Vilcanota, Cuzco, Peru (3000 m)—resides in the ZMH collection. The Bolivian syntypes of evansescens comprise a male (Corvico) and a female (Bueyes).

A USNM male from Loja, Ecuador (JSM-1098) has a wing pattern similar to that of P. colana. However, its male genitalia show that this moth represents an undescribed species.

Distribution

Peru (CUIC, BMNH, USNM, ZMH); Bolivia (BMNH, USNM, ZMH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1144); ♂, Bolivia, Cochabamba, Yungas del Espiritu Santo, 1888–89, leg. P. Germain, BMNH (genitalia slide no. JSM-544); ♂, Bolivia, Yungas de la Paz, 1000 m, Oct 1899, leg. Garlepp, BMNH (genitalia slide no. JSM-1099); ♂ paratype of evanescens Hering, Bolivia, La Paz, Río Tanampaya, 1894, leg. Garlepp, ZMH (genitalia slide no. JSM-1111); ♀, Marcapata, Peru, May 1905, [leg. Staudinger], Dognin Collection, USNM (genitalia slide no. JSM-1097); ♀, Peru, ex de Mathan, BMNH (genitalia slide no. JSM-1100); ♀ paratype of evanescens Hering, [“Toroch.”?], 1890, leg. Garlepp, ZMH (genitalia slide no. JSM-1112).

Polypoetes crenulata, new species

Figures 109, 123; plate 13

Diagnosis

The uniformly dark, charcoal-gray FW and HW dorsal surfaces in P. crenulata are deceptive; these might suggest an affinity with P. leuschneri or P. sublucens (pl. 11). However, those species belong in the Haruspex Group. Features of the male genitalia, such as presence of deciduous caltrop cornuti on the vesica, clearly establish P. crenulata in the Rufipuncta Group. Its male antennae bear short pectinations, another characteristic of this clade.

Once P. crenulata is assigned to the proper Polypoetes species group, identification becomes relatively simple. This is the only Rufipuncta Group taxon showing a uniformly dark FW without an orange subapical spot, as well as a completely dark HW. Polypoetes nox (pl. 13) has a dark FW and HW, but possesses a prominent, orange subapical FW spot. Polypoetes albicuneata (pl. 13) lacks a FW spot, but its HW exhibits a broad, white central area. The strongly crenulate posterior margin of male Tg8 (fig. 123C) is also unusual to P. crenulata. Unfortunately, females are unknown.

Description

Male. Forewing length  =  12.0–13.0 mm. Head: Labial palpus greatly elongate, folded elbowlike over front, apex extending posteriorly to well beyond antennal base; Lp1 short, almost straight, loosely covered with light yellow to lemon yellow scales; Lp2 extremely long, over two and a half times as long as Lp1, with a strong upward curve near apex, lateral surface covered with short, gray-brown scales, ventral surface creamy white in basal two-thirds then gray, dorsal surface with a dense row of long, light yellow to creamy white scales, mesal surface mostly scaleless; distal portion of Lp2 bearing a tuft of long, creamy white to yellowish buff scales on dorsal surface, this tuft extending beyond apex of Lp3; Lp3 short, conical, light gray-brown, dorsal surface with a dense cluster of short, yellowish-brown spicules; central portion of front covered with long, glossy gray, upwardly pointing scales, lateral margins of front trimmed with creamy white, upwardly pointing scales, dorsal scales of front forming raised ridges between antennal bases; occiput charcoal gray in upper third, creamy white in ventral two-thirds; eye moderate in size, bulging strongly outward, a scaleless band anteriorly and dorsally; gena scaleless, relatively wide; eye with a sparse covering of short setae; scales of vertex long, glossy gray-brown, pointing anteriorly, mostly appressed, forming a ledge over antennal bases, areas behind antennal bases white; antenna bipectinate, rami short; scape glossy gray-brown, a few cream-colored scales on ventral surface; dorsum of antennal shaft covered with appressed, glossy gray-brown scales.

Thorax: Legs creamy white on inner surfaces, light gray-brown on outer ones; pleuron loosely covered with a mixture of hairlike and long, bifid white scales, areas of short, light gray scales above epimeron; patagium covered with long, erect, charcoal-gray scales, a small patch of white scales anteriorly on each side; tegula relatively long, apex of ventral angle white, central portion of tegula covered with erect, orange to light orange scales, distal margins fringed with long, hairlike, gray-brown scales; dorsum glossy gray to blackish gray, a few long, light orange scales on either side of midline in posterior portion of mesoscutum; tympanum small, cavity open, barely concave; tympanal membrane small, ovoid, facing laterally.

Forewing: (Dorsal) Ground color dark gray-brown to blackish gray, without contrasting markings (pl. 13); veins, including anal fold, with an extremely sparse lining of light yellow-orange scales; a faint fascia present immediately beyond DC, its surface less densely scaled, forming a diffuse, transverse-ovoid, slightly translucent area. (Ventral) Ground color charcoal gray, veins not lined with lighter scales; basal third silvery white between costa and anal fold; area of fascia with a small, irregular, transverse-ovoid region of short white scales.

Hind wing: (Dorsal) Ground color dark charcoal gray to black, slightly darker than FW (pl. 13); without markings of any kind; white central area from ventral surface showing faintly through above. (Ventral) Ground color silvery white; outer margin with a wide black band extending from apex to anal fold, band abruptly indented at anal fold, then tapering and becoming diffuse toward tornus.

Abdomen: Dorsum glossy charcoal gray, with a faint bluish tinge, Tg8 with a deep middorsal groove; venter white to silvery white.

Terminalia (fig. 123): Tg8 long and narrow, over four times as long as Tg7, arching strongly upward, with a wide, deep middorsal groove in distal three-fourths; anterior margin of Tg8 bearing short, rounded apodemes at lateral angles; Tg8 with lateral margins indented in anterior fourth, gradually widening toward distal margin, posterior margin heavily sclerotized, with a shallow mesal excavation, middorsal groove becoming wide; posterolateral angles of Tg8 rounded outward, strongly crenulate; St8 much wider and more robust than Tg8, somewhat shorter, its surface convex; anterior margin of St8 with a large, wide mesal apodeme, lateral margins slightly excavated at midpoint, posterior margin heavily sclerotized, coarsely rugose, with a shallow U-shaped mesal excavation, posterolateral angles somewhat expanded, each with a wide, shallow dorsal groove; socii/uncus complex extremely wide, robust, broadly fused to tegumen; uncus wide at base, narrowing to form a large, rounded apex, apex ventral surface bearing a dense brush of robust setae; socii extremely large and heavily sclerotized, elbowlike at their bases, arms robust, apices expanded and laterally compressed to form large, paddle-shaped structures, each bearing coarse, spinelike setae on their lateral surfaces; arms of tegumen relatively wide, taller than vinculum, concave, with humplike lateral expansions dorsally; arms of vinculum short, wide, concave, meeting below to create a wide, U-shaped ventral margin; saccus comprising a large, triangular mesal sclerite, folded upward to well above valva bases; valva short, semiupright, mostly membranous; BO large, with numerous pleats, comprising over two-thirds of valva, lateral margins curled anteriorly; inner surface of valva membranous; costa sclerotized, relatively narrow, slightly sinuate; apex membranous, rounded, somewhat bulging, inner surface covered with short setae; valva bases relatively narrow; juxta absent; transtillar arms extremely narrow, curving strongly upward near base, then oriented horizontally, forming a simple junction at midline above aedeagus; aedeagus short, constricted near midpoint, basal half expanded, dorsoventrally compressed, distal half relatively narrow; apex of aedeagus with a short, heavily sclerotized, toothlike ventral process; vesica small, rounded, approximately one-fourth length of aedeagus, bearing a dense brush of spinelike cornuti, as well as 2 or 3 small, delicate, deciduous caltrop cornuti.

Female. Unknown.

Etymology

This species name is derived from the Latin word crenulatus, meaning “minutely notched”. It refers to the heavily scalloped posterior margin of male Tg8 in P. crenulata, an autapomorphy for this taxon. These crenulations can be observed in intact, pinned specimens.

Distribution

Polypoetes crenulata has been recorded from a single western Ecuadorian site near Balsapamba, in the foothills of the Andes at an altitude of 800 meters (fig. 109). Several early naturalists, such as M. de Mathan, collected Lepidoptera intensively at this locality during the late 1800s, and their material is housed in the BMNH. Interestingly, examples of P. crenulata do not exist among those collections. Polypoetes crenulata is almost certainly more widespread, but determining the limits of its distribution must await more thorough sampling.

Discussion

As is noted in the diagnosis (above), the most difficult aspect of identifying P. crenulata involves determining the Polypoetes species group to which it belongs. The elongate labial palpi and bipectinate male antennae leave no doubt that the species is a member of Polypoetes, but as is true throughout the genus, genital dissection is required to identify it further. Once those are examined, placement of P. crenulata in the Rufipuncta Group is unambiguous. Addition of this taxon to the clade is interesting for two reasons: First, it becomes the only described member known from Ecuador, though more will undoubtedly be discovered. Second, it brings an unusual wing pattern to an otherwise fairly uniform group. The other Rufipuncta Group taxon lacking markings, P. nox, appears to be the sister species to P. luteivena (see below), and is not a particularly close relative of P. crenulata.

Elicio Tapia and I captured all the known examples of P. crenulata (13 ♂♂) on a single afternoon in March 2006, along the banks of the Río Cristal on the outskirts of the tiny village of Cristal. The moths were active for roughly half an hour, between 4:00 and 4:30 p.m., and then abruptly stopped flying. Our frantic collecting efforts attracted the interest of a small horde of young children from town. It was clear that they had never seen such lunacy during the course of their young lives.

Holotype

Male (pl. 13). Ecuador: Bolívar: Cristal, N bank Río Cristal, 0.7 km S Balsapamba, 01°45.8′S, 79°10.5′W, 800 m, 15 Mar 2006, day, along river's edge, leg. J.S. Miller & E. Tapia. The type is deposited at the AMNH.

Paratypes

Ecuador: Bolívar: 12♂♂, Cristal, N bank Río Cristal, 0.7 km S Balsapamba, 01°45.8′S, 79°10.5′W, 800 m, 15 Mar 2006, day, along river's edge, leg. J.S. Miller & E. Tapia (AMNH; genitalia slide Nos. JSM-1645, 1646).

Other Specimens Examined

None.

Dissected

2♂♂.

Polypoetes dynastes Hering

Plate 13 [EX]

Polypoetes dynastes Hering, 1925: 517, fig. 69g.

Type Locality

Brazil, Novo-Friburgo.

Type

Holotype ♀ (ZMH).

Discussion

Polypoetes dynastes appears to be the sister species to P. aniplata (pl. 13), from Bolivia and Peru. Their male and female genitalia are extremely similar, differing only in that the valva of dynastes is wider, and the female signum is smaller.

All examples of P. dynastes I have seen were collected in Brazil, with the exception of a single CMNH male from the slopes of Cerro Sumaco (Napo, Ecuador). That specimen is extremely similar to Brazilian dynastes, except that the central area of the HW is more broadly yellow and the FW and HW ground color is darker. Its genitalia (JSM-1562) are essentially indistinguishable from those of Brazilian examples.

Distribution

Brazil (BMNH, MPM, USNM, ZMH); Ecuador (CMNH).

Dissected

♂, Brazil, Paraná, leg. F. Johnson, USNM (genitalia slide no. JSM-1102); ♂, Brazil, Paraná, Castro, USNM (genitalia slide no. JSM-1104); ♂, Ecuador, Napo, Lower south slopes Cerro Sumaco, 1480 m, 22 Nov 1995, leg. Jan Hillman, disturbed forest, CMNH, (genitalia slide no. JSM-1562); ♀, Brazil, Paraná, Castro, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1103).

Polypoetes exclusa Hering

Plate 13

Polypoetes exclusa Hering, 1925: 515.

Type Locality

Colombia.

Type

Holotype ♂, leg. Karst (ZMH).

Discussion

I know P. exclusa exclusively from the holotype (pl. 13). The species exhibits all the wing pattern and male genital characteristics of the Rufipuncta Group, and clearly belongs within it. However, the male valvae of P. exclusa are unusually long and wide compared to other species in this group, and the socii exhibit a unique shape. This is one of five Rufipuncta Group members endemic to Colombia. Thus, half the clade's members occur there.

Distribution

Colombia (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1760).

Polypoetes intersita Hering

Plate 13

Polypoetes intersita Hering, 1925: 515.

Type Locality

Colombia.

Type

Holotype ♀, “7875”, “Bnno” (ZMH).

Discussion

Polypoetes intersita is known solely from the holotype (pl. 13). When wing pattern and size are compared, this species (FW length  =  13.5 mm) is inseparable from examples of the Brazilian taxon, P. rufipuncta (pl. 13). Comparing the female genitalia of P. rufipuncta with those of the P. intersita type further establishes an extremely close, perhaps sister-species, relationship. Nevertheless, numerous morphological differences, some of which are employed in the species key (above), demonstrate that the two are distinct.

Distribution

Colombia (ZMH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1759).

Polypoetes luteivena (Walker)

Figure 124; plates 12, 38C, 38D

Melanchroia luteivena Walker, 1864: 211.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♂, ex Stevens Collection (BMNH).

Discussion

The BMNH male holotype of P. luteivena is in poor condition; its head is missing and the wings are nearly devoid of scales. However, my examination (March 2005) confirms that luteivena belongs in Polypoetes. Furthermore, dissection shows that the moth belongs in the Rufipuncta Group; it exhibits a long, deeply grooved Tg8 (fig. 124E), a strongly bifid St8 (fig. 124B), and a broad, hoodlike uncus (fig. 124A). The socii are laterally compressed and bladelike.

Comparison suggests that P. luteivena is closely related to P. circumfumata (pl. 13). Conspicuous synapomorphies of the female genitalia include: St7 with a sclerotized, keel-like flange along midline (figs. 121G, 124G), near halfway point of sclerite; Tg8 sclerotized, rooflike (figs. 121D, 124D); a small, spiculate bump in ostium; signum of corpus bursae roughly ovoid, concave. Similarly, the male genitalia exhibit a host of synapomorphies: Tg8 with a deep, middorsal groove (figs. 121B, 124E); St8 constricted in distal two-thirds (figs. 121E, 124B), posterior margin strongly sclerotized, forming a robust Y-shaped structure; socii/uncus complex large, triangular (figs. 121A, 124A); apex of uncus forming a blunt point, with a small patch of coarse setae on ventral surface; socii long, spatulate at their apices; vesica of aedeagus with a brushlike patch of spiny cornuti (figs. 121C, 124C).

Other than the type, the only specimens of P. luteivena known are a male and two females, collected by Dr. L.D. Otero in Mérida, Venezuela. In 1993, Otero discovered larvae of P. luteivena and P. circumfumata feeding on Paullinia macrophylla (Sapindaceae), a novel host for the Dioptinae (table 4). The caterpillar and pupa of P. luteivena (pl. 38C, D) show patterning typical of Polypoetes immatures.

Distribution

Colombia (BMNH, OUMNH); Venezuela (AMNH).

Dissected

Holotype ♂ (BMNH, Dioptidae genitalia slide no. 12); ♂, Venezuela, Mérida, Carr. Estanquez-Las Coloradas, 1420 m, 9 Oct 1993, leg. L.D. Otero, D93-34, ex larva on Paullinia sp., AMNH (genitalia slide no. JSM-1424); ♀, Venezuela, Mérida, Carr. Estanquez-Las Coloradas, 1400 m, 17 Aug 1993, leg. L.D. Otero, D93-29, “visitando una sp. de Paullinia (oviposición?)”, AMNH (genitalia slide no. JSM-669).

Polypoetes nox Druce

Plate 13

Polypoetes nox Druce, 1900: 510.

Type Locality

Colombia, Valparaiso, 4500 ft.

Type

Holotype ♂, leg. H.H. Smith (BMNH).

Discussion

This is a distinctive species, but few specimens are known. Other than the BMNH type, the only material seen includes a ZMH male (Colombia), as well as a series of four AMNH males from Rancho Grande, Venezuela, collected in 1948 (N.Y. Zoological Society). I captured a fifth AMNH male (JSM-1565) at Rancho Grande in 1992, flying during the day.

Although wing pattern does not initially reveal membership in the Rufipuncta Group, P. nox definitely belongs within it. The vesica bears deciduous caltrop cornuti—in nox they are an unusual pinecone shape—and male St8 is strongly bifid, two unambiguous Rufipuncta Group traits. Comparison of male genitalia further suggests that P. nox is an extremely close relative of P. luteivena and P. circumfumata (pls. 12, 13), both also endemic to Colombia and Venezuela. In fact, although their wing patterns differ, P. nox and P. circumfumata (fig. 121A–C, E) exhibit almost identical male genital structure. The Rufipuncta Group species with which P. nox is most similar in wing pattern, P. crenulata (pl. 13), shows male genitalia different from these (fig. 123). Although the larval host plant for nox is not known, one could predict that, like P. luteivena and P. circumfumata, its caterpillars are associated with Paullinia (table 4).

Distribution

Colombia (BMNH, ZMH); Venezuela (AMNH).

Dissected

♂, Venezuela, Aragua, Rancho Grande Station, 18 km NW Maracay, 3800 ft, 21 Mar 1992, leg. J.S. Miller, day, AMNH (genitalia slide no. JSM-1565).

Polypoetes rufipuncta Schaus

Figure 95; plate 13

Polypoetes rufipuncta Schaus, 1894: 236.

Type Locality

Brazil, Paraná, Castro.

Type

Syntype ♂ (USNM type no. 11586).

Discussion

Polypoetes rufipuncta is endemic to southeastern Brazil. Its northern limit is the state of Minas Gerais, and the species has been recorded as far south as Pelotas, in Rio Grande do Sul. This species shares wing-pattern elements with P. aniplata and P. dynastes (pl. 13), but can be recognized by its smaller size; FW length in P. aniplata and P. dynastes ranges between 14.0 and 17.0 mm, whereas in P. rufipuncta it varies between 12.5 and 14.0 mm.

Polypoetes rufipuncta is fairly well represented in museum collections, occasionally in long series (12♂♂, 5♀♀ at the BMNH; 4♂♂, 3♀♀ at the USNM). The most pristine examples can be found in the Vitor Becker Collection.

Polypoetes rufipuncta shows variation in HW coloration. For example, the moth figured by Hering (1925: fig. 69e) differs from type material in exhibiting an almost completely black HW with a small hyaline fascia. In the USNM syntype, the HW is yellow from the wing base to the fascia. A series from Caraça, Brazil (VOB) matches the Hering plate in having an almost completely dark HW. Interestingly, the HW ventral surfaces in these two forms are indistinguishable.

Distribution

Brazil (BMNH, CUIC, MPM, NMW, USNM, VOB).

Dissected

Syntype ♂ (genitalia slide no. JSM-1121); ♂, Brazil, Paraná, Castro, leg. E.D. Jones, BMNH (genitalia slide no. JSM-550); ♂, Brazil, Minas Gerais, Caraça, 1300 m, 25 Oct 1994, leg. V.O. Becker and K.S. Sattler, VOB (genitalia slide no. JSM-1122); ♀, Brazil, Salto Grande, Paranapanema, leg. E.D. Jones, BMNH (genitalia slide no. JSM-551).

4. PERSIMILIS GROUP

The Persimilis Group is restricted to Andean cloud forests. Species occur from western Venezuela (P. oteroi) west to Colombia, and south to Bolivia. All described species are endemic to the Amazonian slope, but an undescribed Ecuadorian taxon (known from a single specimen) occurs on the western slope.

A distinguishing characteristic of this group is the presence of three semihyaline FW patches (pls. 13, 14): one within the DC near the base; one immediately beyond the DC in the position of the FW fascia; and a third, diffuse one posterior to the point where CuA2 leaves the DC. The FW radial sector is in the arrangement Rs2+[Rs3+Rs4], with 3+4 forking near the wing's outer margin (fig. 90I). Forewing vein M1 either arises from the base of the radial sector, or is separate. The eyes are large (fig. 89D), bulging below the ventrolateral margin of the head. The labial palpi are relatively short, with Lp2 shorter than Lp1 (fig. 89D). The male antennae are either subserrate (P. oteroi) or bipectinate with short pectinations (e.g., P. pallinervis). The tympanum is open, not inset into a cavity, and the membrane is extremely large. Genital characteristics of the Persimilis Group include the following: male eighth segment forming a large, jawlike structure, Tg8 elongate (e.g., figs. 126B, 128D), with a deep medial groove; male St8 either small (e.g., fig. 126D), or extremely large, widening distally (e.g., fig. 128C); female Tg7 excavated on lateral margins, Tg8 sclerotized, rooflike (figs. 129D, 130E), ostium ovoid, not funnel shaped.

Of the 10 Persimilis Group species recognized here, three had most recently been assigned to Polypoetesineldo Schaus, jipiro Dognin, and villiopsis Hering. Two, pallinervis Felder and villiodes Warren, are here newly transferred to Polypoetes from Xenomigia. Four taxa—empheres Prout, eximia Warren, opaca Hering, and persimilis Dognin—are taken from Stenoplastis, and here combined with Polypoetes for the first time. The final species, P. oteroi, is newly described.

KEY TO PERSIMILIS GROUP SPECIES (MALES)

1. Forewing fascia wide and trapezoidal (pl. 13), semihyaline, extending distally past fork of M3+CuA1; veins M1 and M2 dark as they pass through fascia; FW without a subterminal line; uncus of male genitalia wide, quadrate, apex with a pair of hornlike processes at lateral angles (figs. 128A, 129A); valva extremely short, truncate, inner surface covered with a dense brush of robust setae2

FW fascia small (pls. 13, 14), ovoid or rectangular, opaque white, not extending past fork of M3+CuA1; veins M1 and M2 light yellow as they pass through fascia; FW (dorsal surface) with a diffuse subterminal line, comprising a series of V-shaped white markings between veins; uncus wide (e.g., fig. 125A), but variable in shape, without a pair of hornlike distal processes; valva elongate, inner surface covered with fine setae (e.g., fig. 126A)3

2. Forewing ground color gray-brown (pl. 13), veins lined with creamy yellow to light orange-yellow scales; central area of HW yellowish white, this region expanded toward outer margin at fork of M3+CuA1, almost touching margin; central process on posterior margin of male Tg8 small (fig. 129E); socii/uncus complex relatively narrow (Colombia S to SE Ecuador)persimilis (Dognin)

FW ground color chocolate brown (pl. 13), veins lined with orange to ochreous orange scales; central area of HW immaculate white, this region falling well short of outer margin, barely extending beyond fork of M3+CuA1, HW with a wide, gray-brown marginal band; central process on posterior margin of male Tg8 large, lobate (fig. 128D); socii/uncus complex wide (W Venezuela)oteroi, sp. nov.

3. Hind wing anal margin diffuse gray-brown (pl. 13), HW central area semihyaline, white6

HW anal margin white (pl. 14), HW central area opaque yellowish white4

4. Forewing fascia conspicuous, white; FW basal third with diffuse, transverse white markings; FW anal margin white in basal third, this connecting with white transverse maculation posterior to DC; FW length  =  13.5–16.0 mm (SE Peru)5

FW fascia faint (pl. 14), sparsely covered with brown scales; FW basal third with faint, semihyaline markings; FW anal margin buff to gray-brown; FW length  =  17.0 mm (Bolivia)opaca (Hering)

5. Dark brown marginal band of HW terminating abruptly at CuA2 (pl. 14); posterior margin of male St8 with a deep mesal notch (fig. 125D); costa of male valva with dorsal margin smoothly arched; FW length  =  16.0 mmeximia (Warren)

Dark brown marginal band of HW gradually tapering to tornus (pl. 14); posterior margin of male St8 without a mesal notch; costa of valva with dorsal margin sinuate; FW length  =  13.5–15.0 mmempheres (Prout)

6. Male antenna bipectinate, rami relatively short, thin; posterior margin of male Tg8 forming a distal point (fig. 127B), or with a mesal excavation (fig. 130D); socii/uncus complex wide7

Male antenna subserrate, rami comprising short, flangelike structures; posterior margin of male Tg8 convex (fig. 126B); socii/uncus complex relatively narrow (fig. 126A); FW length  =  18.0–18.5 mm (Central Colombia)ineldo Schaus

7. White basal marking of FW between cubitus and 1A+2A, roughly perpendicular to anal margin; FW veins light yellow to light orange; posterior margin of male Tg8 forming a point; apex of uncus not notched; valva moderately long; FW length  =  13.5–17.0 mm8

White basal marking of FW, between cubitus and 1A+2A, at a 45° angle relative to anal margin (pl. 13); FW veins orange to ochreous orange; posterior margin of male Tg8 with a V-shaped mesal excavation (fig. 130D); apex of uncus notched (fig. 130A), valva long; FW length  =  20.5–21.5 mm (N Colombia)villiodes (Prout)

8. Posterior margin of male Tg8 abruptly tapered to a sharp mesal point (fig. 127B); distal portion of valva expanded (fig. 127A), much wider than at base; costa of valva wide; aedeagus moderately long, thin9

Posterior margin of male Tg8 gradually tapered to a blunt point; distal portion of valva only slightly expanded, barely wider than at base; costa of valva narrow; aedeagus fairly short, wide; FW length  =  15.0 mm (Colombia)villiopsis (Hering)

9. Forewing ground color gray-brown (pl. 13); costa of male valva not expanded in distal portion, angled downward near apex, valva apex simple; FW outer margin strongly convex; FW length  =  13.5 mm (Colombia)pallinervis (Felder)

FW ground color blackish brown (pl. 13); costa of male valva expanded in distal portion (fig. 124A), arching upward, valva apex minutely spoon shaped; FW outer margin gently convex; FW length  =  14.0–17.0 mm (E Ecuador)jipiro Dognin

SPECIES INCLUDED AND MATERIAL EXAMINED

Polypoetes empheres (Prout), new combination

Plate 14

Momonipta empheres Prout, 1918: 412.

Type Locality

Peru (SE), Santo Domingo, 6000 ft.

Type

Holotype ♂, leg. G. Ockenden, Nov 1904 (BMNH).

Discussion

Polypoetes empheres—endemic to southeastern Peru—is known from two BMNH males collected by Ockenden (one being the holotype), as well as from a beautiful USNM male (pl. 14) collected by John Heppner in December, 1979. Morphological characters suggest that P. eximia (pl. 14), also from Peru, is an extremely close relative of P. empheres. However, the two can be easily separated.

In addition to the distinguishing characters given in the Persimilis Group species key (above), differences between P. empheres and P eximia include: Tg8 in eximia (fig. 125C) with a deeper middorsal groove than in empheres; St8 small and narrow in empheres, but broad in eximia (fig. 125D); posterior margin of St8 bearing a small, acute medial notch in eximia, absent in empheres; and socii larger in empheres than in eximia (fig. 125A). Further, P. empheres has a shorter wing length. The easiest way to separate the two species is by their hind wings; the dark outer band extends to the tornus in P. empheres, but terminates at vein CuA2 in eximia.

Distribution

Peru (BMNH, USNM).

Dissected

♂, Peru, Carabaya, 6500 ft, Oct 1902, dry season, leg. G. Ockenden, BMNH (genitalia slide no. JSM-841).

Polypoetes eximia (Warren), new combination

Figure 125; plate 14

Stenoplastis eximia Warren, 1909: 74.

Type Locality

Peru, Huánuco, Cushi, 1900 m.

Type

Holotype ♂, leg. W. Hoffmanns (BMNH).

Discussion

As is noted above, P. eximia is the apparent sister species to P. empheres. Means for separating the two are given in the Persimilis Group species key, as well as in the P. empheres discussion. The only specimens of P. eximia of which I am aware are the male dissected for this study (JSM-840), as well as the holotype—both at the BMNH. Hering (1925: fig. 69i) accurately figured this species, but it is unclear upon which specimen the rendering was based; P. eximia was not available to him at the ZMH.

The male genitalia of P. eximia (fig. 125A) clearly show the striate sclerite located above the transtillar arms, one of the synapomorphies uniting the Persimilis Group.

Distribution

Peru (BMNH).

Dissected

♂, Peru, Huánuco, Cushi, 1900 m, leg. W. Hoffmanns, BMNH (genitalia slide no. JSM-840).

Polypoetes ineldo Schaus

Figure 126; plate 13

Polypoetes ineldo Schaus, 1933: 491–492.

Type Locality

Colombia, Guasca.

Type

Syntype ♂, leg. Apollinaire (USNM type no. 34378).

Discussion

Polypoetes ineldo is one of the few species of Dioptinae described since publication of Bryk's (1930) catalog. It is interesting that Schaus (1933) foresaw the classification proposed here by describing ineldo in Polypoetes; earlier authors consistently placed Persimilis Group species either in the genus Stenoplastis, or in Xenomigia.

The type locality for ineldo, Guasca, is located less than 50 km NE of Bogotá, at an elevation of approximately 2700 m. The Schaus type, a second USNM male (Frank Johnson Collection)—also from Guasca—and a CMNH example from southeastern Ecuador, are the only specimens of P. ineldo I have seen.

Dissection of the P. ineldo type (fig. 126) confirms its placement in the Persimilis Group. Based on a suite of synapomorphies from male genitalia, three species within the Persimilis Group—ineldo, jipiro, and pallinervis (pl. 13)—form a tight clade. Further study suggests that P. ineldo may be sister to the other two, differing in having a truncate (fig. 126A) rather than blunt (fig. 127A) uncus, and in having the distal margin of Tg8 rounded (fig. 126B) instead of acute (fig. 127B).

Distribution

Colombia (USNM); Ecuador (CMNH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1003).

Polypoetes jipiro Dognin, revised status

Figure 127; plate 13

Polypoetes jipiro Dognin, 1893: 368–369.

Type Locality

Ecuador, “Environs de Loja”.

Type

Syntype ♂, leg. 1891 (USNM type no. 30961).

Discussion

Dognin (1893) described this species in Polypoetes, Prout (1918) moved it to Momonipta, and subsequent authors (Hering, 1925; Bryk, 1930) retained it in Stenoplastis. I here re-assign jipiro to Polypoetes, in the Persimilis Group. Male genitalia show that P. jipiro is an extremely close relative of P. pallinervis, from Colombia. The two show subtle differences in the shape of Tg8 (fig. 127B), especially on the posterior margin, and in the width and shape of the valval costa (fig. 127A). Polypoetes jipiro also tends to be darker in color.

Polypoetes jipiro is endemic to cloud forests along the eastern slope of the Ecuadorian Andes, at altitudes between 2000 and 3000 meters. The moth is quite common and, unlike most dioptines, is readily attracted to lights. Collectors from the AMNH and CMNH have captured P. jipiro in large numbers. Interestingly, no females have appeared among that material.

Distribution

Ecuador (AMNH, CMNH, USNM)

Dissected

Syntype ♂ (genitalia slide no. JSM-1004); ♂, Ecuador, Napo, SE slope Reventador, 2900 m, 5 Jul 1994, leg. Jan Hillman, cloud forest, CMNH (genitalia slide no. JSM-753); ♂, Ecuador, Napo, SE slope Reventador, 2900 m, 5 Jul 1994, leg. Jan Hillman, cloud forest, CMNH (genitalia slide no. JSM-1325); ♂, Ecuador, Napo, South slopes Cerro Sumaco, 1850 m, 15 Nov 1995, leg. Jan Hillman, virgin cloud forest, CMNH (genitalia slide no. JSM-1326); ♂, Ecuador, Morona-Santiago, Río Culebrillas, 34 km SE Gualaceo, 2200 m, 22–23 Oct 1987, leg. J. Rawlins, C. Young & R. Davidson, wet forest, CMNH (genitalia slide no. JSM-1584).

Polypoetes opaca (Hering), new combination

Plate 14

Stenoplastis opaca Hering, 1925: 517–518; fig. 69h.

Type Locality

Bolivia, San Jacinto, 2000 m.

Type

Holotype ♂, leg. Garlepp, 1890 (ZMH).

Discussion

Hering (1925) described this species in Stenoplastis, undoubtedly because of its subserrate antennae, and it was retained there by Bryk (1930). I here assign it to Polypoetes for the first time.

Comparison of wing patterns suggests that Polypoetes opaca is a close relative of P. empheres and P. eximia (pl. 14). There is no material of P. opaca known to me other than the ZMH holotype, which is missing its abdomen. Study of that specimen (March 2004) reveals the following characteristics: eyes large, bulging; labial palpus short, delicate, upturned to slightly above clypeus; Lp1 yellow, with a loose fringe of long scales below; Lp2 shorter than Lp1; antenna subserrate; tympanum open, membrane large, triangular, facing laterally; FW veins Rs2-Rs4 branching in the arrangement 2+[3+4], with 3+4 on a short stalk.

This species exhibits the three, semihyaline FW fasciae typical of the Persimilis Group, but the one along the anal margin is less conspicuous that the others. Because the type's abdomen is missing, it will be difficult to firmly establish the identity of this moth until additional specimens, collected at or near the type locality, eventually become available.

Distribution

Bolivia (ZMH).

Dissected

None.

Polypoetes oteroi, new species

Figures 52, 128; plate 13

Diagnosis

The FW markings of Polypoetes oteroi (pl. 13) show somewhat less contrast than those of most Persimilis Group species (pls. 13, 14). The moth is relatively large, and the wings are broad. The delicate, light orange FW veins against a smooth, light brown FW ground color are distinguishing feature of P. oteroi.. The HW is broad, with a wide, dark gray-brown band at the outer margin, and the central area is translucent white. The body of this moth is fairly robust, and the abdomen is truncate at its apex, with an obvious dorsal groove on male Tg8.

The species with which P. oteroi would most easily be confused is P. persimilis (pl. 13). The FW of P. oteroi is lighter brown and the veins are more strikingly lined with orange. The easiest way to separate the two is by their HW; the white central area in P. persimilis extends nearly to the outer margin at CuA1, but falls well short of the outer margin in P. oteroi. Male genitalia of the two differ in obvious ways, such as the shape of the uncus (figs. 128A, 129A), as well as the configuration of Tg8 (figs. 128D, 129E).

Description

Male. Forewing length  =  15.0–18.0 mm. Head: Labial palpus short, porrect, curving slightly upward to immediately above clypeus; Lp2 much shorter than Lp1, Lp3 small, bullet shaped; Lp1 light lemon yellow, fringed with long scales below; Lp2 and Lp3 brown; lateral portions of front with long, upwardly pointing, yellow scales reaching antennal bases, central portion of front brown; occiput with a mixture of long, light brown and cream-colored scales; eye large, bulging; vertex with long, light brown scales; antenna subserrate, with two transverse rows of setae on short protuberances; scape brown, with a small patch of creamy scales below; dorsum of antennal shaft brown.

Thorax: Coxa and pleural region covered with long, light brown to cream-colored scales; femora, tibia and tarsus light brown on outer surfaces, creamy white inside; spurs light brown to beige; patagium with long, brown scales and a few scattered cream-colored scales; tegula yellow-orange, fringed on margins with long brown scales; dorsum mostly brown, beige on sides; tympanum shallow; tympanal membrane large, subtriangular, facing lateroventrally.

Forewing: (Dorsal) Ground color brown, slightly darker brown in distal one-third of DC (pl. 13); veins, including anal fold, outlined with light ochreous orange scales, orange falling short of outer margin; ochreous orange base of Rs2+[Rs3+Rs4] appearing as a highlight near apex; three semihyaline areas, an elongate one within DC from base to two-thirds out on DC, the second a diffuse dash below the point where CuA2 branches from DC, the third, and most prominent, a trapezoidal fascia immediately beyond DC; anterior margin of trapezoidal fascia touching R1, posterior margin touching the fork of M3+CuA1; veins M2 and M3 dark brown as they pass through fascia, then orange beyond. (Ventral) Similar to upper surface except: ground color slightly darker brown; veins marked with orange only near outer margin; and semihyaline areas, especially trapezoidal one, dusted with white scales.

Hind wing: (Dorsal) Broad central area translucent white, almost transparent (pl. 13); outer margin dark brown from apex to anal fold, margin widest near apex, indented near fork of M3+CuA1; a thin brown band along anterior margin; anal margin broadly light gray-brown. (Ventral) Similar to dorsal surface except anal margin silvery white.

Abdomen: Gray brown above, slightly lighter below; apex truncate; Tg8 with a deep dorsal groove.

Terminalia (fig. 128): Tg8 elongate, narrower than Tg7, lateral margins rounded, a wide, deep groove along midline; posterior margin of Tg8 with a lobate, triangular process attached at midline; anterior margin of Tg8 with a pair of short, curved, quadrate apodemes near lateral angles; St8 extremely large, somewhat triangular, sharply narrowed anteriorly; posterior margin wide with large, quadrate processes at lateral angles and a deep, U-shaped mesal excavation, its edges sclerotized; St8 abruptly narrowed toward anterior margin, margin with a broad, bifid mesal apodeme; pleural of segment 8 with large, sclerotized flanges in membrane; socii/uncus complex large, with a wide, transverse attachment to ring; uncus large, quadrate, with thumblike processes at dorsolateral angles, dorsal surface with long setae; socii forming greatly elongate arms, their apices spatulate, ventral surfaces of apices with robust, downwardly pointing setae; tegumen wide, expanded in dorsal half, the two parts constricted toward midline; vinculum narrow, short; saccus forming a large pocket, V-shaped at lower margin, its dorsomedial margin folded upward to enclose the valva bases; valva extremely short, truncate; BO present only as a set of 5 small, transverse pleats along ventral margin of valva; costa wide, concave, forming a pocket along dorsal margin of valva; valva apex with a crenulate, flattened process dorsally, outer margin broadly truncate, bearing a brush of long, coarse setae; transtillar arms short, wide at base, sharply narrowed to meet at midline; aedeagus long, thin, widened at base, curved upward near middle; apex of aedeagus simple; opercular sclerite with a series of small dentations above; vesica small, ovoid, a single cornutus, comprising an elongate brush of short setae, present distally.

Female. Unknown.

Etymology

This species is named in honor of Luis Daniel Otero, from the Universidad de Los Andes (Mérida, Venezuela). Daniel and I have taken four field trips together—two in Venezuela, one in Ecuador, and one in French Guiana. Daniel's knowledge of neotropical natural history is beyond compare, covering not only entomology, but botany as well. Daniel is a remarkable person to travel with; his warmth and charm are magnetic to all who meet him.

Distribution

Polypotoes oteroi is endemic to the western Andes of Venezuela (fig. 52). The majority of specimens, including the holotype, were collected at Parque Nacional Sierra Nevada, near the Mucuy Fish Hatchery, in the vicinity of the city of Mérida.

Discussion

Polypoetes oteroi is the apparent sister species of P. persimilis, from Colombia and eastern Ecuador. In addition to similarities in wing pattern, the two exhibit extremely similar male genital morphology. Together these species form a subclade within the Persimilis Group. Their socii/uncus complex is unique; the quadrate uncus bears a pair of small horns at its apex (figs. 128A, 129A). Their valva shape, with its dense brush of setae at the apex, is also highly unusual.

Although most specimens of P. oteroi have been collected at lights, I captured the holotype flying in late morning along the main trail at Parque Nacional Sierra Nevada. Females have not yet been discovered.

Holotype

Male (pl. 13). Venezuela: Mérida: Parque Nacional Sierra Nevada, 7 km E of Tabay, 6600 ft, 30 Mar 1992, leg. J.S. Miller, 10 a.m. The type is deposited at the AMNH.

Paratypes

Venezuela: Mérida: 1♂, Carr. Estanquez—Las Coloradas, 1300 m, 17 Jul 1993, D93-28, leg L.D. Otero (AMNH); 8♂♂, Mucuy Fish Hatchery, 7 km E Tabay, 6600 ft, 10–13 Feb 1978, black-light, leg. J.B. Heppner (USNM; genitalia slide Nos. JSM-528, JSM-1342). Barinas: 1♂, San Isidro, 14 km Sur La Soledad, 1500 m, 23–25 Sep 1975, leg. R.E. Dietz (AMNH).

Other Specimens Examined

Venezuela: Lara: 3♂♂, Yacambu Nat. Pk., 1560 m, 13 km SE Sanare, 28 Jul–11 Aug 1981, leg. J. Heppner, cloud forest (FNHM).

Dissected

2♂♂.

Polypoetes pallinervis (Felder), new combination

Plate 13

Stenoplastis pallinervis Felder, 1875: pl. 133, fig. 16.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♀, leg. Lindig (BMNH).

Scotura semisocia Dognin, 1914: 380. New synonymy.

Type Locality

Colombia, Pacho, “Ost. Cord”, 2200 m.

Type

Holotype ♂, leg. Fassl (USNM type no. 30962).

Discussion

The generic placement of P. pallinervis has long been controversial. It was described in Stenoplastis by Felder, and was retained there (Maassen, 1890; Kirby, 1892) until Prout (1918: 406) moved it to Xenomigia, placing it in his “Section II” along with villiodes. My studies show that it does not belong in Xenomigia, but instead belongs, along with villiodes Prout, as a new combination in Polypoetes.

Study of Felder's pallinervis type (March 6, 2005), the only example of this species in the BMNH collection, suggests that semisocia Dognin, also from Colombia, is conspecific. I here propose semisocia as a new synonym. Polypoetes pallinervis is known from only two specimens—the female BMNH holotype, and the male USNM type of semisocia (pl. 13). My research suggests that, within the Persimilis Group, P. pallinervis and P. jipiro (fig. 127) are sister taxa; their male genitalia are extremely similar, differing most notably in the configuration of the valval costa. Polypoetes pallinervis is apparently restricted to Colombia, whereas P. jipiro is endemic to eastern Ecuador.

Females are extremely rare throughout the Persimilis Group. Although I did not dissect the pallinervis female type, it shows the following traits: St7 heavily sclerotized, shiny, lacking scales but bearing a set of long, robust setae; Tg8 sclerotized, forming a rooflike structure over papillae anales. These characteristics occur in females of P. villiodes (fig. 130E) as well.

Distribution

Colombia (BMNH, USNM).

Dissected

♂ Holotype of semisocia Dognin, USNM (genitalia slide no. JSM-1006).

Polypoetes persimilis (Dognin), new combination

Figures 89D, 90I, 90L, 129; plate 13 [EX]

Scotura persimilis Dognin, 1913: 6.

Type Locality

Colombia, Monte Tolima, 3200 m, “Centr. Cord”.

Type

Holotype ♂, leg. Fassl (USNM type no. 30963).

Discussion

Within the Persimilis Group, P. persimilis is the apparent sister species to P. oteroi from western Venezuela. The two exhibit unusual male genital morphology (figs. 128, 129), and numerous synapomorphies unite them. Although males of P. persimilis are quite common in collections, females are extremely rare; in addition to the female dissected for this study (CMNH, JSM-752), there is a single example among a large series of males at the AMNH (leg. J.S. Miller and E. Tapia, October 2004).

Polypoetes persimilis occurs in cloud forests on the eastern slope of the Andes in Colombia and Ecuador, at elevations between 2000 and 3200 meters. An undescribed species from western Ecuador is known from a single specimen: ♂, Cotopaxi, Otonga, 2200 m, 22 Feb 1998, leg. F. Piñas, FPC (genitalia slide no. JSM-1580). The undescribed species is distinctive in showing a completely white HW, marked solely by a dark brown spot at its apex.

Distribution

Colombia (USNM); Ecuador (AMNH, CMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1005); ♂, Ecuador, Morona-Santiago, Río Culebrillas, 34 km SE Gualaceo, 2200 m, 22–23 Oct 1987, leg. J. Rawlins, C. Young & R. Davidson, wet forest, CMNH (genitalia slide no. JSM-529); ♂, Ecuador, Napo, Cosanga, 8 Sep 1996, leg. F. Piñas, FPC (genitalia slide no. JSM-890); ♀, Ecuador, Napo, SE slope Reventador, 2900 m, 5 Jul 1994, leg. Jan Hillman, cloud forest, CMNH (genitalia slide no. JSM-752, wing slide no. JSM-1803).

Polypoetes villiodes (Prout), new combination

Figure 130; plate 13 [EX]

Xenomigia villiodes Prout, 1918: 406.

Type Locality

Colombia, Sierra del Libano, 6000 ft.

Type

Holotype ♂, leg. H.H. Smith (BMNH).

Discussion

Polypoetes villiodes was described by Prout (1918) in Xenomigia, and has been retained there by subsequent workers (Hering, 1925; Bryk, 1930). However, morphological examination reveals that villiodes belongs as a new combination in Polypoetes, as it exhibits none of the characters peculiar to Xenomigia, but all the characters of the Persimilis Group. The wing-pattern resemblance of P. villiodes (pl. 13) to some species in Xenomigia (pls. 22, 23) is superficial.

I know P. villiodes from only three specimens, all at the BMNH—a male and a female collected in the Santa Marta range of northeastern Colombia, as well as the holotype. This is one of the largest species in Polypoetes (FW length  =  20.5–22.0 mm).

Distribution

Colombia (BMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-474); ♀, Colombia, Magdalena, Sierra Nevada de Santa Marta, 2300 m, 10°54′N.74°00′W, Oxford Expedn to Colombia, 3 Jul–2 Sep 1973, BMNH (genitalia slide no. JSM-475).

Polypoetes villiopsis (Hering)

Plate 13

Xenomigia villiopsis Hering 1925: 509.

Type Locality

Colombia, Caucatal, Cauca Valley.

Type

Holotype ♂ (ZMH).

Discussion

Hering (1925: 509) originally described villiopsis in Xenomigia, but later (1928: 272) moved it to Polypoetes. He noted, however, that the wing venation of P. villiopsis is unusual for members of Polypoetes, because FW vein “[Rs2] branches off well before [Rs4]”. This refers to a character state that helps define the Persimilis Group (fig. 90I), where these radials occur in the pattern Rs2+[Rs3+Rs4].

After studying the ZMH villiopsis holotype, I located an AMNH male matching it precisely. These are the only two specimens seen. Dissection shows that P. villiopsis is a close relative of P. pallinervis. Their wing patterns and genitalia are extremely similar, but they show obvious male genital differences.

Distribution

Colombia (AMNH, ZMH).

Dissected

♂, Colombia, Grace H. and John L. Sperry Collection, AMNH (genitalia slide no. JSM-1583).

6. RUBRIBASIS GROUP

Like the Persimilis Group, members of the Rubribasis Group (pl. 14) are unusual within Polypoetes in possessing short labial palpi (figs. 89A, 89C, 91D) and subserrate male antennae (fig. 92A). The two groups also show a similar distribution. Rubribasis Group species occur in Andean cloud forests from western Venezuela and Colombia south to Bolivia. Four of the seven described species are from Colombia. The two groups are distinguished by at least two morphological differences: the eyes are small in the Rubribasis Group (fig. 89C), but large in the Persimilis Group (fig. 89D); and the tympanal membrane is small in the Rubribasis Group, but large in the Persimilis Group.

The following genital features apply to members of the Rubribasis Group: male socii laterally compressed, apices broadly paddle shaped (figs. 131AFigure 132Figure 133134A); uncus tapered, with a group of stout setae on ventral surface near apex; female Tg7 excavated on lateral margins (figs. 132F, 134F), St7 usually with large, shallow posterolateral depressions (fig. 134G); female Tg8 rooflike (figs. 132E, 133E, 134D), with small dorsolateral pockets; ostium dorsoventrally compressed.

Of the seven species in the Rubribasis Group (appendix 2), two from northeastern Ecuador, P. bifenestra and P. sumaco, are described here as new. The balance are new combinations: Five species are taken from Stenoplastis and assigned to PolypoetesP. aborta (Dognin), P. aterrima (Dognin), P. pellucida (Dognin), and P. rubribasis (Hering). The final taxon, P. disconnexa (Dognin), was moved to Polypoetes from Monocreaga. At least five undescribed Rubribasis Group species were found among existing material in museum and private collections. Description of these will await revisionary research.

KEY TO RUBRIBASIS GROUP SPECIES

Plate 14

1. Forewing veins Rs2–Rs4 in the arrangement [2+3]+4; FW with a large white basal dash between cubitus and 1A+2A, this extending outward to base of CuA2; ventral margin of Lp2 with a ridge of long, bristlelike scales2

FW veins Rs2–Rs4 in the arrangement 2+[3+4]; FW without a large white basal dash, rarely (pellucida) with white basal blotches; ventral surface of Lp2 covered with short, appressed scales4

2. Forewing DC whitish, semihyaline in basal half; FW veins near outer margin lined with light reddish-brown scales3

FW DC brownish, semihyaline in basal half; FW veins near outer margin dark brown, concolorous with ground color; FW length  =  11.5–12.0 mm (NE Ecuador)sumaco, sp. nov.

3. A white FW dash between fork of M3+CuA1 and CuA2; light-colored areas of wings immaculate white; HW anal margin white; FW length  =  12.0–13.0 mm (Colombia)disconnexa (Dognin)

No white dash between fork of M3+CuA1 and CuA2; light-colored areas of wings creamy white to yellowish white; HW anal margin with scattered brown scales; FW length  =  10.5–11.0 mm (Colombia)aborta (Dognin)

4. Forewing without white basal markings; FW veins not forming daggers near outer margin; HW central area white or charcoal gray, with a round, translucent fascia beyond DC, anal margin charcoal gray; posterior margin of male St8 with a deep, narrow mesal excavation5

FW with diffuse, white basal markings, veins whitish yellow in basal third, orange-yellow beyond; FW veins forming yellow-orange daggers near outer margin; HW central area creamy white to yellowish white, anal margin white; posterior margin of male St8 serrate; FW length  =  12.0–13.0 mm (Colombia)pellucida (Dognin)

5. Forewing without an orange basal dash; some FW veins thinly lined with orange-yellow scales; HW central area white or dark, without a black comma crossing distal margin of DC6

FW with a striking orange to ochreous orange basal dash, located between cubitus and anal fold; FW veins black, concolorous with ground color; HW central area white, with a black comma crossing distal margin of DC; FW length  =  10.5–15.5 mm (SE Peru, Bolivia)rubribasis (Hering)

6. Forewing dark brown, veins boldly lined with orange-yellow scales; HW dorsal surface with a white central area and a wide, dark brown marginal band; male valva constricted near apex (fig. 131A), costa narrow; aedeagus relatively wide distally (fig. 131C), gently curved; female signum located ventrally; FW length  =  13.5–14.0 mm (Colombia)aterrima (Dognin)

FW dark charcoal gray to black, a few veins near base lined with scattered orange-yellow scales, most veins black; HW dorsal surface uniformly blackish gray, with a semihyaline window immediately beyond DC; valva not constricted near apex (fig. 132A), gradually narrowed, costa wide; aedeagus narrow distally (fig. 132C), strongly sinuate; signum located dorsally (fig. 132E); FW length  =  10.5–13.5 mm (NE Ecuador)bifenestra, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Polypoetes aborta (Dognin), new combination

Plate 14

Scotura aborta Dognin, 1913: 6.

Type Locality

Colombia, Monte Tolima, 4200 m, “Cent. Cord”.

Type

Syntype ♀, leg. Fassl (USNM type no. 30964).

Discussion

Polypoetes aborta, known from the syntype female and a syntype male (missing its abdomen; pl. 14), shows genitalia indicating membership in the Rubribasis Group. Based on wing pattern, P. aborta could potentially be a close relative of P. disconnexa and P. sumaco (pl. 14). The only significant pattern differences between these involve the configuration of the whitish markings near the FW base (see Rubribasis Group species key), and the amount of white in the HW. Other morphological characters for P. aborta, such as short labial palpi with erect scales, small eyes, and a small tympanum, are exhibited by most Rubribasis Group members.

The altitude on the P. aborta ♀ syntype label (4200 m), if correctly recorded by Fassl, represents the highest elevation yet known for the Dioptinae. Another Rubribasis Group species, P. sumaco, was collected at 3700 meters on Cerro Sumaco (Napo, Ecuador). It will be fascinating to learn about the biology of these high-altitude taxa; at present, nothing is known. Their host plants may mirror that of P. bifenestra, the only Rubribasis Group species for which the life history has been discovered. That species is unique in its association with Euphorbiaceae (table 4).

Distribution

Colombia (USNM).

Dissected

Syntype ♀ (genitalia slide no. JSM-1009).

Polypoetes aterrima (Dognin), new combination

Figure 131; plate 14

Scotura aterrima Dognin, 1913: 6.

Type Locality

Colombia, Monte Tolima, “Cent. Cord”, 3200 m.

Type

Syntype ♂, leg. Fassl (USNM type no. 30957).

Discussion

I know this species exclusively from its male and female syntypes. The male antennae are subserrate and the eyes are small, with a dense covering of short setae. Based on similarities of the genitalia, P. aterrima is an extremely close relative of P. bifenestra (pl. 14; fig. 132) from Ecuador; morphological differences between the two are subtle. Wing-pattern differences include the presence of a white HW central area in aterrima, but a dark HW in P. bifenestra. Furthermore, the HW fascia is poorly defined in aterrima, but is more conspicuous in P. bifenestra. Finally, the FW veins in P. aterrima are sharply lined with orange scales, whereas in P. bifenestra only a scattering of scales occurs along the veins.

A specimen in the Florida Natural History Museum (JSM-1670), from cloud-forest habitat in western Venezuela, shows male genitalia extremely similar to those of P. aterrima. However, differences in valva shape show that it is a different species, as yet undescribed. This specimen provides the only documentation of the Rubribasis Group in Venezuela, further indicating that additional collecting is needed to understand the group's distribution. Label data for the undescribed species are as follows: ♂, Venezuela, Lara, Yacambu Natl. Park, 13 km SE Sanare, 1560 m, 28–31 Jul 1981, leg. J. Heppner, cloud forest, FNHM (genitalia slide no. JSM-1670).

Distribution

Colombia (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1007); ♀, Colombia, Río Toche, Quindiu, 2400 m, USNM (genitalia slide no. JSM-1496).

Polypoetes bifenestra, new species

Figures 89A, 89C, 91, 92A, 92B, 109, 132; plates 14, 38E [EX]

Diagnosis

The FW and HW of P. bifenestra are uniformly dark charcoal gray to almost black on their dorsal surfaces (pl. 14), but show small, windowlike fasciae (larger in the FW) immediately beyond the DC. Both windows are bisected by vein M2, which is thinly lined with black scales. The FW veins tend to be sparsely lined with light orange scales in the basal third. The FW ventral surface shows a white dash near the base, and the HW ventral surface is white in the basal half. The presence of a window on each wing, located within a dark ground color, is diagnostic for the species. Such fasciae occur in other members of Polypoetes, but they are generally not as striking as in P. bifenestra. When genital morphology is examined, P. bifenestra is unique among Rubribasis Group species in possessing a thin, sinuate aedeagus (fig. 132C).

In P. bifenestra, FW veins Rs2–Rs4 are in the arrangement 2+[3+4]. The antennae are subserrate in males (fig. 92A) and ciliate in females. The labial palpi are relatively short (fig. 89C) and porrect (fig. 89A). As in other Rubribasis Group species, the eyes and tympanal membrane of P. bifenestra are small. This contrasts with most Polypoetes, where the eyes and tympanal membrane are large.

Description

Male. Forewing length  =  10.5–13.0 mm. Head (figs. 89A, 89C, 91, 92A, 92B): Labial palpus relatively short, upturned to below middle of front; Lp1 orange-yellow, with a fringe of long scales below; Lp2 blackish brown with a few white scales on mesal surface; Lp3 blackish brown, apex with a dense set of yellowish brown-spinules; front blackish brown, scales moderately long, pointing upward and reaching to immediately beyond antennal bases; eye small, completely surrounded by a scaleless area, this widest below; eye sparsely covered with short setae; occiput black above, yellow to cream below; vertex completely blackish brown; a few long, white scales at junction of head and thorax; antenna subserrate, each annulation with two transverse rows of setae set on short protuberances; scape and dorsal surfaces of antennal shaft blackish brown.

Thorax: Coxae and pleuron covered with long, white, hairlike scales; tibiae, including spurs, and femora charcoal on outer surfaces, white on inner surfaces, inner scales long; tarsi charcoal gray with scattered white scales on inner surfaces; patagium with long, upwardly pointing, blackish-brown scales, a few white scales on posterior margins; tegula blackish brown with a small orange patch near base, distal scales hairlike; dorsum entirely blackish brown; tympanum small, membrane facing posteroventrally.

Forewing: (Dorsal) Ground color dark charcoal gray, almost black (pl. 14); a single, trapezoidal fascia, hyaline with a few scattered charcoal-gray scales, immediately beyond DC, its anterior margin touching the base of Rs1–Rs4 and its posterior margin touching the base of M3+CuA1; fascia bisected by M2, which is thinly lined with black scales; cubitus, anal fold and 1A+2A lined with light orange scales near base; radial and medial veins in some specimens touched with light orange near outer margin. (Ventral) Similar to dorsal surface, but a slightly lighter shade of charcoal; no orange in veins; two white dashes near base, a short one behind SC and a longer one, anterior to anal fold, extending halfway out DC.

Hind wing: (Dorsal) Dark charcoal gray, almost black (pl. 14); a small, quadrate, hyaline fascia immediately beyond DC, its anterior margin touching base of Rs+M1, its posterior margin falling short of base of M3+CuA1; fascia dusted with black scales, bisected by black M2; white area on basal half of ventral surface showing slightly through above. (Ventral) Outer half dark charcoal, almost black; dark area wider near apex, narrowing at lower angle; basal half silvery white to distal margin of DC; outer margin of white area irregular; hyaline fascia separated from DC by a thin, black inner margin.

Abdomen: Dark charcoal gray, almost black above; venter white from base to St7, St8 dark charcoal gray.

Terminalia (fig. 132A–D): Tg8 narrow, elongate, widest at anterior margin, a slight lateral constriction in distal one-fourth, gradually narrowing to a blunt, tapered posterior process; dorsum of Tg8 with a wide, shallow groove along midline; anterior margin of Tg8 with a pair of short, broad processes near lateral angles; St8 wide, ovoid, widest at anterior margin, lateral margins smoothly curved; posterior margin of St8 with a pair of broadly rounded humps on either side of a U-shaped mesal excavation; anterior margin with a short, wide central apodeme; socii/uncus complex extremely large, hoodlike, with a wide attachment to ring; uncus wide at base, narrowed to a blunt point, ventral surface near apex bearing relatively short, robust setae; socii extremely large, armlike, elbowed slightly upward, laterally compressed near apex to form paddlelike structures, their lateral surfaces densely covered with robust setae; tegumen much taller than vinculum; tegumen expanded near midpoint; vinculum short, narrow; saccus U-shaped below, dorsal margin folded upward at midline to slightly short of valva bases; valva extremely short and small; costa moderately wide, margins parallel; distal portion of valva slightly narrowed; apex smoothly rounded, with a large patch of coarse setae below; BO small, slightly folded anteriorly, pleats and androconia fairly long; transtillar arms short, wide at base then quickly narrowed to meet in a small mesal process; a triangular sclerite in anellus above transtilla, bordered above with several transverse striations; aedeagus relatively long, sinuate, wide at base; apex of aedeagus narrow, with a curved opercular sclerite, no point or process below; vesica fairly large, bearing a tight brush of short setae halfway out, and approximately 20 longer, spinelike cornuti beyond.

Female. Forewing length  =  13.0–13.5 mm. Head, thorax, and abdomen similar to male; wings similar to male, except ground color a slightly lighter shade of charcoal gray; antenna ciliate, with a few scattered bristlelike ventral setae.

Terminalia (fig. 132E–G): Tg7 trapezoidal, widest at anterior margin, slightly narrowed posteriorly, lateral angles rounded; posterior margin minutely spiculate, anterior margin simple; St7 wide, with a sclerotized transverse band at halfway point; lateral angles of St7 broadly rounded, protruding posteriorly; posterior margin of St7 broadly concave, edged with coarse setae, anterior margin slightly convex, simple; Tg8 large, sclerotized, minutely spiculate on dorsum, forming a hoodlike structure over PA; a pair of small, sclerotized lateral pockets near anterior margin; posterior margin of Tg8 with a V-shaped notch at midline; AA, curved slightly downward; pleuron of Tg8 melanized; membrane above ostium folded inward below PA; ostium partially sclerotized, dorsoventrally compressed; DB partially sclerotized, dorsoventrally compressed; DS attached to a small, dorsal appendix at base of CB; CB ovoid, with a wide dorsal signum; PA triangular along outer margin; PP melanized, straight, minutely club shaped at apex.

Etymology

This name comes from Latin, bi for “two”, and fenestra, meaning “window”, in reference to the hyaline, windowlike fasciae, present beyond the DC, in both the FW and the HW.

Distribution

Polypoetes bifenestra is known exclusively from cloud forests in the Oriente of northern Ecuador (fig. 109), at elevations between 2000 and 3000 meters. Together, the sites where it has been collected span a distance of less than 50 km. The bulk of known material was captured on a single night in July 1994, at 2900 meters on the southeastern slope of Volcán Reventador (CMNH). This volcano, nearly 3600 m high, erupted in a spectacular explosion on November 3, 2002, destroying the SE slope and sending lava flows 8 km down the mountain. That collecting site for P. bifenestra is no more.

Biology

The life history of P. bifenestra, discovered at Yanayacu Biological Station in June 2007 (G. Gentry), is the newest life history finding for Polypoetes. Polypoetes bifenestra is unique in being associated with Alchornea grandis, in the Euphorbiaceae (table 4); no other dioptine is associated with that plant family. Caterpillars of P. bifenestra (pl. 38E) are somewhat unusual for the genus, because each body segment shows a small, purple dorsal triangle. These run the entire length of the body. Most Polypoetes larvae show only four purple dorsal markings (e.g., P. villia; pl. 38B)—on A1, A3, A5, and A8. This is the only life history known for the Rubribasis Group, but Euphorbiaceae should be considered likely host-plant candidates for additional species.

Discussion

A cursory morphological survey suggests that the Rubribasis Group (pl. 14) is comprised of three subclades—one solely for pellucida; a second encompassing aborta, disconnexa, and sumaco; and a third containing aterrima, bifenestra, and rubribasis. In addition to wing-pattern differences, P. bifenestra can be separated from P. rubribasis and P. aterrima by genital autapomorphies. For example, the aedeagus of P. bifenestra is thin and sinuate distally (fig. 132C), whereas those of P. aterrima (fig. 131C) and P. rubribasis (fig. 133C) are wider and not sinuate.

Three males (BMNH, USNM) from San Antonio (03°29′N, 76°38′W; 2000 m), in western Colombia, show a completely dark HW as in P. bifenestra, but they differ in lacking the hyaline HW fascia. Their male genitalia differ from those of P. bifenestra, most notably in the shape of the posterior margins of Tg8 and St8, and in the shape of the aedeagus. The Colombian material thus represents an as yet undescribed species.

Holotype

Male (pl. 14). Ecuador: Napo: Oriente, Yanayacu Biological Station, S00°35.9′ W77°53.4′, 2163 m, 4–5 Mar 2003, at light UV/MV, leg. S. Rab Green & M. Tapia, eastern cloud forest, undisturbed. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 5♂♂, 2♀♀, SE slope Reventador, 2900 m, 5 Jul 1994, leg. Jan Hillman, cloud forest (CMNH; male genitalia slide Nos. JSM-754, 1704; female genitalia slide no. JSM-755); 1♀, Yanayacu Biological Station, 5 km W Cosanga on Cosanga-Río Alíso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 4 Mar 2006, leg. J.S. Miller, MV light (AMNH); 1♂, Yanayacu Biological Station, 5 km W Cosanga, Cosanga-Río Alíso Rd., 2200 m, 3 Oct 2004, MV light, leg. J.S. Miller & E. Tapia (AMNH); 1♂, Yanayacu Biological Station, S 00°35.9′ W 77°53.4′, 2163 m, 4–5 Mar 2003, at light UV/MV, leg. S. Rab Green & M. Tapia, eastern cloud forest, undisturbed (AMNH).

Other Specimens Examined

None.

Dissected

2♂♂, 1♀.

Polypoetes disconnexa (Dognin), new combination

Plate 14

Tanaostyla disconnexa Dognin, 1911a: 21.

Type Locality

Colombia, “Yuntas, près Cali”.

Type

Syntype ♂, leg. Fassl (USNM type no. 30966).

Discussion

Male genital characters of P. disconnexa demonstrate membership in Polypoetes, a new combination. It seems a mystery that Dognin (1911a) described disconnexa in the genus Tanaostyla (currently Monocreaga); he gave no rationale. The moth bears no resemblance to the other species in that genus, all of which possess hyaline wings (pl. 21). Dognin was perhaps misled by the presence of ciliate antennae in disconnexa, a trait that occurs in Monocreaga as well (fig. 216C, D). However, so-called “ciliate” antennae are found in at least six clades of the Dioptinae, including the Rubribasis Group of Polypoetes (fig. 92A), where P. disconnexa belongs.

My knowledge of P. disconnexa is limited to only two specimens—the male syntypes, both at the USNM. Wing pattern in this taxon resembles that of P. aborta (pl. 14), also from Colombia. The two differ in that P. disconnexa is slightly larger (disconnexa FW length  =  12.0 mm; aborta FW length  =  11.0 mm), and its FW is whiter.

Distribution

Colombia (USNM).

Dissected

Syntype ♂, Colombia, Yuntas près Cali, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-549).

Polypoetes pellucida (Dognin), new combination

Plate 14

Scotura pellucida Dognin, 1910a: 16.

Type Locality

Colombia, Cali, San Antonio, Alto de las Cruces, 2200 m.

Type

Holotype ♂, leg. Fassl, 1 Sep 1908 (USNM type no. 30960).

Discussion

The wing pattern of Polypoetes pellucida is extremely similar to that of P. trimacula (pl. 11). However, numerous morphological differences reveal that the two taxa belong in different Polypoetes species groups; P. pellucida, with its short palpi and subserrate male antennae, belongs in the Rubribasis Group, whereas P. trimacula, with elongate palpi and bipectinate male antennae, belongs in the Haruspex Group. Polypoetes pellucida seems to be morphologically isolated within the Rubribasis Group. Although I conclude that it belongs there, its wing pattern and genitalia show few affinities to other species in the clade.

An undescribed taxon from western Ecuador, whose male genitalia (JSM-883) share numerous similarities with those of pellucida, is known from three males—one from Mindo, Pichincha Province (FPC) and two from Balsapamba, Bolívar Province (BMNH). In addition to genital differences, the two taxa can be separated because the wide, dark brown outer band of the HW curves around the wing, tapering near the anal margin in pellucida, whereas in the undescribed species this HW band ends abruptly at vein CuA2.

Distribution

Colombia (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1008).

Polypoetes rubribasis (Hering), new combination

Figure 133; plate 14 [EX]

Stenoplastis rubribasis Hering, 1925: 518.

Type Locality

Bolivia, Río Tanampaya, La Paz.

Type

Syntype ♂/♀, leg. Garlepp (ZMH).

Discussion

Although relatively few specimens of P. rubribasis are known, they suggest that the species has a relatively broad geographical distribution; it occurs on the eastern slope of the Andes from central Peru south to Argentina, at elevations between 1500 and 2500 meters. In contrast to species in the Persimilis Group, where females are virtually unknown, it is males that are rare in P. rubribasis.

The following female, collected in western Ecuador, is distinct from P. rubribasis: Pichincha, 39 km NE Alluriquín, old Quito-Sto. Domingo Rd., 7100 ft, 25 Oct 1988, leg. J.S. Miller, AMNH (genitalia slide no. JSM-1495). The entire HW central area of this moth is dusted with black scales, except for the fascia, and the FW veins are lined with orange-yellow scales. Its genitalia differ significantly from those of P. rubribasis.

The genitalia of material collected in the Cosñipata Valley of Peru (JSM-1581, 1554) differ slightly from those of Bolivian examples. Further study may reveal a distinct species in Peru. Argentine specimens should also be studied. The possibility exists that what is now called “rubribasis” in collections in fact represents an assemblage of cryptic species.

Martin Hering deposited a paratype of P. rubribasis at the BMNH. That specimen, the only example of the species in their holdings, bears the following data: Peru, Callanga (pr. Cuzco), 1500 m, 1898, leg. O. Garlepp.

Distribution

Bolivia (USNM, ZMH); Argentina (AMNH); Peru (AMNH, BMNH, MUSM).

Dissected

♂, Bolivia, Cochabamba, Incachaca, leg. J. Steinbach, USNM (genitalia slide no. JSM-524); ♂, Peru, Cuzco, Cosñipata Valley, Pillahuata-Pilcopata Rd., 2300 m, S13°08′58″, W71°35′07″, 23 Oct 2005, leg. G. Lamas, day, MUSM (genitalia slide no. JSM-1581); ♀, Bolivia, Cochabamba, Incachaca, leg. J. Steinbach, USNM (genitalia slide no. JSM-525); ♀, Peru, Cuzco, Cosñipata Valley, Pillahuata-Pilcopata Rd., 2300 m, S13°08′58″, W71°35′07″, 23 Oct 2005, leg. J.S. Miller, day collecting, on Compositae flowers, AMNH (genitalia slide no. JSM-1554); ♀, Argentina, Buenos Aires, Villa Ballester, Nov 1953, leg. Juan Foerster, AMNH (genitalia slide no. JSM-1582).

Polypoetes sumaco, new species

Figures 109, 134; plate 14

Diagnosis

Wing pattern and morphology suggest that, within the Rubribasis Group, P. sumaco belongs in a subclade along with P. aborta and P. disconnexa. Their wing patterns (pl. 14) are similar, but show characters for easy separation (see Rubribasis Group species key, above). All three species exhibit a whitish basal dash posterior to the discal cell, but only P. sumaco is brown within the DC; the others are white within it. It is difficult to use genital characters for diagnostic purposes, since females are unknown for disconnexa, and intact males remain undiscovered for aborta. For P. sumaco itself, both sexes have been captured.

Other characters of P. sumaco are typical for the Rubribasis Group: Antenna subserrate in male, ciliate in female; labial palpus short; eye small; FW radial sector in the arrangement 1+[[2+3]+4]; FW vein M1 arising at base of radial sector; tympanum small.

Description

Male. Forewing length  =  12.0–13.0 mm. Head: Labial palpus thin, delicate, upturned to well above middle of front but short of antennal base; Lp1 light brown with a few cream-colored scales on dorsal and lateral surfaces, a loose ventral fringe of long, bristlelike scales; Lp2 and Lp3 light brown with a few scattered beige scales; front covered with long, upwardly pointing brown scales, longest ones at dorsum reaching upward to well beyond antennal bases; eye extremely small, completely surrounded by a wide, scaleless area, widest below; occiput brown in dorsal two-thirds, cream colored in ventral third; vertex covered with long, bristlelike brown scales and a lower layer of short, light brown scales close to head surface, a patch of cream-colored scales behind each antennal base; antenna subserrate, each annulation bearing two transverse rows of setae, the proximal one larger with longer setae set on short protuberances; scape brown with a few light brown scales below; dorsal surface of antennal shaft brown to light brown.

Thorax: Coxa and pleuron covered with long, hairlike, light brown to cream-colored scales; tibia and femur light brown on upper surfaces, cream to beige on inner ones; tarsus light brown with a few scattered cream-colored scales on ventral surfaces; metathoracic tibia lighter in color than other legs; patagium a mixture of long, light brown and a few cream-colored scales; tegula with moderately long, cream to beige scales in middle, surrounded by hairlike brown scales, longest at apex; dorsum covered with brown, hairlike, and shorter scales, a region of cream-colored scales posterolaterally; tympanum small, membrane facing posterolaterally.

Forewing: (Dorsal) Ground color brown to light brown (pl. 14), slightly darker along anal margin, scale covering somewhat sparse; a trapezoidal fascia, hyaline with a few scattered white scales, immediately beyond DC, its anterior margin touching base of radial sector and its posterior margin touching base of M3+CuA1; fascia bisected by M2, which is scaleless; basal half of DC more sparsely scaled than distal half; a wide, white streak from base to fork of cubitus and CuA2, its anterior margin falling short of cubitus and its posterior margin reaching anal fold; fringe light brown. (Ventral) Essentially the same as dorsal surface; scales slightly longer overall.

Hind wing: (Dorsal) Brown to light brown (pl. 14); a small, quadrate hyaline fascia immediately beyond DC conjoined with white central area, which extends from base to end of DC; white area extending from anterior margin of DC posteriorly to anal fold; anal margin fringed with hairlike, light brown and whitish scales. (Ventral) Similar to dorsal surface, except anterior margin white in basal third.

Abdomen: Dorsum gray-brown; venter light brown.

Terminalia (fig. 134A–C, E): Tg8 narrow, sclerotized, greatly elongate, posterior margin with lobelike processes at lateral angles, a deep U-shaped mesal notch, anterior margin flanged outward laterally, with a pair of short, inward pointing apodemes near midline; dorsum of Tg8 with a wide, deep groove along midline; St8 much shorter than Tg8, widest anteriorly, narrowing distally; posterior margin of St8 with armlike, sclerotized lateral angles, a wide U-shaped mesal excavation, its margin heavily sclerotized, trimmed with fine setae; anterior margin of St8 with a short, wide apodeme; socii/uncus complex large, with a wide attachment to ring; uncus wide, short, apex blunt, rugulose below; socii large, apices greatly expanded, paddle shaped, approximate medially, lateral margins clothed with short, coarse, upturned setae; tegumen wide, much taller than vinculum; vinculum wide, short; saccus V-shaped below, upper margin triangular, upturned to cover valva bases; valva very short, mostly membranous; BO present, pleated area not curled, androconia moderately long; costa of valva lightly sclerotized; valva apex angulate, turned slightly dorsomedially; inner surface of valva with a patch of short, fine setae distally; transtillar arms thin, downturned slightly; anellus sclerotized above transtilla, a small knob below, transverse striations above; aedeagus moderate in length, expanded at base, apex with a tiny hook-shaped point below; vesica narrow, straight, cornuti absent.

Female. Forewing length  =  12.5 mm. Head, thorax, wings and abdomen similar to male; antenna ciliate, with a few bristlelike setae on ventral surface.

Terminalia (fig. 134D, F, G): Tg7 large, broad, widest near posterior margin, lateral angles broadly rounded; Tg7 less sclerotized along midline, posterior margin sparsely setose, anterior margin simple; St7 broad, slightly shorter than Tg7, distal third sclerotized, expanded laterally to form large, shallow pockets, their surfaces sparely setose; posterior margin of St7 slightly irregular, anterior margin simple; Tg8 sclerotized, posterior margin with complex, longitudinal folds, dorsum with a short, broad crest along midline; AA long, straight; pleuron of A8 narrowly melanized; membrane above ostium deeply infolded below PA, surface crenulate; ostium short, wide, dorsoventrally compressed, a lip along lower margin; DB relatively short, heavily sclerotized, dorsoventrally compressed, with a small distal appendix below; DS attached dorsally at junction of DB and CB; CB narrow in basal one-third, wide, somewhat heart shaped in distal two-thirds; a wide, shield shaped signum on left side of CB near middle; PA slightly triangular along outer margin; PP short, straight.

Etymology

The species name for this taxon, a noun in apposition, pays tribute to the type locality—Cerro Sumaco in Napo, Ecuador.

Distribution

Polypoetes sumaco has been captured at a single site in eastern Ecuador; Cerro Sumaco, approximately 30 km E of Cosanga (fig. 109). The three known examples of this species were collected near the peak's summit. Cerro Sumaco attains an elevation of 3732 meters, and P. sumaco is recorded from 3700 meters. This mountain, one of the most beautiful in Ecuador, is situated in Parque Nacional Sumaco-Galeras, an incredible expanse of montane forest stretching from San Rafael falls (Sucumbíos Province) in the north (pl. 41A), to the Narupa-Loreto Road (Napo) in the south. Sumaco itself is unique in being somewhat isolated from the rest of the Andes. Its cloud covered peak stands alone, overlooking the entire Amazon Basin which stretches east, essentially uninterrupted, for 3000 miles to the Atlantic Ocean. Seeing Cerro Sumaco from the Baeza-Tena road in the early morning light is an unforgettable experience.

Discussion

The specimens upon which this description is based were found among unsorted Lepidoptera, during a visit to the BMNH. This discovery adds to the mystery of the Rubribasis Group. Three Rubribasis Group species—P. sumaco, P. aborta, and P. disconnexa—form a subclade. All are incredibly rare. Polypoetes sumaco, known from three specimens, is the commonest member. The two remaining taxa, both from central Colombia, are known from a pair of specimens each. Furthermore, all occur above treeline on cloud-covered peaks. Polypoetes aborta, collected at 4200 meters, is the record holder for altitude in the Dioptinae. There can be little doubt that many additional undescribed species representing this clade will eventually be discovered as more becomes known about the moth fauna of the Andes.

Holotype

Male (pl. 14). Ecuador: Napo: Cerro Sumaco, 3700 m, 23 Apr–8 May 1979, leg. T. deVries, B.M. 1979-569, S33. The type is deposited in the collection of the Natural History Museum, London (BMNH).

Paratypes

Ecuador: Napo: 1♂, 1♀, Cerro Sumaco, 3700 m, 23 Apr–8 May 1979, leg. T. deVries, B.M. 1979-569, S33 (BMNH; ♂ genitalia slide no. JSM-837, ♀ genitalia slide no. JSM-838).

Other Specimens Examined

None.

Dissected

Paratype ♂, paratype ♀.

The following species have been transferred from Polypoetes: cuatropuntada Dognin to incertae sedis leucocrypta Dognin to Xenorma Prout mesitana Dognin to Argentala New Genus sirenia Hering to Nebulosa (Albitumida Group) tiznon Dognin to Nebulosa (Fulvipalpis Group)

CACOLYCES WARREN, 1906

Figures 135, 136; plate 14

Cacolyces Warren, 1906, 409. Type species: Lyces plagifera Walker, 1856 (by original designation).

Figure 135

Morphology of Cacolyces plagifera ♂. A, head, lateral view; B, head, lateral view; C, head, posterior view; D, wings; E, tegula (illustration by J.S. Miller).

i0003-0090-321-1-1-f135.gif

Figure 136

Genitalia of Cacolyces plagifera (♂ JSM-731, ♀ JSM-1436). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f136.gif

Diagnosis

Cacolyces, containing a single species—plagifera Walker—is easy to recognize. The wingspan is long (FW length  =  20.0–25.0 mm), and the pattern is unmistakable (pl. 14). Especially notable are the locations of the light yellow, ovoid FW spots; one at the anterolateral angle of the DC, and a second, larger one near the tornus. The FW is trimmed with white at its apex. The wing venation of Cacolyces (fig. 135D) is somewhat unusual in that M3 and CuA1 are approximate, but not stalked, in the FW and HW. Males have a well-developed stridulatory organ, the DC being less than one-half the FW length. The labial palpi are long and curved (fig. 135A), with an unusually wide Lp2 (fig. 135B), but they are unlike the elbowed palpi of genera such as Oricia (fig. 31E), Erbessa (e.g., fig. 35B C), Phaeochlaena (fig. 70A) and Polypoetes (e.g., fig. 89B). The antennae of C. plagifera are bipectinate in males and ciliate in females. Genital morphology in Cacolyces plagifera is also distinctive. Males exhibit extremely long, narrow valvae (fig. 136A), bound tightly to the vinculum. The thin, strongly curved socii, with their truncate apices, are unlike those of any other dioptine. Similarly, the swollen, bilobed configuration of Tg8 in females (fig. 136E) is unique for the subfamily.

Redescription

Male. FW length  =  19.0–21.0 mm. Head (fig. 135A–C): Labial palpus long, extending upward to above middle of front, but falling well short of antennal base; proboscis reddish brown to yellowish brown; Lp1 moderately long, yellow, with a loose fringe of long scales below; Lp2 elongate, much longer than Lp1, wide, closely scaled; Lp3 extremely short, conical, almost fused with Lp2; scales of front erect, most pointing anteriorly, a pair of lateroventral depressions formed where palpi rest against front; eye large, round, bulging, with a narrow scaleless band anteriorly and ventrally; postgena moderately wide; scales of vertex pointing anterodorsally, evenly melded with frontal scales; antenna bipectinate, rami relatively short, terminal 10–12 annulations simple.

Thorax (fig. 135E): Epiphysis two-thirds length of tibia, not extending beyond tibia apex; tegula long, over two-thirds length of mesoscutum, distal portion narrowly rounded, ventral portion acute, the two parts divided by a strong sulcus; metathoracic tympanum small, often obscured by pleural scales, cavity deep and scaleless; tympanal membrane small, ovoid, oriented horizontally.

Forewing (fig. 135D; pl. 14): Long, fairly narrow; vein Rs1 arising from radial sector below Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC near anterolateral angle, close to, but separate from, the base of radial sector; stridulatory organ well developed, comprising a semihyaline fascia beyond DC, its surface corrugated; bases of M1 and M2 swollen, with a well-defined ventral fold between them; DC less than one-half FW length; veins M3 and CuA1 arising together from posterolateral angle of DC, touching but not stalked; wings dark chocolate brown, veins thinly lined with ochreous brown; a yellowish spot anterior to fascia, and a large, ovoid, light yellow spot near tornus, its anterior margin falling short of M2 and its posterior margin crossing behind CuA2; apex trimmed with white or whitish yellow.

Hind wing (fig. 135D; pl. 14): Blackish brown with a broad, light yellow area near base; base itself brown, radius, cubitus, anal fold, and 1A+2A lined with scattered dark brown scales as they pass through yellow area; M3 and CuA1 arising from posterolateral angle of DC, approximate but not stalked.

Abdomen: Elongate; dorsum dark brown, venter creamy white; a narrow, white, longitudinal stripe running along pleuron.

Terminalia (fig. 136A–D): Tg8 relatively short, narrower than Tg7, simple and roughly quadrate, anterior margin simple, posterior margin gently convex; St8 slightly longer than Tg8, roughly ovoid, lateral margins convex, anterior margin forming a broad, shallow, V-shaped apodeme, sclerotized near midline, posterior margin with a short, wide, lightly sclerotized mesal process; socii/uncus complex large, narrowly attached to tegumen; uncus short, truncate at apex, setose on dorsum; socii heavily sclerotized, elongate, wide at their bases then abruptly narrowed and tube shaped, curving sharply upward; tegumen wide, much taller than vinculum, extremely wide and expanded laterally in lower two-thirds; vinculum narrow, forming a wide U-shape at ventral margin of genitalia; saccus small, dorsal margin forming a broad triangle between valva bases; valva greatly elongate, tightly held to ring, constricted in basal two-thirds, then abruptly expanded in distal third, BO highly reduced, pleats barely visible, dorsal margin of BO forming a large, heavily sclerotized flange near base of valva; costa narrow; apex of valva broadly rounded, paddle shaped, inner surface with a dense brush of long setae; arms of transtilla apparently absent; juxta tall, comprising a pair of long narrow sclerites below aedeagus; aedeagus long, curving slightly downward, slightly wider at base; apex of aedeagus gradually tapered, not forming a distal point; opercular sclerite located dorsolaterally, finely spiculate; vesica wide, approximately half as long as aedeagus, opening dorsally, bearing approximately 15, long, thin spinelike cornuti on posterior surface.

Female. FW length  =  23.5–25.0 mm. Head, thorax, and wings similar to male, except: labial palpus shorter, extending upward to below middle of front; antenna finely ciliate; wings longer and broader, ground color lighter brown; frenulum comprising approximately 15 bristles.

Abdomen: Shorter and wider than male.

Terminalia (fig. 136E): Tg7 slightly longer than Tg6, narrowing posteriorly, anterior and posterior margins simple; St7 equal in length to Tg7, anterior margin simple, lateral margins gently convex, posterior margin with a wide, shallow mesal excavation; Tg8 sclerotized, bulbous, comprising a pair of large, swollen lobes with a small longitudinal crest between them, surface finely spiculate; AA short, straight and acute; A8 pleuron membranous, a thin sclerotized band lining anterior margin; PP short, straight, bases broadly sclerotized; PA somewhat elongate, membranous, with group of long dorsal setae; PVP wide, mouth-shaped, with lateral margins wrapping upward, posterior margin rugose; DB sclerotized, moderately long, dorsoventrally compressed; CB comprising two parts of roughly equal size, an ovoid, membranous anterior part, and a smoothly sclerotized, bean-shaped basal part; signum absent; DS arising from right side at base of membranous half of CB.

Distribution

Cacolyces plagifera is relatively rare. The moth is endemic to lowland forests, having been recorded from scattered sites across the Guiana Shield, as well as along the lower portion of the Amazon River. The furthest it has been collected upriver is at Obidos, near Santarém.

Biology

Nothing is known concerning the biology of Cacolyces.

Discussion

Cacolyces Warren (1906) was established in the Cyllopodinae (now Geometridae: Sterrhinae), and later moved to the Dioptidae by Prout (1918). My cladistic analyses place Cacolyces within a clade of 51 species that includes four additional genera—Hadesina, Brachyglene, Chrysoglossa, and Nebulosa (Clade 9; fig. 7). In all these taxa, the male FW bears a stridulatory organ characterized by veins M1 and M2 swollen at their bases (fig. 135D), and an area of sparsely arranged scales beyond the DC (figs. 144C, 144D, 161). The analyses further suggest that Cacolyces and Hadesina are sister groups. Supporting evidence includes the presence of elongate, spatulate valva apices in males (e.g., figs. 136A, 139A, 141A), as well as presence of a large, swollen sclerotized appendix at the base of the CB in females (e.g., figs. 136E, 139F, 141F). On the other hand, wing patterns in these taxa (pl. 14) are not particularly suggestive of a close relationship.

Cacolyces plagifera (Walker)

Figures 135, 136; plate 14 [EX]

Lyces plagifera Walker, 1856: 1656.

Type Locality

“Valley of the Amazon”.

Type

Syntype ♂/♀, ex Saunders Collection (OUMNH).

Discussion

Fewer than 20 specimens of C. plagifera were located in the world's collections. The largest series is at the BMNH (6♂♂, 4♀♀). The holdings of other museums number fewer than one or two examples in each. The location of Walker's plagifera type material had long been a mystery. It was not in London, where the vast majority of his types reside. Not until the Hope Museum in Oxford was contacted (October 2006), in reference to a different type altogether, did the plagifera types surface. They include a male and female with labels simply stating “Amaz.”. Walker's (1856) description gives little additional detail, stating that the specimens came from “Mr. Saunder's collection”, their provenance being the “Valley of the Amazon”.

This species shows a confusing combination of morphological features. Among other things, the labial palpi are long and wide (fig. 135A, B), a shape atypical of the larger clade to which Cacolyces belongs. In Hadesina, its sister group, the labial palpi are short (fig. 137A), with Lp2 being shorter than Lp1. Biological information for this strange taxon is sorely needed. Perhaps the morphology of immature stages will provide help in elucidating its phylogenetic position within the Dioptinae.

Distribution

Brazil (OUMNH, USNM); Venezuela (USNM, BMNH, ZMH); Guyana (USNM); Suriname (BMNH, CUIC); French Guiana (AMNH, BHC, USNM).

Dissected

♂, French Guiana, Cayenne, USNM (genitalia slide no. JSM-1023, wing slide no. JSM-1435); ♂, [no data], USNM (genitalia slide no. JSM-1436); ♀, Brazil, Saõ Paulo, Obidos, Nov, leg. B. Pohl, no. 126, USNM (genitalia slide no. JSM-731, wing slide no. JSM-1437).

HADESINA WARREN, 1900

Figures 137Figure 138Figure 139Figure 140Figure 141142; plate 14

Hadesina Warren, 1900: 126. Type species: Hadesina limbaria Warren, 1900 (by original designation).

Figure 137

Morphology of Hadesina (♂♂). A, head of H. limbaria, lateral view; B, head of H. limbaria, frontal view; C, head of H. limbaria, posterior view; D, head of H. goeleti, lateral view; E, head of H. goeleti, lateral view; F, H. caerulescens wings (JSM-799) (illustration by J.S. Miller).

i0003-0090-321-1-1-f137.gif

Figure 138

Genitalia of Hadesina. A, ♂ of H. limbaria (JSM-411); B, ♂ St8 of H. limbaria; C, aedeagus of H. limbaria; D, ♂ Tg8 of H. limbaria; E, Syntype ♀ of H. caerulescens (JSM-412) (illustration by A. Trabka).

i0003-0090-321-1-1-f138.gif

Figure 139

Genitalia of Hadesina. A, Syntype ♂ of H. caerulescens (JSM-1050); B, ♂ St8 of H. caerulescens; C, aedeagus of H. caerulescens; D, ♂ Tg8 of H. caerulescens; E, ♀ St7 of H. limbaria; F, ♀ of H. limbaria (JSM-1469); G, ♀ Tg7 of H. limbaria.

i0003-0090-321-1-1-f139.gif

Figure 140

Genitalia of Hadesina divisa (Syntype ♂ JSM-1217, ♀ JSM-784). A, ♂ genitalia; B, ♀ genitalia; C, ♂ Tg8; D, aedeagus; E, ♂ St8.

i0003-0090-321-1-1-f140.gif

Figure 141

Genitalia of Hadesina goeleti, sp. nov. (JSM-1310, 1311). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ St7; F, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f141.gif

Figure 142

Costa Rica, showing the known distributions of Hadesina goeleti, sp. nov., and Brachyglene albicephala, sp. nov.

i0003-0090-321-1-1-f142.gif

Diagnosis

Although at first glance the two Hadesina species groups seem poorly matched, phylogenetic evidence for placing them in the same genus is compelling. Species in the Limbaria Group exhibit hyaline wings with the ground color, including the wing veins, iridescent blue or purplish black (pl. 14). Their FW is notable in exhibiting a hyaline subapical band. These moths resemble some Dioptis species, especially those in the Chloris Group (pl. 17), but can be separated from them because the antennae are bipectinate in Hadesina, but quadripectinate in Dioptis. The two Divisa Group taxa possess wings with a chocolate-brown ground color and no hyaline areas (pl. 14). Their FW exhibits a light yellow, ovoid fascia, and the HW central area is broadly orange-yellow.

These four species share the following characters making them recognizable as members of Hadesina: the male FW bears a highly developed stridulatory organ (fig. 137F); the DC is extremely short, approximately one-fourth the FW length; veins M1 and M2 are swollen at their bases, protruding from the wing's ventral surface, with a distinct ventral fold between them; and the wing surface in the fascia beyond the DC is corrugated. The antennae in Hadesina are bipectinate in both sexes, the rami being long in males, but short in females. The labial palpi are relatively short, curving strongly upward (fig. 137A, D, E). The male palpi exhibit a wide tuft of long, straight scales on the apex of Lp2 (fig. 137E). The eyes are moderate in size (fig. 137A–D), with the gena broadly scaleless. The male abdomen in Hadesina is unusual in curving upward distally, with A6 and A7 swollen. It is interesting that Hadesina exhibits one of the signature characteristics of the newly described genus Chrysoglossa—presence of a golden-yellow proboscis.

Redescription

Male. FW length  =  12.0–15.5 mm. Head (fig. 137A–E): Labial palpus relatively short, held close to head, curving upward to below middle of front; Lp1 short, curved, with a diffuse fringe of slightly longer scales below; Lp2 short, approximately the same length as Lp1 or slightly shorter; Lp3 either short, ovoid (Limbaria Group), or somewhat elongate (Divisa Group); scales of front long, pointing dorsomedially from immediately above clypeus, longer above, meeting at midline to form short tufts between antennal bases; eye relatively small, not bulging, surrounded by a scaleless area, this area wider in dorsal and ventral area, gena forming a moderately wide scaleless band below; postgena moderately wide; scales of vertex long, loosely arranged, erect; antenna bipectinate, rami long, terminal 6–8 annulations simple.

Thorax: Epiphysis long, over three-fourths as long as tibia, extending beyond (Divisa Group), or falling slightly short of (Limbaria Group) tibia apex; tegula long, over two-thirds as long as mesoscutum, distal portion narrow, apex rounded, ventral angle somewhat blunt, transverse sulcus poorly defined; metathoracic tympanum large, open, depression extremely shallow; tympanal membrane large, round, facing posterolaterally.

Forewing (fig. 137F; pl. 14): Somewhat elongate, apical angle acute, wings strongly triangular in Limbaria Group; vein Rs1 extremely long stalked with Rs2–Rs4; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from anterolateral angle of DC, touching, or separate from, base of radial sector, UDC short or absent; stridulatory organ highly developed; DC extremely short, approximately one-fourth FW length, with an elongate lateroposterior angle; bases of veins M1 and M2 swollen, protruding from wing's ventral surface, with a distinct ventral fold between them; surface in fascia beyond DC corrugated; M3 and CuA1 stalked for almost one-half their lengths; wings hyaline with ground color and veins iridescent blue-black, a hyaline transverse, subapical band (Limbaria Group), or ground color dark brown to dark chocolate brown, an ovoid, light yellow fascia beyond DC and a diffuse, thinly scaled area beyond fascia.

Hind wing (pl. 14): Small and rounded (Limbaria Group), or broad and rounded (Divisa Group); M3 and CuA1 long stalked; UDC greatly displaced toward base, LDC and cubitus forming a long, acute angle.

Abdomen: Elongate, curving upward distally, A6 and A7 swollen.

Terminalia (figs. 138A–D, 139A–D, 140A, 140C–E, 141A–D): Tg8 narrower than Tg7, tapered toward posterior margin, anterior margin simple (Divisa Group), or with two short, broad lateral apodemes (Limbaria Group), posterior margin with a poorly defined, U-shaped mesal excavation; St8 variable in shape, wide (extremely so in H. limbaria), anterior margin with a short, wide mesal apodeme, posterior margin tapered with mesal area often membranous; Limbaria Group with posterior half of St8 less heavily sclerotized than anterior half; socii/uncus complex narrowly (Limbaria Group) or broadly (Divisa Group) attached to tegumen; uncus and socii greatly elongate (Divisa Group), or uncus shorter than socii (Limbaria Group); socii wide at base; tegumen narrow in dorsal section, much wider near junction of valva below, approximately equal in height to vinculum or slightly taller; vinculum wide or moderately so; saccus wide, dorsal margin forming a large triangular sclerite between valva bases; valva long, mostly membranous except for costa; BO large, bearing long, hairlike androconia, occupying basal half or more of valva, expanded below, lateral margin wrapping anteriorly; costa of valva heavily sclerotized, greatly elongate, extending well beyond rest of valva; costa curved distally, expanded at apex to form a bladelike or quadrate, spatulate distal process; lateral area below valva apex and above BO forming a delicate, membranous appendix, often expanded laterally; arms of transtilla narrow, oriented horizontally, meeting at midline to form a narrow, elongate sclerite; aedeagus moderately long and wide, straight, slightly narrower at base; apex of aedeagus with a small ventral point (Limbaria Group), or with a small, rugose, transverse flange (Divisa Group); vesica small, much less than one-half aedeagus length; cornuti spinelike, evenly scattered on posterior surface of vesica, several robust ones distally, shorter ones basally.

Female. FW length  =  13.0–18.0 mm. Head, thorax, and wings similar to male, except: labial palpus without distal tuft; antenna bipectinate, rami short; wings longer and broader, DC short, but longer than in male, approximately one-third FW length; frenulum comprising approximately six bristles.

Abdomen: Similar in length to males, but distal portion not swollen.

Terminalia (figs. 138E, 139E–G, 140B, 141E, 141F): Tg7 wide, either abruptly tapered distally with posterior two-thirds more heavily sclerotized (Limbaria Group), or excavated along lateral margins with a longitudinal ridge (Divisa Group); St7 wide, with a wide transverse groove across middle, anterior margin simple, posterior margin with a shallow (Divisa Group) or deep (Limbaria Group) mesal excavation; surface of St7 in Divisa Group sclerotized, scabrous; Tg8 large, sclerotized and hoodlike with an acute process on posterior margin (Divisa Group), or short and rooflike, posterior margin simple (Limbaria Group); anterior apophyses short and downturned (Divisa Group), or thin and greatly elongate (Limbaria Group); A8 pleuron membranous; PP extremely short nubs (Divisa Group), or thin, moderately long (Limbaria Group); PA large, posterior margins simple; PVP membranous, ostium ovoid, funnel shaped (Limbaria Group), or wide, sclerotized, with plicate lateral margins (Divisa Group); DB sclerotized, moderately wide, expanded into a large appendix in limbaria, with complex folds in goeleti; CB large and membranous, almost round; signum extremely small (e.g., limbaria) or absent (goeleti); DS arising on left side, either at base of DB near ostium (Limbaria Group) or near junction of CB and DB.

Distribution

Hadesina species are distributed from northern Costa Rica south into southwestern Ecuador, at least as far as Cañar Province. Of the species pairs within the two existing species groups, one taxon occurs on the eastern slope of the central mountains while its sister taxon is endemic to the western side. Thus, H. caerulescens from Costa Rica is eastern, while H. limbaria occurs exclusively in western Colombia and Ecuador. Similarly, H. goeleti from Costa Rica is eastern, whereas its sister species, H. divisa, lives in western Colombia.

Three of the taxa—limbaria, caerulescens, and goeleti—are restricted to a relatively narrow band of elevation; recorded altitudes range between 500 to 800 meters. The fourth species, H. divisa, is known from Papayán Colombia, a site situated at roughly 1700 meters. As with most dioptines, distributional information for Hadesina is in a primitive state. All four species are rare; none is known from more than a handful of specimens.

Biology

Nothing is known regarding the host plants or immature stages of Hadesina.

Discussion

The two species groups of Hadesina differ with respect to their wing patterns, as well as to many features of their male and female genitalia. However, the phylogenetic analyses performed in this paper strongly support a sister-group relationship between the Limbaria and Divisa groups (fig. 3); 14 synapomorphies support the monophyly of Hadesina (appendix 4), and the clade H. goeleti + H. caerulescens shows a Bremer support of 5 (fig. 2). I have chosen to reflect those results by placing the two clades together in a single genus.

The overall similarity between Limbaria Group species and some Dioptis is reflected by the fact that Schaus (1913) originally described caerulescens in Hyrmina, established as a subgenus of Dioptis by Walker (1854). The type species of Hyrmina, D. areolata Walker (pl. 19), bears superficial resemblance to H. caerulescens, but the two exhibit no synapomorphies.

Hadesina Warren (1900) was initially assigned to the Cyllopodinae (Geometridae), and later moved to the Dioptidae by Prout (1918). Previous authors considered it to include only two species—limbaria and caerulescens. These hyaline-winged taxa are closely related. My broader concept of the genus adds two species, divisa, previously placed in Brachyglene (Bryk, 1930), as well as goeleti, newly described. I place the original members of Hadesina in the Limbaria Group, whereas the new additions are in the Divisa Group. Characters from adult morphology suggest that Hadesina and Cacolyces are sister groups (fig. 7).

KEY TO HADESINA SPECIES GROUPS

1. Forewing broadly triangular (fig. 137F; pl. 14); wing ground color, including veins, dark gray-brown to blackish brown, with purple iridescence, rich iridescent blue along posterior margin of FW and in outer margin of HW; FW hyaline in basal two-thirds, with a hyaline, transverse, subapical band; HW central area broadly hyalineLimbaria Group

FW somewhat elongate (pl. 14); ground color dark brown to chocolate brown; FW with an ovoid yellow fascia beyond DC, as well as a diffuse, thinly scaled fascia beyond that, veins lined with light brown; HW dark brown to blackish brown along outer margin, with a broad, orange-yellow central areaDivisa Group

1. LIMBARIA GROUP

The Limbaria Group is distributed from Costa Rica south to northwestern Panama, and along the Pacific slope of the Colombian and Ecuadorian Andes. The species generally appear to be endemic to dry forest habitats, although H. caerulescens has been collected at Braulio Carrillo National Park in Costa Rica, a fairly wet site. Much more remains to be learned about the biology, distribution, and systematics of this group.

KEY TO LIMBARIA GROUP SPECIES

1. Wing ground color blackish brown to black (pl. 14); basal region of FW, posterior to DC and anterior to anal fold, densely scaled with blue black; FW anal margin iridescent turquoise blue; FW vein 1A+2A with a long, contrasting white streak from base; FW length  =  14.0–18.0 mm (Costa Rica S to NW Panama)caerulescens (Schaus)

Wing ground color dark gray-brown (pl. 14); basal region of FW, posterior to DC and anterior to anal fold, hyaline; FW anal margin dark, iridescent purplish gray-brown; FW vein 1A+2A with an inconspicuous, short white streak from base; FW length  =  15.0–15.5 mm (SW Colombia S to SW Ecuador)limbaria Warren

SPECIES INCLUDED AND MATERIAL EXAMINED

Hadesina caerulescens (Schaus)

Figures 137F, 138E, 139A–D; plate 14 [EX]

Hyrmina caerulescens Schaus, 1913: 382.

Type Locality

Costa Rica, Carrillo.

Type

Syntype ♂ (USNM type no. 18038).

Discussion

Hadesina caerulescens shows a more brilliant iridescence in the wings than its sister species, H. limbaria (pl. 14). The two are easily separable by characters given in the key (above), as well as by features of male and female genitalia (figs. 138, 139). For example, male Tg8 is narrow in H. caerulescens (fig. 139D) but wide in H. limbaria (fig. 138D). In an even more dramatic diagnostic difference, the uncus is digitate in H. limbaria (fig. 138A) but bifid in H. caerulescens (fig. 139A).

Hadesina caerulescens, either rare or absent in most collections, is relatively well represented at INBio (5♂♂, 2♀♀). The USNM holdings contain three specimens—a male syntype from Carrillo Costa Rica, a female syntype from Chiriquí Panama, and a female from Costa Rica. All were dissected. The syntype female is notable in being the only record of H. caerulescens for Panama.

Predictably, material from the Pacific side of the Cordillera Central appears to represent a species distinct from that on the Caribbean slope. For example, the DB of a female from Limón in the east (JSM-1334), differs in shape from that of the Chiriquí female (fig. 138E). This then leads to the conclusion that Schaus' male and female caerulescens syntypes represent two different species. Males from Chiriquí (Pacific slope) will ultimately need to be captured and dissected for comparison with the Carrillo male type (Caribbean slope), in order to confirm this suspicion. If two taxa are revealed, a lectotype should be designated to stabilize the name.

Distribution

Costa Rica (BMNH, INBio, USNM, ZMH); Panama (USNM).

Dissected

Syntype ♂, (genitalia slide no. JSM-1050); ♂, Costa Rica, San José Prov., Estación Carrillo, P. N. Braulio Carrillo, 700 m, May 1985, leg. I. & A. Chacón, INBio (genitalia slide no. JSM-799, wing slide no. JSM-1470); ♂, Costa Rica, Alajeula Province, R. B. San Ramón, 800 m, Mar 1997, leg. G. Carbalio, INBio (JSM-1333); ♀, Costa Rica, Carrillo, Jun–Jul 1903, leg. Underwood, BMNH (genitalia slide no. JSM-800); ♀, Costa Rica, Limón Province, P. N. Barbilla, Camino a Valle Escondido, Sector Río Dantas, 400–500 m, Jan 2002, leg. L. Chavarría, INBio (genitalia slide no. JSM-1334); Syntype ♀, Panama, Chiriquí, May 1907, Wm. Schaus Collection, USNM (genitalia slide no. JSM-412).

Hadesina limbaria Warren

Figures 137A–C, 138A–D, 139E–G; plate 14

Hadesina limbaria Warren, 1900: 127.

Type Locality

Ecuador, Chimbo, 1000 ft.

Type

Syntype ♀, leg. Rosenberg, Aug 1897 (BMNH).

Discussion

Hadesina limbaria, endemic to the Chocó region of northwestern South America, is even rarer than its Central American sister species, H. caerulescens (pl. 14). Hadesina limbaria is known from only seven specimens worldwide—four from southwestern Ecuador, and three from Cauca, Colombia. Ecuadorian material consists of two female BMNH syntypes and two recently collected AMNH specimens (♂, JSM-1468; ♀, JSM-1469). The type locality, Chimbo, is an historically famous collecting site for Lepidoptera, located near the town of Bucay in Guayaquil Province.

The two Limbaria Group species differ in that H. limbaria shows less iridescent blue in the wings than H. caerulescens. Their male genitalia exhibit numerous synapomorphies, but differ markedly in the configuration of the socii/uncus complex (compare figs. 138A, 139A). Female genitalia in the two taxa are radically different, especially regarding the configuration of the DB (figs. 138E, 139F).

Distribution

Ecuador (AMNH, BMNH); Colombia (BMNH).

Dissected

♂, Ecuador, Cañar, El Chorro, 20 km from la Troncal, S02°28.6′ W79°16.3, 475 m, 9 Mar 2003, leg. S. Rab Green & M. Tapia, at light UV/MV, western tropical dry forest, undisturbed (genitalia slide no. JSM-1468); ♂, Colombia, Cauca, N.elle Grenade, Juntas, fin 1897 to Jan 1898, leg. M. de Mathan, BMNH (genitalia slide no. JSM-411); ♀, Ecuador, Cañar, El Chorro, 20 km from la Troncal, S02°28.6′ W79°16.3, 475 m, 9 Mar 2003, leg. S. Rab Green & M. Tapia, at light UV/MV, western tropical dry forest, undisturbed (genitalia slide no. JSM-1469).

2. DIVISA GROUP

The Divisa Group is as obscure as the Limbaria Group. Specimens are known from only two collections—INBio and the USNM. The bulk of this material was collected at either Popayán, Colombia (H. divisa), or Estación Pitilla (H. goeleti) in the Area de Conservación Guanacaste, Costa Rica.

KEY TO DIVISA GROUP SPECIES

1. Forewing ground color light brown to chocolate brown (pl. 14); front completely light yellow; costa of male valva curving gently upward (fig. 140A); female genitalia with DB broad, laterally compressed (fig. 140B); FW length  =  12.0–13.0 mm (SW Colombia)divisa (Dognin)

FW ground color chocolate brown to dark chocolate brown (pl. 14); front orange-yellow, bordered dorsally with dark brown scales; costa of valva curling strongly upward (fig. 141A); female genitalia with DB narrow, intricately folded (fig. 141F); FW length  =  14.0–16.0 mm (NW Costa Rica)goeleti, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Hadesina divisa (Dognin), new combination

Figure 140; plate 14

Brachyglene divisa Dognin, 1902: 474.

Type Locality

Colombia, Popayán.

Type

Syntype ♂ (USNM type no. 30941).

Discussion

This species was described in Brachyglene (Dognin, 1902), and has remained there ever since (Bryk, 1930). Here it is placed in Hadesina as a new combination. Hadesina divisa (pl. 14) is known exclusively from eight USNM specimens (three ♂♂, five ♀♀), all collected at Popayán Colombia in 1897 (collector unknown). This city is in the state of Cauca, in southern Colombia on the western slope of the Andes at approximately 1700 meters. Assuming the USNM specimens were actually collected at or near Popayán, H. divisa occurs at a higher altitude than other Hadesina species, which occur at elevations between 500 and 800 meters.

A male specimen labeled as the type of divisa (USNM type no. 30941) has had its abdomen re-attached with glue. Such instances raise a question as to whether the abdomen originated from that type, or came from a different specimen altogether. Based on comparison of genital configuration in the purported type (fig. 140A, C–E; JSM-1217) with the genitalia of a second male in the series (JSM-1682), I can say with confidence that the abdomen of this H. divisa type has been properly associated.

Distribution

Colombia (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1217); ♂, Colombia, Popayán, 1897, Dognin Collection, USNM (genitalia slide no. JSM-1682); ♀, Colombia, Popayán, 1897, Dognin Collection, USNM (wing slide no. JSM-1216, genitalia slide no. JSM-784).

Hadesina goeleti, new species

Figures 137D, 137E, 141, 142; plate 14; cover [EX]

Diagnosis

Hadesina goeleti and its sister species, H. divisa (pl. 14), are similar in general appearance. Both exhibit dark brown forewings with a light yellow fascia of variable size beyond the discal cell, as well as hind wings with a rich, orange-yellow central area, bordered broadly with dark brown. The two moths differ in that H. goeleti has darker, more contrasting wings, and the yellow FW fascia of goeleti is typically larger and better defined. Although the number of specimens for comparison is small, H. goeleti is also slightly larger than H. divisa. In both species, the labial palpi are moderately long, curving upward against the front, and the male FW discal cell is short, approximately one-third the FW length. Male antennae exhibit long pectinations, while those of females are short and stubby.

The most reliable way to separate H. divisa and H. goeleti involves differences in their genitalia (figs. 140, 141). Males exhibit dramatic differences in the shape of the valva apices, as well as the configuration of the distal portion of the aedeagus. In females, an obvious difference is that the CB is round, lacking a signum in H. goeleti (fig. 141F), whereas the CB is ovoid in divisa (fig. 140B), and a figure-eight–shaped signum is faintly visible on the right side. Additional, more subtle, genital differences abound.

Description

Male. Forewing length  =  14.0–15.5 mm. Head (fig. 137D, E): Labial palpus moderately long, wide, upturned, reaching halfway up front; Lp1 yellow-orange; Lp2 yellow, except dark brown on ventral surface in distal half; Lp3 with long, dark brown scales forming an apical point; front clothed with long, upwardly pointing yellow-orange scales, except long, dark brown scales below antennal bases; occiput yellow-orange in lower three-fourths, brown in dorsal one-fourth; vertex covered with long, loosely packed, dark brown scales; antenna widely bipectinate; antennal scape with cream to yellow scales below, dorsum of scape and dorsal surfaces of antennae covered with dark brown scales.

Thorax: Coxa of prothoracic leg bright yellow-orange, femur and tibia brown on lateral surface, creamy white on mesal surfaces; meso- and metathoracic legs brown on lateral surfaces, creamy white on mesal surfaces; spurs creamy white; patagium dark brown, with a fringe of yellow-orange scales along posterior margin; tegula yellow-orange, fringed laterally and distally with long, dark brown scales; dorsum completely dark brown; tympanum shallow, dorsal portion of metepimeron scaleless; tympanal membrane moderately large, round, facing posterolaterally.

Forewing: (Dorsal) Dark chocolate brown (pl. 14); a round, yellow fascia beyond discal cell, located between radial sector and base of M3+CuA1; transverse area beyond yellow fascia blackish brown; a second diffuse, light brown fascia in apical third, located between M1 and M3; veins, especially in apical third, slightly lighter brown; entire anal margin blackish brown. (Ventral) Ground color dark chocolate brown; area of discal cell from base with a mixture of brown and yellow scales; a yellow-orange fascia immediately beyond DC; a smaller, ovoid yellow fascia, corresponding with light brown dorsal one, in apical third, located between base of Rs2–Rs4 and M3.

Hind wing: (Dorsal) Dark chocolate brown, with a yellow-orange central area (pl. 14); anal margin lighter brown, yellow from ventral surface showing through slightly above; a short streak of brown scales in yellow area from base to halfway out DC. (Ventral) Dark chocolate brown; with two yellow-orange areas from base, one corresponding to central area on dorsal surface, the second, a broad band along anal margin; yellow regions almost touching at base; ground color between yellow areas forming a long, brown streak anterior to anal fold, streak wider near margin, tapered toward base.

Abdomen: Dorsum dark chocolate brown; venter creamy white; pleuron yellow near base.

Terminalia (fig. 141A–D): Tg8 widest in basal third, gradually narrowing posteriorly; posterior margin of Tg8 with a V-shaped mesal excavation, distal membrane with longitudinal wrinkles; anterior margin of Tg8 simple; St8 slightly wider than Tg8, widest at anterior margin, gradually narrowing distally; posterior margin of St8 with a wide, U-shaped mesal excavation; anterior margin of St8 with a single, blunt apodeme at midline; uncus extremely long, widest at base, gradually narrowing distally, apex blunt; socii extremely long and robust, curved upward, with small crest-shaped processes at two-thirds, and bladelike flanges below apex; tegumen relatively thin, wider below; vinculum deeply concave; saccus quadrate, folded upward to valva bases; valva with BO well developed, curled anteriorly; costa of valva heavily sclerotized, robust at base, narrowing distally; distal third of valva sclerotized, greatly elongate, curving dorsomesally; a large, bladelike process on inner surface below valva apex, outer margin of process finely serrate; apex itself narrow, dorsoventrally compressed, curving slightly inward; transtillar arms narrow, straplike, produced anteriorly at midline; aedeagus moderately wide, slightly constricted near base; apex of aedeagus with a small, crenulate area on right side, and several irregular denticles on left side; vesica relatively small, covered on posterior surface with short to medium length, spinelike cornuti.

Female. Forewing length  =  15.5–16.0 mm. Head: Coloring similar to male; labial palpus slightly shorter than in male; antenna with short, stubby rami.

Thorax: Similar to male.

Forewing: (Dorsal) Pattern similar to male, but ground color lighter brown, especially near base and in apical third; dark transverse area more contrasting than in male, veins in brown areas lighter. (Ventral) Pattern similar to male, but ground color lighter brown.

Hind wing: (Dorsal) Similar to male. (Ventral) Similar to male, except yellow anal margin not as bright, in some specimens almost brown.

Abdomen: Markedly different from male, dorsum of each segment (A1–A7) with a pair of large, roundish yellow spots on either side of midline.

Terminalia (fig. 141E, F): Tg7 wide, lateral margins with wrinkled areas above each spiracle, anterior and posterior margins simple, a smooth, raised ridge along midline from distal margin; St8 sharply crenulate along posterior margin and at lateral angles; a wide, transverse groove near distal margin; anterior margin of St8 simple, posterior margin with a broad, shallow mesal indentation; Tg8 broadly sclerotized, forming a robust rooflike structure above papillae anales, posterior margin of Tg8 strongly emarginate, with a long apical point at midline; AA short, pointing downward; ostium shallow, flanged laterally; DB short, narrow, sclerotized, irregular, in shape; DS arising at junction of DB and CB; CB round, signum absent; membrane surrounding PA wrinkled, folded anteriorly; outer margin of PA smoothly rounded; PP extremely short, pointing downward.

Etymology

This species is named in honor of Robert G. Goelet, chairman emeritus and current trustee of the American Museum of Natural History, who provided me with two years of funding at the AMNH (2006–2007). Thanks to his support, the fieldwork, writing, and illustrations for this publication were completed, allowing the project to become a reality. Over the past 30 years, Goelet's generosity and enthusiasm have advanced entomological research at the AMNH immeasurably.

Distribution

So far, H. goeleti is known exclusively from a small area of northwestern Costa Rica, near the Nicaraguan border (fig. 142). The two confirmed localities are situated close together on the eastern slope of Volcán Orosí (pl. 47A). Dan Janzen (personal commun.) characterizes that volcano as the northernmost extent of the Andes. Hadesina divisa is from southwestern Colombia. As far as I am aware, neither species has been collected in Panama. The range of recorded altitudes for H. goeleti is extremely narrow, between 700 and 750 meters.

Discussion

Except for a single USNM specimen, all material of Hadesina goeleti has been collected within the past 20 years. Thanks to the remarkable inventory work of the INBio staff, as well as the ongoing Lepidoptera survey of Dan Janzen and his colleagues, this incredibly rare species is now known from seven specimens. Five of those were captured at Estación Pitilla (pls. 47B, 48A, 48D) in the Area de Conservación Guanacaste. Dan Janzen and Winnie Hallwachs collected the sixth nearby at Dos Ríos (March 1985). It is hoped that the ACG caterpillar collectors will discover the immature stages and host plant of Hadesina goeleti.

The USNM example of H. goeleti, originally in the William Schaus Collection, bears scant data other than purportedly being from Cachi, Costa Rica. On modern maps, Cachi (09°49′49″N, 83°47′59″W; 1000 m elevation) is located far south of the ACG sites, in the state of Cartago near the town of Juan Viñas. Until modern material is found which verifies this record, I consider it specious.

Holotype

Male. Costa Rica: Guanacaste: P. N. Guanacaste, Est. Pitilla, 9 km S Sta. Cecilia, 700 m, 19–23 Jun 1993, leg. C. Moraga, L N 330200_380200, INBio # 2897 (genitalia slide no. JSM-781). The type is deposited at INBio, Heredia, Costa Rica.

Paratypes

Costa Rica: Guanacaste: 1♂, P. N. Guanacaste, Est. Pitilla, 9 km S Sta. Cecilia, 700 m, May 1992, L_N_330200, 380200, leg. P. Ríos (INBio); 1♀, 22 Jan 1994, leg. C. Moraga, INBio # 2563 (genitalia slide no. JSM-782); 1♀, 22 Ago 1993, leg. C. Moraga, INBio #2322 (genitalia slide no. JSM-1311); 1♂, Jul 1988, leg. M. Scoble & S. Brooks (INBio). Alajuela: 1♂, Fca Campana, 5 km NW Dos Ríos, 750 m, 21 Mar 1985, leg. D.H. Janzen & W. Hallwachs (INBio).

Other Specimens Examined

Costa Rica: Cartago: 1♂, Cachi, Oct, Wm. Schaus Collection, USNM (genitalia slide no. JSM-783, wing slide no. JSM-1438).

Dissected

2♂♂, 2♀♀.

BRACHYGLENE HERRICH-SCHÄFFER, 1855

Figures 142Figure 143Figure 144Figure 145Figure 146Figure 147Figure 148149; plates 14, 15

Brachyglene Herrich-Schäffer, 1855: 99, 100. Type species: Phaeochlaena bracteola Geyer, 1832 (in Hübner, 1832) 4: 17, pl. 113, figs. 655, 656.

Figure 143

Brachyglene heads (♂♂). A, B. albicephala, sp. nov., lateral view; B, B. subtilis, lateral view; C, B. bracteola, lateral view; D, B. schausi, lateral view; E, B. subtilis, frontal view; F, B. subtilis, posterior view; G, labial palpus of B. caenea, lateral view (illustration by J.S. Miller).

i0003-0090-321-1-1-f143.gif

Figure 144

Scanning electron micrographs of Brachyglene albicephala, sp. nov. (♂). A, antenna in ventral view; B, a single flagellomere in ventral view; C, FW stridulatory organ (ventral surface); D, scales in FW fascia (ventral surface).

i0003-0090-321-1-1-f144.gif

Figure 145

Appendages of Brachyglene (♂♂). A, B. subtilis metathoracic leg; B, B. subtilis mesothoracic leg; C, B. subtilis foreleg; D, B. bracteola tegula; E, B. schausi tegula; F, B. subtilis wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f145.gif

Figure 146

Genitalia of Brachyglene albicephala, sp. nov. (♂ JSM-1318, ♀ JSM-1319). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♀ genitalia; E, ♂ St8.

i0003-0090-321-1-1-f146.gif

Figure 147

Genitalia of Brachyglene bracteola (♂ JSM-787, ♀ JSM-1213). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f147.gif

Figure 148

Genitalia of Brachyglene schausi (♂ JSM-905, ♀ JSM-906) and B. fracta, sp. nov. (Holotype ♀, JSM-1538). A, B. schausi ♂ genitalia; B, B. schausi ♂ Tg8; C, B. schausi ♂ St8; D, B. schausi aedeagus; E, B. schausi ♀ genitalia, F, B. fracta ♀ genitalia; G, B. fracta ♀ Tg7; H, B. fracta ♀ St7.

i0003-0090-321-1-1-f148.gif

Figure 149

Genitalia of Brachyglene subtilis (♂ JSM-418, ♀ JSM-419). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f149.gif

Diagnosis

Species in Brachyglene have a light brown to dark brown or blackish-brown FW, with a yellow to orange-yellow spot or oblique transverse band beyond the DC (pls. 14, 15). The HW is also brown, usually with the anterior portion, or the entire central area, being orange-yellow. Study of taxa where relatively large series are available, such as Venezuelan examples of B. bracteola, demonstrates extensive intraspecific wing-pattern variation.

In all Brachyglene species, the male FW stridulatory organ is well developed, comprising a short DC—less than one-half the FW length, sometimes much less than one-half—and swollen bases of M1 and M2 (figs. 144C, 145F). In both sexes, veins M3 and CuA1 are stalked in both the FW and HW. The antennae are bipectinate, the pectinations long in males (fig. 144A), but much shorter in females. The labial palpi are short (figs. 143A–D, 143G), barely curving upward above the clypeus; Lp2 is shorter than Lp1. The palpi of Brachyglene males are usually acutely scaled at their apices (fig. 143A). The metathoracic tympanum is fairly large and open, with the membrane, which faces posterolaterally, sitting in a shallow, scaleless depression. Brachyglene species are also notable in that the foreleg epiphysis is long, extending beyond the apex of the tibia (fig. 145C).

Redescription

Male. FW length  =  11.0–17.0 mm. Head (figs. 143, 144A, 144B): Labial palpus short, barely curving upward, apex reaching to immediately above clypeus; Lp1 moderately long, curved, with a loose fringe of scales below; Lp2 shorter and sometimes wider than Lp1, more tightly scaled, scales on ventral margin longer, forming a ridge; distal scales on mesal surface of Lp2 forming a diffuse apical tuft; Lp3 short, quadrate; clypeus extremely narrow; scales of front long, semierect, pointing dorsomesally, forming a loose dorsal tuft between antennal bases; eye variable in size, from large to fairly small; postgena narrow (e.g., B. schausi) to moderately wide (e.g., B. bracteola, B. subtilis); scales of vertex long, loosely arranged, pointing anteriorly; antenna bipectinate, rami long, terminal 10–15 annulations simple.

Thorax (fig. 145A–E): Epiphysis long and narrow, over three-fourths the length of tibia, extending beyond apex of tibia; tegula slightly longer than one-half length of mesoscutum, distal portion rounded, apex of ventral angle somewhat blunt, dorsal and ventral portions divided by a weak sulcus; metathoracic tympanum moderately large, open, area of depression shallow, scaleless; tympanal membrane fairly large, ovoid, facing posterolaterally.

Forewing (fig. 144C, 144D, 145F; pls. 14, 15): Elongate, apical angle acute; vein Rs1 arising from radial sector below Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC near base of Rs1–Rs4, UDC short; stridulatory organ well developed, area beyond DC, surrounding bases of M1 and M2, sparsely scaled, semihyaline; DC short, from one-half to one-third FW length, bases of M1 and M2 swollen with a ventral fold between them; veins M3 and CuA1 long stalked; ground color light brown to blackish brown, veins lighter (especially near base), a yellow to orange-yellow spot or oblique transverse band beyond DC; ventral surface of wing in bracteola and fracta with additional light yellow maculations, including a basal streak and an oval between Rs4 and M3.

Hind wing (fig. 145F; pls. 14, 15): Rounded to slightly elongate; M3 and CuA1 long stalked; ground color dark brown to blackish brown, frequently with a transverse or teardrop-shaped orange maculation along anterior margin (e.g., B. bracteola, B. caenea), or with central area broadly light yellow (Subtilis Group).

Abdomen: Relatively short, apex acute; dorsum light brown to dark chocolate brown; pleuron frequently with a yellow or whitish longitudinal stripe; venter white to cream-colored.

Terminalia (figs. 146A–C, 146E, 147A–D, 148A–D, 149A–D): Tg8 much longer and narrower than Tg7, anterior margin with a pair of extremely short, blunt apodemes; lateral margins of Tg8 gently concave in anterior one-half to two-thirds, then abruptly narrowed, distal portion sclerotized, forming a wide central process, its posterior margin slightly convex, rarely transverse (B. caenea); St8 shorter and wider than Tg8, tapered posteriorly, lateral margins forming expanded angles approximately at halfway point; anterior margin of St8 gently convex, with a wide, short, quadrate or rarely acute (B. crocearia, B. subtilis) mesal apodeme, posterior margin narrow, with a V-shaped mesal excavation of varying width and depth; socii/uncus complex small, narrowly attached to tegumen; uncus short, curving downward slightly, apex acute, sometimes moderately long; socii short, not extending beyond apex of uncus, curving upward, or socii moderately long and narrow, extending slightly beyond apex of uncus; tegumen moderately wide, much taller than vinculum, expanded ventrally above junction of valva; vinculum short, narrow; saccus moderately large, wide below, upper margin of saccus forming a large triangle between valva bases; ventral margin of genitalia transverse or slightly convex; valva fairly short, to moderately long, usually upright in orientation; BO large, usually occupying at least one-half of valva, lateral margin curled anteriorly, ventral margin greatly expanded; costa of valva sclerotized, upper margin simple, extremely wide and curving sharply upward (Caenea Group), or moderately wide and curving gently upward (Subtilis Group); apex of valva expanded, either rounded (Subtilis Group) or forming a blunt, dorsomedially directed process (Caenea Group); arms of transtilla narrow, straplike, curving downward to form a U-shaped structure, arms thin, acute, thinly joined at midline; aedeagus straight, rarely sinuate (B. caenea), either moderately long and narrow (Caenea Group) or short and wide (Subtilis Group); apex of aedeagus with a single long ventral point (Caenea Group) or with a pair of small ventral points (Subtilis Group); vesica arising dorsally, either small (Caenea Group) or moderately large, bulbous; vesica bearing long, robust spinelike cornuti and no deciduous cornuti (Subtilis Group), or bearing short, bifid or trifurcate cornuti near base and deciduous caltrop cornuti distally (Caenea Group).

Female. FW length  =  13.0–19.0 mm. Head, thorax, and abdomen similar to male, except: labial palpus slightly shorter, thinner; antenna bipectinate, rami short; wings longer and broader, coloration often slightly lighter; orange-yellow maculations of FW larger, often with additional basal and distal markings, especially on ventral surface of wing; frenulum comprising 10–15 bristles.

Abdomen: Much wider than male, area of St7 surrounding ostium often scaleless.

Terminalia (figs. 146D, 147E, 148E–H, 149E): Tg7 large, slightly tapered posteriorly, anterior margin simple, posterior margin broadly convex, sometimes with posterior third and region along midline less melanized; St7 wide, anterior margin simple, lateral margins slightly concave, posterior margin with a deep, wide U-shaped mesal excavation; Tg8 lightly sclerotized, rooflike, varying from long (e.g., B. subtilis) to short (e.g., B. bracteola), often with a shallow depression along midline (e.g., B. albicephala); AA moderately long, thin, rarely short (B. subtilis); A8 pleuron membranous; PP short; PA membranous, moderate in size, posterior margin slightly angulate; PVP extremely wide, wrapping upward to touch anterolateral margin of Tg8 near AA, region above ostium often with a raised section and several striae; ostium sclerotized, funnel shaped; DB extremely short, membranous; CB moderately large, round, sometimes ovoid, either entirely membranous (Caenea Group), or with a large sclerite dorsally near base (B. subtilis); signum moderately large, rarely extremely small (B. subtilis), located anteroventrally, figure-eight shaped, internal surface coarsely dentate; DS arising dorsally at base of CB from a small, laterally compressed appendix.

Distribution

Brachyglene species occur from southern Mexico to southern Brazil. The group is poorly represented in the Andean countries, but instead inhabits the dry coastal forests of Central America, northern South America, and eastern Brazil. Except for B. bracteola, which is frequently collected in Venezuela, Brachyglene species are relatively uncommon. Much remains to be learned about the geographical distribution of this genus.

Biology

Until recently, known host records for Brachyglene came from label data on two adult specimens of B. subtilis at the USNM. These, from El Valle, Venezuela, bear labels stating that they were found as larvae, feeding on Bauhinia splendens (Fabaceae). One moth was reared in July 1938, and the other in September 1938 (leg. A. Escalona). Members of Bauhinia, all lianas, are distinctive; the leaves are incompletely split in half, and the stems are conspicuously flattened—thus their common name, “monkey's ladder”. The genus is relatively large, containing 150 species in the Neotropics, with an additional 200 species in the Old World (Gentry, 1993). These vines are commonly seen growing on tree trunks along trails in seasonal tropical forests. On two separate occasions (1989, 1992), I spent considerable time searching leaves of Bauhinia at Rancho Grande, Venezuela, but no larvae of B. subtilis were found.

It was not until December 2006 that the life history of a second Brachyglene species was discovered. The team at ACG in Guanacaste, Costa Rica, reported larvae of B. albicephala, sp. nov., on Bauhinia guianensis. This modern record thus substantiates the earlier finding from Venezuela (table 4), made over 70 years ago.

Discussion

Compared with most genera in the Dioptinae, the membership of Brachyglene has remained relatively stable from its inception until the present. When Prout (1918) first attempted to organize the genus, he included nine species in Brachyglene. Bryk (1930) listed 11 species. Of those, seven are retained in the current classification. Three taxa, placed in Brachyglene by previous authors, are here removed: peba Druce is moved to its own new genus, Sagitalla; divisa Dognin belongs in Hadesina; and thirmida Hering is placed incertae sedis.

Genital morphology among Brachyglene species is remarkably uniform. Males show subtle interspecific differences in the shape of the socii/uncus complex, the valva apex and the aedeagus; Tg8 and St8 can also be useful for separation. Females show variation in the shape of Tg8, the ostium and the PVP. As with males, differences between species are relatively slight.

Watson et al. (1980) determined the precise publication date for Brachyglene as 1855. Brachyglene was established in the “Lithosina”, now Arctiidae. It was placed in the Cyllopodinae (now Geometridae, subfamily Sterrhinae) by Kirby (1892: 407). Prout (1918: 418) finally placed it in the Dioptidae.

KEY TO BRACHYGLENE SPECIES GROUPS

1. Forewing ground color dark chocolate brown to blackish brown (pls. 14, 15); HW with anterior margin orange-yellow, or with a teardrop-shaped, orange-yellow maculation near apex; aedeagus long and narrow (e.g., fig. 146B), apex with a single ventral process; female CB entirely membranous, or with a lightly sclerotized dorsal area at base (e.g., fig. 146D); FW length  =  13.0–19.0 mmCaenea Group

2. FW ground color olive brown (pl. 15); HW with central area yellow, and an even, dark brown band around outer margin; aedeagus short and wide (fig. 149C), apex with two small ventral processes; CB with a large, sclerotized dorsal plate at base (fig. 149E); FW length  =  11.0–14.0 mmSubtilis Group

1. CAENEA GROUP

The Caenea Group contains moths of moderate size. The FW is dark brown with a yellow-orange transverse band or ovoid fascia. In the male genitalia, the uncus and socii are short, the aedeagus is narrow, and the vesica is relatively small. In females, the CB is entirely membranous, or occasionally bears a broad, lightly sclerotized area at its base.

KEY TO CAENEA GROUP SPECIES

1. Forewing dorsal surface with a transverse, orange-yellow band immediately beyond DC (pl. 15), extending from subcosta to anal margin; FW ventral surface without a submarginal spot between Rs4 and M33

FW dorsal surface with an ovoid, orange-yellow fascia (males; pl. 15) or with a wedge-shaped, orange-yellow maculation (females; pls. 14, 15) immediately beyond DC; FW ventral surface with a large, diffuse, orange-yellow, submarginal spot located between Rs4 and M32

2. Hind wing dorsal surface with an orange, comma-shaped spot at apex (pl. 14); FW ventral surface without a basal dash (Venezuela)fracta, sp. nov.

Anterior margin of HW orange (pl. 15), this band sometimes extremely wide, extending posteriorly beyond DC; FW ventral surface with a narrow basal dash along posterior margin of DC (Venezuela and Colombia S to Brazil)bracteola (Geyer)

3. Head, including labial palpus and occiput, brown; orange-yellow transverse FW band wide (pl. 15); orange-yellow band along anterior margin of HW elongate, extending from apex halfway to base (Brazil)scaenea (Drury)

Head brown with yellow or white markings on front, labial palpus and occiput; orange-yellow FW band relatively narrow (pl. 15); HW with a short, comma-shaped, orange-yellow spot at apex4

4. Front, Lp1, and occiput yellow-orange (NW Colombia N to S Mexico)schausi Prout

Lateral portions of front, Lp1, and occiput white to whitish brown (Costa Rica)albicephala, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Brachyglene albicephala, new species

Figures 142, 143A, 144, 146; plate 15

Diagnosis

Three species of Brachyglene—caenea, schausi, and albicephala—exhibit a similar wing pattern (pl. 15). In these, the FW is dark blackish-brown with a yellow to yellow-orange transverse band, and the HW is dark brown to blackish brown with a teardrop- or comma-shaped, yellow-orange spot near the apex. My taxonomic interpretation suggests that B. caenea is strictly South American. The other two—schausi and albicephala, mostly Central American—can easily be distinguished from one another by the color of the head and prothorax. In B. schausi, Lp1, as well as the front, occiput and propleuron, are bright lemon-yellow to orange-yellow. In B. albicephala, on the other hand, these areas are white and gray or gray-brown, head characteristics unique for Brachyglene. Other features of B. albicephala occur throughout the genus: male antenna widely bipectinate (fig. 144A, B); labial palpus short and wide, curving upward over the clypeus (fig. 143A); FW discal cell short, approximately one-third the wing length.

Description

Male. Forewing length  =  13.0–16.0 mm. Head (figs. 143A, 144A, 144B): Labial palpus relatively short, wide, reaching upward to less than one-half height of front; Lp1 white with a few gray-brown scales on dorsal surface; Lp2 white on dorsal and ventral surfaces, gray-brown on mesal and lateral surfaces; Lp3 dark brown at base, gray-brown to apex; front with long, upwardly pointing scales reaching beyond antennal bases; frontal scales dusty gray, darker above, with two white patches on either side of midline; occiput dark brown immediately behind eye, white behind that; eye moderately large, surrounded on all sides by a narrow scaleless band; vertex dark brown; antenna widely bipectinate; antennal scape dark brown above, whitish brown below; antennal shaft dark blackish brown above.

Thorax: Coxa and femur white on ventral and lateral surfaces, dark gray-brown above; tibia and tarsus mostly gray-brown, cream colored ventrally; spurs white to cream colored; pleuron white and dark gray-brown; patagium dark brown; tegula completely blackish brown, scales with a bluish luster; scales on dorsum uniformly blackish brown with a bluish luster, no contrasting markings; tympanal membrane relatively small, facing posteroventrally.

Forewing: (Dorsal) Ground color evenly blackish brown (pl. 14); a yellow-orange transverse band of varying width, extending from inside costa to immediately short of tornus; inner margin of transverse band located immediately beyond DC, outer margin slightly irregular; band narrowing gradually toward wing's anal margin. (Ventral) Similar to dorsal surface, a slightly lighter shade of blackish brown; yellow-orange transverse band somewhat wider than on dorsal surface; area of transverse band in FW fold of stridulatory organ, between M1 and M2, whitish yellow.

Hind wing: (Dorsal) Blackish brown (pl. 14), a slightly lighter shade than FW; area of anal margin somewhat lighter than wing central area; anterior margin with a yellow-orange spot extending from halfway out, to immediately short of apex; spot widest distally, tapered toward base; inner half of anterior margin gray-black to brownish black. (Ventral) Similar to dorsal surface, except a long, silvery gray dash from base along Sc+R; anal margin broadly dark, charcoal gray; yellow-orange spot near apex wider than on dorsal surface.

Abdomen: Gradually tapered toward apex; dorsum dark brown to blackish brown, with a steel-blue luster; a diffuse, whitish gray longitudinal stripe along pleuron; venter white.

Terminalia (fig. 146A–C, E): Tg8 sclerotized, longer than St8, widest at anterior margin, sides slightly concave; Tg8 wide in basal two-thirds, then abruptly narrowed in distal one-third to form a large, robust central process, distal margin of process rounded; St8 wide at anterolateral angles, then narrowed distally, posterior margin with a short mesal groove, anterior margin with a short quadrate mesal process; socii/uncus complex small, uncus dorsally curved, apex narrow; socii short, barely upturned; tegumen wide, sides roughly parallel for entire length; vinculum short, narrow; saccus broad, upturned to form a triangular sclerite, barely touching valva bases; valva mostly membranous, BO large, curled anteriorly, pleats and androconia long; costa of valva extremely wide and broad, inner surface membranous; valva apex a blunt, inwardly curved process; aedeagus long, relatively thin, slightly curved downward near middle; apex of aedeagus forming a thin, straight point below; vesica short, bearing deciduous cornuti and short, bifurcate cornuti.

Female. Forewing length  =  16.5–18.0 mm. Head: Labial palpus mostly gray-brown with a few white scales above and below; front dark gray-brown, with short, upwardly pointing scales; antenna with short, stubby rami; antennal scape entirely dark gray-brown; other features of head similar to male.

Thorax: Similar to male, but generally darker.

Forewing: Somewhat more elongate than in male; pattern similar to male above and below, but ground color slightly lighter and transverse band wider, frequently light yellow rather than orange-yellow.

Hind wing: Pattern similar to male, ground color slightly lighter; spot near apex darker in tone than FW band, orange-yellow rather than light yellow.

Abdomen: Wider and shorter than male, less tapered at apex; coloration similar to male.

Terminalia (fig. 146D): Tg7 large, broad, slightly tapered distally; St7 extremely wide, posterior margin with a deeply rounded mesal excavation; Tg8 narrow, bilobed distally, rooflike; PVP expanded above, with paired flanges near opening; ostium funnel shaped; DB short, melanized; DS arising from base of CB; CB large, ovoid, with a pair of small, faint, dentate patches near base above; a figure-eight–shaped, dentate, signum on ventral surface of CB.

Etymology

The name, which combines the Latin words albi and cephalus, refers to the white head region of this species. This feature distinguishes the moth from its Central American counterpart, Brachyglene schausi Prout, in which the head and front are yellow, as well as from all other Brachyglene species.

Distribution

Brachyglene albicephala appears to be endemic to the northern half of Costa Rica (fig. 142); no specimens have been collected south of Juan Viñas. The vast majority of material, in the INBio collection, was captured at Estación Pitilla, a site at 700 meters in Guanacaste National Park (pls. 47A, 48A). The moth ranges from altitudes as low as 50 m to as high as 1000 m. The other Caenea Group species occurring in Central America, B. schausi, overlaps with B. albicephala but has a broader distribution, extending from northwestern Colombia north into Nicaragua.

Biology

Until recently, host records for Brachyglene were unconfirmed; our entire knowledge of biology for the genus was based on the two specimens of B. subtilis, discussed above (see Brachyglene: Biology). Then, in December 2006, the ACG group in Costa Rica, discovered larvae of B. albicephala. Like its congener, these caterpillars are associated with Bauhinia (table 4), but this Brachyglene species feeds on Bauhinia guianensis.

Discussion

As noted in the discussions for B. caenea and B. schausi, material from Central America, usually identified simply as B. caenea in collections, instead contains a third species—B. albicephala, sp. nov. The two Central American taxa are easy to separate based on body markings (see key and diagnosis above). The male and female genitalia of B. schausi and B. albicephala differ in almost every respect. In fact, comparison of genital morphology suggests that B. albicephala (fig. 146) is more closely related to B. caenea than it is to B. schausi (fig. 148).

Holotype

Male (pl. 15). Costa Rica: Guanacaste: Guanacaste National Park, Estación Pitilla, 9 km S Sta. Cecilia, 700 m, L_N_330200, 380200, 19 May–3 June 1993, leg. C. Moraga. The type is deposited in the INBio collection, Heredia, Costa Rica.

Paratypes

Costa Rica: Guanacaste: Guanacaste National Park, 1♂, Estación Pitilla, 9 km S Sta. Cecilia, 700 m, L_N_330200, 380200, 19 May–3 Jun 1993, leg. C. Moraga (INBio); 3♂♂, 1♀, 18 Apr–9 May 1993, leg. C. Moraga (INBio; male genitalia slide no. JSM-1318; female genitalia slide no. JSM-1319); 1♀, Jan 1994, leg. C. Moraga (INBio; INBio slide no. 1828449); 2♂♂, May 1994, leg. P. Ríos, de Luz, #2895 (INBio); 1♂, Jun 1994, leg. P. Ríos, #2996 (INBio); 1♂, 9–14 Jul 1993, leg. Gredy, Diego, Carlos, Estudiantes, #2319 (INBio); 1♂, W85°25′40″, N10°59′26″, Sep 1988, GNP Biodiversity Survey (INBio); 1♂, 330200, 380200, May 1989, GNP Biodiversity Survey (INBio).

Other Specimens Examined

Costa Rica: Heredia: 1♂, Reserva La Selva, 10.42°N, 84.00°W, CCL 350, 50 m, rainforest, Blacklight trap 8W canopy of Lecithys ampla, 30 m (26), 22 Mar 2004, 18.30–5.30 h, leg. Gunnar Brehm (SMNS); 1♂, NP Braulio Carrillo, 10°16.1′N, 84°05.1′W, 1070 m, rainforest, Blacklight 30W, MS a (5), 19 Feb 2004, 19.30–20.30 h, leg. Brehm & Corrales (SMNS). Cartago: 1♂, Tuis, May 28–Jun 4, Collection Wm. Schaus (USNM); 1♀, Aug, Schaus Collection (USNM); 1♀, Jun 1907, Collection Wm. Schaus (USNM; genitalia slide no. JSM-1337); 1♀, Juan Viñas, 2500 ft, May, leg. W. Schaus, 1911-32 (BMNH); 1♂, 1♀, Juan Viñas, June, Collection Wm. Schaus (USNM; male genitalia slide no. 1336); 1♀, Irazu, 6–7000 ft, leg. H. Rogers (BMNH); 1♀, ex Coll. A. Gillott (BMNH).

Dissected

2♂♂, 2♀♀.

Brachyglene bracteola (Geyer)

Figures 143C, 145D, 147; plate 15 [EX]

Phaeochlaena bracteola Geyer, 1832 (in Hübner, 1832) 4: 17, [pl. 113], figs. 655, 656.

Type Locality

“South America”.

Type

Holotype ♂, ex Herrich-Schäffer Collection (ZMH).

Brachyglene circumlita Prout, 1918: 419. New synonymy.

Type Locality

Brazil, Amazonas, Ceara.

Type

Holotype ♀, leg. Leach, Aug 1884 (BMNH).

Brachyglene dilatata Hering, 1925: 523, fig. 70d. New combination, revised synonymy (formerly a synonym of caenea Drury).

Type Locality

Venezuela, Valencia.

Type

Holotype ♂ (ZMH).

Brachyglene elongata Hering, 1925: 524.

Type Locality

Venezuela, Valencia.

Type

Holotype ♂ (ZMH).

Phaeochlaena privata Walker, 1864: 156.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♂, ex Birchall Collection (CAS).

Discussion

The two wing-pattern traits used in the species key above—presence of a basal dash on the FW ventral surface and an orange-yellow band along the HW margin—seem to characterize Brachyglene bracteola (pl. 15) well. The moth's distribution, however, is problematic. The holotype (ZMH) does not bear a locality label, and the original description simply gives “Sudamerika” as the type locality. A male specimen from Portachuelo, Venezuela (JSM-1214), matches the type of B. bracteola precisely. My research suggests that B. bracteola occurs from Venezuela east to Ceará, Brazil, and south at least as far as Rio de Janeiro. The distribution of the species within Brazil is uncertain; it may extend west up the Amazon River to Fonte Boa.

Females of B. bracteola (pl. 15) show extensive wing-pattern variation, especially with regard to the size and shape of the FW fascia, as well as the width of the orange HW band. This seems to have confused specialists over the years. Based on careful study of available material, including types, I here propose two newly recognized synonyms of B. bracteoladilatata Hering and circumlita Prout—adding to the two already in the literature.

Hering (1925: 524, fig. 70f) described elongata, from Venezuela, as a subspecies of B. bracteola. He noted that it differs from bracteola in the following ways: “longer and narrower forewings, the costal margin is straighter, the apex more rounded off, the spot of the forewing above and beneath smaller.” I found no differences in male genital morphology between the two phenotypes, and therefore retain elongata as a synonym following previous authors.

The type of privata Walker is not in the BMNH holdings. However, a male specimen from the California Academy of Sciences bears a white, handwritten label stating “Phaeochlaena privata W., type”. That specimen, formerly in the R.H. Stretch collection, matches Walker's original description. It does not bear a locality label; Walker (1864: 156) gives the type locality as “Bogotá”. The CAS specimen, in poor condition and missing its abdomen, shows precisely the same wing pattern as the type of elongata Hering. I retain privata as a synonym of bracteola.

Distribution

Brazil (BMNH, MPM, NMW, USNM); Venezuela (AMNH, BMNH, IZA, USNM, ZMH); Colombia (CAS); Peru (BMNH).

Dissected

♂, Venezuela, Aragua, Portachuelo, Rancho Grande, 1100 m, 20 Jul 1975, leg. J. Salcedo & J. Clavijo, IZA (genitalia slide no. JSM-1214); ♂, Brazil, Rio de Janeiro, Santo Antonio dos Brotos, San Fidelis Distr., 1876–1882, leg. Auguste Vincent de Lyon, BMNH (genitalia slide no. JSM-1213); ♂, Brazil, Pernambuco, leg. A.M. Moss, BMNH (genitalia slide no. JSM-734); ♀, Venezuela, Aragua, Rancho Grande nr. Maracay, 15 Jul 1946, N. Y. Zool. Soc., AMNH (genitalia slide no. JSM-1539); ♀, Brazil, Fonte Boa, Upper Amazon, July 1907, leg. S.M. Klages, BMNH (genitalia slide no. JSM-1179); ♀, Brazil, Pernambuco, USNM (genitalia slide no. JSM-787).

Brachyglene caenea (Drury)

Figure 143G; plate 15

Callimorpha caenea Drury, 1782: 29, pl. 21, fig. 3.

Type Locality

Brazil, Rio de Janeiro.

Type

Syntype ♀, ex Bonifas, 1775 (not seen).

Scedrosa extensa Walker, 1864: 139.

Type Locality

“Brazil”.

Type

Syntype ♀, ex Gardner Collection (BMNH).

Discussion

Brachyglene caenea (pl. 15) is unique within Brachyglene in possessing a completely brown head and thorax; all other species exhibit yellow, orange, or white areas on the front, labial palpi, occiput, and tegulae. Having established this distinction, differences in body coloration and genital morphology show that what has historically been called B. caenea in Costa Rica (e.g., see Druce, 1885a) is instead an undescribed species closely related to it. I describe that species above as Brachyglene albicephala. Based on numerous morphological differences, Prout's (1918) so-called “aberration” of caenea, B. fracta, is here described as new (see below).

Brachyglene caenea is apparently restricted to southeastern Brazil, from Rio de Janeiro south to Santa Catarina. The species is quite rare. I have been unable to locate the type of Brachyglene caenea, but Drury types of Saturniidae are in the Adelaide Museum, Australia (I. Kitching, personal commun.), so an inquiry to that collecton would be important. The label data listed in the original description states: “Rio Janeiro, Mr. Bonifas, 1775”. Material I have come to regard as B. caenea corresponds closely in wing pattern with the moth figured by Drury (1782; pl. 21, fig. 3).

I have transferred Hering's form dilatata from it former position as a synonym of caenea (Bryk, 1930), to its new place as a synonym of bracteola. The female type of extensa Walker shows a wing pattern supporting it as conspecific with caenea, although Walker's type is exceptionally large (FW length  =  21.0 mm).

Distribution

Brazil (BMNH, CUIC, NMW, USNM, VOB).

Dissected

♂, Brazil, Santa Catarina, Brusque, 100 m, 5 Jan 1989, leg. V.O. Becker, VOB (genitalia slide no. JSM-904).

Brachyglene fracta, new species

Figures 148F–H; plate 14

Diagnosis

Brachyglene fracta (Venezuela) and B. caenea (Brazil) show similar wing patterns (pls. 14, 15). The two can be separated by the color of Lp1, the occiput, and the propleuron, which are orange-yellow in B. fracta but brown in B. caenea. Brachyglene fracta is sympatric with B. bracteola (pl. 15), and these two could potentially be confused. However, B. fracta has a teardrop-shaped orange spot near the HW apex, whereas the HW of B. bracteola is broadly orange in its anterior third. The FW of B. bracteola shows a diffuse orange-yellow basal dash on its ventral surface, not present in B. fracta. Finally, the abdominal pleuron in B. fracta is brownish gray, concolorous with the dorsum, whereas in B. bracteola there is a longitudinal orange-yellow pleural stripe running the length of the abdomen. In the genitalia, females of B. bracteola possess a prominent signum on the CB, while in B. fracta the signum is highly reduced, almost absent (fig. 148F).

Description

Male. Unknown.

Female. FW length  =  15.5–16.5 mm. Head: Lp1 yellow-orange, Lp2 brown with a few yellow-orange scales ventrally near base, Lp3 brown; front chocolate brown; occiput brown in anterior half, yellow-orange posteriorly; vertex and antenna chocolate brown.

Thorax: Propleuron yellow-orange; procoxa brown, inner surface creamy with a few yellow scales; remainder of pleuron brown with a few yellow-orange hairlike scales; patagium, tegula, and dorsum uniformly chocolate brown.

Forewing: (Dorsal) Ground color chocolate brown; a yellow-orange transverse band crossing immediately beyond DC, from Sc to anal fold, occasionally reaching 1A+2A; band widest anteriorly, gradually tapering posteriorly. (Ventral) Ground color chocolate brown; yellow-orange transverse band wider and longer than on dorsal surface; a diffuse, ovoid, yellow-orange submarginal patch beyond transverse band, its anterior margin touching Rs4, its posterior margin falling short of M3.

Hind wing: (Dorsal) Ground color dark brown to chocolate brown; a large, comma-shaped, yellow-orange spot near apex, widest distally, tapering toward base, its outer margin falling short of apex, its inner margin reaching halfway to base. (Ventral) Similar to dorsal surface, except yellow-orange apical spot slightly larger.

Terminalia (fig. 148F–H): Tg7 broad, tapered distally, anterior margin simple, posterior margin broadly rounded, lateral margins indented near midpoint; posterior half of Tg7 lightly sclerotized; St7 slightly shorter than Tg7, anterior margin simple, anterolateral angles rounded, posterior margin with a deep, U-shaped mesal excavation, posterolateral angles rounded; lateral margins of St7 indented immediately beyond halfway point, posterior half of St7 lightly sclerotized, marking a shallow transverse groove; Tg8 wedge shaped, posterior margin rooflike, with a mesal notch; AA broad and short, acute at apices; PP relatively wide and short, apices acute; CB almost round, coarsely wrinkled; signum located ventrolaterally on right side, highly reduced, comprising a few internal denticles; base of CB with two small, denticulate pockets, one on each side; DS short, roughly cylindrical; DS arising from a laterally compressed, lightly sclerotized dorsal appendix at base of CB; ostium funnel shaped, relatively small; PVP with a pair of sinuate crests extending from ostium to posterior margin.

Etymology

The name fracta, chosen by Prout (1918), was apparently taken from the Latin fractus, meaning “broken”. He noted that in B. fracta the orange-yellow FW cross band is “incomplete”. Prout's name is retained here to acknowledge his discovery of this taxon.

Distribution

Based on the six known specimens of B. fracta, this species is endemic to north-central Venezuela. The easternmost record is Caracas (BMNH), while the westernmost locality is San Felipe in Yaracuy Province (LACM). The majority of examples were captured midway between those sites, at Rancho Grande Field Station near Maracay.

Discussion

Prout (1918: 419) described fracta as an aberration of B. caenea Drury. Prout's phenotype, a species distinct from B. caenea and all other Brachyglene, is here described as new. Prout intimated that B. fracta is closely related to B. caenea from Brazil; the two show similar wing patterns (pls. 14, 15). In fact, B. fracta is the apparent sister species to B. bracteola, with which it is sympatric. Means for separating all three of these are provided in the B. fracta diagnosis above. Brachyglene fracta is known to me from six female specimens.

Material from western Ecuador exhibits wing-pattern characteristics similar to those of B. fracta. However, differences in genitalia show this to be an undescribed species. This taxon is known from a single BMNH female, as well as from a large series of 18 males and six females at the LACM, all collected by S. McKamey. Genitalia slide data for the undescribed Ecuadorian Brachyglene are as follows: ♂, Ecuador, Guayas, Hacienda San Juaquin, 4 road km SW Bucay, 250 m, 1–4 May 1986, leg. Stuart McKamey, LACM (genitalia slide no. JSM-1678); ♀, Ecuador, BMNH (genitalia slide no. JSM-735).

Holotype

Female (fig. 148F–H; pl. 14). Venezuela: Aragua: Rancho Grande, 1084 m, 28 Feb 1989, leg. J.S. Miller, day-collecting along trail (genitalia slide no. JSM-1538). The type is deposited at the AMNH.

Paratypes

None.

Other Specimens Examined

Venezuela: Aragua: 1♀, Rancho Grande, 1084 m, 8 Jul 1948, leg. H. Fleming (AMNH); 1♀, Rancho Grande, 1100 m, 4 May 1971, leg. J. Salcedo & A. Ramirez (IZA); 1♀, Tropical Research Station, New York Zoological Society, no. 49633 (AMNH); 1♀, Caracas (BMNH). Yaracuy: 1♀, Hacienda Tropicale, ca. 10 km S San Felipe, 10°17′30″S, 68°40′W, 100–400 m, 26 Jan–23 Feb 1993, leg. Kareofelas & Witham, diurnal (LACM).

Brachyglene schausi Prout

Figures 143D, 145E, 148; plate 15 [EX]

Brachyglene schausi Prout, 1918: 419.

Type Locality

Costa Rica, Siquirres, “Railway 36 miles from Limón”, 1000 ft.

Type

Holotype ♂, Sep–Oct 1901, leg. A. Hall (BMNH).

Discussion

Siquirres in Limón Province, the type locality for Brachyglene schausi, is on the Caribbean side of the Cordillera Central. This species is also known from higher elevations further inland, as far as Tuis in Cartago Province. Brachyglene schausi is easily distinguishable from the similar-appearing Costa Rican Brachyglene species, B. albicephala, sp. nov. (pl. 15): In B. schausi the front, occiput, and first two labial palpus segments are bright yellow. These regions are light gray to whitish in B. albicephala. The latter is also a slightly larger moth. Their genitalia differ in numerous ways. For example, the male valva apex differs dramatically (compare figs. 146A, 148A), as does the shape of the aedeagus (figs. 146B, 148D) and the configuration of the female ostium (figs. 146D, 148E).

A single locality record shows that Brachyglene schausi occurs in Nicaragua. Six male specimens in the CMNH collection are labeled: “Great Falls, Pis Pis River, 10 miles NW of Eden, Nicaragua”. However, the distribution of this species extends even further north, having been collected by Rafael Turrent in southern Mexico (ARTC).

Prout designated a paratype of schausi in the BMNH collection, which bears the following label data: Colombia, Chocó, El Tigre, Río Tamaua, 320 ft, Feb 1909, leg. G.M. Palmer. If this example is truly conspecific with the Costa Rican type, which I have not verified by dissection, then the distribution of Brachyglene schausi is extensive, stretching from northwestern Colombia north to southern Mexico. This hypothesis merits further scrutiny.

Distribution

Colombia (BMNH); Costa Rica (BMNH, INBio, LACM, NMW, SMNS, USNM); Nicaragua (CMNH); Mexico (ARTC).

Dissected

♂, Costa Rica, Limón, Hacienda Tapezco, 29 air km W Tortuguero, 40 m, 10°30′N, 83°47′W, 12 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller, LACM/Earthwatch Trees of Tapezco Expedition, LACM (genitalia slide no. JSM-905); ♀, Costa Rica, Limón Province, Hacienda Tapezco, 29 air km W Tortuguero, 40 m, 10°30′N, 83°47′W, 12 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller, LACM/Earthwatch Trees of Tapezco Expedition, LACM (genitalia slide no. JSM-906).

2. SUBTILIS GROUP

Members of the Subtilis Group (pl. 15) are generally smaller (FW length  =  11.0–14.0 mm) than Caenea Group species (FW length  =  13.0–19.0 mm). The best way to separate members of the two clades is by their FW ground color. This is olive to gray-brown in Subtilis Group species, but dark chocolate brown to blackish brown in the Caenea Group. Genital characters for separation are listed in the species group key (above).

KEY TO SUBTILIS GROUP SPECIES

1. Patagium and tegula bordered with contrasting dull olive-brown scales; a wide, conspicuous, dull olive-brown band along thoracic midline; FW with an ovoid yellow fascia immediately beyond DC2

Patagium and tegula almost entirely yellow; thoracic midline with a thin, inconspicuous gray-brown line; basal half of FW with a large yellow triangle from base to outer margin of fascia (Costa Rica N to Guatemala)crocearia (Schaus)

2. Yellow FW fascia small, roughly teardrop shaped, posterior margin of fascia not reaching base of M3+CuA1; dorsum of abdomen dull olive brown from base to apex (Colombia and Venezuela S to Paraguay)subtilis (C. and R. Felder)

Yellow FW fascia large, ovoid, posterior margin of fascia extending beyond fork of M3+CuA1; dorsum of abdomen orange-yellow at base, a narrow dull olive-brown dorsal stripe extending from A3–A8, wider distally (Brazil)patinata Prout

Brachyglene crocearia (Schaus)

Plate 15

Phaeochlaena crocearia Schaus, 1912: 432.

Type Locality

Costa Rica, Sixaola River.

Type

Syntype ♂ (USNM type no. 17616).

Discussion

The male genitalia of B. crocearia, a Central American endemic, are barely distinguishable from those of B. subtilis from northern South America. They differ most noticeably in the shape of the valva apex. The major wing-pattern difference is the size of the yellow FW maculation (pl. 15), which is large and triangular in most specimens of B. crocearia (but not all), but small and teardrop shaped in B. subtilis. The most effective characters for separation, showcased in the species key, involve the amount of yellow on the thorax; the patagia, tegulae, and thoracic dorsum are almost entirely yellow in B. crocearia, but these bear areas of contrasting dull olive-brown scales in B. subtilis.

I have seen no females of Brachyglene crocearia in museum collections. The moth seems to be rare; the largest series consists of 10 USNM males from Cayuga, Guatemala. There are two males (1 from Costa Rica, 1 from Honduras) at the BMNH, and several Costa Rican males at INBio.

Distribution

Costa Rica (BMNH, INBio, USNM); Honduras (BMNH); Guatemala (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1215).

Brachyglene patinata Prout

Plate 15

Brachyglene patinata Prout, 1918: 419.

Type Locality

Brazil.

Type

Holotype ♂, leg. F. Moore, “77-17” (BMNH).

Discussion

Prout's type of B. patinata (pl. 15) bears close resemblance to certain specimens of B. subtilis (pl. 15), especially those in a USNM series collected in Paraguay. It differs from them in possessing a considerably larger FW fascia, in showing more yellow on the FW ventral surface, and in having more yellow on the abdominal dorsum. I have seen no verified examples of B. patinata other than the type, which I did not dissect. Future study may reveal that B. patinata is a junior synonym of B. subtilis.

Distribution

Brazil (BMNH).

Dissected

None.

Brachyglene subtilis (C. and R. Felder)

Figures 143B, 143E, 143F, 145A–C, 145F, 149; plate 15 [EX]

Anatolis subtilis C. and R. Felder, 1874; pl. 105, fig. 10.

Type Locality

“Columbia”(?).

Type

Not seen.

Eudesmia punctata Druce, 1899: 293.

Type Locality

Venezuela, Cucuta.

Type

Syntype ♂ (BMNH).

Discussion

While C. and R. Felder (1874: 1) give the type locality for B. subtilis as Colombia, the only specimens I have seen from that country are in the ZMH and NMW collections. On the other hand, based on relatively extensive holdings in other museums, Brachyglene subtilis is quite common in the dry forests of northern Venezuela. This species has been reared on Bauhinia splendens in the Fabaceae (table 4; see Brachyglene: Biology).

Since I have not been able to locate the Felder type of B. subtilis for comparison, it would have been pointless to dissect the BMNH type of punctata Druce in an attempt to determine whether it is a synonym, as proposed by Prout (1918: 419). In the meantime, that synonymy is retained.

Brachyglene subtilis exhibits male and female genital traits characteristic of the Subtilis Group; the aedeagus is short and wide (fig. 149C), and the female postvaginal plate is greatly expanded (fig. 149E).

Distribution

Colombia (NMW, ZMH); Venezuela (AMNH, BMNH, CMNH, IZA, LACM, USNM); Paraguay (USNM).

Dissected

♂, Venezuela, Aragua, Rancho Grande, 1100 m, N. Y. Zoological Society, AMNH (genitalia slide no. JSM-418); ♂, Venezuela, Cucuta, Wm. Schaus Collection, USNM (wing slide no. JSM-1433); ♀, Venezuela, Las Quiguas, Esteban Valley, CMNH (genitalia slide no. JSM-419); ♀, Venezuela, Aroa, Wm. Schaus Collection, USNM (wing slide no. JSM-1434).

The following have been transferred from Brachyglene: divisa Dognin to Hadesina Warren peba Druce to Sagittala, gen. nov. superbior Strand to the Arctiidae (see Prout, 1920) thirmida Hering to incertae sedis

CHRYSOGLOSSA MILLER, new genus

Figures 150Figure 151Figure 152Figure 153Figure 154Figure 155Figure 156158; plates 15, 38H

Type species: Polypoetes demades Druce, 1885a.

Figure 150

Morphology of Chrysoglossa (♂♂). A, head of C. maxima, lateral view; B, head of C. maxima, frontal view; C, head of C. maxima, posterior view; D, head of C. norburyi, lateral view; E, C. maxima tegula; F, C. demades wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f150.gif

Figure 151

Scanning electron micrographs of Chrysoglossa maxima (Druce) ♂ antenna. A, dorsolateral view, distal at left; B, apex of ramus in lateral view, showing dorsal seta (d); C, sensilla auricillica on ventral surface of ramus; D, sensillum coeloconicum on ventral surface of ramus.

i0003-0090-321-1-1-f151.gif

Figure 152

Genitalia of Chrysoglossa, sp. nr. demades (♂ JSM-1056, ♀ JSM-1058). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f152.gif

Figure 153

Holotype male genitalia of Chrysoglossa fumosa, sp. nov. (JSM-1070). A, genitalia; B, St8; C, aedeagus; D, Tg8, dorsal view.

i0003-0090-321-1-1-f153.gif

Figure 154

Genitalia of Chrysoglossa maxima (♂ JSM-458, ♀ JSM-1067). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, caltrop cornuti of vesica enlarged; E, ♂ St8; F, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f154.gif

Figure 155

Genitalia of Chrysoglossa norburyi, sp. nov. (♂ JSM-816, ♀ JSM-1363). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♀ genitalia; E, ♂ Tg8.

i0003-0090-321-1-1-f155.gif

Figure 156

Costa Rica, showing the known distributions of Chrysoglossa norburyi, sp. nov., and C. phaethon (Schaus).

i0003-0090-321-1-1-f156.gif

Figure 157

Genitalia of Chrysoglossa phaethon (Schaus) (♂ JSM-229, ♀ JSM-230). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f157.gif

Figure 158

Genitalia of Chrysoglossa submaxima (♂ JSM-780, holotype ♀ JSM-1769). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♀ genitalia; E, ♂ St8.

i0003-0090-321-1-1-f158.gif

Diagnosis

The seven described species of Chrysoglossa exhibit a drab, often mottled, brown or gray FW (pl. 15). They have a similarly drab HW, sometimes with a white central area. The genus is distinguished by the following set of characteristics: proboscis yellow to golden brown; each ramus of male antenna with a robust, subapical seta on dorsum (151A, B); eye large and rounded, bulging outward (fig. 150A–D); labial palpus moderately long, ascending to above middle of front (fig. 150A, D); Lp2 as long as or longer than Lp1; Lp3 slightly elongate, scales forming an acute apex (fig. 150D); epiphysis long and narrow; male FW stridulatory organ present (fig. 150F), DC less than one-half wing length; tympanum large, anterior margin of cavity acute; tympanal membrane large, ovoid, oriented horizontally.

In Nebulosa, the genus with which Chrysoglossa could most easily be confused, the haustellum is blackish brown, the male antennal rami lack a dorsal seta, the palpus is short (fig. 159), and the tympanal cavity is shallow, with the membrane facing laterally (fig. 160F). Features of the male genitalia also distinguish the two genera: In Chrysoglossa Tg8 is shorter than St8, rather than being longer (Nebulosa), and the posterior margin of Tg8 never exhibits a central process. The vesica of Chrysoglossa usually bears three types of cornuti (e.g., fig. 154C): A large, isolated spinelike distal cornutus, a group of shorter spinelike cornuti near the base, and a set of deciduous caltrop cornuti around the middle. Caltrop cornuti are never present in Nebulosa. Many other genital differences separate the two genera, including several from female structure.

Description

Male. FW length  =  13.5–25.0 mm. Head (figs. 150A–D, 151): Proboscis yellow to golden brown; labial palpus moderately long, curving upward to above middle of front; Lp1 strongly curved, loosely scaled, sometimes with a fringe of longer scales below (e.g., C. demades); Lp2 slightly curved, as long as, or longer than, Lp1, with a short ventral ridge of scales; Lp3 slightly to moderately elongate, closely scaled, apex acute; scales of front fairly long and thin, pointing dorsomedially, upper scales forming a loose tuft between antennal bases; eye extremely large and rounded, bulging outward, completely surrounded by scales; gena absent; postgena extremely narrow; scales of vertex long or moderately so, pointing anteriorly; antenna bipectinate almost to apex, terminal 3–4 annulations simple; antennal rami long, dorsum of each with a robust, erect, subapical seta.

Thorax (fig. 150E): Epiphysis long and narrow, longer than three-fourths length of tibia, extending beyond tibia apex; tegula orange-yellow at base, long, at least two-thirds length of mesoscutum, distal portion wide, ventral portion long, apex acute, the two parts divided by a weakly defined transverse suture; metathoracic tympanum large, cavity relatively deep, its anterior and posterior margins with sharply defined edges; tympanal membrane large, ovoid, oriented horizontally but lateral margin tipped slightly upward.

Forewing (fig. 150F; pl. 15): Broad, somewhat elongate; vein Rs1 long stalked with Rs2–Rs4; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from anterolateral angle of DC, separate from base of radial sector, UDC short; stridulatory organ present, M1 and M2 swollen at bases, with a short ventral fold between them; DC much shorter than one-half FW length, sometimes less than one-third; veins M3 and CuA1 long stalked; ground color light olive brown, dark brown or gray; pattern often mottled with thin transverse whitish lines, less commonly evenly colored, usually with a semihyaline fascia beyond DC, frequently with a whitish or semihyaline subapical maculation, located roughly between the base of Rs2+Rs3 and M3.

Hind wing (fig. 150F; pl. 15): Full, outer margin rounded; M3 and CuA1 long stalked; ground color brown or gray, often with a white central area.

Abdomen: Relatively short, acute distally; evenly brown or gray, occasionally with venter whitish.

Terminalia (figs. 152A–D, 153, 154A–E, 155A–C, 155E, 157A–D, 158A–C, 158E): Tg8 lightly sclerotized, much longer than Tg7 but slightly shorter than St8, often narrower than Tg7 (e.g., C. norburyi); lateral margins either parallel (e.g., C. submaxima) or gently convex (e.g., C. maxima), anterior margin either simple (e.g., C. nigrifascia) or with a pair of extremely short, wide apodemes on either side of midline, posterior margin transverse and simple (e.g., C. norburyi), or slightly convex (e.g., C. fumosa, C. maxima); membrane beyond posterior margin of Tg8 finely striate; St8 wide and relatively short, but longer than Tg8, St8 as wide as or wider than St7; St8 anterior margin with a broad, short, often truncate, mesal apodeme, its ventral surface sometimes with a small ligulate fold, lateral margins parallel (e.g., C. submaxima), convex (e.g., C. demades), or laterally expanded near middle (e.g., C. norburyi); posterior margin of St8 much narrower than anterior margin, with a deep, often poorly defined, U-shaped or horseshoe-shaped mesal excavation; membrane along posterior margin of St8 striolate; socii/uncus complex large or moderately so, often roughly triangular and wide at base (e.g., C. phaethon), complex narrowly attached to tegumen; uncus variable in length, usually short (e.g., C. demades, C. nigrifascia), rarely long and narrow (C. fumosa); socii fairly large, laterally compressed, longer than uncus, curving upward, apices variable in shape, ventral margins sometimes strongly crenulate (C. fumosa, C. maxima), lateral surfaces densely covered with setae; tegumen much taller than vinculum, wide in lower third above connection with valva, becoming narrower above near junction with socii/uncus complex; vinculum short, variable in width, ranging from extremely wide (C. norburyi) to relatively narrow (C. fumosa); saccus comprising a large, lightly sclerotized, triangular sclerite, apex of triangle folded upward between valva bases; ventral margin of genitalia usually transverse, sometimes convex (e.g., C. maxima); valva long and relatively wide, mostly membranous; BO large, occupying one-half to two-thirds of valva, lateral margin curled anteriorly; costa of valva wide, often expanded in basal half; apex of valva sclerotized, usually broadly spatulate, sometimes forming a small, triangular process (C. norburyi); arms of transtilla extremely narrow at bases, arising from a crestlike ridge running the length of valva, arms becoming wider toward midline, curving gently upward and meeting in manica at midline to form a small, transverse or acute sclerite; bases of transtillar arms in C. demades and C. nigrifascia coarsely strigate; aedeagus wide, relatively short, narrowest near base, widest distally; apex of aedeagus ending in a small tooth-shaped ventral process (e.g., C. fumosa), or a small transverse flange (e.g., C. demades, C. norburyi); opercular sclerite located dorsally at apex of aedeagus, usually narrow and straplike, occasionally large and claw shaped (C. demades, C. nigrifascia); vesica relatively large, wide, between one-half and three-fourths the length of aedeagus, often bent upward; vesica usually bearing three types of cornuti, a large, spinelike distal one, a group of shorter spinelike or thornlike ones, and a group of deciduous caltrop ones near middle; some species bearing deciduous cornuti only (C. norburyi, C. submaxima).

Female. FW length  =  14.5–26.0 mm. Head and thorax similar to male, except: Labial palpus shorter, reaching upward to immediately above clypeus; antenna bipectinate, rami short and wide; wings much longer and broader, outer margin more convex; frenulum comprising 6–10 bristles.

Abdomen: Shorter and much wider than male.

Terminalia (figs. 152E, 154F, 155D, 157E, 158D): Tg7 large, as wide as Tg6 but much longer, slightly narrower distally, anterior margin simple, posterior margin simple, rarely somewhat convex (C. phaethon); lateral margins of Tg7 sometimes slightly concave (e.g., C. fumosa) or broadly rounded outward (C. phaethon); St7 extremely wide, shorter than Tg7, anterior margin simple, posterior margin usually simple, sometimes with a deep mesal excavation, ostium migrated anteriorly (e.g., C. fumosa, C. maxima); Tg8 short, wide, forming a rooflike structure over PA, posterior margin with a deep mesal notch; AA short, acute distally; A8 pleuron membranous, a thin, straplike sclerite along anterior margin; PP short to long, often curving downward; PA moderately large, membranous, posterior margin angulate near middle; PVP wide, lightly sclerotized, lateral angles reaching to AA; PVP rarely long and narrow (C. maxima); DB short, somewhat wide, membranous or lightly sclerotized; ostium a transverse funnel; CB large and ovoid or round, mostly membranous; a large, laterally compressed, lightly sclerotized appendix dorsally at base of CB; appendix bearing a pair of shallow lateral pockets, their internal surfaces coarsely spiculate or dentate; signum figure-eight shaped, located ventrally or, less commonly, laterally on right side, its internal surface coarsely dentate; DS arising from right side of dorsal appendix at base of CB.

Etymology

The name combines two words taken from Greek, chrysos (“gold”) and glossa (“tongue”), referring to the golden brown proboscis of moths in this genus. A yellowish proboscis occurs elsewhere in the Dioptinae (e.g., Phanoptis, Oricia, Scotura), and is a prominent feature of many Geometridae. However, the trait is showcased here as an important diagnostic character for separating Chrysoglossa from the genus with which it would most likely be confused—Nebulosa.

Distribution

Chrysoglossa is strictly Central American, ranging from northeastern Mexico south to Chiriquí, Panama. None has been recorded south of the Canal Zone. The species seem to favor dry forest habitats between 1000 and 1500 meters in elevation, perhaps in accordance with the distribution of their host plants.

Biology

There are two Chrysoglossa species for which the biology is known—an undescribed taxon closely related to C. demades, reared on Quercus germana (Fagaceae) in northeastern Mexico by Alma Solis (USNM), and C. norburyi, discovered feeding on Alfaroa guanacastensis (Juglandaceae) in northern Costa Rica (Janzen and Hallwachs, 2008). As is noted in the general discussion (see Host Plants), these food plants are unusual for Dioptinae, but seem to reflect patterns of host use more typical of other notodontids, such as Datana in the Phalerinae.

Discussion

All the species now in Chrysoglossa were placed in Tithraustes by previous authors (Prout, 1918; Hering, 1925; Bryk, 1930). Tithraustes was formerly a heterogeneous assemblage of taxa. Bryk (1930) listed 42 included species that I have now dispersed into five different, mostly unrelated genera. In my classification, there are only 10 Tithraustes species, two of which are newly described. Chrysoglossa, the apparent sister genus to Nebulosa (fig. 7), is a well-defined monophyletic group. Sixteen synapomorphies from adult morphology support the clade (appendix 4), and Bremer support for the clade comprising Chrysoglossa exemplar taxa measured an extremely high 13 (fig. 2).

Chrysoglossa fumosa, from Panama, was formerly designated an aberration (Warren, 1905), but is here described as new, and C. norburyi is newly described from Costa Rica. At least three additional taxa remain to be described: two are closely related to C. demades, and the third is a relative of C. fumosa and C. maxima. I leave these descriptions for future work.

KEY TO CHRYSOGLOSSA SPECIES

Plate 15

1. Forewing with a white or semihyaline subapical maculation, spot subtended by radial veins and M3; wings moderately long (FW length  =  13.5–22.0 mm)2

FW without a subapical spot, instead with a wavy, often indistinct, submarginal line extending from Rs1 anteriorly to 1A+2A posteriorly; wings long (FW length  =  18.0–26.0 mm)5

2. Subapical FW maculation long, touching fork of Rs2+Rs3 anteriorly and M3 posteriorly; HW central area white3

Subapical maculation shorter, extending anteriorly to Rs4, posteriorly to M3; HW central area semihyaline (Panama, Costa Rica)demades (Druce)

3. Forewing uniformly gray-brown to slate gray, veins slightly lighter; subapical FW maculation clearly defined, semihyaline; HW ground color slightly darker than FW (Costa Rica)4

FW unevenly mottled with patches of dark brown and reddish brown, veins much lighter orange brown; subapical FW maculation diffuse, whitish; HW ground color slate gray, much darker than FWsubmaxima (Hering)/mexicana (Hering)

4. Male genitalia with valva apex forming a broad, scoop-shaped structure (fig. 157A); socii wide, not curving upward beyond uncus; aedeagus with spinelike, as well as deciduous, cornuti (fig. 157C); female St7 smooth (visible in pinned specimens), with a deep lateral concavity; anterior margin of female St7 simple; paired pockets at base of CB shallow (fig. 157E), finely spiculate (Costa Rica)phaethon (Schaus)

Valva apex forming a simple, triangular process (fig. 155A); socii narrow, curving strongly upward beyond uncus; aedeagus with deciduous cornuti only (fig. 155B); female St7 coarsely rugose (visible in pinned specimens); anterior margin of female St7 with a deep, wide, irregularly shaped groove; paired pockets at base of CB deep (fig. 155D), strongly denticulate (Costa Rica)norburyi, sp. nov.

5. Forewing dark chocolate brown to blackish brown, with a wavy, cream-colored submarginal line and usually a diffuse, whitish transverse band crossing fascia from subcosta to anal fold; uncus short, truncate (fig. 154A); socii curving upward; vesica with deciduous cornuti near middle (fig. 154C), as well as a huge, spinelike distal cornutus and a small patch of short, spinelike cornuti at base; ♂ FW length  =  19.0–23.5 mm (Panama N to Guatemala)maxima (Druce)

FW dirty olive brown, submarginal line extremely faint, transverse band absent; uncus elongate (fig. 153A), narrowed at base; socii bending downward; vesica without deciduous cornuti (fig. 153C), instead with a single large distal cornutus and an evenly dispersed group of short, thornlike cornuti; ♂ FW length  =  18.0 mm (Panama)fumosa, sp. nov.

Chrysoglossa demades (Druce), new combination

Figure 150F; plate 15 [EX]

Polypoetes demades Druce, 1885a: 160.

Type Locality

Panama, Volcán de Chiriquí, 3000–4000 ft.

Type

Syntype ♂, leg. Champion (BMNH).

Tithraustes nigrifascia Hering, 1925: 514, fig. 67k. New synonymy.

Type Locality

“patria unknown”.

Type

Syntype ♂/♀ (ZMH).

Discussion

The taxonomic boundaries and geographical distribution of C. demades are poorly understood. Material from Chiriquí, Panama, and southwestern Costa Rica can safely be regarded as being C. demades, but identifications become problematic elsewhere in Central America. At least two undescribed species occur—one from Costa Rica and one from Mexico. These are noted below. I list the genitalia slides for all this material under demades.

Careful study of the ZMH type of Tithraustes nigrifascia Hering (1925) reveals that name to be a newly recognized synonym of C. demades. The nigrifascia type bears no data other than a label with the number “177”. Furthermore, the type is a male, but a female abdomen, apparently taken from a small butterfly species, has been glued to its body. Needless to say, I did not dissect this type. Nevertheless, based on wing pattern and other body characters, it is safe to propose that this specimen is conspecific with C. demades.

Alma Solis (USNM) reared a series of a Chrysoglossa, extremely similar in wing pattern to C. demades but slightly darker and smaller in size, on Quercus germana (Fagaceae) in the state of Tamaulipas, Mexico. She discovered larvae at Rancho del Cielo, a locality inland from the gulf, approximately 260 miles south of Brownsville, Texas. That site (23°05′ N, 99°45′ W) represents the northernmost extension of tropical flora (A. Solis, personal commun.). The male and female genitalia of these Mexican examples (fig. 152) differ in significant ways from those of demades, especially in the configuration of the valval costa. Mexican material thus represents an undescribed species, closely related to C. demades, whose distribution probably extends south into Guatemala (BMNH, USNM) and possibly Nicaragua (BMNH).

A second undescribed Chrysoglossa species, similar in appearance to C. demades, has been collected at Monteverde, Costa Rica. These specimens are slightly larger than demades, they have a FW with darker, more contrasting markings, and the HW is white with a dark outer margin. Material can be found in the J. Bolling Sullivan Collection and at the AMNH. I leave species description for future revisionary work.

Since the undescribed Mexican taxon was reared on oak, it is probable that demades itself uses that host plant as well. According to records from the Missouri Botanical Garden, the distribution of Quercus extends as far south as Huila Province in southwestern Colombia. Chrysoglossa demades has not been recorded south of Chiriquí, but its distribution thus overlaps with that of oak. At sites where I have collected C. demades in Costa Rica, the moths are relatively common. They are readily attracted to lights.

Distribution

Panama (BMNH, LACM); Costa Rica (AMNH, BMNH, INBio, JBSC, LACM, SMNS); Nicaragua (BMNH); Guatemala (BMNH, USNM); Mexico (AMNH, BMNH, FNHM, LACM, USNM, VOB).

Dissected

♂, Costa Rica, Puntarenas Prov., Tajo Bella Vista, 35 km NE San Vito nr. Las Alturas, 4700 ft, 20 Mar 1991, leg. J.S. Miller, at light, AMNH (genitalia slide no. JSM-770); ♂, Mexico, Jalapa, USNM (genitalia slide no. JSM-1055); ♂, Mexico, Tamaulipas, Rancho del Cielo, 6 km NNW Gomez Farias, 3500 ft, Jul 1982, leg. M.A. Solis, USNM (genitalia slide no. JSM-1058, wing slide no. JSM-1439); ♂, Costa Rica, Puntarenas, Monte Verde, 1400 m, 12–15 Jun 1974, leg. W.A. Harding and J.P. Donahue, LACM (genitalia slide Nos. JSM-851); ♀, Costa Rica, Puntarenas, Monte Verde, 1400 m, 12–15 Jun 1974, leg. W.A. Harding and J.P. Donahue, LACM (genitalia slide Nos. JSM-852); ♀, Costa Rica, Puntarenas Prov., Tajo Bella Vista, 35 km NE San Vito nr. Las Alturas, 4700 ft, 20 Mar 1991, leg. J.S. Miller, at light, AMNH (genitalia slide no. JSM-771); ♀, Mexico, Jalapa, USNM (genitalia slide no. JSM-1056, wing slide no. JSM-1057); ♀, Mexico, Tamaulipas, Rancho del Cielo, 6 km NNW Gomez Farias, 3500 ft, Jul 1982, leg. M.A. Solis, USNM (genitalia slide no. JSM-1059).

Chrysoglossa fumosa, new species

Figure 153; plate 15

Diagnosis

Although similar to C. maxima in general appearance (pl. 15), Chrysoglossa fumosa is smaller and drabber. Its olive-brown FW shows only the slightest hint of pattern, including an extremely faint, jagged submarginal line of lighter scales, as well as a few light brown scales near the fascia. The homologous markings in C. maxima are buff colored, standing out in contrast against the dark brown ground color.

Male genitalia in the two taxa differ markedly (figs. 153, 154). Among the numerous differences, the most obvious are that the uncus is much longer in C. fumosa, the processes along the ventral margin of each socius are more prominent, and the aedeagus is narrower, with more delicate cornuti. Unlike the majority of Chrysoglossa species, the vesica in C. fumosa apparently lacks deciduous cornuti.

Description

Male. FW length  =  18.0 mm. Head: Labial palpus, front, occiput and vertex olive brown to light chocolate brown; eye large, bulging outward.

Thorax: Pleuron, legs, patagium, tegula, and dorsum light brown to brown to chocolate brown, no defined markings.

Abdomen: Olive brown.

Forewing: (Dorsal) Ground color uneven olive brown to dark brown, no obvious markings; a small, faint patch of light brown scales within DC; fascia surrounded by light brown scales, fascia itself sparsely scaled; an extremely faint, diffuse, jagged submarginal line of light brown scales extending from Rs1 to tornus. (Ventral) Ground color lighter brown than dorsal surface; no markings present.

Hind wing: (Dorsal) Uniformly light brown to gray-brown, no markings; central area broadly semihyaline. (Ventral) Similar to dorsal surface.

Terminalia: Tg8 gradually tapered distally, dorsum arching upward, anterior margin slightly sinuate, posterior margin broadly rounded; St8 relatively short, narrower posteriorly; anterior margin of St8 with a broad mesal apophysis, its apical margin slightly indented, posterior margin with a deep, U-shaped mesal excavation, posterolateral angles forming long narrow processes on each side of excavation; lateral margins of St8 diffuse; socii/uncus complex large; uncus long, extremely wide at base, abruptly narrowed, then slightly expanded distally; socii large, laterally compressed, drooping downward, ventral margins strongly but irregularly serrate, apices rounded; tegumen narrow, much taller than vinculum; vinculum short, ventral margin of genitalia broadly U-shaped; valva long and wide, inner surface with a sclerotized crest running along valva from base of transtilla to apex; BO relatively small, pleats short, dorsal margin of BO sclerotized, emarginate, arching slightly upward; costa wide; apex broadly spatulate; transtillar arms narrow, arching slightly upward; saccus narrow, U-shaped; aedeagus slightly sinuate, relatively narrow, a delicate hook-shaped process at apex; vesica moderate in length, opening upward, bearing a sparse group of thornlike cornuti in middle, as well as a single enlarged distal cornutus, deciduous cornuti absent.

Female. Unknown.

Etymology

Warren's (1905) name fumosa is apparently derived from the Latin word fumidus, meaning “smoked” or “full of smoke”. It probably refers to the smoky brown FW and HW color of this species.

Distribution

So far, Chrysoglossa fumosa is known exclusively from Chiriquí Province in Panama, but as we learn more about this species, its distribution will almost certainly expand into southern Costa Rica.

Discussion

Warren (1905: 316) decribed fumosa as an aberration of C. maxima Druce, based on a single male at the BMNH. I dissected a MNHN male matching Warren's specimen and collected at its same locality—Chiriquí, Panama. The genitalia of the MNHN example (fig. 153) show that this phenotype is in fact a species distinct from C. maxima (fig. 154). Therefore, Chrysoglossa fumosa as here described as new. Prout (1918) and subsequent authors (Hering, 1925; Bryk, 1930) had relegated this name to being a synonym of maxima. The only examples of C. fumosa of which I am aware are the MNHN male, designated here as the holotype, and Prout's example at the BMNH. Label data on both specimens is scantly. Additional material of C. fumosa is sorely needed.

An undescribed taxon, closely related to both C. fumosa and C. maxima, occurs in Costa Rica. Of the two, its wing pattern and male genitalia exhibit synapomorphies allying it most closely with C. fumosa. The moth is slightly larger than C. fumosa, but smaller than C. maxima. Dissections for the undescribed species are: ♂, Costa Rica, San José, Est. Cuerici, 4.6 km al E de Villa Mills, 2600 m, 21–26 Sep 1995, leg. A. Picado, de Luz, L S 389400 499600, #6307, INBio (genitalia slide no. JSM-1501); ♀, San José, Est. Cuerici, 4.6 km al E de Villa Mills, 2600 m, 22–25 Nov 1995, leg. A.M. Maroto, de Luz, L S 389400 499600, #6458, INBio (genitalia slide no. JSM-1502); ♂, Cartago, P.N. Tapantí, 300 sureste Río Porras, 1660 m, Dec 2002, leg. R. Delgado, de Luz, L N 186550 560600, INBio (genitalia slide no. JSM-1547).

Holotype

Male. Panama: Chiriquí: 1♂, 1919, leg. P. Thierry-Mieg (MNHN; genitalia slide no. JSM-1070). The type is deposited at the MNHN, Paris.

Paratypes

None.

Other Specimens Examined

Panama: Chiriquí: 1♂ (BMNH).

Chrysoglossa maxima (Druce), new combination

Figures 150A–C, 150E, 151, 154; plate 15 [EX]

Polypoetes maximus Druce, 1897: 409, pl. 78, fig. 31.

Type Locality

Panama, Chiriquí.

Type

Syntype ♂ (ZMH).

Discussion

As the name implies, this is one of the largest species in the Dioptinae. Females of C. maxima have a FW length of up to 26.0 mm and males are only slightly smaller. Unlike other Druce types, which are housed at the BMNH, the type of C. maxima, originally in the Staudinger collection, is at the ZMH. Specimens of C. maxima vary in the amount of contrast shown by the transverse whitish FW line and the wavy white submarginal line. However, they can be distinguished from C. fumosa (male FW length  =  18.0–20.0 mm), in their larger size (male FW length  =  20.0–25.0 mm) and their dark brown, rather than olive-brown, FW ground color. The HW of most C. maxima specimens shows a diffuse, whitish central area (pl. 15), whereas in C. fumosa the HW is almost entirely semihyaline gray-brown (pl. 15). Their male genitalia show numerous differences (compare figs. 153 and 154). Chrysoglossa maxima is much more common than C. fumosa, being well represented in most collections of Central American moths.

Distribution

Panama (AMNH, BMNH, USNM); Costa Rica (AMNH, BMNH, CMNH, CUIC, INBio, LACM, USNM); Guatemala (VOB).

Dissected

♂, Panama, Chiriquí, Río Hornito, 800 m, May 1994, leg. C. Snyder, AMNH (genitalia slide no. JSM-1069); ♂, Costa Rica, Juan Viñas, USNM (genitalia slide no. JSM-458); ♂, Costa Rica, Juan Viñas, USNM (genitalia slide no. JSM-1068); ♂, Guatemala, Poptum, Petén, 15–16 Sep 1973, leg. V.O. Becker, VOB (genitalia slide no. JSM-1071); ♀, Costa Rica, Juan Viñas, USNM (genitalia slide no. JSM-1067); ♀, Costa Rica, Puntarenas, 35 km NE San Vito, Las Alturas Field Station, 4800 ft, 29 Jun 1992, leg. C. Snyder & A. Sourakov, at light, AMNH (genitalia slide no. JSM-1546).

Chrysoglossa mexicana (Hering), new combination[not figured]

Tithraustes mexicana Hering, 1925: 514, fig. 69c.

Type Locality

Mexico, Orizaba.

Type

Holotype ♂; not seen (in the Draudt Collection).

Discussion

I know Chrysoglossa mexicana solely from its figure in Hering (1925: fig. 69c), and from the original description. The disposition of the type, supposedly in the Draudt Collection, is unknown. Careful study of Hering's color figure suggests that C. mexicana is either the sister species of C. submaxima (pl. 15), or is synonymous with it. The two were described in subsequent paragraphs on the same page.

At present I am unable to resolve this moth's identity. I have seen no verified material. There is nothing in Hering's description of C. mexicana setting it apart from C. submaxima, other than their widely divergent type localities—Mexico (mexicana) and Panama (submaxima). He mentioned a “very much shortened” male FW discal cell in mexicana, but that trait occurs in submaxima, phaethon, and norburyi as well. Resolution of this issue must await discovery and dissection of the mexicana type.

Distribution

Mexico.

Dissected

None.

Chrysoglossa norburyi, new species

Figures 150D, 155, 156; plates 15, 38H

Diagnosis

Adults of Chrysoglossa norburyi are nearly impossible to distinguish from those of C. phaethon (pl. 15). In collections, the two have been treated as a single taxon—phaethon. However, morphological differences between their genitalia, used in the species key (above), are dramatic. The most distinctive character for separation occurs in females; the surface of St7 is deeply rugose in C. norburyi, but smooth in C. phaethon. This trait can be observed in pinned specimens by brushing the scales from the apex of the abdomen. Dissections show additional female differences, involving signum shape and the basal sclerites of the corpus bursae (see species key above).

Unfortunately, dissection is required to separate males. In males of C. norburyi, the costa of the valva ends in a simple point (fig. 155A), whereas in C. phaethon the costa ends in a wide, broadly sclerotized, cup-shaped process (fig. 157A), curving inward. The vesica of the aedeagus in C. phaethon (fig. 157C) bears three types of cornuti—a single large distal cornutus, a few spinelike basal ones, and a mass of deciduous cornuti. In C. norburyi (fig. 155B) only deciduous cornuti occur.

I am much less confident about proposing coloration characters for separating the two taxa. I provide the following, with considerable reservation: First, the FW and HW ground color is dark slate gray in C. norburyi (pl. 15), whereas in C. phaethon it tends to be more brown (pl. 15). Furthermore, the legs and pleural regions of the thorax are mostly white in C. norburyi, but more cream colored in C. phaethon. However, these differences can be employed only when both taxa are available in series, and even then they are far from reliable.

Description

Male. Forewing length  =  17.0–18.5 mm. Head (fig. 150D): Labial palpus moderately long, upturned to middle of front; Lp1 orange-yellow, clothed with short scales, fringed below with a ridge of longer scales; Lp2 relatively short, basal one-fourth light yellow, distal three-fourths gray-brown; Lp3 fairly long, with longer scales forming a point at apex; front clothed with bristlelike scales, pointing dorsomedially, scales gray-brown in central area, white to whitish brown laterally; occiput whitish brown in dorsal half, white below; eye large, bulging; vertex gray-brown with a few white scales at antennal bases; antenna widely bipectinate; scape and dorsum of antennal shaft gray-brown.

Thorax: Forecoxa light gray-brown laterally, white in central area, meso- and metacoxae completely white; femur and tibia, including spurs, light gray-brown on outer surfaces, white on inner ones; tarsus completely gray-brown; pleuron clothed with long, white scales; patagium gray-brown; tegula small, dorsal arm somewhat short; tegula with orange scales at base, margins fringed with long, gray-brown scales; dorsum completely covered with gray-brown scales; tympanum large, cavity deep; tympanal membrane large, ovoid, oriented horizontally.

Forewing: (Dorsal) Ground color evenly slate gray-brown (pl. 15); DC thinly scaled, extremely short, less than one-fourth the FW length; stridulatory organ present, comprising a quadrate, semitransparent fascia beyond DC, extending from radial sector anteriorly to M3+CuA1 posteriorly; veins M1 and M2 dark gray as they run through fascia; a second ovoid, semitransparent fascia near wing apex, this extending from Rs2+Rs3 anteriorly to M2 posteriorly, veins Rs4 and M1 dark as they run through it. (Ventral) Similar to dorsal surface except ground color slightly lighter slate gray; the stridulatory fascia lightly dusted with white scales; the subapical fascia white, not semitransparent.

Hind wing: (Dorsal) Outer margin with a wide, dark slate-gray band extending from apex to tornus (pl. 15), band narrower at fork of M3 and CuA1; central area shiny white, semitransparent, dusted with gray scales along posterior margin; white central area narrower near base, slightly angled near base of CuA2, teardrop shaped distally; anal margin broadly light gray to slate gray; anterior margin light gray. (Ventral) Similar to dorsal surface, but marginal band lighter gray and anal margin evenly dusted with white scales.

Abdomen: Slate gray above, a thin white longitudinal stripe along pleuron, venter immaculate white.

Terminalia (fig. 155A–C, E): Lateral margins of Tg8 roughly parallel, tergum relatively narrow; anterior margin of Tg8 with a pair of small processes on either side of midline; posterior margin simple, membrane beyond margin with numerous longitudinal wrinkles; St8 wider than Tg8, sides roughly parallel in anterior third, then tapered distally; anterior margin of St8 with a short, broad mesal apophysis, lateral angles of margin slightly produced; posterior margin of S8 with a large, triangular mesal excavation extending forward to more than halfway up sternum; membrane within excavation crenulate anteriorly, then with fine longitudinal wrinkles; anterior third of St8 more heavily sclerotized than rest of St8; uncus moderately long, digitate, apex acute; socii flattened and bladelike, sharply upturned to cover sides of uncus, lateral surfaces of socii setose; base of uncus/socii complex widened; tegumen moderately wide, sides parallel, taller than vinculum; vinculum concave, much wider than tegumen; saccus wide, mesal portion extending upward to form a triangular plate covering valva bases; ventral margin of saccus with a wedge shaped mesal excavation; juxta apparently absent; valva fairly long, gradually tapering toward apex; inner surface in distal half covered with a mat of fine setae; BO relatively small, but androconia well developed, long, hairlike; lateral margin of valva in distal half membranous, finely crenulate; costa broad, concave, narrow at base, then widened toward apex; valva apex tapered, sclerotized portion small, inside surface of apex setose; transtillar arms long, thin, arched upward from base, then bent sharply downward at midline, meeting to form a small, concave sclerite; aedeagus moderately long, wide, arched upward near middle, sides parallel; apex of aedeagus with a small, sharp flange along outer margin, forming a small ventral process; vesica moderately large; middle section covered with caltrop cornuti; all spines of cornuti short, roughly equal in length; no large, spinelike distal cornutus (present in phaethon).

Female (pl. 15): Forewing length 18.0–21.0 mm. Labial palpus shorter than male, porrect; antenna bipectinate, rami fairly long, but not as long as male; FW more elongate than male, ground color darker slate gray; DC longer than male, almost one-half FW length; fascia beyond DC faint; subapical fascia larger than male, extending from fork of Rs2+Rs3 anteriorly to M3 posteriorly; HW broader than male; other wing and body features similar to male.

Terminalia (fig. 155D): CB large, broad, surface covered with transverse, crenulate wrinkles; DS arising from CB dorsally near base; attachment point of DS to CB expanded; CB bearing two, infolded sclerites in addition to the signum, a dorsal one in basal third, and a lateral one on left side in basal fourth, the internal surfaces of these bearing thornlike processes; an ovoid signum, with a seam along midline, located near anterior portion of CB on right side, its surface finely dentate; DB short, sclerotized, moderately wide, roughly funnel shaped, dorsal surface depressed downward; PA slightly triangular; distal margins evenly covered with long setae; AA and PP short, wide at base, then sharply tapered.

Etymology

Chrysoglossa norburyi is named in recognition of Maria Norbury, who gave inspirational support for rainforest conservation in Area de Conservación Guanacaste, where this species lives.

Distribution

Because it is difficult to separate C. norburyi and C. phaethon without dissection, establishing their respective distributions based on superficial study of museum material is problematic. Genitalia dissections suggest that C. norburyi is quite broadly distributed within Costa Rica (fig. 156). Confirmed examples occur on both slopes of the Cordillera Central, from Volcán Orosí (Guanacaste Province) in the north to Parque National Tapantí (Cartago Province) in the south. The type locality, Estación Pitilla (pl. 48A), is in the Caribbean drainage. Chrysoglossa norburyi has been collected at elevations between 700 and 1400 meters.

It will be interesting to further explore the distribution of C. norburyi. It seems to be one of the few Central American dioptines known to occur on both the Pacific and Caribbean slopes. In most other cases, taxa once thought to be widespread are revealed to be at least two endemics, occurring on opposite sides of the Cordillera Central. Additional collecting, along with numerous genital dissections, will be required to further refine the distributional hypothesis for C. norburyi.

Biology

Chrysoglossa norburyi was reared on Alfaroa guanacastensis (Juglandaceae) at Pitilla, by Calixto Moraga and Petrona Ríos of the ACG caterpillar research group. The caterpillars (pl. 38H) show coloring similar to larvae of Nebulosa (pls. 38I, 38K).

Chrysoglossa norburyi is the only member of the Dioptinae whose larvae have been found feeding on Juglandaceae (table 4). As is noted in the general discussion (Host Plants), this association is reminiscent of more northern members of the Notodontidae, such as Datana integerrima (Phalerinae), a species from the northeastern United States (see Wagner, 2005).

Discussion

As so often seems to occur in the Dioptinae, C. norburyi, the newly described species, appears to be more common and more widespread than the taxon with which it had always been confused, C. phaethon. The latter is restricted to the vicinity of Turrialba, in south-central Costa Rica on the Pacific side of the Cordillera Central (fig. 156). This locale, extremely close to Tapantí, an established locality for C. norburyi (fig. 156), potentially puts the two species in sympatry.

Although the wing-pattern similarities of C. norburyi and C. phaethon render them essentially indistinguishable, characters of the male and female genitalia suggest that C. norburyi is more closely related to C. submaxima than it is to C. phaethon.

Holotype

Male. Costa Rica: Guanacaste: Estación Pitilla, 9 km S Santa Cecilia, 700 m, L_N_330200, 380200, Mar 1995, leg. P. Ríos, INBio #4359 (genitalia slide no. JSM-1363). The type is deposited at INBio, Heredia, Costa Rica.

Paratypes

Costa Rica: Guanacaste: Estación Pitilla, 9 km S Santa Cecilia, 700 m, L_N_330200, 380200, 1♀, Oct 1993, leg. C. Moraga, #2392 (INBio; genitalia slide no. JSM-816), 1♂, 1♀, Oct 1994, leg. C. Moraga, INBio #3262, 1♂, Mar 1995, leg. P. Ríos, INBio #4359 (genitalia slide no. JSM-1363), 1♀, 4–24 Apr 1995, leg. M. Moraga, INBio #4627, 1♂, 4 Feb 1989, GNP Biodiversity Survey; 1♀, Area de Conservación Guanacaste, Sector Cacao, Casa Fran, 1140 m, 10.93663, −85.46685, 5 Mar 1997, leg. C. Moraga, 97-SRNP-752 (INBio); 1♀, Sector Cacao, Sendero Toma Agua, 1140 m, 10.92847, −85.46680, leg. D. Garcia, 04-SRNP-35227 (INBio; genitalia slide no. JSM-1364). Alajuela: Area de Conservación Guanacaste, Sector San Cristobal, Bosque Trampa Malaise, 815 m, 10.86280, −85.38460, 25 May 2001, leg. C. Cano, 01-SRNP-1873 (INBio).

Other Specimens Examined

Costa Rica: Guanacaste: 1♂, Derrumbe, Estación Mengo, W side Volcán Cacao, 1400 m, 5 Jun 1988, leg. Janzen & Hallwachs (INBio); 1♂, 11 Jul 1988, leg. Janzen & Hallwachs (INBio); 1♂, Estación Cacao, 2 km SW del Cerro Cacao, 1000–1400 m, L_N_323100_375800, 30 Aug 1995, leg. C. Moraga, de Luz, #6410 (INBio; genitalia slide no. JSM-1780); 1♀, 4 km E Casetilla, Rincon Natl. Pk., 750 m, 23 Feb 1982, leg. D.H. Janzen & W. Hallwachs (INBio); 1♀, Had. Santa María, 750 m, Sep 1996, leg. D. Briceño, A. Solis, E. Araya, F. A. Quesada, C. Moraga, #8416 (INBio). Cartago: 1♂, Tapantí, Río Grande de Orosí, 9°46′ × 83°50′, 1300–1400 m, 17 Nov 1982, leg. D.H. Janzen & W. Hallwachs (INBio; genitalia slide no. JSM-815); 1♀, Paraiso, Parque National Tapantí, Est. Queb. Segundo, 100 N 100 W Inicio de Send. La Pava, 1400 m, Jul 1999, leg. R. Delgado, de Luz, #53757 (INBio).

Dissected

3♂♂; 2♀♀.

Chrysoglossa phaethon (Schaus), new combination

Figures 156, 157; plate 15 [EX]

Tithraustes phaethon Schaus, 1912: 432.

Type Locality

Costa Rica, Sitio.

Type

Syntype ♂ (USNM type no. 17614).

Discussion

As is documented above, at least two cryptic Chrysoglossa species occur in Costa Rica—C. phaethon and C. norburyi, sp. nov. In collections, all material has historically been identified as phaethon. Males of the two are impossible to separate until their genitalia are examined, whereupon the differences are dramatic (compare figs. 155, 157). Females can be distinguished by examining the surface of St7, which is smooth in C. phaethon but coarsely rugose in C. norburyi. Based on my dissections, confirmed material of C. phaethon is restricted to a small area on the south-facing slopes of the Irazu and Turrialba volcanoes (fig. 156) in central Costa Rica. The species has been recorded from three sites in Cartago Province–Sitio, the type locality (1250 m), as well as the towns of Turrialba and Juan Viñas, slightly further down slope.

Distribution

Costa Rica (AMNH, BMNH, INBio, USNM, VOB).

Dissected

Syntype ♂ (genitalia slide no. JSM-1080); ♂, Costa Rica, Cartago, Sitio, May, BMNH (genitalia slide no. JSM-229); ♂, Costa Rica, Cartago, Turrialba, 600 m, 5 Aug 1971, leg. V.O. Becker, VOB (genitalia slide no. JSM-1371); ♀, Costa Rica, Cartago, Sitio, May, BMNH (genitalia slide no. JSM-230).

Chrysoglossa submaxima (Hering), new combination

Figure 158; plate 15

Tithraustes submaxima Hering, 1925: 514, fig. 69h.

Type Locality

Panama, Chiriquí.

Type

Holotype ♀ (ZMH).

Discussion

The wing shape of C. submaxima resembles that of C. phaethon, C. norburyi, and C. mexicana (pl. 15). In addition, all four show a contrasting white central area of the HW with a dark gray outer margin. Of these, based on similarities of FW pattern, C. submaxima is most closely related to C. mexicana. Unfortunately, as was discussed above, I have not been able to establish the identity of C. mexicana. Chrysoglossa submaxima can easily be separated from C. phaethon and C. norburyi because its FW is olive to reddish brown, rather than being uniformly gray-brown as in the other two, and the FW veins are lined with light yellowish scales, rather than being concolorous. Genital similarities suggest that C. submaxima (fig. 158) and C. phaethon (fig. 157) are more closely related than either is to C. norburyi (fig. 155). Chrysoglossa submaxima, is rare, known from fewer than a dozen specimens, but appears to be quite broadly distributed. The species has been collected from Panama north to Nicaragua.

Distribution

Panama (ZMH); Costa Rica (AMNH, INBio, SMNS); Nicaragua (CMNH).

Dissected

Holotype ♀ (JSM-1769); ♂, Costa Rica, Puntarenas, R. B. Monteverde, 1520 m, Nov 1993, leg. N. Obando, L N 253250 449700, #2478, INBio (genitalia slide no. JSM-780).

NEBULOSA MILLER, new genus

Figures 159Figure 160Figure 161Figure 162Figure 163Figure 164Figure 165Figure 166Figure 167Figure 168Figure 169Figure 170Figure 171Figure 172Figure 173Figure 174Figure 175Figure 176Figure 177Figure 178Figure 179Figure 180Figure 181Figure 182Figure 183Figure 184Figure 185186; plates 16, 17; plate 38G, I–L

Type species: Nebulosa elicioi, sp. nov.

Figure 159

Nebulosa heads (♂♂). A, N. huacamayensis, sp. nov., lateral view; B, N. huacamayensis, lateral view; C, N. huacamayensis, frontal view; D, N. huacamayensis, posterior view; E, N. fulvipalpis, lateral view; F, N. fulvipalpis, frontal view; G, N. fulvipalpis, posterior view; H, N. nasor, lateral view; I, N. nasor, frontal view; J, N. nasor, posterior view; K, N. plataea, lateral view; L, N. hermani, sp. nov., lateral view (illustration by J.S. Miller).

i0003-0090-321-1-1-f159.gif

Figure 160

Scanning electron micrographs of Nebulosa (♂♂). A, head of N. yanayacu, lateral view; B, head of N. yanayacu, frontal view; C, antenna of N. yanayacu, ventral view; D, single flagellomere of N. yanayacu, ventral view; E, single flagellomere of N. elicioi, ventrolateral view; F, metathoracic tympanum of N. elicioi, lateral view (anterior at left).

i0003-0090-321-1-1-f160.gif

Figure 161

Scanning electron micrographs of Nebulosa yanayacu ♂. A, FW stridulatory organ, dorsal surface; B, scale from FW stridulatory organ, dorsal surface; C, FW stridulatory organ (ventral surface), showing veins M1 and M2 protruding from wing surface; D, scales in stridulatory organ, ventral surface; E, a single scale from D; F, typical wing scales from FW ventral surface.

i0003-0090-321-1-1-f161.gif

Figure 162

Nebulosa morphology (♂♂). A, N. huacamayensis, sp. nov., wings; B, N. fulvipalpis tegula; C, N. aliena wings; D, N. hermani, sp. nov., wings; E, N. plataea wings; F, N. sirenia wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f162.gif

Figure 163

Holotype ♂ genitalia of Nebulosa cistrinoides (JSM-1051). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f163.gif

Figure 164

Genitalia of Nebulosa creon (♂ JSM-1052, ♀ JSM-1493). A, ♂ genitalia; B, aedeagus; C, ♀ genitalia; D, ♂ Tg8; E, ♂ St8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f164.gif

Figure 165

Genitalia of Nebulosa delicata, sp. nov. (♂ JSM-417, ♀ JSM-759). A, ♂ genitalia; B, ♂ St8; C, ♀ genitalia; D, aedeagus; E, ♂ Tg8.

i0003-0090-321-1-1-f165.gif

Figure 166

Ecuador, showing the known distributions of Nebulosa delicata, sp. nov., and N. elicioi, sp. nov.

i0003-0090-321-1-1-f166.gif

Figure 167

Genitalia of Nebulosa elicioi, sp. nov. (♂ JSM-1324, ♀ JSM-1332). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f167.gif

Figure 168

Genitalia of Nebulosa erymas (♂ JSM-448, ♀ JSM-533). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f168.gif

Figure 169

Genitalia of Nebulosa huacamayensis, sp. nov. (♂ JSM-1317, ♀ JSM-1552). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f169.gif

Figure 170

Ecuador, showing the known distributions of Nebulosa huacamayensis, sp. nov., and N. yanayacu, sp. nov.

i0003-0090-321-1-1-f170.gif

Figure 171

Genitalia of Nebulosa rabae, sp. nov. (JSM-1302, ♀ JSM-1461). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f171.gif

Figure 172

Ecuador, showing the known distributions of Nebulosa rabae, sp. nov., and N. rawlinsi, sp. nov.

i0003-0090-321-1-1-f172.gif

Figure 173

Holotype ♂ genitalia of Nebulosa rawlinsi, sp. nov. (JSM-903). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f173.gif

Figure 174

Male genitalia of Nebulosa plataea (JSM-1609). A, genitalia; B, Tg8; C, St8; D, aedeagus.

i0003-0090-321-1-1-f174.gif

Figure 175

Genitalia of Nebulosa ocellata, sp. nov. (holotype ♂ JSM-1608, paratype ♀ JSM-1610). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, aedeagus; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f175.gif

Figure 176

Peru, Ecuador, and northern Bolivia, showing the known distributions of Nebulosa ocellata, sp. nov., and N. plataea (Druce).

i0003-0090-321-1-1-f176.gif

Figure 177

Genitalia of Nebulosa grimaldii, sp. nov. (paratype ♂ JSM-891, paratype ♀ JSM-1653). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ Tg7; F, ♀ genitalia; G, ♀ St7.

i0003-0090-321-1-1-f177.gif

Figure 178

Genitalia of Nebulosa hermani, sp. nov. (paratype ♂ JSM-728, paratype ♀ JSM-1500). A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, aedeagus; E, ♀ in ventrolateral view (illustration by J.S. Miller).

i0003-0090-321-1-1-f178.gif

Figure 179

Ecuador, showing the known distributions of Nebulosa grimaldii, sp. nov., and N. hermani, sp. nov.

i0003-0090-321-1-1-f179.gif

Figure 180

Genitalia of Nebulosa fulvipalpis (♂ JSM-457, ♀ JSM-462). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f180.gif

Figure 181

Genitalia of Nebulosa tiznon (holotype ♂ JSM-1065, ♀ JSM-1685). A, ♂ genitalia; B, ♀ genitalia; C, ♂ St8; D, ♂ Tg8; E, aedeagus; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f181.gif

Figure 182

Genitalia of Nebulosa yanayacu, sp. nov. (♂ JSM-1498, ♀ JSM-727). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia.

i0003-0090-321-1-1-f182.gif

Figure 183

Genitalia of Nebulosa albitumida (holotype ♂ JSM-1036) and N. nasor (♀ JSM-451). A, N. albitumida ♂; B, N. albitumida ♂ St8; C, N. albitumida ♂ Tg8; D, N. albitumida aedeagus; E, N. nasor ♀; F, N. nasor ♀ Tg7; G, N. nasor ♀ St7.

i0003-0090-321-1-1-f183.gif

Figure 184

Male genitalia of Nebulosa sirenia (JSM-1039). A, genitalia; B, St8; C, aedeagus; D, Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f184.gif

Figure 185

Genitalia of Nebulosa (Halesius Group). A, ♂ of N. halesius (JSM-1053); B, ♀ of N. halesius (JSM-454); C, ♂ St8 of N. halesius; D, aedeagus of N. halesius; E, ♂ Tg8 of N. halesius; F, aedeagus of N. rudicula, sp. nov. (paratype ♂ JSM-1305); G, ♂ St8 of N. rudicula; H, ♂ of N. rudicula; I, ♂ Tg8 of N. rudicula.

i0003-0090-321-1-1-f185.gif

Figure 186

Costa Rica, showing the known distribution of Nebulosa rudicula, sp. nov.

i0003-0090-321-1-1-f186.gif

Diagnosis

The genus Nebulosa spans a broad range of wing patterns and body sizes (pls. 16, 17); FW lengths range from 10.0 mm (N. delicata) to 20.0 mm (N. albitumida). None is brightly colored. The vast majority of Nebulosa species show a pattern combination of brown and white. Rarely, the wings are mustard yellow (N. rabae and N. rawlinsi, pl. 16). The FW ground color is usually light brown to dark brown, and the FW veins are invariably lined with contrasting, lighter-colored scales. Often, there is a white transverse band or spot beyond the DC (e.g., N. elicioi, pl. 16). Two types of small, secondary FW spots occur—an apical one near the base of veins Rs2–Rs4 (e.g., N. huacamayensis and N. aliena, pl. 16), or one near the wing's outer margin straddling M2 (e.g., N. yanayacu, pl. 16; N. hermani, pl. 17). These spots range in color, from white to orange, and are expressed on both wing surfaces. In the majority of species, the HW is white with a broad marginal band of dark brown. Males of Nebulosa possess a FW stridulatory organ (figs. 161, 162). The antennae are bipectinate in both sexes, with the rami long in males (fig. 160C–E), but short in females.

One of the most reliable traits for recognizing Nebulosa species involves the female terminalia. In all taxa, the lateral margins of St7 are greatly expanded (figs. 164G, 169G, 177G, 181G), wrapping upward to touch Tg7. These lateral expansions often form wide, sclerotized, scaleless pockets. Female Tg7 is large, usually narrower posteriorly (figs. 164F, 177F, 181F), and often bears sclerotized dorsal depressions. Tergum 8 is relatively small, but is sclerotized and narrow (e.g., fig. 171E), often protruding at the abdominal apex. Most of these female characters can be observed in intact, pinned specimens; dissection is not required. Unfortunately, throughout Nebulosa, females are much less common than males. Females of Pseudoricia also exhibit scaleless lateral areas on St7, but in that genus the scaleless regions form narrow, longitudinal bands, rather than broad pockets. Numerous morphological differences make these two genera impossible to confuse (see key to genera).

Wing patterns in Nebulosa often resemble those of Polypoetes, but the two genera are easily separable by other characters. For example, Nebulosa species possess short, delicate labial palpi (fig. 159) and usually a short FW DC, bearing a stridulatory organ in males (e.g., fig. 162A, C). In contrast, the vast majority of Polypoetes have greatly elongate labial palpi (e.g., fig. 90A, D), the FW stridulatory organ is absent, and the DC is greater than one-half the wing length (fig. 90G, I).

Description

Male. FW length  =  9.0–20.0 mm. Head (figs. 159, 160A–E): Labial palpus short, curving upward to immediately above clypeus, apex not extending above lower third of front; Lp1 moderate in length, curving upward, with a loose fringe of long scales below; Lp2 short, usually as short as or shorter than Lp1, occasionally slightly longer than Lp1 (e.g., albitumida, rudicula), more tightly scaled than Lp1, with a short fringe below, often with a few longer scales at apex; Lp3 short, bullet shaped, scales at apex longer, forming a point; clypeus narrow, surface rugose; scales of front long, longest above, pointing dorsomedially, scales on either side of midline coming together to form a dorsal tuft extending beyond antennal bases; scales on lateral margins of front usually contrasting in color with mesal scales; eye usually large and rounded, bulging outward, completely surrounded by scales, gena absent, eye occasionally small (e.g., N. mirma, N. fulvipalpis), gena then narrow; postgena narrow; scales of vertex long or moderately long, semierect, mostly pointing anteriorly; antenna bipectinate, rami long and narrow, usually extremely so (Hermani, Albitumida, Halesius and Fulvipalpis groups); each ramus lacking a dorsal subapical seta (found in Chrysoglossa and others); flagellomeres elongate.

Thorax (figs. 160F, 162B): Epiphysis long and narrow, at least four-fifths length of tibia, extending to apex of tibia or slightly beyond; tegula moderately long, greater than one-half but shorter than two-thirds length of mesoscutum, distal portion wide, apex broad, ventral portion short, somewhat blunt at apex, the two portions weakly divided by a short transverse suture; metathoracic tympanum variable in size, cavity shallow; tympanal membrane ovoid, ranging from small (Fulvipalpis Group) to large (Hermani Group), usually moderate in size (Nervosa, Albitumida, and Halesius groups), membrane facing posterolaterally.

Forewing (fig. 162; pls. 16, 17): Broad and triangular, occasionally elongate (Fulvipalpis, Hermani groups); vein Rs1 stalked with Rs2–Rs4; Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC near anterolateral angle, separate from base of Rs1–Rs4, UDC moderately long; stridulatory organ well developed, bases of M1 and M2 swollen, with a short ventral fold between them; DC variable in length, usually one-half or less the FW length, occasionally less than one-third, Hermani Group with DC greater than one-half FW length; veins M3 and CuA1 stalked, separate in Plataea Group; pattern variable, ground color light brown to dark blackish brown or dark gray; veins lined with yellow, orange or light brown scales; many species with a white transverse bar of variable length beyond DC, extending from Sc to CuA2 (Albitumida Group), sometimes beyond (e.g., N. erymas, N. elicioi); Hermani, Halesius, and Fulvipalpis groups with a small, light-colored, ovoid spot near outer margin straddling M2; many Nervosa Group species with a small, yellow-orange or white subapical spot.

Hind wing (fig. 162; pls. 16, 17): Full, outer margin rounded; M3 and CuA1 long stalked; central area white, often semihyaline, outer margin with a brown, dark brown, or dark gray band of variable width and length; in a few species (e.g., N. fulvipalpis), central area concolorous with outer band.

Abdomen: Short or moderately long, often wider in distal third, apex often truncate (e.g., Albitumida Group), sometimes tapered (Hermani Group); many species with Tg8 much longer than St8; dorsum light brown to dark brown or dark gray, venter whitish.

Terminalia (figs. 163; 164A, B, D, E; 165A, B, D, E; 167A–D; 168A–D; 169A–D; 171A–D; 173; 174; 175A–D; 177A–D; 178A–D; 180A–D; 181A, C–E; 182A–D; 183A–D; 184; 185A, C–I): Tg8 narrower and much longer than Tg7, longer than St8, anterior margin simple or with two extremely short apodemes on either side of midline; lateral margins of Tg8 abruptly excavated in distal one-fourth to one-third (except Halesius Group), forming a long, narrow mesal process on posterior margin; apex of Tg8 central process highly variable in structure, sometimes with a small V- or U-shaped mesal excavation (Albitumida Group; some Nervosa Group), occasionally convex (e.g., N. albitumida), rarely coarsely spiculate (e.g., N. hermani); St8 extremely wide, short, anterior margin usually simple, sometimes with a short, broad mesal apodeme (Albitumida and Fulvipalpis groups); lateral margins of St8 convex, often greatly expanded, bearing curved, hooklike processes (Nervosa Group), or earlike structures (Albitumida Group); posterior margin of St8 with a deep U-shaped mesal excavation, this excavation sometimes extremely wide, its posterolateral angles forming thin processes; socii/uncus complex highly variable in size and shape, either extremely large (Albitumida, Halesius, and Fulvipalpis groups), or extremely small (Nervosa and Hermani groups); uncus either greatly elongate and wide at base with shape of apex variable (Albitumida, Halesius, and Fulvipalpis groups), or uncus extremely short, forming a downcurved hook (Nervosa and Hermani groups); socii often greatly elongate, curving sharply upward well beyond apex of uncus, apices acute; Nervosa and Hermani groups with socii short, curved upward, almost meeting apex of uncus; tegumen taller than vinculum, often expanded ventrally in lower third above junction of valva, then narrowing above toward attachment of socii/uncus complex; vinculum narrow; lower portion of genitalia wide, ventral margin simple or slightly concave; saccus wide, its dorsal margin forming a triangular sclerite between valva bases; valva moderately long, narrow, sometimes sclerotized; BO variable in size but never large, occupying less than one-half of valva, sometimes extremely small or absent (Plataea, Albitumida, Halesius groups); costa of valva usually wide, sometimes narrow; apex of valva gradually tapered, occasionally forming a wide, transverse structure (e.g., N. sirenia, N. creon); arms of transtilla wide, often swollen (e.g., Plataea Group), arching upward and meeting at midline to form a narrow sclerite of varying shape; transtillar arms in Albitumida Group forming a huge, Y-shaped dorsal structure; aedeagus usually short and narrow, occasionally elongate (Albitumida Group), always widened at base; apex of aedeagus tapered to a small ventral point, dorsum occasionally with a greatly elongate process, venter rarely with a large, blunt process; vesica variable in size and shape, often moderately long, never longer than aedeagus; cornuti spinelike (N. ocellata), short and thornlike, or sometimes extremely small (e.g., N. huacamayensis, N. rudicula), rarely absent (N. delicata); occasionally a single cornutus present near base of vesica (Nervosa, Albitumida, and Fulvipalpis groups).

Female. FW length  =  11.0–22.0 mm. Head and thorax similar to male, except: labial palpus shorter and thinner, barely extending upward past clypeus; antenna bipectinate, rami short and club shaped; wings broader, slightly longer, ground color often lighter in tone, markings with less contrast; frenulum comprising 4–6 bristles.

Abdomen: Much wider than male.

Terminalia (figs. 164C, F, G; 165C; 167E; 168E; 169E–G; 171E; 175E; 177E–G; 178E; 180E; 181B, F, G; 182E): Tg7 long, much longer than Tg6, wide anteriorly, tapering posteriorly, lateral margins often excavated, anterior margin simple, posterior margin convex or simple; dorsum of Tg7 often heavily sclerotized, with a pair of large, shallow pockets (e.g., N. mirma, N. rabae); St7 extremely wide, expanded laterally, anterior margin simple, posterior margin with an extremely wide, U-shaped mesal excavation to accommodate ostium, which is located anteriorly, sometimes almost at posterior margin of St6; posterolateral angles of St7 forming huge, rounded, scaleless expansions, these wrapping upward to meet Tg7, expansions often with shallow pockets; surface of St7 often heavily sclerotized, sometimes with a transverse ridge or groove, surface rarely finely spiculate (Halesius Group); Tg8 long or moderately so, forming a rooflike structure over PA; Tg8 variable in width, ranging from extremely narrow (e.g., N. albitumida, N. rabae) to extremely wide (Halesius Group); AA long and thin, sometimes extremely so (Nervosa Group); A8 pleuron completely membranous; PP long and thin, straight or rarely slightly upcurved (Albitumida Group), often heavily sclerotized at base, PP occasionally short (e.g., N. elicioi); PA moderate in size, membranous, posterior margin gently rounded or quadrate (e.g., N. rabae, N. elicioi); DB short, cylindrical, sclerotized; ostium forming a large, wide, funnel-shaped structure, opening displaced anteriorly, sometimes greatly so; PVP variable in length and width, sometimes expanded posteriorly to form a long, wide plate (e.g., N. hermani, N. albitumida); CB small to moderately large, almost round, abruptly constricted to form a short section anterior to DB; CB completely membranous (e.g., N. elicioi), occasionally with large sclerotized areas (e.g., N. rabae), or rarely with a spiculate area (N. albitumida) near base; signum located on right side of CB in basal third, usually roughly figure-eight shaped, internal surface coarsely dentate, signum occasionally extremely small (e.g., N. elicioi) or absent (e.g., Halesius Group); DS arising dorsally at junction of DB and narrow portion of CB.

Etymology

The name Nebulosa, from the Latin word nebula for “cloud”, refers to the cloud forest habitats in Central and South America where these moths live.

Distribution

Nebulosa species occur along both sides of the Central Cordillera in Central America, from Mexico south to Panama. In South America, they occur on the western and eastern slopes of the Andes, from Colombia south to Bolivia. None is known from Brazil or the Guyana Shield, and none has so far been recorded from the Venezuelan Andes. Most species occur within a relatively narrow altitudinal range; the vast majority has been collected at elevations between 1500 m and 2500 m. Some taxa occasionally range lower. For example, Nebulosa delicata, sp. nov. (Nervosa Group), from western Ecuador, has been collected as low as 475 m and as high as 1250 m. Nebulosa sirenia (Albitumida Group) is known from 750 m in eastern Bolivia. The highest recorded elevation for Nebulosa is a BMNH specimen of N. inaequiplaga (Fulvipalpis Group), collected by Fassl at 3200 m on Monte Tolima, in central Colombia.

Biology

Hostpants are known for four Nebulosa species (table 4)—three in the Nervosa Group, and one in the Fulvipalpis Group. Host plants for the Nervosa Group comprise a disparate assemblage of genera: Perrotettia (Celastraceae) and Cestrum (Solanaceae), recorded for N. erymas, belong in far-flung parts of the dicot classification (Soltis et al., 2005); the newly discovered host plants of N. huacamayensis and N. elicioiCasearia (Salicaceae) and Siparuna (Siparunaceae)—are even further afield. The Salicaceae are currently placed in the Malpighiales, along with Violaceae, Passifloraceae, Achariaceae and 24 additional families, while the Siparunaceae belong in the primitive angiosperm order Laurales (Soltis et al., 2005).

In 2005, larvae of Nebulosa yanayacu (Fulvipalpis Group), an eastern Ecuadorian endemic, were discovered on Tibouchina lepiota (Melastomataceae). Interestingly, this is the second dioptine genus recorded from Melastomataceae, Erbessa being the other (table 4). However, my phylogeny for the Dioptinae (figs. 3, 7) shows conclusively that this plant association arose twice within the subfamily. With host records available for only four species, and those providing essentially no discernible pattern, we seem to be a long way from understanding the evolution of host-plant associations in Nebulosa.

Nebulosa species are readily attracted to lights, but can occasionally be seen flying in the day. Nebulosa creon (Nervosa Group), from Costa Rican cloud forests, has been captured during the day flying in dense fog. I have collected males and females of Nebulosa hermani (Hermani Group), at approximately 2200 meters in the western Andes of Ecuador, flying along gravel roadsides as well as sitting, probably feeding, on Asteraceae flowers. The moths seem to fly most commonly in the morning between 8 and 10 a.m., as well as in the late afternoon (after 4 p.m.). During that time period, Nebulosa yanayacu (Fulvipalpis Group), from the eastern slope of the Ecuadorian Andes, can be seen in great numbers, flying along gravel roads approximately 3–4 m above the ground, or fluttering over their host plant (pl. 44A, B, D) in pastures and other disturbed habitats (pl. 43D).

Discussion

Nebulosa currently contains 30 species assigned to six species groups. Its sister genus is Chrysoglossa (fig. 7). The monophyly of Nebulosa (Bremer support  =  9) and most of its species groups (see fig. 2) is strongly supported. However, relationships among subgroups are poorly understood. Taken together, Nebulosa spans a broad morphological range. For example, an unusually wide diversity of male and female genital structure occurs, and homology assessments can be difficult. Additional characters, from DNA or immature stages, may provide the information needed to understand phylogenetic relationships within this genus.

Earlier authors (Prout, 1918; Hering, 1925) placed most of the described species now assigned to Nebulosa in the genus Tithraustes, at that time a wildly polyphyletic group (fig. 354; and see Discussion: Classification) containing 42 species. In this paper, Tithraustes totals only 10 species (appendix 2). The remaining taxa formerly included there have been dispersed to five genera, Nebulosa one of them.

Many Nebulosa species await description. For example, the Hermani Group currently contains two species (appendix 2), both of which are described here as new. Study of recently collected material (BMNH, PTC) reveals two additional undescribed members of the clade, both from Ecuador. One (JSM-1549), a distinctive dark species from Imbabura on the western slope (1750 m), is known from a single BMNH specimen collected by A. Spalding in 1992. Claude Lamaire and Paul Thiaucourt collected a single example of the second taxon (JSM-1550) near Gualaceo, Morona-Santiago province (2200 m), in 1983. When the Hermani Group has been properly sampled and subjected to taxonomic scrutiny, it will undoubtedly show considerable diversity.

Similarly, in this paper I describe five new species in the Nervosa Group, all of which were collected in Ecuador during the past 20 years. At least four Ecuadorian Nervosa Group taxa (AMNH, CMNH, LACM), each currently known from only one or a few specimens, remain to be described. I estimate that exhaustive collecting in Colombia, Peru, and Bolivia could yield well over a dozen undescribed species in the Nervosa Group alone. With serious field and systematic work, the Albitumida Group, now containing only four species, will probably double in size. Based on these estimates, the genus Nebulosa could ultimately contain 60 species or more—twice its current size.

KEY TO NEBULOSA SPECIES GROUPS

1. Forewing veins M3 and CuA1 long stalked from posterolateral angle of DC (fig. 162A, C, D, F); metathoracic tympanum facing posterolaterally (fig. 160F); lateral margins of male Tg8 abruptly excavated in posterior half (e.g., figs. 163D, 167D, 182C)2

FW veins M3 and CuA1 arising separately from posterolateral angle of DC (fig. 162E); metathoracic tympanum facing anteroventrally; male Tg8 trapezoidal, not abruptly narrowed in posterior half (figs. 174B, 175C)Plataea Group

2. Uncus of male genitalia long or short, not broadly spatulate at apex; female St7 not heavily shagreened; FW usually with small secondary spots near outer margin (e.g., N. aliena, pl. 16; N. sirenia, pl. 17), located either at apex or along vein M2; wing span variable3

Uncus greatly elongate (fig. 185A, H), broadly spatulate at apex; female St7 strongly shagreened along posterior margin; FW with a single, white transverse oblong or ovoid maculation beyond DC (pl. 17), no distal secondary spots; wing span relatively large; FW length  =  14.0–19.0 mmHalesius Group

3. Transtillar arms of male genitalia without long dorsal processes; moths small (pls. 16, 17); FW length  =  9.0–15.0 mm4

Transtillar arms forming long dorsal forks (figs. 183A, 184A), extending upward almost to socii/uncus complex; moths relatively large (pl. 17); FW length  =  16.0–20.0 mmAlbitumida Group

4. Male socii/uncus complex small (e.g., figs. 165A, 178A), narrow at base; uncus short, often highly reduced; socii short; female CB bearing only a signum (e.g., figs. 165C, 178E), no denticulate pockets5

Socii/uncus complex large and triangular (figs. 180AFigure 181182A), wide at base; uncus and socii elongate; CB bearing a pair of small, denticulate pockets near base, in addition to signum (figs. 180E, 181B, 182E)Fulvipalpis Group

5. Forewing elongate, with a diffuse fascia beyond DC and a small submarginal spot on vein M2 (pl. 17); DC of male FW long (fig. 162D); each socius of male genitalia bearing a small, hornlike ventral process (figs. 177A, 178A); male St8 with elongate, straplike projections on posterolateral angles (figs. 177B, 178C)Hermani Group

FW broad, triangular (pl. 16), with a small, subapical spot at base of Rs2–Rs4, or without secondary spots, never with a spot on M2; DC of male FW short (fig. 162A, C); socii without ventral processes (e.g., fig. 167A); posterolateral angles of male St8 rounded (e.g., figs. 163B, 171D), occasionally with hook-shaped lateral processes (e.g., figs. 169B, 173B)Nervosa Group

1. NERVOSA GROUP

These are small moths (♂ FWL  =  10.0–15.0 mm), among the smallest Dioptinae, with a fairly broad, triangular FW and broadly rounded HW (pl. 16). The outer third of the FW is invariably brown, the veins highlighted by a light color—usually creamy white, light brown, or light yellow. Most species have a white transverse band halfway out on the FW, immediately beyond the DC. In many species there is a small, subapical FW spot, either white or orange, located near the fork of Rs2+Rs3. The HW central area is usually white, but the shape of this area is variable. The HW outer margin is almost always brown, darker at the apex.

Although the key below employs wing-pattern characteristics for separation, the Nervosa Group provides another example in the Dioptinae where fantastic genital diversity occurs. When either male or female genitalia are examined, they provide instantly recognizable features for species identification.

Thirteen Nervosa Group species are recognized here, five of which are newly described. The remaining eight were previously assigned to the genus Tithraustes Druce (Bryk, 1930), and now belong in Nebulosa as new combinations.

KEY TO NERVOSA GROUP SPECIES

1. Light-colored areas of HW (dorsal and ventral surfaces) mustard yellow (pl. 16); FW mostly or completely mustard yellow2

Light-colored areas of HW white (pl. 16); FW brown and white3

2. Dorsal surface of FW brown in distal third, veins light yellow; an irregular, mustard yellow transverse fascia beyond DC; HW with a brown spot at apex; patagium a mixture of brown and mustard yellow scales; tegula mustard yellow, brown at basal angles; FW length  =  13.0–15.0 mm (E Ecuador)rabae, sp. nov.

Dorsal surface of FW uniformly mustard yellow, without pattern (brown areas of ventral surface showing faintly through above); HW uniformly mustard yellow, no spot at apex; patagium mustard yellow; tegula mustard yellow, yellow-orange at basal angles; FW length  =  11.0–12.5 mm (W Ecuador)rawlinsi, sp. nov.

3. Forewing with a white or orange-yellow subapical spot, variable in size, located between fork of Rs2+Rs3 and M15

FW without a subapical spot, distal third uniformly brown, veins lighter4

4. White transverse FW band simple, wide; HW anal margin broadly diffuse gray to gray-brown; tegula orange-yellow at base, gray-brown distally; Lp1 white, Lp2 white and gray-brown; FW length  =  12.5–14.0 mm (E Ecuador)elicioi, sp. nov.

White transverse FW band broken or indented at stem of M3+CuA1, usually forming two parts; HW anal margin white; tegula orange-yellow; Lp1 and Lp2 orange-yellow; FW length  =  13.5–15.0 mm (Costa Rica)creon (Druce)

5. Forewing with a large, broadly rounded white area arising from anal margin in basal half, this extending anteriorly beyond DC, but falling short of Sc; FW apical spot relatively large, ovoid, orange-yellow (Peru, Bolivia)aliena (Dognin)

FW without a rounded maculation arising from anal margin; FW apical spot variable in size6

6. Forewing with a broad, white transverse band arising from SC, extending posteriorly to CuA2 or beyond, band never touching FW anal margin; inner and outer margins of white band smooth, often slightly convex9

FW with an irregular white band in basal half, arising from costa and widening posteriorly to anal margin; inner and outer margins of white band sinuate7

7. Hind wing white with a dark brown spot at apex, frequently with a brown marginal tooth along anal fold; head, thorax and abdomen snowy white to creamy white; FW length  =  10.0–13.0 mm (W Ecuador)delicata, sp. nov.

HW white with a wide brown to gray-brown marginal band extending to tornus; portions of head, thorax, and abdomen mostly brown to gray-brown8

8. Subapical FW spot white, small, its posterior margin falling well short of M1; veins in FW distal third barely contrasting, light brown; FW length  =  11.5–12.5 mm (SE Peru, Bolivia)mirma (Druce)

Subapical FW spot light yellow to light orange, its posterior margin extending to M1 or beyond; veins in FW distal third contrasting light yellow; FW length  =  11.0–12.0 mm (SE Peru, Bolivia)thanatos (Hering)

9. White transverse band of FW moderately wide, much less than one-third wing length, outer margin of band concave; FW veins in distal third light brown to ochreous brown, barely contrasting with brown ground color; DC of FW only slightly less than one-half wing length10

White transverse band of FW extremely wide, nearly one-third wing length, outer margin of band slightly convex; FW veins in distal third boldly lined with orange, contrasting with dark brown ground color; DC of FW short, much less than one-half wing length; FW length  =  12.5–13.5 mm (SE Ecuador)latialbata (Prout)

10. Subapical FW spot white, extremely small, its posterior margin falling well short of M1; white central area of HW elongate, extending from base to outer margin12

Subapical FW spot light orange-yellow, relatively large, its posterior margin extending beyond M1; white central area of HW rounded, with either a narrow, or wide, brown marginal band11

11. Outer margin of HW with a relatively narrow brown band (Panama N to Guatemala)erymas (Druce)

Outer margin of HW with a wide brown band (Mexico)nervosa (Edwards)

12. White longitudinal area of HW wide, extending posteriorly beyond cubitus almost to anal fold; FW veins light yellow to cream colored, contrasting with gray-brown ground color; inner margin of dark brown spot on HW apex straight or slightly concave; FW length  =  13.0–13.5 mm (SW Colombia)cistrinoides (Dognin)

White longitudinal area of HW narrow, its posterior margin reaching only to cubitus; FW veins ochreous brown, barely contrasting with dark gray-brown ground color; inner margin of dark brown spot on HW apex convex; FW length  =  13.0–14.0 mm (NE Ecuador)huacamayensis, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Nebulosa aliena (Dognin), new combination

Figure 162C; plate 16

Tithraustes aliena Dognin, 1904: 119.

Type Locality

Bolivia, Yungas de la Paz, 1000 m.

Type

Syntype ♂ (USNM type no. 30934).

Discussion

The white FW area of N. aliena (pl. 16), arching forward to near the subcosta from the posterior margin, makes this moth distinctive. Similarities of wing pattern, wing venation, and genital morphology suggests that N. aliena is the sister species of N. latialbata (pl. 16), from southeastern Ecuador. These two are notable in that the DC of the male FW is much less than one-half the wing length (fig. 162C), shorter than in other members of Nebulosa (e.g., fig. 162A, D, E, F). Together, N. aliena and N. latialbata appear to belong in a clade with two additional Nervosa Group taxa—N. mirma and N. thanatos (pl. 16)—both from the eastern Andes of Bolivia and Peru. All four species share similarities in the shape of the valva apex, in having a wide aedeagus, and in that the vesica of the aedeagus bears a single large, serrate cornutus.

Distribution

Bolivia (BMNH, USNM); Peru (AMNH, BMNH, USNM, ZMH).

Dissected

Syntype ♂ (genitalia slide no. JSM-1042); ♂, Peru, Marcapata, May 1905, Staudinger, Dognin Collection, USNM (genitalia slide no. JSM-766, wing slide no. JSM-1043); ♀, Peru, Upper Madre de Dios, 500–1200 m, leg. Fassl, USNM (genitalia slide no. JSM-767).

Nebulosa cistrinoides (Dognin), new combination

Figure 163; plate 16

Polypoetes cistrinoides Dognin, 1909: 224.

Type Locality

Colombia, Cali.

Type

Holotype ♂, leg. Fassl (USNM type no. 30931).

Discussion

Wing-pattern similarities suggest a close relationship between N. cistrinoides and N. huacamayensis, sp. nov., from eastern Ecuador. In both, the HW is usual because the white central area extends to the wing margin along the fork of M3+CuA1 (pl. 16), thus isolating a large, dark brown spot near the apex. Wing-pattern differences between N. cistrinoides and N. huacamayensis include having the FW veins more contrastingly lined in the former. Another difference involves the shape of the dark brown spot on the HW apex; in N. cistrinoides its inner margin is straight or slightly concave, while in N. huacamayensis its inner margin is convex, giving the spot a more ovoid shape. Their male genitalia are not indicative of a close relationship; Tg8, St8 and the valva apices show marked differences in shape (compare figs. 163A–D, 169A–D).

In addition to the holotype of cistrinoides, the USNM collection also contains four males and a female (lacking its abdomen). These all bear the same brief label data as the type: “Colombie, Fassel”. There are two additional males at the BMNH (see JSM-536), as well as five males at the EMEC, Berkeley. Nebulosa cistrinoides is endemic to southwestern Colombia, occurring at approximately 2000 meters on the Pacific slope of the Andes.

Distribution

Colombia (BMNH, EMEC, USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1051); ♂, Colombia, Valle, San Antonio, 5800 ft, Dec 1907, leg. M.G. Palmer, BMNH (genitalia slide no. JSM-536).

Nebulosa creon (Druce), new combination

Figure 164; plate 16

Polypoetes creon Druce, 1885a: 161, pl. 14, fig. 22.

Type Locality

Costa Rica, Irazu, 6000–7000 ft.

Type

Syntype ♂ (BMNH).

Discussion

As is true for most members of Nebulosa, N. creon was placed by previous authors in Tithraustes (Prout, 1918; Hering, 1925; Bryk, 1930). My analyses suggest that the species belongs within the Nervosa Group. Nebulosa creon, one of the few Nervosa Group species from Central America, appears to be a close relative of the South American N. cistrinoides (pl. 16). Although their wing patterns are not overly similar, this hypothesis is supported by numerous synapomorphies of the genitalia, including the shape of male Tg8 (figs. 163D, 164D), and the configuration of the male valva apex (figs. 163A, 164A).

Nebulosa creon is rare in collections; only a handful of specimens were available for study. In January 2007, I captured one male and one female in the exquisite cloud forests of Parque Nacional Tapantí (pl. 42D), flying during late morning in thick fog. The previous night, another male was captured there at MV light. The BMNH female dissected for this study (JSM-1493) and the one I collected are the only two so far known.

Distribution

Costa Rica (AMNH, BMNH, INBio, SMNS).

Dissected

♂, Costa Rica, Cartago, Tapantí, Río Grande de Orosí, 1300–1400 m, 9°48′× 83°50′, 17 Nov 1982, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-1052); ♀, Costa Rica, Irazu, 6–7000 ft, leg. H. Rogers, BMNH (genitalia slide no. JSM-1493).

Nebulosa delicata, new species

Figures 165, 166; plate 16

Diagnosis

The wing-pattern details of N. delicata are similar to those of N. rabae, sp. nov. (pl. 16), but the moths are easily separable. The wing ground color of N. delicata is immaculate white, whereas the wings are mustard yellow in N. rabae. Nebulosa delicata (FW length  =  10.0–13.0 mm) is also significantly smaller than N. rabae (FW length  =  12.5–14.0 mm). In addition to its small size, N. delicata is recognizable by the following wing-pattern characteristics: FW gray in outer one-third, veins outlined in light creamy yellow; FW white in basal two-thirds, a light gray-brown triangle along costa for one-third the wing length; HW immaculate white with a dark gray spot at apex. In some specimens, (including the holotype; pl. 16), there is a small gray-brown wedge on the HW outer margin, located at the distal end of the anal fold. The head and thorax are almost entirely white, and the tegulae are yellow-orange at the base with long, white scales distally. The abdomen is dusty white at its base, becoming light gray-brown toward the apex.

Description

Male. Forewing length  =  10.0–12.0 mm. Head: Labial palpus thin, relatively short, upturned to immediately above clypeus; Lp1 and Lp2 white to light creamy yellow on ventral surface, light gray-brown above; Lp3 mostly gray-brown, with a few cream-colored scales below; front covered with long, upwardly pointing, white scales, scales reaching beyond antennal bases; occiput and vertex completely clothed in white scales; eye large and bulging; antenna bipectinate, each ramus thick and club shaped; antennal scape gray-brown with a few creamy scales below; antennal shaft gray-brown above.

Thorax: Prothoracic leg with coxa white, femur light brown on inner surface, white on outer, rest of proleg gray-brown; mesothoracic leg white on inner surface, gray-brown on outer one; metathoracic leg mostly white, with light brown scales on upper surface; pleuron clothed with white, hairlike scales; patagium white, with a few light brown scales on anterior margin; tegula lemon yellow to orange-yellow, but ventral process white, and distal margin trimmed with long, white scales; dorsum entirely white; tympanal membrane large, almost triangular, facing slightly posterolaterally, but mostly laterally.

Forewing: (Dorsal) Outer third gray-brown to dark gray (pl. 16), with veins contrasting, light creamy yellow; fringe dark gray-brown; a small round, white apical spot present, its anterior margin touching the fork of Rs2+Rs3, its posterior margin crossing Rs4 but falling short of M1; a white transverse band straddling apex of DC, band abruptly wider near fork of M3+CuA1; basal third with a diffuse, light gray triangle in DC, from base along anterior margin; triangle touching subcosta anteriorly and reaching cubitus posteriorly, veins within it cream to light yellow; costa dark gray to brownish gray; a diffuse patch of brownish-gray scales in basal third, located on either side of anal fold; anal margin white in basal two-thirds, gray-brown beyond. (Ventral) Pattern similar to dorsal surface, but dark area in outer third uniformly gray-brown to dark gray, veins concolorous; gray subcostal triangle slightly darker than on dorsal surface; scales along anal fold completely white.

Hind wing: (Dorsal) Almost entirely white (pl. 16); a prominent gray-brown to dark gray spot at apex; a small, diffuse wedge of gray-brown scales at outer margin, located distally along anal fold; wedge very small in some specimens; fringe dusty white to gray-brown. (Ventral) Similar to dorsal surface, except spot at apex slightly darker.

Abdomen: Dorsum white from base, becoming progressively gray-brown along midline distally, terminal segments completely gray-brown above; venter immaculate white from base to St7; St8 gray-brown, with scale tufts at corners.

Terminalia (fig. 165A, B, D, E): Sides of Tg8 parallel in basal two-thirds, abruptly narrowed in distal one-third to form a wide central process, apex of process truncate; anterior margin of Tg8 with a pair of small, short apodemes; St8 extremely wide, with hook-shaped lateral processes; anterior margin of St8 with a small, tonguelike, sclerotized fold; posterior margin of St8 simple; socii/uncus complex small, triangular, uncus extremely small, shorter than socii; tegumen much wider below; saccus widely V-shaped below; valvae with BO well developed, curled; valva apex acute, costa roughly parallel sided, slightly wider short of apex; transtillar arms wide, curved upward near base, narrowly joined at midline; aedeagus relatively wide, apex with a robust, curved tooth below; an extremely long, narrow process extending from distal portion of aedeagus above; upper process gently curved, then forming a hook at apex; vesica relatively large, lacking cornuti.

Female. Forewing length  =  11.0–13.0 mm. Wing pattern and body characters as in male. Antenna with short, club-shaped rami; abdomen broad, truncate.

Terminalia (fig. 165C): Tg7 wider anteriorly, gradually narrowed distally; St7 extremely wide, with a large, deep medial excavation and a corrugated transverse ridge; Tg8 forming a small, rooflike structure above PA; AA extremely long and thin; ostium simple; DB short, folded, membranous; CB large, almost round; signum absent, but two small, spiculate, sclerites present dorsally in CB membrane near base; the first patch flat, the second forming a triangle raised from surface of CB; DS arising dorsally from base of CB; PA gently rounded at outer margin; PP long and thin.

Etymology

This is one of the smallest species of Dioptinae. The name, taken from the Latin word delicatus, applies to the moth's size and to its intricate wing pattern.

Distribution

Nebulosa delicata has been recorded from sites in western Ecuador as far north as Chical (Carchi Province) on the Colombian border, to as far south as a locale near Jesus María (Azuay Province), southeast of Guayaquil. The moth's range thus spans nearly the entire length of Ecuador (fig. 166), and almost certainly occurs north into Colombia as well. Its southern limit probably terminates near the border with Peru.

Nebulosa delicata occurs at a wide range of elevations. It has been collected at the record low for any Nebulosa species, 475 m (Cañar Province), but has also been captured as high as 2800 m near Pallatanga (Chimborazo Province). In contrast, the majority of Nervosa Group taxa live within a narrow altitudinal range close to, or somewhat above, 2000 m. The reason for this phenomenon in D. delicata is unclear, but could perhaps be related to the distribution of its host plant, as yet unknown.

Discussion

Although not reflected in their wing patterns, which are quite different, characters of the male genitalia suggest that N. delicata is most closely related to N. rawlinsi (pl. 16). The two species are sympatric, at least in portions of their ranges (compare figs. 166, 172). Synapomorphies include the shape of St8 (figs. 165B, 173B), the shape of the valva apex (figs. 165A, 173A), and the presence of an extremely long, curved process arising from the apex of the aedeagus (figs. 165D, 173C). This unusual process provides a useful diagnostic feature for both species—it can frequently be observed, with the aid of a stereomicroscope, protruding from the terminus of the abdomen in pinned specimens.

Holotype

Male (pl. 16). Ecuador: Cañar: El Chorro, 20 km from la Troncal, S02°28.6′ W79°16.3, 475 m; 9 Mar 2003, at light UV/MV, western tropical dry forest, undisturbed, leg. S. Rab Green & M. Tapia. The specimen is deposited at the AMNH.

Paratypes

Ecuador: Carchi: 1♀, Chical, 1250 m, 0–56N, 78–11W, 6 Jul 1983, leg. J. Rawlins, R. Davidson (CMNH; genitalia slide JSM-759). Esmeraldas: 2♂♂, 5 km W Río de Cristal, near Alto Tambo, Cotacachi-Cayapas Reserve, 1550 m, 7 Dec 1995, cloud forest, leg. Jan Hillman (CMNH). Pichincha: 1♂, Tinalandia, 700 m, 20 May 1985, leg. C.V. Covell Jr. (AMNH); 1♂, Tinalandia, 600 m, 5–11 May 1990, leg. R.H. Leuschner (AMNH); 1♀, Tinalandia, 700 m, 20 May 1993, leg. J.S. Miller, at light (AMNH); 1♂, Mindo, Km 48, 1700 m, leg. F. Piñas (FPC); 1♂, Otongachi, La Unión del Toachi, 00°19.3′S, 78°57.1′W, 933 m, 3 Aug 2005, leg. G. Onore (AMNH); 1♂, Toachi, S00°19.3′ W78°57.3′, 800 m, 23 Feb 2003, leg. S. Rab Green & M. Tapia, western cloud forest, disturbed (AMNH); 5♂♂, Toachi, “on other side of river”, S. Rab Green & A. Tapia (AMNH); 3♀♀, above Toachi, S00°19.3′ W78°57.0′, 900 m, 29 Apr 2000, at light UV/MV, leg. S. Rab Green & A. Tapia (AMNH); 1♀, 4 km E Tandayapa, 2100 m, 26 June 1994, Secondary forest, leg. Jan Hillman (CMNH). Chimborazo: 1♀, 11 km NE Pallatanga, 2800 m, 11 Nov 1987, semiarid, leg. C. Young, R. Davidson, J. Rawlins (CMNH). Cañar: 1♂, El Chorro, 20 km from la Troncal, S02°28.6′ W79°16.3, 475 m, 9 Mar 2003, at light UV/MV, leg. S. Rab Green & M. Tapia, western tropical dry forest, undisturbed (AMNH). Azuay: 4♂♂, 18 km SE Jesus María, 1200 m, 10 Nov 1987, leg. J. Rawlins, C. Young, R. Davidson, wet forest habitat (CMNH; genitalia slide JSM-417).

Other Specimens Examined

None.

Dissected

1♂, 1♀.

Nebulosa elicioi, new species

Figures 160E, 160F, 166, 167; plates 16, 38K [EX]

Diagnosis

Nebulosa elicioi, known exclusively from eastern Ecuador, shows wing-pattern similarities to N. cistrinoides (pl. 16), from the western side of the Colombian Andes, as well as to N. huacamayensis (pl. 16), from eastern Ecuador. In all three, the FW is gray-brown with a wide, oblong transverse band, extending from the costa to the anal fold. Additionally, in these species the FW veins are finely lined with whitish-gray scales as they pass through the dark areas.

However, N. elicioi can be easily separated from the other two: In N. cistrinoides and N. huacamayensis there is a small, but prominent, white subapical FW spot, absent in elicioi. Their hind wings also differ: In N. elicioi the white central area extends outward to near the distal HW margin, but does not touch it; in N. cistrinoides and N. huacamayensis the white area extends to the distal margin. Genital differences are unequivocal. For example, the three differ dramatically in valva shape (compare figs. 163A, 167A, 169A).

Description

Male. Forewing length  =  12.5–14.0 mm. Head (fig. 160E): Labial palpus short and thin, curving upward, but barely reaching above clypeus; Lp1 white, lightly fringed below with long scales; Lp2 white on ventral surface, dark gray-brown above; Lp3 dark gray-brown; front covered with long, upwardly pointing white scales, reaching dorsally past antennal bases; occiput white; eye extremely large, bulging; vertex covered with long brown scales; antennal scape gray-brown with a few white scales on dorsum, dorsum of antennal shaft covered with brown scales, edged with a few white ones.

Thorax (fig. 160F): Pro- and mesothoracic legs with coxa and femur white on inner surface, brown on outer, tibia mostly brown with a few cream-colored scales on inner surface; metathoracic leg almost entirely white to cream, with a few scattered brown scales; spurs brown to light brown; patagium covered with an even mix of brown and white, hairlike scales; tegula orange-yellow at base, fringed distally with long, brown scales and a few buff-colored ones; dorsum a mixture of light brown and cream-colored scales; tympanum large, round, and exposed, as in other members of Nebulosa; tympanal membrane facing posteroventrally.

Forewing: (Dorsal) Ground color brown to gray-brown (pl. 16), slightly lighter from base to distal margin of DC, darker in outer third; an oblong, white cross-band extending from costa to anal fold, band sometimes slightly irregular beyond DC; wing veins in gray-brown areas finely lined with whitish-gray scales; a small, obscure, translucent apical spot located between Rs4 and M1. (Ventral) Pattern similar to dorsal surface, except wing veins not sharply delineated with whitish scales.

Hind wing: (Dorsal) Central area and anterior margin translucent white (pl. 16); a gray-brown band along anal and outer margins; band light gray-brown and broad at anal margin, very narrow at outer margin, then abruptly wider and becoming dark gray-brown at apex. (Ventral) Similar to upper surface, except anal margin whitish brown.

Abdomen: Dorsum gray to gray-brown; venter white.

Terminalia (fig. 167A–D): Tg8 highly modified, basal half wide, almost heart shaped, gradually narrowing toward anterior margin; distal half of Tg8 forming a robust, elongate central process with a raised ridge along midline, apex of process with a small, sharply defined U-shaped excavation; St8 with sides roughly parallel, narrowing slightly at distal margin; posterior margin of St8 with a deep, narrow mesal excavation; socii/uncus complex small, uncus extremely short, socii upturned, forming small points at apices; tegumen abruptly widened halfway up to form large, winglike lateral processes; vinculum much shorter than tegumen, moderately wide, saccus U-shaped below; valva with BO almost absent, a few short pleats present along lower margin; sclerotized distal portion of valva forming a wide, truncate structure; transtillar arms moderately wide, arched slightly upward near base, narrowly joined at midline; aedeagus relatively narrow, widest at base; apex of aedeagus with a small hook-shaped tooth below; vesica small, with a single, dentate, thornlike cornutus.

Female. Forewing length  =  13.0–14.0 mm. Head, thorax, wing pattern, and abdomen similar to males, except wings slightly less contrasting in color, whitish lines along FW veins less clearly defined.

Terminalia (fig. 167E): Tg7 almost quadrate, slightly constricted immediately short of halfway point, distal margin more heavily sclerotized, a faint, shallow indentation at midline; St7 wide, trapezoidal, widest at distal margin; posterior margin of St7 with a wide, deeply rounded medial excavation; Tg8 small, delicate, forming a rooflike structure over PA; AA long and thin; PA quadrate; PP short, tapered at apex; ostium large, funnel shaped, with a small, melanized dorsal appendix; DB sclerotized, moderately wide, narrowing abruptly at corpus; CB large, membranous, round; signum absent, but two small, lightly sclerotized, spiculate patches present dorsally near base of CB.

Etymology

This species is named in honor of Elicio Tapia, from Quito, Ecuador, who has accompanied me on all of my collecting trips to Ecuador (1988, 1993, 2004, 2006, 2009). He and I have become steadfast friends. Without the aid of Elicio's phenomenal expertise as a naturalist, and his almost superhuman work ethic, only a fraction of the findings described in this paper would have come to light. During more than 20 years of fieldwork in the Neotropics, the vast majority of what I know was taught to me by Elicio.

Distribution

Nebulosa elicioi is endemic to the eastern slope of the Ecuadorian Andes (fig. 166). Its distribution appears to be fairly restricted. The furthest north the moth has been collected is Volcán Reventador, north of the Río Quijos (CMNH). Its southernmost records come from two female specimens (USNM, VOB), collected east of Baños along the Río Pastaza. The known distribution of N. elicioi thus spans less than 200 km. Specimens have been captured at altitudes as low as 1600 m (VOB), and as high as 2900 m (CMNH).

Biology

Nebulosa elicioi has been reared on four separate occasions at Yanayacu Biological Station (pl. 43A–C). The larvae (pl. 38K) have been recorded on two hosts—Casearia arboreum (Salicaceae) and Siparuna lepidota (Siparunaceae). Casearia was previously placed in the now defunct family Flacourtiaceae (Chase et al., 2002). Salicaceae belongs in the order Malphigiales, which includes Passifloraceae and Violaceae. Siparunaceae is completely unrelated to these, being placed in the order Laurales. Caterpillars of a second Nebulosa species, N. huacamayensis, which occurs in sympatry with N. elicioi, have also been recorded on Casearia (table 4).

Discussion

Nebulosa elicioi can be separated from other Nebulosa species by wing pattern differences (see Nervosa Group species key). However, an undescribed taxon from the western Andes of Colombia and Ecuador (AMNH, BMNH), apparently its sister species, matches N. elicioi in almost every respect. I found no reliable way to distinguish the two other than differences in their genitalia. These, however, provide unambiguous distinguishing characters. For example, in N. elicioi the tegumen bears large, winglike lateral processes (fig. 167A). In the unnamed form, the tegumen is expanded in this area, but such processes do not occur. The tegumen structure of N. elicioi is apparently autapomorphic for the species. Female genitalia in the two taxa are also distinct, especially with regard to the shape of Tg8 and the shape of the anterior and posterior apophyses.

I refrain from describing the western species, leaving that for future revisionary work. Genitalia slides for it are as follows: ♂, Colombia, Manizales, Caldas, 2150 m, Nov 1973, leg. A. Negritt (VOB; genitalia slide no. JSM-1331); ♀, Colombia, leg. A.M. Patino (BMNH; genitalia slide no. JSM-537); ♀, Ecuador, Pichincha, San Francisco de las Pampas, 2000 m, 7–14 May 1993, leg. A. Sourakov (AMNH; genitalia slide no. JSM-1323).

Holotype

Male (pl. 16). Ecuador: Napo: Yanayacu Biological Station, 5 km W Cosanga on Cosanga-Río Aliso Rd., 00°35.9′S, 77°53.4′W, 2163 m, MV light, 4 Mar 2006, leg. J.S. Miller. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 2♂♂, Yanayacu Biological Station, 5 km W Cosanga on Cosanga–Río Aliso Rd., 00°35.9′S, 77°53.4′W, 2163 m, MV light, 3–4 Mar 2006, leg. J.S. Miller (AMNH); 3♂♂, 4 Mar 2006, leg. J.S. Miller (AMNH); 3♂♂, 4–5 Mar 2003, at light UV/MV, eastern cloud forest, undisturbed, leg S. Rab Green and M. Tapia (AMNH; genitalia slide no. JSM-1322); 2♂♂, 1♀, Reared (#1320.1, #1321, #1367), H. Greeney et al., Jan 2005 (AMNH); 2♀♀, Reared (#1716, #1717), Feb 2005 (AMNH); 1♀, Reared (#1724), Mar 2005 (AMNH); 1♂, South slopes Cerro Sumaco, 1855 m, 21 Nov 1995, leg. Jan. Hillman, submontane wet forest (CMNH; genitalia slide no. JSM-1324); 2♂♂, SE slope Reventador, 2900 m, 5 Jul 1994, Jan Hillman, cloud forest (CMNH; genitalia slide no. JSM-901); 1♂, SE slope Reventador, 1900 m, 7 Jul 1994, cloud and secondary forest, leg. Jan Hillman (CMNH); 1♂, Río Reventador, San Rafael, 1400 m, 3 Jul 1994, leg. Jan Hillman, farms and secondary forest (CMNH).

Other Specimens Examined

Ecuador: Tungurahua: 1♀, Río Verde, 1600 m, 26 Dec 1992, leg. V.O. Becker (VOB); 1♀, 39 km E Baños, 25 Jan 1976, blacklight, Spangler, et al., Ecuador-Peace Corps—Smithsonian Institution Aquatic Insect Survey (USNM; genitalia slide no. JSM-1332).

Dissected

3♂♂, 1♀.

Nebulosa erymas (Druce), new combination

Figure 168; plate 16; plate 38G, I, J [EX]

Polypoetes erymas Druce, 1885a: 161, pl. 14, fig. 21.

Type Locality

Panama, Volcán de Chiriquí, 3000–4000 ft.

Type

Syntype ♂, leg. Champion (BMNH).

Tithraustes albifera Warren, 1901: 443.

Type Locality

Costa Rica, San José.

Type

Holotype ♂, leg. Underwood, 15 May–10 Jun 1899 (BMNH).

Tithraustes undulata Hering, 1925: 513.

Type Locality

Brazil, Blumenau.

Type

Holotype ♀ (ZMH).

Discussion

Nebulosa erymas has been reared in Costa Rica on two different host plants (table 4)—Cestrum megalophyllum (Solanaceae) and Perrottetia longistylis (Celastraceae). One might postulate that there are two separate moth species, reflected by these different hosts. However, based on my dissections from several localities, a single taxon exists. Nebulosa erymas is the sister taxon to N. nervosa (pl. 16) from Mexico. I note in my discussion of the latter that these two may be conspecific.

The larvae of N. erymas (pl. 38I) are unusual in exhibiting bright yellow stripes, along with conspicuous pairs of black, subdorsal spots on the thorax and on A3, A5, and A7. The pupae are similarly unusual (pl. 38J); the contrasting markings, yellowish ground color and large eyes give them the appearance of butterfly chrysalides.

Having examined Warren's type of albifera, I found few features distinguishing it from the type of N. erymas. The only noticeable difference is that the albifera type is paler (probably more faded), and shows a larger white central area of the HW. I retain Warren's taxon as a synonym of erymas, following previous authors (Bryk, 1930).

Hering's name undulata is a mystery. On two separate visits to Berlin I was unable to locate his female type, supposedly at the ZMH. He described undulata (1925: 513) as a subspecies of N. erymas in which the HW margin shows an undulate black border. The supposed type locality for undulata—Blumenau, in southeastern Brazil—is highly unusual; not only would this be far removed from other specimens of N. erymas, all of which are Central American, but it would also be the first known Brazilian locality for Nebulosa. Obviously, the status of undulata requires further study.

Distribution

Panama (AMNH, BMNH, FNHM, LACM, ZMH); Costa Rica (AMNH, BMNH, FNHM, INBio, MUSM, UCB, VOB).

Dissected

♂, Costa Rica, Puntarenas, Las Alturas, 35 km NE San Vito, 4300 ft, Río Bella Vista and Tajo Rd., 20 Mar 1991, leg. J.S. Miller, day coll. along river, AMNH (genitalia slide no. JSM-533); ♂, Costa Rica, Cartago, Tapantí, Río Grande de Orosí, 1300–1400 m, 9°48′× 83°50′, 9 Apr 1984, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-447); ♂, Costa Rica, Heredia, El Angel waterfall, 8.3 km downhill Vara Blanca, 1350 m, 3 Jan 1981, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-1061); ♂, Panama, Chiriquí, Sta. Clara, 1200 m, 7 Sep 1981, leg. G.B. Small, USNM (genitalia slide no. JSM-1060); ♀, Costa Rica, Puntarenas Prov., Las Alturas, 35 km NE San Vito, 1540 m, 29 Jun 1992, leg. C. Snyder, at light, AMNH (genitalia slide no. JSM-818); ♀, Costa Rica, Puntarenas, Las Nubes, 11 km NW Monteverde, 31 Jul 1981, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-448); ♀, Costa Rica, Guanacaste, 4 km E Casetilla, Rincon Natl. Pk., 18 Oct 1982, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-1490).

Nebulosa huacamayensis, new species

Figures 159A–D, 162A, 169, 170; plate 16

Diagnosis

Nebulosa huacamayensis is similar to several other Nebulosa species, where the FW is gray-brown with a white cross-band located immediately beyond the DC, extending from the costa to the anal fold (pl. 16). However, the HW of N. huacamayensis, showing an elongate white central area from the wing base to the outer margin, is found in only one other taxon—N. cistrinoides from western Colombia (pl. 16). The HW of N. huacamayensis differs in that the white area is much narrower, almost hourglass shaped. Other features for separating the two species are listed in the Nervosa Group species key and the discussion for N. cistrinoides (above). Nebulosa huacamayensis can be separated from N. elicioi (pl. 16), with which it is sympatric (figs. 166, 170), by the presence of a white subapical FW spot, absent in N. elicioi, and by the shape of the white HW central area, which is narrow in N. huacamayensis, but rounded in N. elicioi. The male genitalia of N. huacamayensis are distinctive in their valva shape (fig. 169A) and in the shape of the distal portion of the aedeagus (fig. 169C).

Description

Male. Forewing length  =  12.0–14.0 mm. Head (fig. 159A–D): Labial palpus extremely short, curving upward, barely reaching clypeus; Lp1 light yellow to lemon yellow, fringed below with long, lemon-yellow scales; Lp2 light yellow to lemon yellow on venter and sides, dark gray above; Lp3 dark gray; front covered with long, upwardly pointing scales, reaching dorsally past antennal bases; central portion of front gray, lateral portions creamy white; occiput creamy white; eye large and bulging; vertex a mixture of light gray-brown and cream-colored scales, area behind antennal sockets creamy white; antenna widely bipectinate; antennal scape gray-brown with a ring of cream-colored scales at base; antennal shaft gray along midline, bordered on either side with a row of cream-colored scales.

Thorax: Coxae and pleuron cream to creamy yellow; femur and tibia, including spurs, cream-colored with gray-brown on dorsal surfaces; patagium covered with upwardly pointing light gray-brown scales, bordered anteriorly and posteriorly with cream-colored ones; tegula yellow-orange with long, gray-brown scales along margins, a few cream-colored scales mixed in; ventral angle of tegula creamy white; dorsum covered with long, gray-brown and beige scales; tympanum extremely large, open; tympanal membrane almost round, facing posterolaterally.

Forewing (fig. 162A; pl. 16): (Dorsal) Ground color brown to gray-brown (pl. 16), slightly lighter from base to distal margin of DC, darkest in distal third; an oblong white, transverse band extending from costa to slightly beyond CuA2, costal margin of band slightly yellowish; transverse band slightly widened at ventral angle; wing veins in gray-brown areas lined with yellowish brown to rusty brown scales, slightly more contrasting in basal third; a small, thinly scaled, white subapical spot straddling Rs4, its anterior margin falling short of Rs3. (Ventral) Similar to dorsal surface, except veins concolorous, not contrasting.

Hind wing (fig. 162A; pl. 16): (Dorsal) A conspicuous, dark gray-brown spot at apex, extending from anterior margin to immediately short of M3 (pl. 16); posterior half of wing gray to gray-brown, lighter at base; gray posterior area extending from anal margin forward to cubitus, DC then light gray from base to slightly short of its distal margin; remainder of wing white with creamy yellow highlights along veins and at margin; white forming a shallow, U-shaped central area extending from anterior margin to outer margin. (Ventral) Similar to dorsal surface, except broadly banded anal margin lighter gray.

Abdomen: Light gray to gray-brown dorsally; pleuron and venter cream to creamy yellow; Tg8 gray-brown with creamy yellow scales along sides.

Terminalia (fig. 169A–D): Basal two-thirds of Tg8 wider, narrowing gradually to form a long central process in distal third, apex of process bifurcate, a wide ridge running along dorsum of Tg8; anterior margin of Tg8 with a pair of short apodemes; St8 wide, with lobate lateral processes; anterior margin of St8 simple, with a small, triangular mesal sclerotization; posterior margin of St8 with a sclerotized depression running parallel to margin and a small, V-shaped mesal excavation; uncus/socii complex small, uncus shorter than socii; uncus blunt, with dorsal spicules; socii robust, upturned and hook shaped; tegumen expanded in ventral portion; saccus small, forming a narrow, horizontal band below; valva with BO small, comprising an area of crenulate pleats along ventral margin; valva apex truncate, with a small ventral knob; transtillar arms extremely wide at base, narrowly joined at midline; aedeagus long, slightly constricted beyond midpoint, then expanded, ending in a sharp, recurved hook; vesica moderately large, bearing a triangular opercular sclerite at base, and a single, denticulate cornutus distally.

Female. FW length  =  13.0 mm. Wings and body similar to male, except: antenna with short, wide rami; frenulum comprising six bristles.

Terminalia (fig. 169E–G): Tg7 large, anterior margin gently convex, lateral margins constricted in anterior third then convex in distal two-thirds, posterior margin with a shallow mesal excavation; St7 large and wide, narrowed in anterior two-thirds, then abruptly expanded laterally in distal third, lateral expansions sclerotized to form large, shallow pockets; anterior margin of St7 broadly convex, posterior margin broadly concave with a large, deep, quadrate mesal excavation; Tg8 small, delicate, forming a rooflike structure over PA; AA long and thin; PA oblong, narrowed dorsally; PP short, tapered at apices; PVP large, flat; ostium small, rugose; DB long, wide and heavily sclerotized, elbow shaped; DS arising from sclerotized DB basally, on right side a short distance from ostium; CB large and membranous, ovoid; signum absent, a pair of lightly sclerotized, denticulate patches at base of CB.

Etymology

This species name celebrates the Cordillera Huacamayos in eastern Ecuador, home to N. huacamayensis, and one of the most beautiful places on earth. Huacamayos is the Quechua word for the military macaw, Ara militaris, now extinct in that region (H. Greeney, personal commun.).

Distribution

The Cordillera Huacamayos is a vaguely defined region in the Andes of eastern Ecuador, extending roughly from the Río Pastaza at its southern boundary, to Baeza in the north (see fig. 5). This area in fact encompasses a complex series of mountain ranges, each with its own name. Although Nebulosa huacamayensis is named in honor of the Cordillera Huacamayos, its distribution extends further south to the Río Gualaceo (Morona-Santiago Province), east of Cuenca (fig. 170). Collecting at either end of the current distribution for N. huacamayensis will undoubtedly expand the species' limits even further north and south.

Nebulosa huacamayensis lives exclusively in cloud-forest habitat. The majority of material has been collected at or near Yanayacu Biological Station (pl. 43A–C), 10 km W of Cosanga on the Cosanga–Río Aliso Road.

Biology

The larvae of N. huacamayensis have been recorded from Casearia (Salicaceae), also a host for N. elicioi (see above). This plant genus may prove to be an important host for the Andean Nebulosa fauna.

Discussion

Nebulosa huacamayensis shares wing-pattern similarities with N. cistrinoides (pl. 16), especially with regard to the HW markings. However, these taxa exhibit extremely different male genitalia (compare figs. 163 and 169A–D). In contrast, the wing patterns of N. huacamayensis and N. rabae differ dramatically (pl. 16), but valva shape (figs. 169A, 171A) and the structure of Tg8 (figs. 169D, 171B) suggest that these species are closely related. A clearer understanding of relationships within the Nebulosa Group will require a comprehensive species-level revision.

Holotype

Male (pl. 16). Ecuador: Napo: Yanayacu Biological Station, S00°35.9′ W77°53.4′, 2163 m, 4–5 Mar 2003, eastern cloud forest, undisturbed, leg. S. Rab Green & M. Tapia. The type is deposited at the AMNH

Paratypes

Ecuador: Napo: 4♂♂, Cordillera Huacamayos, San Isidro–Río Aliso, 2250 m, 00°37′36″S, 77°57′12″W, 3 Aug 1996, leg. Jan Hillman, deforested hacienda (CMNH); 3♂♂, Cordillera Huacamayos, Estero Chico, 2650 m, 5 Aug 1996, leg. J. Hillman, virgin humid forest (CMNH; genitalia slide no. JSM-1317); 1♂, Yanayacu Biological Station, S00°35.9′ W77°53.4′, 2163 m, 4–5 Mar 2003, leg. S. Rab Green & M. Tapia, eastern cloud forest, undisturbed (AMNH); 2♂♂, 25 Sep 2004, leg. J.S. Miller & E. Tapia (AMNH); 1♂, Jan 2005, leg. G. Gentry (AMNH); 1♀, Reared (#1368.111), January 2005, H. Greeney et al. (AMNH; genitalia slide no. JSM-1552).

Other Specimens Examined

Ecuador: Morona-Santiago: 3♂♂, Río Culebrillas, 34 km SE Gualaceo, 2200 m, wet forest, 22–23 Oct 1987, leg. J. Rawlins, C. Young, R. Davidson (CMNH; genitalia slide no. JSM-902, wing slide no. JSM-1460).

Dissected

2♂♂, 1♀.

Nebulosa latialbata (Prout), new combination

Plate 16

Tithraustes latialbata, Prout, 1918: 409.

Type Locality

Ecuador, Alpayacu, Río Pastaza, 3600 ft.

Type

Holotype ♀, leg. M.G. Palmer (BMNH).

Discussion

Nebulosa latialbata (pl. 16) is extremely rare, known to me from a male in the Francisco Piñas Collection (JSM-881), and from the female holotype. Both specimens were captured in eastern Ecuador near the Río Pastaza. The shape and location of the white FW area, and the conspicuous orange lines along the FW veins, make N. latialbata distinctive. In addition, this taxon is unusual among Nebulosa species in exhibiting an extremely short DC, a feature shared with N. aliena (fig. 162C), endemic to northeastern Bolivia and southeastern Peru. Wing-pattern (pl. 16) and genital synapomorphies provide further evidence that N. latialbata and N. aliena are sister species.

Distribution

Ecuador (BMNH, FPC).

Dissected

♂, Ecuador, Morona-Santiago, Macas, 28 Mar 1994, leg. F. Piñas, FPC (genitalia slide no. JSM-881).

Nebulosa mirma (Druce), new combination

Plate 16 [EX]

Polypoetes mirma Druce, 1899: 301.

Type Locality

Bolivia.

Type

Syntype ♂, leg. G. Garlepp (BMNH).

Polypoetes dryas Dognin, 1902: 477.

Type Locality

Bolivia, Yungas.

Type

Syntype ♂/♀, ex Staudinger, 1897, Dognin Collection (USNM type no. 30930).

Momonipta semilugens Warren, 1900: 128.

Type Locality

Bolivia, Río Tanampaya.

Type

Syntype ♂, leg. Garlepp, 1894 (BMNH).

Discussion

Nebulosa mirma is closely related to N. thanatos (pl. 16), with which it is roughly sympatric. In addition to their wing-pattern similarities, in males of both the valva apex is broadly truncate and slightly convex. However, there are also numerous genital differences. For example, they show markedly different configurations of the female seventh segments.

Dissection of the dryas male syntype (JSM-1074) corroborates its synonymy with mirma; their genitalia are identical. I have not dissected the type of semilugens Warren, and so defer to previous authors in retaining it as a synonym of mirma (Prout, 1918; Hering, 1925; Bryk, 1930). Material from the type locality of semilugens (Tanampaya, Bolivia; USNM) is superficially indistinguishable from other examples of N. mirma, and Warren's (1900) description of semilugens indicates no differences. I have seen only a single specimen of N. mirma collected outside Bolivia—a USNM male collected by J.B. Heppner at Buenos Aires, Cuzco, Peru (2280 m).

Distribution

Bolivia (BMNH, USNM); Peru (USNM).

Dissected

♂ type of dryas Dognin, USNM (genitalia slide no. JSM-1074); ♂, Bolivia, Incachaca, Cochabamba, B.P. Clark Collection, USNM (genitalia slide no. JSM-1072); ♀, Bolivia, Incachaca, Cochabamba, B.P. Clark Collection, USNM (genitalia slide no. JSM-1073).

Nebulosa nervosa (Edwards), new combination

Plate 16

Dioptis nervosus Edwards, 1884: 15.

Type Locality

Mexico, Jalapa.

Type

Holotype ♂, ex Neumögen Collection (USNM).

Discussion

The name “nervosa” has traditionally been applied in collections to all Mexican material resembling N. erymas, the more common taxon. Examples of N. nervosa include the following: The male holotype and three additional USNM males (all from southeastern Mexico); three males and one female at the LACM (Chiapas); three examples collected by Rafael Turrent (Chiapas); as well as one male in the Vitor Becker Collection (Veracruz, Huatusco, 1300 m). The wing pattern and genitalia of Guatemalan material are inseparable from those of N. nervosa specimens captured in southern Mexico, and I consider them to be conspecific.

Nebulosa nervosa purportedly differs from its more southerly distributed sister species, N. erymas (pl. 16), in having a wider white FW band (Hering, 1925). However, after studying specimens from a range of localities, I found no consistent difference in band width. Some N. erymas specimens from Costa Rica show a wider band than examples of N. nervosa from Chiapas, Mexico. Furthermore, my dissection of the N. nervosa type revealed no differences between its genitalia and those of Costa Rican N. erymas males. A female of N. nervosa from Chiapas (JSM-1681) cannot be separated from Costa Rican N. erymas females based on genitalia. There is thus a strong possibility that erymas is a junior synonym of nervosa. I defer that decision to a time when more exhaustive taxonomic study can be done.

Distribution

Mexico (ARTC, LACM, USNM, VOB); Guatemala (AMNH, BMNH, LACM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1075); ♂, Guatemala, Antígua, Acatenango, Quisache, Chimaltenango, 1750 m, 6 Nov 1966, leg. E.C. Welling, AMNH (genitalia slide no. JSM-1980); ♀, Mexico, Chiapas, Lagos de Montebello, 10 Dec 1972, leg. Robert Wind, LACM (genitalia slide no. JSM-1681).

Nebulosa rabae, new species

Figures 171, 172; plate 16

Diagnosis

This striking species is unlike any other dioptine. The mustard-yellow wing color and intricate FW markings are diagnostic. The only taxon with which N. rabae could potentially be confused is N. rawlinsi, sp. nov., also with mustard-yellow wings (pl. 16). However, N. rawlinsi is a smaller moth, lighter in color, whose wing dorsal surfaces lack contrasting markings of any sort. In addition to its unique FW pattern, the HW of N. rabae bears a conspicuous brown spot near the apex. As in all Nebulosa species, males of N. rabae possess a FW stridulatory organ. However, the N. rabae FW is notable in that the DC is almost one-half the wing length, longer than in most members of the Nervosa Group (see fig. 162A, C).

Description

Male. Forewing length  =  12.5–14.0 mm. Head: Labial palpus extremely short, curving upward to immediately above clypeus; Lp1 mustard yellow, fringed ventrally with long scales; Lp2 mustard yellow, distal half gray-brown; Lp3 gray-brown; front with long, upwardly pointing cream to mustard-yellow scales, a few gray-brown scales near labrum; occiput mustard yellow; eye large and bulging; vertex mustard yellow with a few gray-brown scales interspersed; antenna narrowly bipectinate; antennal scape brown with a few buff-colored scales below; antennal shaft covered mostly with gray-brown scales above, a few cream-colored scales.

Thorax: Coxa creamy yellow; femur, tibia, and tarsus of prothoracic and mesothoracic legs gray-brown on inner surfaces, creamy yellow on outer surfaces; metathoracic leg entirely creamy yellow; spurs cream colored; pleural region covered with a mixture of cream-colored and gray-brown scales; patagium with a mixture of gray-brown and fewer cream-colored scales; tegula gray-brown at inner angle, orange-yellow at base, then fringed with long, cream-colored to mustard-yellow scales; dorsum broadly gray-brown along midline, with cream-colored scales laterally; tympanum slightly enclosed; tympanal membrane large, almost round, facing posterolaterally.

Forewing: (Dorsal) DC translucent, sparsely covered with mustard yellow and brown scales; an irregular, cream to light mustard-yellow transverse band beyond DC (pl. 16), its inner margin bordered by a thin, dark brown line; transverse band extending from costa to anal fold, band narrowest as it traverses M1 and M2, abruptly wider as it crosses base of M3+CuA1; outer third brown to dark brown with contrasting, mustard-yellow dashes along veins near margin; fringe dark brown; an oval-shaped, mustard-yellow to cream-colored apical spot present at base of Rs2–Rs4, its anterior margin touching Rs2 and its posterior margin crossing M1; costa dark brown; anal margin rich mustard yellow from base to two-thirds out, outer one-third dark brown. (Ventral) Pattern similar to dorsal surface except less brilliant; DC mostly brown; mustard yellow submarginal dashes in brown area not as contrasting.

Hind wing: (Dorsal) Rich creamy white to mustard yellow (pl. 16), a dark brown, elbow-shaped spot at apex. (Ventral) Similar to dorsal surface, except spot at apex lighter brown.

Abdomen: Dorsum gray-brown, with a few scattered cream-colored scales; venter covered with light, cream-colored scales.

Terminalia (fig. 171A–D): Tg8 widest in basal half, then gradually narrowing to form an elaborate distomedial process; distal process of Tg8 sclerotized, widely bifurcate at apex, crenulate laterally, with a strong, upcurved ridge along midline; anterior margin of Tg8 bearing a pair of small, thumb-shaped processes; St8 broad and wide, with small lateral bumps; posterior margin of St8 with a small, shallow V-shaped medial notch; socii/uncus complex small, uncus a tiny medial ridge, socii small, slightly upcurved; tegumen gradually widening in basal half; saccus narrow, forming a transverse band below; valva with BO extremely small, apparent only as a small series of ridges on margin near midpoint below; sclerotized apex of valva large, broadly rounded, with a small ventral lobe below; transtillar arms swollen near base, transverse, thinly joined at midline; aedeagus relatively wide, boat shaped, sides roughly parallel; distal portion of aedeagus ending in a thin flange, no apical tooth but several small serrations; vesica large, wide, with an ovoid opercular sclerite at base, and a single, long, serrate cornutus distally.

Female. Forewing length  =  13.0–14.0 mm. Wing pattern and body characters similar to male. Antenna with short, stubby rami; abdomen broad, truncate, St7 scaleless around ostium.

Terminalia (fig. 171E): Tg7 widest at anterior margin, narrower posteriorly, broadly sclerotized in distal half, with a large, central depression anteriorly; St7 wide, slightly wider at anterior margin; posterior margin of St7 with a deeply rounded medial excavation, excavated almost to margin itself; Tg8 small, forming a narrow, rooflike structure over PA; AA long and thin; PA quadrate; PP moderately long, thin; ostium wide, expanded dorsolaterally; DB short, wide, lightly sclerotized; CB large, dorsal half broadly sclerotized; DS arising from base of CB on right side above; a small, denticulate, wing-shaped signum present ventrally.

Etymology

This species is named in honor of Suzanne Rab Green, an expert on Arctiidae at the AMNH. During her years of fieldwork, Suzanne has collected important specimens of Dioptinae in Ecuador, Peru, Costa Rica, and Panama, all deposited at the AMNH. Her collections include type material of six newly described Nebulosa species—delicata, elicioi, grimaldii, hermani, huacamayensis, and rabae.

Distribution

Nebulosa rabae is known from cloud forests on the eastern slope of the Ecuadorian Andes, in Napo Province. The moth occurs within a relatively narrow altitudinal band (between 2100 and 2650 m), from Baeza south to Tena. This region roughly corresponds with the Cordillera Huacamayos, home to two other newly described Nebulosa species—elicioi and huacamayensis.

Discussion

Comparison of male genitalia (figs. 171A–D, 173) suggests that the other mustard-yellow Nebulosa, N. rawlinsi (pl. 16), is not a particularly close relative of N. rabae. Instead, as seems so commonly the case, the sister species of N. rabae is not among described material, but remains undescribed. The undescribed moth is currently known from four specimens (LACM), all collected at Sebundoi in eastern Ecuador, near La Bonita on the Colombian border, north of Volcán Reventador.

The undescribed species shares pattern elements with N. rabae, but its wings are white rather than mustard yellow in the light-colored areas. Their male genitalia differ. For example, the aedeagus of N. rabae ends in a broad flange, whereas that of the undescribed species terminates in an apical hook. The two can also be separated by the shape of the distal notch on Tg8—crenulate in N. rabae (fig. 171B), but broad and smooth in the other taxon. Slide data for this undescribed species are as follows: ♂, Ecuador, Napo-Pastaza, Sebundoi, between Santa Barbara and La Bonita, 2600 m, 11–15 Sep 1977, leg. L.E. Peña, LACM (genitalia slide no. JSM-1303); ♀, Ecuador, Napo-Pastaza, W. Sebundoi, 3000 m, 11–12 Sep 1977, leg. L.E. Peña, LACM (genitalia slide JSM-1341).

Holotype

Male (pl. 16). Ecuador: Napo: Yanayacu Biological Station, 5 km W Cosanga on Cosanga–Río Aliso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 4 Mar 2006, leg. J.S. Miller, MV light. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 1♂, Yanayacu Biological Station, 5 km W Cosanga on Cosanga-Río Aliso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 4 Mar 2006, leg. J.S. Miller (AMNH); 2♂♂, 4–5 Mar 2003, at light UV/MV, leg. S. Rab Green & M. Tapia (AMNH); 1♀, Río Alíso, 10 km W Cosanga, Cosanga–Río Alíso Rd., 2200 m, 25 Sep 2004, leg. J.S. Miller & E. Tapia, MV light, AMNH (genitalia slide no. JSM-1461); 2♂♂, Cosanga, 24 Jul 1996, F. Piñas (FPC; genitalia slide no. JSM-882); 3♂♂, South slopes Cerro Sumaco, 2250 m, 20 Nov 1995, leg. Jan Hillman, laguna in montane forest (CMNH; genitalia slide no. JSM-1302); 1♂, 2150 m, 16 Nov 1995, leg. Jan Hillman, bamboo and cloud forest (CMNH); 2♂♂, 1♀, Cordillera Huacamayos, San Fernando de Sierra Azul, 2350 m, 4 Aug 1996, leg. Jan Hillman, disturbed montane forest (CMNH; genitalia slide no. JSM-1301); 4♂♂, 1♀, Cerro Huacamayos, Estero Chico, 2650 m, 6 Aug 1996, leg. J. Hillman, virgin humid forest (CMNH).

Other Specimens Examined

None.

Dissected

2♂♂, 2♀♀.

Nebulosa rawlinsi, new species

Figures 172, 173; plate 16

Diagnosis

The wing pattern of Nebulosa rawlinsi makes this species unmistakable. Its FW and HW upper surfaces are uniformly mustard yellow (pl. 16), the only discernible FW pattern resulting from the brown areas on the ventral surface showing through. The species is relatively small and delicate. The head and thorax are covered with whitish yellow to light yellow scales. The abdomen is white with scattered light brown scales, except for A8, which is light gray-brown. This combination of traits is not found elsewhere in Nebulosa.

Description

Male. Forewing length  =  11.0–12.5 mm. Head: Labial palpus short and thin, held close to front, curving strongly upward to immediately above clypeus, all segments evenly cream colored; Lp1 with a ventral fringe of long, mustard-yellow scales; front and occiput covered with light, cream-colored scales; eye large and bulging; vertex covered with long, mustard-yellow scales; antenna narrowly bipectinate; antenna with scape light brown dorsally, mustard yellow below, dorsal surfaces of shaft light brown.

Thorax: Prothoracic and mesothoracic legs covered with light brown scales on outer surfaces, creamy white scales on inner surfaces; metathoracic leg entirely creamy white; patagium dark mustard yellow, almost orange; tegula orange to mustard yellow at base, with a distal fringe of long, cream-colored scales; dorsum creamy white; tympanal membrane large and almost round, facing posterolaterally.

Forewing: (Dorsal) Uniformly cream to mustard yellow (pl. 16), with no contrasting markings; the only visible pattern being that of ventral surface showing through, making FW slightly darker in area of DC and in wing's outer third, lighter beyond DC and along anal margin. (Ventral) Entirely light brown, except for a creamy white fascia beyond DC, and a fairly wide, creamy yellow band along anal margin.

Hind wing: (Dorsal) Light, creamy yellow in basal third (pl. 16), rich cream to mustard yellow beyond; no contrasting markings of any sort. (Ventral) Entirely cream colored, with no markings.

Abdomen: Segments A1–A7 creamy white; A8 light dusty brown.

Terminalia (fig. 173): Sides of Tg8 roughly parallel in basal two-thirds, slightly wider at two-thirds point, gradually tapered in distal one-third to a sclerotized distomedial process; shoulders of tapered portion sclerotized, slightly raised; distal process of Tg8 sclerotized, truncate, dentate laterally, with a strong dorsal ridge along midline; anterior margin of Tg8 with a pair of small, quadrate processes; St8 extremely wide, widest at posterior margin; lateroposterior angles of St8 forming ear-shaped processes extending distally, posterior margin transverse, simple, without a medial notch; anterior margin of St8 sclerotized, forming a broad triangle at midline; socii/uncus complex small, uncus small, triangular, socii short, curving slightly inward toward midline; ring (tegumen + vinculum) dorsolaterally compressed; tegumen slightly wider below; saccus forming a shallow, U-shaped structure; valva with BO well developed, curled anteriorly; costa of valva widely sclerotized, margins roughly parallel, curving dorsally forming a blunt, setose apical process with a small, expanded area below; transtillar arms widest at base, transverse, but oriented slightly downward to thinly join at midline; aedeagus wide, slightly narrower at base, apex with a small, recurved ventral tooth; an extremely long process extending from apex of aedeagus, process curved upward, tapered to a point at apex, surface finely spiculate, especially at base; vesica moderate in size, with a triangular, denticulate sclerite near base, cornuti absent.

Female. Unknown.

Etymology

This species is named after John E. Rawlins, curator of Lepidoptera at the Carnegie Museum of Natural History, Pittsburgh. John was an early mentor of mine while we were both graduate students, studying under John G. Franclemont at Cornell University. His infectious enthusiasm played a major role in the growth of my own entomology career. He and his CMNH colleagues have collected vast amounts of important neotropical insect material, especially in Ecuador and the Dominican Republic.

Distribution

Nebulosa rawlinsi is so rare that its distribution cannot be characterized. The species has been collected at two cloud forest localities (fig. 172): Maldonado on the western slope of the Andes in northern Ecuador, near the Colombian border; and La Otonga Reserve, also on the western side of the Ecuadorian Andes, located between the towns of San Francisco de Las Pampas and La Unión del Toachi. The moth undoubtedly occurs in similar habitats, at elevations near 2000 meters, in southwestern Colombia. It will eventually be found further south in Ecuador as well.

Discussion

Nebulosa rawlinsi is known from only two specimens—the holotype and a male paratype (FPC). Even though N. rawlinsi exhibits a mustard-yellow cast similar to that of N. rabae (pl. 16), numerous similarities of the male genitalia suggest that, among described species of Nebulosa, N. rawlinsi is most closely related to N. delicata (pl. 16). In both species there is an extremely long process arising from the apex of the aedeagus (figs. 165D, 173C), a structure unique for the genus. At least for Nebulosa, wing pattern seems to be a poor indicator of relationship.

Holotype

Male (pl. 16). Ecuador: Carchi: 18 km SE Maldonado, 2420 m, 27 Jul 1983, leg. John E. Rawlins (genitalia slide no. JSM-903). The type is deposited at the CMNH.

Paratypes

Ecuador: Cotopaxi: 1♂, Otonga, 2200 m, 22 Feb 1998, leg. F. Piñas (FPC).

Other Specimens Examined

None.

Dissected

Holotype.

Nebulosa thanatos (Hering), new combination

Plate 16

Tithraustes thanatos Hering, 1925: 513, fig. 69c.

Type Locality

Peru, Cuzco.

Type

Holotype ♂; not seen (“in Coll. Seitz”).

Discussion

My identification of N. thanatos is based on the original description, and on the color figure in Hering (1925: fig. 69c). I was unable to locate Hering's type, noted by him as in the A. Seitz Collection. That specimen is not housed at the ZMH in Berlin, where Hering's other dioptine type material resides. Nevertheless, I am quite certain of the identity of N. thanatos. Among other features, this moth differs from N. mirma (pl. 16), with which it is closely related and shares a similar distribution, in possessing a light yellow to orange subapical FW spot, rather than a tiny white one.

I know this species from a series of 10 males and five females at the BMNH, as well as from two AMNH females. I collected the latter (October 2005) in the Cosñipata Valley of southeastern Peru, at an altitude of 1650 meters.

Distribution

Peru (AMNH, BMNH, ZMH); Bolivia (BMNH).

Dissected

♂, Bolivia, leg. Germain, BMNH (genitalia slide no. JSM-540); ♀, Bolivia, Cochabamba, Yungas del Espirito Santo, 1888–89, leg. P. Germain, BMNH (genitalia slide no. JSM-541).

2. PLATAEA GROUP

My research suggests that four species—N. bialbifera, N. cletor, N. ocellata, and N. platea—form a subclade, the Plataea Group, within Nebulosa. They are characterized by having FW veins M3 and CuA1 arising separately from the posterolateral angle of the DC (fig. 162E), a condition unique within Nebulosa. In males, the FW stridulatory organ is characterized by a DC approximately one-half the wing length. The FW also shows a tiny, light yellow or light orange submarginal spot straddling vein M2 (pl. 17). The metathoracic tympanum of the Plataea Group is unusually large for Nebulosa species, most of which have a relatively small tympanum. Furthermore, an anteroventral orientation of the tympanal membrane in Plataea Group species is unique for Nebulosa, where it usually faces posteroventrally (fig. 160F). The eyes are variable in size, either small, completely surrounded by a scaleless band (N. ocellata, N. cletor), or large and bulging (N. plataea; fig. 159K). Unique features of the male genitalia include a long uncus, curving downward (figs. 174A, 175A), and extremely long, narrow socii, curving upward. The female postvaginal plate is folded and its surface is densely spiculate (fig. 175E).

The four Plataea Group species have the following taxonomic histories: bialbifera Warren and cletor Druce are transferred to Nebulosa from Tithraustes Druce; plataea Druce was taken from Xenorma Prout; and ocellata is here described.

KEY TO PLATAEA GROUP SPECIES

1. Forewing with a white transverse band crossing distal margin of DC (pl. 17); FW ground color dark brown, veins ochreous2

FW with a white triangle along posterior margin, extending from near base to half way out (pl. 17); FW ground color brown to blackish brown, veins concolorous3

2. Hind wing central area white; white FW band narrow, extending from costa to beyond anal fold, falling well short of wing margin; submarginal FW spot on M2 inconspicuous, ochreous (E Ecuador)bialbifera (Warren)

HW uniformly dark chocolate brown; white FW band wide, extending from costa to wing margin near tornus; submarginal FW spot on M2 conspicuous, whitish yellow (Ecuador, Bolivia)cletor (Druce)

3. Anterior angle of white FW triangle extending past cubital vein into DC; eye large, bulging outward (fig. 159K), surrounded by scales except for a narrow region near clypeus; socii of male genitalia with a tiny ventral knob at elbowlike bend (fig. 174A); inner surface of valva smooth (fig. 174A), apex broadly scoop shaped (Ecuador)plataea (Druce)

Anterior angle of white FW triangle terminating at cubital vein; eye relatively small, surrounded by a scaleless band, gena wide; socii with a large, flangelike process at elbowlike bend (fig. 175A); inner surface of valva with a large, sclerotized flange (fig. 175A), expanded toward apex (Peru, Bolivia)ocellata, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Nebulosa bialbifera (Warren), new combination

Plate 17

Phaeochlaena bialbifera Warren, 1904: 18.

Type Locality

Ecuador (eastern), Rosario, St. Inez, 1250 m.

Type

Syntype ♂/♀, leg. Haensch, 7 Nov 1899 (BMNH).

Discussion

The only material of N. bialbifera so far known consists of the male syntype (pl. 17), which is missing its abdomen, and the female syntype. Study of superficial characters confirms placement of bialbifera in Nebulosa. Although the transverse FW band in this species bears resemblance to some members of the Nervosa Group (pl. 16), I have instead placed N. bialbifera in the Platea Group. My rationale is based on wing-pattern similarities between N. bialbifera and N. cletor (pl. 17), a taxon whose membership in the Plataea Group is confirmed by genital morphology. However, this placement of N. bialbifera should be considered provisional, pending additional morphological study.

Distribution

Ecuador (BMNH).

Dissected

None.

Nebulosa cletor (Druce), new combination

Plate 17

Polypoetes cletor Druce, 1893: 296.

Type Locality

Ecuador, Intaj.

Type

Holotype ♂, leg. Buckley (BMNH).

Discussion

Material of Nebulosa cletor (pl. 17)—three specimens in all—shows a disjunct distribution, having been recorded from Ecuador and Bolivia. As far as I am aware, no examples are known from Peru. Dissections have not been performed comparing material from Ecuador and Bolivia, but it seems likely that two taxa are involved.

Nebulosa cletor, with its wide, white FW cross-band, differs in wing pattern from N. plataea and N. ocellata (pl. 17). However, the female genitalia of cletor show unmistakable synapomorphies indicating membership in the Plataea Group, examples being a swollen, sclerotized region between the CB and ostium, and the presence of a densely spiculate PVP.

Distribution

Ecuador (BMNH); Bolivia (BMNH, USNM).

Dissected

♀, Bolivia, Río Songo, 750 m, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1612).

Nebulosa ocellata, new species [EX]

Figures 175, 176; plate 17

Diagnosis

Nebulosa ocellata can quickly be identified as a member of the Plataea Group because FW veins M3 and CuA1 arise separately from the DC (fig. 162E), rather than being stalked as they are in all other Nebulosa subgroups (fig. 162A, C, D, F). The large white triangle along the FW posterior margin (pl. 17), in conjunction with presence of a tiny submarginal spot on M2, occurs only in N. ocellata and N. plataea within the Dioptinae. Separating these two, whose wing patterns are similar, can be accomplished by examining the eyes, which are large and bulging in Plataea (fig. 159K), but small in ocellata. The white FW triangle is also slightly smaller in ocellata (see Key to Plataea Group species). Numerous genital characters, such as the shape of the male valva and socii/uncus complex (fig. 175A), are unique to this species.

The description below is based on material from southeastern Peru, which is grayer than specimens from Bolivia. Bolivian examples are generally brown, and the light-colored wing areas exhibit more yellow than white. However, their genitalia are identical, indicating that N. ocellata occurs in both countries.

Description

Male. Forewing length  =  12.5–13.0 mm. Head: Labial palpus short, curved strongly upward to immediately below middle of front; Lp1 fairly short, strongly curved, loosely covered with creamy white to light yellow scales, a tuft of long white scales arising from base, and a sparse fringe of longer light yellow scales along venter; Lp2 short, almost straight, shorter than Lp1, mostly cream colored, a few light yellow scales near base, a row of longer dark brown scales distally; Lp3 short, quadrate, closely covered with dark brown scales; scales of front pointing dorsomedially, meeting at midline, central area gray-brown, lateral portions creamy white with a few light brown scales; dorsal scales of front slightly longer, forming short, acute tufts between antennal bases; occiput white with a few light brown scales; eye relatively small, a narrow scaleless band anteriorly and posteriorly, a wider band dorsally, gena wide, black, minutely spiculate; vertex covered with long, gray, anteriorly pointing scales, a few scattered long, white scales behind antennal bases; antenna bipectinate, rami fairly long, terminal 7–9 flagellomeres simple; scape gray with a small patch of white scales ventrally; dorsum of antennal shaft covered with appressed, glossy, gray black scales, lateral margins of shaft trimmed with long white scales.

Thorax: Outer portions of legs gray, inner portions white to creamy white; tibia gray to gray-brown; pleuron covered with short gray scales and a few long white scales; patagium covered with long gray scales, a few long white scales near midline; tegula light yellow to light orange-yellow in central portion, margin trimmed with long gray scales, apex bearing hairlike, light gray scales; dorsum covered with appressed gray scales along midline, a pair of wide, light yellow to white longitudinal bands on either side of midline; tympanum moderately large, cavity deeper than most Nebulosa (but typical for Plataea Group), a small area within cavity (below membrane) scaleless; tympanal membrane large, ovoid, facing anteroventrally.

Forewing: (Dorsal) Ground color charcoal gray to dark gray-brown (pl. 17); veins thinly lined with light yellow to light orange-yellow scales; a tiny, round, white to light orange-yellow, submarginal spot located on vein M2; posterior margin bearing an immaculate white triangle, basal angle of triangle terminating well short of base, distal angle terminating at approximately halfway point, anterior angle touching, but not crossing, cubitus; a small, diffuse fascia present beyond DC between bases of M1 and M2, its surface sparsely covered with short, spatulate dark gray scales. (Ventral) Similar to dorsal surface, except: veins not lined with light scales, concolorous with ground color; white triangle on anal margin larger; submarginal spot on M2 slightly larger.

Hind wing: (Dorsal) Central area immaculate white (pl. 17), semihyaline, extending distally to immediately beyond fork of M3+CuA1; a wide, dark charcoal-gray marginal band extending from apex to tornus; anterior margin of wing white; anal margin white in basal half, light gray in distal half, trimmed with light gray to light gray-brown hairlike scales; wing base dark gray. (Ventral) Similar to dorsal surface, marginal band almost black, gray region at wing base slightly larger.

Abdomen: Dorsum, including pleuron, slate gray to charcoal gray; venter white.

Terminalia (fig. 175A–D): Tg8 longer and wider than St8, broadly trapezoidal, posterior margin slightly wider than anterior one, a wide membranous band along midline; anterior margin of Tg8 simple, posterior margin simple, slightly convex, finely wrinkled along edge; St8 short and relatively wide, roughly heart shaped; anterior margin of St8 with a broad, acute mesal apodeme, posterior margin with a deep, U-shaped mesal excavation, an evenly sclerotized band along edge; socii/uncus complex extremely large, projecting posteriorly, junction with tegumen narrow; uncus long, narrow, curving strongly downward, apex acute, minutely crenulate below; socii extremely long, wide and robust at bases, elbowed sharply upward (almost 90°) at basal third, elbow bearing a large, scoop-shaped ventral flange; distal two-thirds of socii narrow, upright, extending well above uncus, with a serrate ridge along inner surface, apices subacute; tegumen much taller than vinculum, arms moderately wide, sides parallel; arms of tegumen approximate, almost touching; vinculum much shorter and slightly narrower than tegumen, forming a cone-shaped saccus below; ventral margin of saccus acute, dorsal margin almost horizontal, extending beyond valva apex; valva wide, robust, almost entirely sclerotized except for basomedial portion; costa extremely wide, narrow at base and at apex; inner surface of valva bearing a large, raised, heavily setose sclerotized area, this extending beyond apex; distal portion of sclerotized area broadly emarginate, outer edge wavy; saccus small and narrow, sclerotized; BO nearly absent, pleats extremely faint, lateral surface bearing short androconia; valva bases narrowly joined; juxta absent; transtillar arms short, strongly curved (almost 90°), narrow at junction with valva, swollen and sclerotized in middle, surface heavily spiculate, arms meeting at midline to form a laterally compressed sclerite; aedeagus moderate in length, base wide and funnel shaped, abruptly narrowed in distal two-thirds; apex of aedeagus rounded; vesica long, approximately equal in length to aedeagus, distal portion bearing a group of 5–8 long, narrow, spinelike cornuti.

Female. Forewing length  =  13.0–14.5 mm. Wing and body characters similar to male, except: labial palpus shorter, ascending upward to slightly above clypeus; antenna bipectinate, rami short; wings longer and broader than male, FW and HW ground color lighter gray-brown; FW stridulatory organ, and associated fascia, absent.

Terminalia (fig. 175E): Tg7 large, wide, narrowing distally, anterior margin simple, posterior margin with a small, quadrate mesal notch, a narrow, U-shaped, membranous area behind notch; St7 extremely wide, shorter than Tg7; lateral portions of St7 heavily sclerotized, margins convex, wrapping upward to touch lateral margins of Tg7; anterior margin of St7 simple, posterior margin with an extremely wide U-shaped mesal excavation extending anteriorly for more than one-half sternum length; Tg8 short, sclerotized, concave along dorsum, surface covered with minute spicules; AA long, thin, curving slightly downward; PA moderate in size, roughly ovoid, a small bump along posterior margin; PP short, apices acute; region surrounding PA deeply infolded, sclerotized, surface minutely spiculate, a second, large ventral fold above ostium; DB moderately in length, tubular, membrane thickened; ostium with numerous membranous folds at junction with DB, expanding into an irregularly shaped funnel; PVP lightly sclerotized, loosely folded, surface shagreened; CB almost round, membranous, constricted at base to form a wide, curved, sclerotized portion joining DB; signum small, located ventrally one-third of distance from base, forming a pair of wings, their inner surfaces minutely dentate; DS attached dorsally at junction of DB and sclerotized base of CB.

Etymology

The name ocellata, from the Latin word meaning, “having small eyes”, refers to the small eyes of this species compared to the large, rounded eyes of its sister species, N. plataea.

Distribution

Based on available material of N. ocellata, most of which was collected in the late 1800s, this species occurs in cloud forests along the eastern slope of the Andes from southeastern Peru south to Espiritu Santo (17°04′55″S, 65°38′02″W; elevation  =  1360 m), near Cochabamba in central Bolivia. The lowest elevation so far recorded is 1200 meters (AMNH), and the highest comes from material collected in the Cosñipata Valley of southeastern Peru (2300 m).

There is a large geographical gap between the localities for the species pair N. ocellata and N. plataea (fig. 176), spanning an area from near Cuzco, Peru north to Loja, Ecuador. Collecting in the vast area between these locations, which encompasses most of the length of Peru, may reveal more detail regarding the distributions of the two taxa.

Discussion

I had long known that the BMNH and ZMH collections housed material, identified as plataea, collected in Bolivia before the turn of the 20th century. However, the type locality for plataea is Chiguinda, Ecuador. My attempt to identify specimens captured in Peru (October 2005) revealed the existence of a second species, here described as N. ocellata. The wing pattern of N. ocellata differs only slightly from that of N. plataea (pl. 17), but their male genitalia are drastically different, and their eyes differ markedly in size (see Diagnosis).

I collected the male holotype and female paratype of N. ocellata on the same date and at the same locality, in late afternoon, along a dirt road passing through the Cosñipata Valley east of Cuzco. Both specimens were sitting on the flowers of an unidentified white Asteraceae, common along the roadside. Presumably, the moths were feeding on nectar.

Holotype

Male (pl. 17). Peru: Cuzco: Cosñipata Valley, Pillahuata-Pilcopata Rd., 2300 m, S13°08′58″, W71°35′07″, 23 Oct 2005, leg. J.S. Miller, day coll., on Compositae flowers (genitalia slide no. JSM-1608). The holotype is deposited at the AMNH.

Paratypes

Peru: Cuzco: 1♀, Cosñipata Valley, Pillahuata-Pilcopata Rd., 2300 m, S13°08′58″, W71°35′07″, 23 Oct 2005, leg. J.S. Miller, day coll., on Compositae flowers (AMNH; genitalia slide no. JSM-1610).

Other Specimens Examined

Bolivia: La Paz: 1♂, Río Tanampaya, La Paz, 1894, leg. Garlepp (ZMH). Cochabamba: 1♂, Yunga del Espiritu Santo, 1888–89, leg. P. Germain (BMNH; genitalia slide no. JSM-1611); 1♀, Yungas de Puente Villa, 1200 m, 15 Dec 1955, leg. L.E. Peña (AMNH; genitalia slide no. JSM-1044).

Dissected

2♂♂, 2♀♀.

Nebulosa plataea (Druce), new combination

Figures 159K, 162E, 174, 176; plate 17

Trochiodes plataea Druce, 1893: 310, pl. 21, fig. 22.

Type Locality

Ecuador, Chiguinda.

Type

Syntype ♂, leg. C. Buckley (BMNH).

Discussion

Druce (1893) described plataea in the genus Trochiodes, currently a member of the Geometridae (Laurentiinae). Prout (1918) moved this taxon to the dioptine genus Xenorma, an assignment followed by subsequent authors (Hering, 1925; Bryk, 1930). Here, Nebulosa plataea (Druce) is proposed as a new combination. Although Prout provided no rationale for his judgment, it was probably based on the observation that veins M3 and CuA1 are separate in the FW of N. plataea, but stalked in the HW (fig. 162E). These characteristics also occur in the wings of Xenorma (fig. 53F). However, my analyses demonstrate that this trait, extremely inconsistent throughout the Dioptinae, is by itself an unreliable diagnostic character. Furthermore, none of the other wing venation traits exhibited by N. plataea correspond with those in Xenorma. For example, the male FW stridulatory organ of N. plataea is absent in Xenorma. When all adult morphology is considered, plataea falls firmly within Nebulosa.

Chiguinda, Ecuador—the type locality for N. plataea—is a famous site for much of Buckley's material, now at the BMNH. The town is located in Morona-Santiago Province (03°16′52″S, 78°41′54″W), on the eastern slope of the Andes at an elevation of 1700 meters. The locale is relatively close to Zamora (fig. 5). The sister species of N. plataea, N. ocellata, occurs at similar altitudes in southeastern Peru and eastern Bolivia.

Distribution

Ecuador (BMNH, SMNS).

Dissected

♂, Ecuador, Zamora-Chinchipe, Río San Francisco, Estación Cientifica San Francisco, S3°58′, W79°4′, SG 1 (8), 1912 m, 3 Oct 2002, LF IV, 20.15–20.45 h, leg. N. Hilt & C. Schultz, SMNS (genitalia slide no. JSM-1609).

3. HERMANI GROUP

The described members of the Hermani Group are relatively small (FW length  =  12.0–15.0 mm). Their FW is elongate (pl. 17) with a small, whitish yellow to orange submarginal spot located on vein M2. The FW ground color is a dull, greyish olive. Hermani Group males possess a FW stridulatory organ (fig. 162D), with the bases of M1 and M2 swollen, but the DC is longer than one-half the wing length. In most Nebulosa species, the DC is significantly shorter (fig. 162A, C, E, F).

Both included species of the Hermani Group, known exclusively from Ecuador, are newly described here. However, as is noted in the Nebulosa discussion (above), existing collections contain at least two undescribed Ecuadorian Hermani Group taxa. Collecting in the cloud forests of southern Colombia and northern Peru will undoubtedly extend the range of this group into those countries.

KEY TO HERMANI GROUP SPECIES

Plate 17

1. Hind wing white with a gray-brown marginal band, extending from apex to anal fold or slightly beyond; FW submarginal spot on M2 light yellow-orange; male valva (fig. 178A) gently narrowed toward apex (W Ecuador)hermani, sp. nov.

HW white with a gray-brown marginal band, extending from apex to tornus; FW submarginal spot on M2 whitish; valva (fig. 177A) constricted near apex (E Ecuador)grimaldii, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Nebulosa grimaldii, new species

Figures 177, 179; plate 17

Diagnosis

The wing-pattern traits listed in the key to Hermani Group species can be used to distinguish N. grimaldii from its sister taxon, N. hermani (pl. 17). The shape of the dark brown HW marginal band and the color of the FW submarginal spot are obvious differences. Numerous genitalia characters are also useful for separation. For example, the valva in N. grimaldii is constricted near its apex (fig. 177A), whereas the valva in N. hermani is gently narrowed toward the apex (fig. 178A). Females are likewise easy to separate: Tg8 is simple along its posterior margin in N. hermani (fig. 178E), but in N. grimaldii the distal margin of Tg8 bears folds and transverse rugae (fig. 177F). The PVP offers additional structural differences.

Description

Male. Forewing length  =  13.5–14.0 mm. Head: Labial palpus relatively short, held close to head, curving strongly upward to below middle of front; Lp1 moderately long, curving upward, Lp2 short and thin, almost straight, shorter than Lp1, Lp3 short, apex acute; Lp1 and Lp2 lemon yellow to orange-yellow, with a loose fringe of longer scales ventrally; Lp3 tightly covered with glossy, gray-brown scales, these forming an acute apex; central portion of front glossy gray-brown, lateral portions with long, upwardly pointing, buff-colored to light orange-yellow scales reaching to beyond antennal bases; occiput light brown near dorsum and immediately behind eye, remainder cream colored to creamy yellow; eye large and rounded, bulging outward, gena absent; vertex brown to light brown, with a few buff-colored scales posteriorly and behind antennal bases; antenna bipectinate, rami long; scape brown, light brown ventrally; dorsum of antennal shaft covered with appressed, glossy gray-brown scales.

Thorax: Legs white to cream colored on inner surfaces, glossy gray-brown on outer ones; pleuron cream colored, covered with a mixture of hairlike and short scales; patagium covered with long, erect scales, lateral halves gray-brown, mesal halves creamy white; tegula relatively short, base orange-yellow, becoming creamy white toward apex, margin fringed with long, hairlike, gray-brown scales; dorsum gray-brown with a pair of wide, diffuse, creamy yellow bands on either side of midline; tympanum large, cavity shallow, a small scaleless area ventrally; tympanal membrane extremely large, roughly triangular, facing posterolaterally.

Forewing: (Dorsal) Ground color olive brown to gray-brown (pl. 17); veins lined with light yellow to light orange-yellow scales; a wide, creamy white dash surrounding basal third of anal fold, distal two-thirds of fold light yellow; a round, translucent white fascia immediately beyond DC, its anterior margin touching base of Rs1–Rs4, its posterior margin extending slightly past fork of M3+CuA1; a small, round, white spot near outer margin, centered on M2, spot almost touching M1 anteriorly, falling well short of M3 posteriorly. (Ventral) Ground color gray-brown, veins concolorous except basal third of anal fold thinly lined with creamy white scales; fascia beyond DC and submarginal spot on M2 creamy white.

Hind wing: (Dorsal) Central area creamy white (pl. 17); outer margin with a wide, gray-brown band extending from apex to tornus, band widest at apex, narrowest at CuA2; anterior margin light gray-brown; anal margin white to light gray-brown, fringe creamy white. (Ventral) Similar to dorsal surface, except anterior margin and anal margin creamy white; fringe buff colored to light brown.

Abdomen: Dorsum gray-brown; pleuron a mixture of gray-brown and creamy white scales; venter white to creamy white.

Terminalia (fig. 177A–D): Tg8 long, wide, anterolateral angles expanded; anterior margin of Tg8 gently concave, forming a pair of extremely short apodemes, lateral margins concave; posterior margin of Tg8 deeply excavated at lateral angles, forming a wide, short mesal process, distal margin of process rugose, minutely dentate, slightly convex; St8 wider and shorter than Tg8; anterior margin of St8 wedge shaped, forming a short, blunt mesal apodeme, lateral margins diverging slightly distally; posterior margin of St8 with a deep, extremely wide, trapezoidal mesal excavation, posterolateral angles forming a pair of long, narrow, inward pointing processes; socii/uncus complex small, roughly triangular; uncus short, curving gently downward, forming an acute, beaklike apex; socii short, elbowed strongly upward, each with digitate process at elbow below; tegumen taller than vinculum; arms of tegumen wide, narrowing dorsally; arms of vinculum relatively narrow; saccus wide, somewhat convex, dorsal margin upturned to form a triangular sclerite, barely covering junction of valva bases; valva long, somewhat narrow; BO occupying less than one-half of valva, pleats short, robust, lateral margin of BO slightly curled anteriorly; costa of valva narrow, dorsal margin concave; valva apex curving dorsomedially, forming an expanded, earlike structure, inner surface densely setose, lateral surface sclerotized; juxta diffuse, heart shaped; transtillar arms narrow, straight, oriented horizontally, meeting above aedeagus to form a tiny, U-shaped sclerite; aedeagus long, moderately wide, slightly constricted near base, curved downward in distal half; apex of aedeagus gradually acute; vesica almost as long as aedeagus, slightly wider, opening upward, curving anteriorly, with an abrupt bend near base, bearing a robust, spinelike cornutus on a small appendix in basal third, and a dense series of short, spinelike cornuti in distal third.

Female. Forewing length  =  14.0 mm. Body and wing colors similar to male. Other characters similar to male, except: labial palpus shorter, reaching upward to immediately above clypeus; antenna bipectinate with extremely short, nublike rami; frenulum comprising eight bristles.

Terminalia (fig. 177E–G): Tg7 longer than Tg6, equal to it in width at anterior margin, gradually tapering distally; anterior margin of Tg7 simple, posterior margin transverse, only one-third as wide as anterior margin; St7 wide, heavily sclerotized, lateral angles expanded outward; anterior margin of St7 simple, broadly convex, posterior margin with a huge, U-shaped mesal excavation, reaching almost to anterior margin; Tg8 short, U-shaped, wide anteriorly, abruptly tapered, posterior margin truncate, heavily sclerotized, bilobed with transverse folds, surface spiculate; AA long, sharply tapered to thin points; ostium and PVP together forming a large, funnel-shaped structure; PVP forming a broad, concave triangle, posterolateral angles expanded, posterior margin transverse; ostium a deep cylinder, narrower anteriorly; DB short, membranous; DS arising from a small, bulbous appendix at junction of DB and CB; CB large, almost round; signum ovoid, with a seam along midline, located on right side of CB near base, internal surface coarsely dentate; PA ovoid, posterior margin slightly angulate; PP long and thin, heavily sclerotized, almost straight.

Etymology

This species is named in honor of Dave Grimaldi, curator of Diptera and fossil insects at the AMNH. Dave and I have known each other since our days in graduate school at Cornell University (1981–1985)—two budding morphologists learning from George Eickwort, Bill Brown, and John Franclemont. I will forever be grateful for Dave's inspirational support during the production and writing of this publication.

Distribution

Nebulosa grimaldii is known from a handful of specimens. Based on these, the moth occurs in a small area of eastern Ecuador near the town of Cosanga (fig. 179). All of this material was caught within a narrow altitudinal band, ranging from 2000 to 2200 meters. The only female discovered to date (CMNH) was collected on the lower slopes of Cerro Sumaco, a volcano approximately 30 km east of Cosanga (see Polypoetes sumaco, sp. nov.).

Discussion

It is interesting that N. grimaldii is known exclusively from recent collections; the oldest known example (CMNH) was collected in 1995. This is perhaps testament to the rarity of the species, but more likely reflects the general neglect that Dioptinae have received from amateur and professional Lepidoptera collectors. Cloud-forest dioptines, which tend to be small and relatively drab, have been almost completely overlooked. It is hoped that this paper will help reverse that trend.

Holotype

Male (pl. 17). Ecuador: Napo: Yanayacu Biological Station, S 00°35.9′, W 77°53.4′, 2163 m, 4–5 Mar 2003, at light UV/MV, eastern cloud forest, undisturbed, leg. S. Rab Green & M. Tapia. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 1♂, Río Alíso, 10 km W Cosanga, Cosanga-Río Alíso Rd., 2200 m, 25 Sep 2004, MV light, leg. J.S. Miller & E. Tapia (AMNH); 1♂, Cosanga-Tena, 2030 m, 29 May 1998, leg. F. Piñas (FPC); 1♂, Cosanga, 24 July 1996, leg. F. Piñas (FPC; genitalia slide no. JSM-891); 1♀, South slopes Cerro Sumaco, 2250 m, 20 Nov 1995, laguna in montane forest, leg. Jan Hillman (CMNH; genitalia slide no. JSM-1653).

Other Specimens Examined

None.

Dissected

1♂, 1♀.

Nebulosa hermani, new species

Figures 159L, 162D, 178, 179; plate 17 [EX]

Diagnosis

The key to Hermani Group species (above) lists features for separating N. hermani from the only moth with which it could potentially be confused, N. grimaldii. The simplest of those is the color of the submarginal FW spot on M2—light orange in N. hermani, but white in N. grimaldii (pl. 17). Genitalia differences are discussed in the diagnosis for N. grimaldii. If all else fails, their geographic distributions set them apart (fig. 179); N. hermani is restricted to the western side of the Ecuadorian Andes, whereas N. grimaldii is eastern.

Description

Male. Forewing length  =  13.0–15.0 mm. Head (fig. 159L): Labial palpus relatively short, held close to head, curving upward to below middle of front; Lp1 moderately long, curving upward, Lp2 short and thin, almost straight, shorter than Lp1, Lp3 short, apex acute; Lp1 and Lp2 mustard yellow to light orange-yellow, with a loose fringe of longer scales ventrally; Lp3 tightly covered with dark brown scales, forming an acute apex; central portion of front gray-brown, lateral portions with long, upwardly pointing, buff to light orange-yellow scales reaching antennal bases; occiput creamy white to light yellow; eye large and rounded, bulging outward, gena absent; vertex light brown with a few buff-colored scales posteriorly and behind antennal bases; antenna widely bipectinate; scape and dorsal surfaces of antennal shaft light brown to brown.

Thorax: Legs white to creamy white on inner surfaces, glossy light brown on outer ones; pleuron cream colored, covered with a mixture of hairlike and short scales; patagium light brown, a few creamy white scales near midline; tegula relatively short, creamy white to light yellow-orange, fringed with light brown hairlike scales; dorsum light brown, buff to light yellow laterally; tympanum large, cavity shallow, a small scaleless area ventrally; tympanal membrane extremely large, roughly triangular, facing posterolaterally.

Forewing: (Dorsal) Ground color brown to light brown (pl. 17); veins lined with light orange scales; basal third of anal fold creamy white, distal two-thirds light orange; a diffuse, translucent white fascia immediately beyond DC, its anterior margin falling short of base of Rs2–Rs4, its posterior margin falling short of fork of M3+CuA1; a small, light orange spot near margin, centered on M2 but not touching M1 or M3. (Ventral) Ground color light brown, veins concolorous (pl. 17); fascia beyond DC white; spot near margin white, rather than light orange as on dorsal surface.

Hind wing: (Dorsal) Ground color translucent white (pl. 17); outer margin with a dark brown band, extremely wide at apex, abruptly tapering to anal fold; anterior margin thinly lined with light brown; anal margin white. (Ventral) Similar to dorsal surface, except anterior margin white rather than brown.

Abdomen: Dark, gray-brown on dorsum; venter creamy white.

Terminalia (fig. 178A–D): Tg8 elongate, narrow, tapered distally; anterior margin of Tg8 simple, lateral margins slightly concave at midpoint, abruptly narrowed in distal third; posterior margin of Tg8 forming a T-shaped mesal process, stem of T wide, gently humped on dorsum, top of T sclerotized, slightly curved, surface coarsely dentate; St8 wider and shorter than Tg8; lateral margins of St8 convex, anterior margin bearing an extremely short, wide mesal process; posterior margin of St8 with a wide, U-shaped mesal excavation, almost as wide as sternum, posterolateral angles forming long, backward pointing projections; socii/uncus complex small, roughly triangular; uncus short, curving downward, widest at base, tapered to a point at apex; socii short, elbowed sharply upward, each with a spinelike process at elbow below; tegumen taller than vinculum; arms of tegumen moderately wide, wider below; arms of vinculum narrow; saccus transverse, upturned at midline to form a triangular sclerite, barely covering junction of valva bases; valva moderately wide; BO small, occupying less than one-half of valva, pleats short, lateral margin of BO curled anteriorly; costa of valva narrow, dorsal margin gently concave; valva apex curving dorsomedially, forming a blunt process, mesal surface setose, lateral surface sclerotized; juxta diffuse, heart shaped; transtillar arms narrow, straight, oriented horizontally, meeting to above aedeagus to form a tiny U-shaped sclerite; aedeagus long, moderately wide, recurved in distal half; apex of aedeagus with a large, broad, flange-shaped ventral process; vesica almost as long as aedeagus, opening upward, gradually curving anteriorly, bearing a robust, thornlike cornutus on a small appendix in basal third, and a series of short, spinelike cornuti in distal fourth.

Female. Forewing length  =  13.0–15.5 mm. Head, thorax, wings, and abdomen similar to male, except: area of HW apex more diffusely dark brown; antenna with extremely short, stubby rami.

Terminalia (fig. 178E): Tg7 longer than Tg6, equal to it in width at anterior margin, gradually tapering distally; anterior margin of Tg7 simple, lateral margins slightly excavated near midpoint, distal portion slightly convex; St7 wide, heavily sclerotized, lateral angles rounded, produced posteriorly; anterior margin of St7 simple, posterior margin with a huge, U-shaped mesal excavation, reaching almost to anterior margin; Tg8 short, triangular, wide anteriorly, abruptly tapered, posterior margin convex, forming a small rooflike structure above PA; AA long, sharply tapered to thin points; ostium and PVP together forming a large, funnel-shaped structure; PVP forming a broad triangle, posterolateral angles expanded, posterior margin slightly concave; ostium cylindrical; DB short, membranous; DS arising from a small appendix at junction of DB and CB; CB large, ovoid; signum an elongate oval, with a seam along midline, located on right side of CB near middle, internal surface coarsely dentate; PA slightly elongate, quadrate, posterior margin smoothly convex; PP long, thin, heavily sclerotized, slightly curved.

Etymology

This species is named in honor of Lee Herman, curator of Coleoptera at the AMNH and one of the world's leading experts on Staphylinidae. For me, Lee's insights into music, politics, bugs, and life in general continue to challenge and inspire. Lee and I have made numerous field trips together to Central and South America. Our initial expedition was to Ecuador in 1988. Although I had been studying dioptine taxonomy for several years at that point, I had never seen one alive—only pinned museum material. During our first day in the field, a breathtaking drive through the Andes on the dirt road from Quito to Chiriboga, I collected my first dioptine, a specimen of Nebulosa hermani.

Distribution

Nebulosa hermani is a cloud-forest species occurring on the western slope of the Ecuadorian Andes (fig. 179), at elevations between 2000 and 2800 meters. The furthest north it has been collected is Maldonado in Carchi Province, on the Colombian border (VOB), and the furthest south is near Pallatanga in Chimborazo Province (CMNH). Its range thus roughly spans the northern two-thirds of Ecuador. Additional collecting will undoubtedly extend this distribution north into Colombia and south into the lower third of Ecuador.

Discussion

It seems strange that all known specimens of N. hermani were collected within the past 20 years. I have seen none in historical collections, such as those of the BMNH, MNHN, or USNM. This same phenomenon occurs in N. grimaldii. In this paper, I describe 10 new species of Nebulosa, in part to highlight the need for more rigorous sampling of cloud-forest moths.

Nothing is known regarding the life history of either species in the Hermani Group. I have collected occasional adults of N. hermani at lights, but more typically they are captured flying in disturbed, weedy areas along roadsides, in midmorning and late afternoon. The species is not common. In March 2006, I spent considerable effort traveling to Las Palmeras, a remote mountain location where N. hermani had been collected on previous trips, only to be frustrated by the moth's absence.

Holotype

Male (pl. 17). Ecuador: Pichincha: Las Palmeras, 59 km W Quito, 8 km W Chiriboga, 6400 ft, 25 Oct 1988, leg. J.S. Miller. The type is deposited at the AMNH.

Paratypes

Ecuador: Pichincha: 1♂, Las Palmeras, 59 km W Quito, 8 km W Chiriboga, 6400 ft, 25 Oct 1988, leg. J.S. Miller (AMNH; genitalia slide no. JSM-728); 1♀, 24 Oct 1988, leg. J.S. Miller & L. Herman, black light (AMNH; genitalia slide no. JSM-1500); 2♀♀, 15 Oct 1988, leg. J.S. Miller & L. Herman (AMNH); 1♂, W Quito, E Chiriboga, 7900 ft, 15 Oct 1988, leg. J.S. Miller, at flowers (AMNH; genitalia slide no. JSM-1499, wing slide no. JSM-1662); 2♀♀, 39 km NE Alluriquín, old Quito-Sto. Domingo Rd, 7100 ft, 25 Oct 1988, leg. J.S. Miller (AMNH; genitalia slide no. JSM-729); 1♀, on foliage, 21 Oct 1988, leg. J.S. Miller (AMNH); 1♂, La Virgen, main road 27 km E of Toachi, S 00°26.3′, W 78°44.4′, 866 m, 26 Apr 2000, at light UV/MV, leg. S. Rab Green & I. Tapia (AMNH). Cotopaxi: San Francisco de Las Pampas, Otonga, 2000 m, 30–31 Jul 1993, leg. E. Tapia, G. Onore & C. Young (AMNH).

Other Specimens Examined

Ecuador: Carchi: 4♂♂, Maldonado, 2200 m, 9–11 Jan 1993, leg. V.O. Becker (VOB). Esmeraldas: 1♂, Cuellaje, 10 Sep 1996, leg. F. Piñas (FPC). Pichincha: 1♀, 16 km W San Juan, Old Santo Domingo Road, 2700 m, 14 Jul 1994, cloud forest, disturbed, leg. Jan Hillman (CMNH). Cotopaxi: 1♂, San Francisco de Las Pampas, Otonga, 2600 m, 22 March 1993, undisturbed cloud forest, leg. Jan Hillman (CMNH). Chimborazo: 1♂, 11 km NE Pallatanga, 2800 m, 11 Nov 1987, semiarid, leg. C. Young, R. Davidson & J. Rawlins (CMNH). 1♀, Las Palmas, 2 Sept 1996, leg. F. Piñas (FPC; genitalia slide no. JSM-1654).

Dissected

2 ♂♂, 3 ♀♀.

4. FULVIPALPIS GROUP

The Fulvipalpis Group includes four closely related species from the cloud forests of Colombia and Ecuador. Other than N. yanayacu, newly described here, all were described by Dognin (1899, 1910a, 1911). He described tiznon and fulvipalpis in Polypoetes, but fulvipalpis was subsequently moved to Tithraustes (Prout, 1918). The third Dognin species, inaequiplaga, was described in Tithraustes and has remained there ever since.

Members of the Fulvipalpis Group exhibit a dark chocolate brown FW and HW ground color (pl. 16). In three species, the HW central area is white, whereas in N. fulvipalpis it is uniformly chocolate brown. Wing patterns and body coloring within the group are so similar that the only reliable means for separating the taxa is by study of their genitalia. Other notable features of the Fulvipalpis Group include a somewhat prognathous head (fig. 159E), unusual for the Dioptinae.

Although the three previously described Fulvipalpis Group species are rare in collections, this is almost certainly a result of inadequate sampling. The new species, Nebulosa yanayacu, is the most common day-flying moth in the area around Baeza, Ecuador, where it occurs. Adults can sometimes be observed in the hundreds, flying in the late afternoon in pastures and other disturbed habitats.

KEY TO FULVIPALPIS GROUP SPECIES (MALES)

Plate 16

1. Hind wing central area white, outer margin broadly banded with dark chocolate brown; FW with a diffuse, ovoid white fascia beyond DC, fascia touching base of radial sector anteriorly and fork of M3+CuA1 posteriorly; FW vein M2 with a small, white submarginal spot2

HW central area brown, slightly lighter than outer margin; FW with a large, roughly crescent-shaped, white fascia beyond DC, fascia touching M1 anteriorly and anal fold posteriorly; vein M2 without a white submarginal spot (W Colombia and W Ecuador)fulvipalpis (Dognin)

2. Forewing fascia beyond DC diffuse, dorsal surface suffused with dark brown scales; white submarginal spot on FW vein M2 tiny, inconspicuous; aedeagus bent strongly upward near apex (fig. 181E), with a large ventral knob at bend3

FW fascia beyond DC conspicuous, semihyaline (fig. 161), dorsal surface sparsely scaled with white; white submarginal spot on FW vein M2 conspicuous, round; aedeagus almost straight (fig. 182B), ventral margin without a knob (NE Ecuador)yanayacu, sp. nov.

3. Hind wing ventral surface uniformly brown along anal margin; socii long, narrow, gradually attenuated (fig. 181A), drooping downward near apex (SE Ecuador)tiznon (Dognin)

HW ventral surface an even mix of white and dark brown scales along anal margin; socii wide, laterally compressed, bent sharply upward, each socius with a bladelike ventral process near middle (W Colombia)inaequiplaga (Dognin)

SPECIES INCLUDED AND MATERIAL EXAMINED

Nebulosa fulvipalpis (Dognin), new combination

Figures 159E–G, 162B, 180; pl. 16 [EX]

Polypoetes fulvipalpis Dognin, 1910a: 16.

Type Locality

Colombia, Cali, San Antonio.

Type

Syntype ♂, 15 May 1908, leg. Fassl (USNM type no. 30932).

Discussion

Nebulosa fulvipalpis occurs at midelevations on the western slope of the Andes, from Cali, Colombia, south to Pichincha, Ecuador. The species is unmistakable in exhibiting a dark chocolate-brown FW with a white fascia beyond the DC, located between veins M1 and CuA2, and a uniformly brown HW (pl. 16). All other Fulvipalpis Group species have a white HW with a dark brown marginal band, and a smaller, more distally located white FW spot, straddling M2. The white FW maculation in N. fulvipalpis is located in a different position than occurs in any other Fulvipalpis Group taxon, beyond the DC but well short of the wing apex.

Nebulosa fulvipalpis is known worldwide from fewer than 20 specimens. The USNM collection contains the bulk of this material—10 specimens (including the male syntype), all collected by Fassl.

Distribution

Colombia (AMNH, BMNH, USNM); Ecuador (AMNH, VOB).

Dissected

Syntype ♂ (genitalia slide no. JSM-1062); ♂, Ecuador, Pichincha, 59 km W Quito, 8 km W Chiriboga, 6400 ft, 24 Oct 1988, leg. J.S. Miller, black light, AMNH (genitalia slide no. JSM-457); ♂, Colombia, leg. Fassl, USNM (genitalia slide no. JSM-461); ♂, Ecuador, Carchi, Maldonado, 2200 m, 9–11 Jan 1993, leg. V.O. Becker, VOB (genitalia slide no. JSM-1063); ♀, Colombia, leg. Fassl, USNM (genitalia slide no. JSM-462).

Nebulosa inaequiplaga (Dognin), new combination

Plate 16

Tithraustes inaequiplaga Dognin, 1911b: 5.

Type Locality

Colombia, Boquia, “Paso del Quindin” (west), 2000–2200 m.

Type

Syntype ♂, Sep 1909, leg. Fassl (USNM type no. 30938).

Discussion

This species is known from the USNM type and four additional specimens, all captured in western Colombia. Nebulosa inaequiplaga is similar in wing pattern to N. yanayacu (pl. 16), from eastern Ecuador. The major difference is subtle: the FW fascia beyond the DC in N. yanayacu is scaled with white on its dorsal surface, whereas in N. inaequiplaga this fascia is suffused with dark brown scales. In addition, the white submarginal spot on M2 is smaller in N. inaequiplaga. The two species differ markedly in male genital structure, particularly in the shape of the socii.

The other Fulvipalpis Group taxon bearing a strong resemblance to N. inaequiplaga is N. tiznon (pl. 16), from southern Ecuador. In both species, the FW fascia is suffused with dark scales and the HW central area is white. The only reliable means I could find to separate these two was by comparison of their male genitalia, which differ vastly. The male genitalia of N. inaequiplaga are unique in exhibiting large, bladelike ventral processes on the socii; the socii in all other species are simple (figs. 180AFigure 181182A).

Of the two N. inaequiplaga specimens at the BMNH, one, collected by Fassl at 3200 meters on Monte Tolima in the Central Cordillera of Colombia, represents the highest altitude yet recorded for the genus Nebulosa.

A male in the EMEC in Berkeley represents an undescribed Fulvipalpis Group species. This moth, from Valle de Cauca in western Colombia (collected by A.H. Miller, March 1958), is remarkable in possessing genitalia (JSM-1624) similar to those of N. fulvipalpis, but wings resembling those of inaequiplaga. It differs from other Fulvipalpis Group species in that the distal FW spot on M2, white in all others, is light orange-yellow. The HW central area is white. The only other specimen of this undescribed taxon I have been able to locate is a Colombian male (La Estrella, Antioquia) in the collection of the Fundación Miguel Lillo, Argentina.

Distribution

Colombia (BMNH, FML, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1064).

Nebulosa tiznon (Dognin), new combination

Figure 181; plate 16

Polypoetes tiznon Dognin, 1894: 239–240.

Type Locality

Ecuador, Loja.

Type

Holotype ♂ (USNM type no. 30973).

Discussion

This taxon, described in Polypoetes by Dognin (1899) and retained there by all subsequent authors (Prout, 1918; Hering, 1925; Bryk, 1930), was poorly placed. It exhibits none of the apomorphic features of Polypoetes, such as greatly elongate labial palpi (e.g., fig. 92C). Nebulosa tiznon instead belongs in the Fulvipalpis Group, far removed from Polypoetes.

Nebulosa tiznon is apparently endemic to southeastern Ecuador. The only specimen of N. tiznon I have been able to locate in collections, other than the male holotype, is a female (SMNS) from Río San Francisco, a location near Loja (fig. 5). Based on male genital differences, a CMNH specimen (JSM-1684) collected near Gualaceo, approximately 150 km north of Loja, represents an undescribed species closely related to N. tiznon; its wing pattern differs from the latter in showing a better defined white FW fascia. The wings of N. tiznon differ markedly from those of N. fulvipalpis (pl. 17), and the two taxa occur on opposite slopes of the Andes. Nevertheless, their genitalia (figs. 180, 181) are extremely similar.

Distribution

Ecuador (SMNS, USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1065); ♂, Ecuador, Morona-Santiago, Río Culebrillas, 34 km SE Gualaceo, 2200 m, 22–23 Oct 1987, wet forest, leg. J. Rawlins, C. Young & R. Davidson, CMNH (genitalia slide no. JSM-1684); ♀, Ecuador, Zamora-Chinchipe, Río San Francisco, Estación Científica San Francisco, 3°58′S, 79°5′W, 1913 m, KH(1), 21 Sept 2003, LF V, 20.45–21.15 h, leg. N. Hilt & C. Ramenda, SMNS (genitalia slide no. JSM-1685).

Nebulosa yanayacu, new species

Figures 160A–D, 161, 170, 182; plates 16, 38L [EX]

Diagnosis

This moth is close in general appearance to two other Fulvipalpis Group species—N. inaequiplaga from Colombia and N. tizon from southeastern Ecuador (pl. 16). All three possess a whitish FW fascia accompanied by a small, white distal spot straddling M2. Their HW is white centrally. One subtle difference distinguishes N. yanayacu; the FW fascia is completely covered with white scales on the dorsal surface. The other two taxa exhibit a whitish or semihyaline FW fascia suffused with dark brown scales. It is impossible to confuse any of the three with N. fulvipalpis (pl. 16), in which the HW dorsal surface is evenly dark brown.

By far the most reliable means for separating these taxa is by their genitalia. The male genitalia of N. yanayacu show several autapomorphies. For example, the aedeagus is essentially straight in N. yanayacu (fig. 182B), but shows a strong elbowlike distal bend in all other species (figs. 180C, 181E). In addition, the socii/uncus complex of N. yanayacu (fig. 182A) is much larger and more robust than occurs elsewhere in the clade (figs. 180A, 181A). Females are known for three Fulvipalpis Group taxa—N. fulvipalpis, N. tiznon, and N. yanayacu. Comparing their genitalia, they differ markedly in the shape of Tg8, and in the configuration of their PVP. Nebulosa yanayacu females are unique in that the posterior margin of Tg8 is flattened and rooflike (fig. 182E), extending posteriorly well beyond the terminus of the PVP.

Description

Male. Forewing length  =  12.0–14.0 mm. Head (fig. 160A–D): Labial palpus moderate in length, curving gently upward; Lp1 and Lp2 orange-yellow, Lp3 dark brown; lateral portions of front with long, upwardly pointing, whitish to buff-colored scales, central portion dark gray-brown; eye moderately large, but not bulging outward, surrounded by a scaleless area; occiput white; vertex dark brown; antenna widely bipectinate, scape and dorsal surface of shaft dark brown.

Thorax: Coxa of prothoracic and mesothoracic legs covered with long, white scales, gray-brown on mesal surfaces; femur, tibia, tarsus, and spurs of prothoracic and mesothoracic legs brown on outer surface, white on inner; metathoracic leg lighter than other two legs, coxa and femur white, tibia and tarsus, including spurs, mostly white with a few light brown scales on outer surfaces; patagium covered with long, erect, charcoal-gray scales; tegula small, ventral angle gray-brown, central area with long, orange-yellow scales and white scales around perimeter, apex bearing hairlike, gray-brown scales and a few white ones; dorsum gray-brown to charcoal gray; tympanum open, fairly large, membrane almost round, facing posteroventrally.

Forewing: (Dorsal) Ground color dark brown (pl. 16); an almost round, translucent white fascia beyond DC, located between the base of veins Rs2–Rs4 and the fork of M3+CuA1; a second, small white spot near FW apex, its anterior margin touching M1 and its posterior margin crossing M2, but not reaching M3. (Ventral) Similar to dorsal surface except ground color lighter and basal third dusted with white scales.

Hind wing: (Dorsal) Outer margin with a wide, dark chocolate-brown border (pl. 16); anal margin broadly bordered with slightly lighter brown; anterior margin with a thin, diffuse border of light brown; central area white; most specimens with a small tooth of dark brown scales along CuA2 encroaching into white area. (Ventral) Similar to dorsal surface except anterior margin completely white, anal margin whitish gray-brown.

Abdomen: Dorsum dark brown; venter creamy white.

Terminalia (fig. 182A–D): Tg8 longer than St8; Tg8 somewhat narrow, sides tapered slightly toward distal margin, posterior margin with a narrow mesal process, apex of process blunt, lightly sclerotized; anterior margin simple; St8 wide, short, widest at posterolateral angles, these angles with long, armlike projections produced posteriorly; posterior margin of St8 with a short, rounded mesal process; anterior margin of St8 with a short, truncate mesal process; socii/uncus complex large, triangular; uncus extremely wide at base, abruptly narrowed toward apex; socii widest at bases, elbowed sharply upward, a low flange on dorsal surface of each, short of apex; tegumen wide, gently expanded below; vinculum narrower, short, saccus broadly truncate below, produced upward to a point at midline to cover junction of valva bases; valva relatively narrow; BO well developed, curled anteriorly, androconia long; costa of valva sclerotized from base, then narrowing to a thin strip at apex, apex itself gradually tapered, mostly membranous; transtillar arms narrow at base, then expanded and arched upward in manica, meeting in a wedge at midline; aedeagus moderately wide, widest at base, apex with a tiny downcurved tooth below; vesica long and thin, with a single thornlike cornutus near base.

Female. Forewing length  =  12.5–14.5 mm. Head, thorax, and abdomen similar to male, wings similar to male, except basal areas on ventral surfaces whiter.

Terminalia (fig. 182E): Tg7 wide at anterior margin, then narrowing abruptly to form a conelike process distally; St7 extremely wide, almost twice as wide as Tg7, lateral angles broadly rounded outward, a smoothly rounded mesal excavation on posterior margin, anterior margin simple; a shallow, lightly sclerotized, transverse groove present on St7, immediately anterior to halfway point; Tg8 extended posteriorly well beyond PA, forming a rooflike structure; posterior margin of Tg8 with a shallow mesal excavation; AA and PP moderately long, robust, heavily sclerotized; PVP large, shallow, platelike, expanded dorsally; DB short, membranous, expanded near middle; CB large, ovoid; a spiculate, figure-eight–shaped signum present on right side; a pair of sclerotized, spiculate conjoined humps at base of CB on left side; DS arising dorsally at junction of DB and ostium; membrane surrounding PA infolded, melanized; outer margin of PA angulate.

Etymology

This species is named for the type locality, Yanayacu Biological Station, located 5 km west of Cosanga Ecuador (Napo Province). Yanayacu, a Quechua word meaning “Black River”, is situated in beautiful cloud-forest habitat at approximately 2000 meters elevation (pl. 43A–C), on the eastern slope of the Andes approximately 10 km east of the Río Quijos. Yanayacu is rich in undescribed moth and butterfly species.

The tireless caterpillar-rearing efforts of Harold Greeney, the station owner, and his coworkers have produced a wealth of discoveries in Lepidoptera natural history. These findings, which include immature stages of taxa seen for the first time, as well as hundreds of new host-plant records, are featured on the group's website ( http://www.caterpillars.org).

Biology

The Yanayacu caterpillar team recently discovered larvae of N. yanayacu feeding on Tibouchina lepiota (Melastomataceae). Tibouchina, which grows as a dense round shrub or small tree with conspicuous magenta flowers (pl. 44A, B, D), is common in disturbed habitats throughout the Andes at mid- and high elevations. The genus contains approximately 250 species (Gentry, 1993). It seems likely that all members of the Fulvipalpis Group will eventually be found in association with this plant.

Nebulosa yanayacu is the most common day-flying moth in the vicinity of Baeza. On a single afternoon near Yanayacu, especially between the hours of 4 p.m. and 6 p.m., one can observe hundreds of individuals fluttering across the gravel access road, or hovering in pastures above their host plant, which grows there in abundance. I have also collected N. yanayacu flying along the banks of the Río Quijos, which runs below Baeza. One day at that site I captured a large series (19♂♂, 5♀♀) nectaring on the flowers of a composite growing next to the river. On rare occasions, individuals of N. yanayacu are attracted to light traps at night.

The larvae of N. yanayacu (pl. 38L) are unusual. Of particular note is their light green body and wide yellow dorsal band, within which are pinkish-purple transverse spots on all body segments. Unlike the caterpillars of most dioptines, the head is not conspicuously marked.

Distribution

Nebulosa yanayacu has a restricted distribution (fig. 170). Specimens have been collected on the eastern slope of the Ecuadorian Andes in a narrow band of elevations, between 2000 and 2400 meters. It is known from as far north as La Bonita (0°27′N, 77°30′W) near the Colombian Border, and as far south as Cosanga (0°34′N, 77°52′W) in Napo Province—localities approximately 100 km apart. Collecting along the eastern slope in Colombia, particularly in the states of Putumayo and Caqueta near the Ecuadorian border, is needed to firmly establish the northern limits of N. yanayacu.

Discussion

It seems unusual, considering how common this moth is, that material of N. yanayacu does not appear in older collections. My first encounter with the species occurred during my initial visit to Ecuador in 1988. During that and subsequent trips I retained approximately 70 specimens, a small fraction of what could have been collected. A few have been sent to me on loan (EMEC, VOB), all captured within the past 20 years. Perhaps the moth's recent abundance is related to an increase in habitat disturbance since its host plant, Tibouchina, invariably grows on grazed land.

The four species of the Fulvipalpis Group, although each is clearly demarcated by genitalia differences, are so closely related that I hesitate to hypothesize concerning their interrelationships. Furthermore, at least one species remains to be described. Generating a phylogeny for this clade should be referred to a full-scale revision.

Holotype

Male (pl. 16). Ecuador: Napo: Yanayacu Biological Station, 5 km W Cosanga on Cosanga-Río Alíso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 4 Mar 2006, leg. J.S. Miller, day-coll. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 5♂♂, 2♀♀, Yanayacu Biological Station, 5 km W Cosanga on Cosanga-Río Alíso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 2–4 Mar 2006, leg. J.S. Miller, day-coll. (AMNH); 12♂♂, 3♀♀, 24–25 Sep 2004, leg. J.S. Miller & E. Tapia, day collecting (AMNH; male genitalia slide no. JSM-1498); 1♂, 1♀, Reared (#C1055, #1619), Jan 2005, H. Greeney et al. (AMNH); 1♂, Reared (#1088), Jan 2005, H. Greeney et al. (AMNH); 4♂♂, Baeza, nr. Río Quijos, 5800 ft, May 28 1993, leg. J.S. Miller & E. Tapia, day-collecting (AMNH); 1♀, 5 km W Baeza on Baeza-Quito Rd, nr. Río Quijos, 5600 ft, May 29 1993, leg. J.S. Miller & E. Tapia, at light (AMNH); 19♂♂, 5♀♀, Baeza, near Río Quijos, 6200 ft, 31 Oct 1988, shrub flowers, leg. J.S. Miller (AMNH; female genitalia slide no. JSM-727); 12♂♂, 27 Oct 1988, leg. J.S. Miller (AMNH; genitalia slide no. JSM-726).

Other Specimens Examined

Ecuador: Napo: 2♂♂, Baeza, 2000 m, 29 Dec 1992, leg. V.O. Becker (VOB); 1♂, Via Sta. Barbara–La Bonita, km 23, 2400 m, 7–9 Apr 1986, bl, leg. S. McKamey (EMEC).

Dissected

2♂♂, 1♀.

5. ALBITUMIDA GROUP

Supporting evidence for monophyly of the Albitumida Group is provided by the presence of unique processes on the transtilla of the male genitalia (figs. 183A, 184A). The clade is entirely South American, endemic to Andean cloud forests from Colombia south to Bolivia. Diagnostic features for the Albitumida Group include the following: labial palpus short (fig. 159H), curving strongly upward to slightly above clypeus; wings long (16.0–20.0 mm); FW ground color olive brown to dark brown, often with diffuse white patches near base (pl. 17); FW veins orange to ochreous brown; an irregular, white transverse FW band crossing distal margin of DC, extending from subcosta to CuA2, sometimes slightly beyond; FW DC shorter than one-half the wing length (fig. 162F), veins M1 and M2 swollen; HW white with a wide, dark brown marginal band, widest at apex; body robust; male genitalia with arms of transtilla bearing long dorsal processes where they meet over aedeagus (figs. 183A, 184A); aedeagus long, curving downward (figs. 183D, 184C), vesica with a single, large cornutus.

Developing an understanding of species-level taxonomy within the Albitumida Group falls well outside the scope of this paper. All taxa exhibit the same fundamental wing pattern (pl. 17), and it seems impossible to distinguish them on that basis. Their genitalia, on the other hand, provide sound differences. Unfortunately, this implies that the only way to identify Albitumida Group taxa is to dissect every specimen, an untenable solution. Three complicating factors make the situation even more difficult: First, of the four described species, females are known for only one, N. nasor (fig. 183E–G), so their characters are unavailable for comparison. Second, all species are extremely rare. Finally, there are at least two undescribed species, and additional dissections will undoubtedly reveal more.

My approach, for the purposes of providing a starting point to identify taxa in the Albitumida Group, has been to restrict species concepts to material with wings closely resembling the type, and with a provenance as close to the type locality as possible. I admittedly ignored confusing issues beyond that. Male genitalia are employed in the key to Albitumida Group species because they currently provide the only reliable means for identification. Dissection of all relevant types will ultimately be crucial in resolving systematics within this clade.

Three Albitumida Group species—albitumida Dognin, cistrina Druce, and nasor Druce—were transferred to Nebulosa from Tithraustes, while sirenia Hering was taken from Polypoetes.

KEY TO ALBITUMIDA GROUP SPECIES (MALES)

Plate 17

1. White transverse band of FW variable in shape, always curved, its margins irregular, often sinuate; subapical FW spot on M2 white; HW margin light brown, gray-brown, or rarely white2

White transverse band of FW almost straight, its margins roughly parallel; subapical FW spot on M2 yellowish orange; HW anal margin white; FW length  =  18.0 mm (SE Ecuador)cistrina (Druce)

2. Male genitalia with uncus long, bifid (fig. 184A), socii long and thin; male valva broadly truncate at apex; white transverse FW band constricted near middle; FW length  =  16.0–17.0 mm (SE Peru, Bolivia)sirenia (Hering)

Male genitalia with uncus short, simple (fig. 183A), socii short and wide; valva acute at apex; white transverse band of FW irregular, not constricted near middle; FW length  =  17.0–20.0 mm3

3. Anterior apodeme on male St8 broadly bifid (fig. 183B); valva long and narrow, gradually narrowing toward apex; cornutus of vesica slightly curved (fig. 183D); FW length  =  17.0–18.5 mm (SE Ecuador)albitumida (Dognin)

Anterior apodeme on male St8 simple, rounded; valva relatively short and wide, abruptly narrowing near apex; cornutus of vesica straight; FW length  =  17.5–18.0 mm (W Colombia)nasor (Druce)

SPECIES INCLUDED AND MATERIAL EXAMINED

Nebulosa albitumida (Dognin), new combination

Figure 183A–D; plate 17

Phaeochlaena albitumida Dognin, 1902: 475.

Type Locality

Ecuador, “Environs de Loja”.

Type

Holotype ♂, leg. 1890 (USNM type no. 30933).

Discussion

My concept of Nebulosa albitumida is restricted to material from southeastern Ecuador, in the region of Loja (fig. 5). A CMNH specimen (JSM-450) was captured on the Río Culebrillas approximately 120 km N of Loja, the furthest north this species has been recorded. The wing pattern of N. albitumida is similar to that of N. nasor (pl. 17), endemic to western Colombia, but their male genitalia differ dramatically.

I know of only three verified examples of N. albitumida, all males—the USNM holotype, and two specimens at the CMNH. Their FW lengths range between 17.0 and 18.5 mm. A third CMNH male, from El Oro province in southwestern Ecuador, matches the type of N. albitumida in all details of body and wing coloration, but is larger (FW length  =  20.0 mm), and almost certainly represents an undescribed species.

Distribution

Ecuador (CMNH, USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1036); ♂, Ecuador, Morona-Santiago, Río Culebrillas, 34 km SE Gualaceo, 2200 m, 22–23 Oct 1987, leg. J. Rawlins, C. Young & R. Davidson, wet forest, CMNH (genitalia slide no. JSM-450).

Nebulosa cistrina (Druce), new combination

Plate 17

Polypoetes cistrina Druce, 1899: 301.

Type Locality

Ecuador, Chiguinda.

Type

Holotype ♂, leg. Buckley (BMNH).

Discussion

The only specimen I feel comfortable identifying as N. cistrina is the BMNH holotype (pl. 17). It was collected over 100 years ago at Chiguinda in southeastern Ecuador, a site within 40 km of the Río Culebrillas, a modern locality for N. albitumida (above). Dissection of the cistrina type will be required to establish the identity of this species. Until then, its wing pattern provides tentative means for identification. The white transverse FW band of N. cistrina is more regular in shape than in other Albitumida Group species (pl. 17), and the submarginal spot on FW vein M2 is yellowish orange, rather than white.

Distribution

Ecuador (BMNH).

Dissected

None.

Nebulosa nasor (Druce), new combination

Figure 159H–J, 183E–G; plate 17 [EX]

Devara nasor Druce, 1899: 298.

Type Locality

Colombia, Antioquia, Fentino.

Type

Syntype ♀ (BMNH).

Discussion

The type of N. nasor and the AMNH specimen dissected (fig. 183E–G) are the only two females known for the entire Albitumida Group. In this species, females (FW length  =  20.0 mm) are significantly larger than males (FW length  =  17.0–18.5 mm). In addition to these two females, five males can safely be regarded as examples of N. nasor: four from the BMNH, and one at the USNM. These share the same label data—San Antonio, 5800 ft, western Colombia, leg. M.G. Palmer—and they match the wing pattern of the nasor type precisely.

The male genitalia of moths from this series (JSM-1038) differ from N. albitumida (JSM-1036), especially regarding the shape of St8 and the shape of the valva. The wing patterns of the two species are nearly indistinguishable (pl. 17), although specimens of N. nasor tend to be somewhat darker, with more brown in the HW. The two show disjunct areas of endemism; N. nasor is found on the western slope of the Colombian Andes, whereas N. albitumida occurs on the eastern slope in southern Ecuador. A third species, N. cistrina, also from southeastern Ecuador, can be distinguished from these by its wing pattern (see species key). Nebulosa sirenia (pl. 17), the fourth member of the Albitumida Group, is endemic to Bolivia and southeastern Peru. Its male genitalia (fig. 184), particularly valva shape, differ markedly from all others.

Distribution

Colombia (AMNH, BMNH, USNM).

Dissected

♂, Colombia, Valle, San Antonio, 5800 ft, Dec 1907, leg. M.G. Palmer, BMNH (genitalia slide no. JSM-1038); ♀, Colombia, Cauca, Timbio, 1750 m, AMNH (genitalia slide no. JSM-451).

Nebulosa sirenia (Hering), new combination

Figures 162F, 184; plate 17

Polypoetes sirenia Hering, 192: 516, fig. 69e.

Type Locality

Bolivia, Río Songo, 750 m.

Type

Holotype ♂ (ZMH).

Discussion

Oddly, Hering (1925) described sirenia in Polypoetes even though the moth shows none of the specialized morphology of that genus. This species instead belongs in the Albitumida Group of Nebulosa. Among other things, N. sirenia exhibits one of the key synapomorphies for this clade—presence of a pair of long, mediodorsal processes on the transtilla of the male genitalia. In N. sirenia, the socii are long and the uncus is spatulate (fig. 184A), with a notch at its apex, whereas in N. albitumida and N. nasor the socii and uncus are short (fig. 183A), without a notch. The wing pattern of N. sirenia seems to be variable, especially in the HW; some examples show a dirty gray-brown anal margin, whereas in others it is completely white. No females are known.

Nebulosa sirenia (FW length  =  16.0–17.0 mm) appears to be somewhat smaller than other described species in the Albitumida Group (FW lengths  =  17.0–20.0 mm). My dissections show that N. sirenia, described from Bolivia, also occurs in southeastern Peru. However, the picture is complicated by the existence of an undescribed species from that same region. The new one (FW length  =  17.0–19.0 mm) is significantly larger than N. sirenia, but its wing pattern is indistinguishable. I have seen 12 specimens of the undescribed taxon, all males—two at the USNM, one from the CMNH, and nine in the BMNH collection. Its genital structure is highly distinctive, but indicates a relationship closest to N. sirenia. The undescribed taxon is represented by the following slides: ♂, Peru, Santo Domingo, Carabaya, 6500 ft, BMNH (genitalia slide no. JSM-449); ♂, Bolivia, Cochabamba, leg. J. Steinbach, CMNH (genitalia slide no. JSM-1037).

Distribution

Bolivia (BMNH, USNM, ZMH); Peru (BMNH, MUSM).

Dissected

♂, Bolivia, Río Songo, 750 m, leg. Fassl, USNM (genitalia slide no. JSM-1039, wing slide no. JSM-1471); ♂, Peru, La Oroya, Río Inambari, 3100 ft, wet season, Mar 1905, leg. G. Ockenden, BMNH (genitalia slide no. JSM-227); ♂, Peru, Utcuyacu, 5000 ft, Dec 1919–Feb 1920, leg. C. Watkins, BMNH (genitalia slide no. JSM-1040).

6. HALESIUS GROUP

The Halesius Group shows a relatively restricted geographical distribution, spanning from Chiriquí, Panama north to central Costa Rica. The three included species, all of which were transferred from Tithraustes, show strong differences in wing pattern and genital morphology, but they also exhibit numerous synapomorphies. The group is undoubtedly monophyletic.

Diagnostic traits for the Halesius Group are numerous; some of them appear nowhere else in the Dioptinae. The list of defining features includes: labial palpus short, curving upward to well below middle of front, Lp1 and Lp2 yellow to orange-yellow, Lp3 dark brown; uncus extremely long, spatulate at apex (figs. 185A, 185H); socii extremely long, elbowed upward, apices bladelike; male valva narrow; BO small, with tiny pleats, densely setose; female St7 extremely wide, surface shagreened near posterior margin; Tg8 rooflike (fig. 185B), surface densely shagreened.

KEY TO HALESIUS GROUP SPECIES

Plate 17

1. Forewing uniformly dark brown to blackish brown; FW veins narrowly lined with orange to ochreous brown scales; FW fascia diffuse, M2 dark brown within it; HW outer margin broadly banded with dark brown, anal margin light brown to gray-brown; FW length  =  13.5–16.0 mm (Panama, Costa Rica)crypsispila (Warren)

FW reddish brown to olive brown, mottled with dark brown on either side of fascia; FW veins robustly lined with beige to orange-yellow scales; FW fascia white, M2 white within it; HW outer margin with a dark brown, comma-shaped maculation at apex, anal margin white2

2. Forewing with patches of reddish brown and light brown, contrasting dark brown on either side of fascia; FW veins boldly colored with burnt orange to ochreous brown; FW fascia somewhat hourglass shaped; male genitalia with valva relatively wide (fig. 185A), densely rugulose along costa, apex gradually narrowed; FW length  =  14.0–17.0 mm (Costa Rica)halesius (Druce)

FW dull olive to brown, slightly darker brown on either side of fascia; FW veins creamy white to beige, finely outlined with reddish brown; FW fascia small, ovoid; valva extremely narrow (fig. 185H), smoothly sclerotized, apex spatulate; FW length  =  17.5–18.0 mm (Costa Rica)rudicula, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Nebulosa crypsispila (Warren), new combination

Plate 17

Phaeochlaena crypsispila Warren, 1901: 442.

Type Locality

Panama, Chiriquí.

Type

Syntype ♂ (BMNH).

Discussion

Although N. crypsispila is superficially different from N. halesius and N. rudicula, exhibiting much darker wings without pattern (pl. 17), it belongs in a clade with them. The male genitalia of all three share numerous apomorphic features, noted in the Halesius Group synopsis (above). Nebulosa crypsispila is extremely rare. The sum total of known material includes a male and a female, in addition to the syntype, at the BMNH, as well as a single female at INBio. The latter (JSM-1497) is the first record of N. crypsispila for Costa Rica.

An undescribed species of Polypoetes from Chiriquí, Panama, closely related to P. suffumosa, has wings that are almost indistinguishable from those of N. crypsispila. However, these taxa can easily be separated by examining two structures: The labial palpi—long in the Polypoetes taxon but short in N. crypsispila; and the FW DC—longer than one-half the FW length in Polypoetes and approximately one-half the FW length in N. crypsispila.

Distribution

Panama (BMNH); Costa Rica (INBio).

Dissected

♂, Panama, Chiriquí, BMNH (genitalia slide no. JSM-854); ♀, Costa Rica, Cartago, P. N. Tapantí, 300 sureste Río Porras, 1660 m, Dec 2003, leg. R. Delgado, de luz, L N 186550 560600, #72467, INBio (genitalia slide no. JSM-1497).

Nebulosa halesius (Druce), new combination

Figure 185A–E; plate 17 [EX]

Polypoetes halesius Druce, 1885a: 161.

Type Locality

Costa Rica, Río Sucio.

Type

Syntype ♂, leg. H. Rogers (BMNH).

Discussion

Nebulosa halesius is distinguished by its reddish-brown FW ground color and white, hourglass-shaped fascia bordered on either side by dark brown patches. The FW veins are orange to orange-brown. The HW is white with a crescent-shaped, brown maculation near the apex. Its sister species, N. rudicula (pl. 17), has a drabber wing pattern, a larger HW crescent, and a slightly longer wingspan. Their male genitalia differ dramatically (fig. 185).

However, identification of these species is complicated by the existence of at least one undescribed Costa Rican taxon. This species, known from four INBio males, has been collected in the vicinity of Parque Tapantí (Cartago Province) at elevations between 2600 and 2700 meters. Its wings closely resemble those of N. halesius, but the undescribed moth (male FW length  =  18.0–19.5 mm) is larger than either halesius or rudicula, and has a generally darker FW. Its uncus is also longer and thinner. Slide label data for this species are as follows: Costa Rica, El Guarco, San Isidro, Estación Esperanza, 2700 m, 28 Feb 2001, leg. R. Delgado, de Luz, L_N_550117_185285, #61623, INBio (genitalia slide no. JSM-1676). Wide valvae of the male genitalia indicate a closer affinity with N. halesius than with N. rudicula.

Nebulosa halesius was described from the Río Sucio in the Caribbean drainage, but its full distribution is poorly known; material from Braulio Carrillo is almost certainly N. halesius, but nearly identical specimens collected close by, at Volcán Poas on the Pacific side, show slightly different valva shape (JSM-1306). Thus, there may ultimately be four Costa Rican species in the halesius/rudicula complex. Until the taxonomy of these taxa has been fully resolved, their identities will remain problematic.

The only N. halesius females of which I am aware are two examples in the BMNH collection, one of which (JSM-454) was dissected.

Distribution

Costa Rica (AMNH, BMNH, INBio, SMNS).

Dissected

♂, Costa Rica, Orosí, 1200 m, leg. Fassl, BMNH (genitalia slide no. JSM-452); ♂, Costa Rica, Heredia Prov., Estación Barva, P.N. Braulio Carrillo, 2500 m, L-N-233400, 528200, May 1990, leg. A. Fernandez, INBio (genitalia slide no. JSM-1053); ♂, Costa Rica, Alajuela, Volcán Poas, 2350 m, 15 Dec 1982, leg. D.H. Janzen & W. Hallwachs, INBio (genitalia slide no. JSM-1306); ♂, Costa Rica, Heredia, vicinity of NP Braulio Carrillo, rainforest E Finca Gurdian, 10°12.5′N, 84°07.0″W, 1690 m, blacklight 30W, FG b (8), II 19.30–20.30 h, 29 May 2003, leg. Gunnar Brehm, SMNS (genitalia slide no. JSM-1781); ♀, Costa Rica, Irazu, 6–7000 ft, leg. H. Rogers, BMNH (genitalia slide no. JSM-454).

Nebulosa rudicula, new species

Figures 185F–I, 186; plate 17

Diagnosis

Wing pattern easily separates N. rudicula from N. crypsispila (pl. 17). The new taxon is much closer in general appearance to N. halesius (pl. 17), its sister species. These two can be distinguished by the amount of pattern contrast and the amount of orange in the FW: the FW of N. halesius shows considerable contrast, with dark patches on either side of the white FW fascia and a fair amount of orange, especially along the wing veins; the FW of N. rudicula is gray-brown overall with little contrast, and the veins are lined with creamy beige and only a small amount of orange. The HW of the two species also differs: the crescent-shaped marking near the apex tends to be orange brown in N. halesius, extending along the outer margin down to CuA2. In N. rudicula this maculation is gray-brown and extends further along the outer margin, passing the anal fold. The FW of N. rudicula is broader and more triangular than in either of the other Halesius Group species.

Male genitalia provide by far the most conclusive means for separating N. rudicula from N. halesius: In N. rudicula, the valvae are smoothly sclerotized and extremely narrow, spatulate at their apices (fig. 185H); in N. halesius the valvae are wider (fig. 185A), densely rugulose along the costa, and the valva apex is produced into a wedge-shaped structure.

Description

Male. Forewing length  =  17.5–18.0 mm. Head: Labial palpus short, reaching upward to bottom fourth of front; Lp1 and Lp2 yellow-orange to lemon yellow, fringed below with long, yellow-orange scales; Lp3 brown, tipped with long, light yellow scales; front covered with long, bristlelike, upwardly pointing scales reaching to antennal bases; central area of front light brown or yellow, lateral portions buff to cream colored; occiput with short, light brown scales immediately behind eye, long cream-colored scales behind those; eye extremely large, bulging; vertex covered with light brown, hairlike scales, trimmed posteriorly with buff-colored scales; antenna bipectinate; scape and antennal shaft brown to dark brown.

Thorax: Coxa light brown to cream colored; femur white on inner and lateral surfaces, translucent brown on outer one; tibia and tarsus, including spurs, translucent brown to beige; pleural region covered with long, white to buff-colored scales; patagium with long, light brown scales and a few scattered cream-colored scales; tegula with long, orange-yellow scales at base, fringed distally with extremely long, cream-colored scales, lower angle brown; dorsum broadly light brown in central area, beige at posterolateral margins; tympanum relatively small; tympanal membrane subtriangular, facing posteroventrally.

Forewing: (Dorsal) Ground color gray-brown (pl. 17); basal half of DC light whitish brown, semitransparent, almost hyaline; a white, oval-shaped fascia immediately beyond DC, its anterior margin touching base of radial sector and its posterior margin touching fork of M3+CuA1; outer two-thirds gray-brown, slightly darker basad to and immediately beyond fascia; all veins, including anal fold, lined with creamy yellow scales; fringe dark brown. (Ventral) Similar to dorsal surface, but ground color more evenly gray-brown, and veins not as contrasting.

Hind wing: (Dorsal) Translucent white, almost transparent (pl. 17); a crescent-shaped, gray-brown maculation at apex, widest at upper angle, tapering as it extends along outer margin to immediately beyond anal fold; fringe light brown to light orange brown; anal margin completely white, edged with long, hairlike scales; anterior margin white. (Ventral) Similar to dorsal surface, crescent shaped maculation lighter brown.

Abdomen: Light gray-brown above, with scattered white scales; venter immaculate white to creamy white.

Terminalia (fig. 185F–I): Tg8 elongate, much longer than St8; Tg8 widest at anterior margin, gradually tapering distally, posterior margin truncate, rugose, anterior margin simple; St8 short, roughly trapezoidal, posterior margin slightly concave, anterior margin convex, with a shallow mesal process; socii/uncus complex very large, triangular at base; uncus extremely long, widest at base then abruptly narrowed, apex spatulate; socii extremely long, elbowed sharply from base, a bladelike dorsal process short of apex, apex itself acute; tegumen much taller than vinculum, wide, curled posteriorly below; vinculum short, narrow; saccus gently rounded below; valva elongate, sclerotized; BO extremely small, comprising a setose bump near base of valva, corrugations small; valva widest near base, then abruptly narrow in outer two-thirds, forming a cup-shaped process at apex; transtillar arms thin, straplike at base, arching upward and expanded in manica, thinly joined at midline; aedeagus relatively small, wide at base, extremely narrow distally, apex bearing a small, blunt tooth below; vesica small, ovoid, bearing approximately 15 short, spinelike cornuti.

Female. Unknown.

Etymology

This species name comes from the Latin word, rudicula, meaning a “ladle” or “spatula”. It refers to the spoon-shaped valva apex of the male genitalia, a unique feature of this moth.

Distribution

Nebulosa rudicula is known exclusively from three, tightly grouped Costa Rican localities in San José Province, on the Pacific slope of the Cordillera de Talamanca (fig. 186). The moth occurs at relatively high altitudes, between 2500 and 2650 meters. Additional collecting will be needed to better establish the distributional limits of this taxon.

Discussion

Only four specimens of N. rudicula are known, all males. Since it could potentially be confused with N. halesius, with which it shares many wing-pattern similarities, additional examples of N. rudicula perhaps reside unrecognized in collections under the name “halesius”. Hopefully, now that we have a means for identifying N. rudicula, more will be learned about its distribution and natural history.

Holotype

Male (pl. 17). Costa Rica: San José: Est. Cuerici, Sendero al Mirador, 4.6 km al E de Villa Mills, 2640 m, 17–22 Mar 1996, leg. A. Picado, de luz, L_S_389700_499600, #7026. The type is deposited at INBio, Heredia, Costa Rica.

Paratypes

Costa Rica: San José: 1♂, San Gerardo de Dota, Cerro de la Muerte, (INBio/AMNH; genitalia slide no. JSM-453); 1♂, Est. Cuerici, Sendero al Mirador, 4.6 km al E. de Villa Mills, 2640 m, 17–22 Mar 1996, leg. A. Picado, de luz, L_S_389700_499600, #7026 (INBio; genitalia slide no. JSM-1305).

Other Specimens Examined

Costa Rica: San José: 1♂, Llano Bonito, Chirripo, N 09°27′16″, W 83°32′4″, 2500 m, 24 Jun 2006, day flyer, leg. Kenji Nishida (INBio; genitalia slide no. JSM-1791).

Dissected

3♂♂.

DIOPTIS HÜBNER, 1818

Figures 187Figure 188Figure 189Figure 190Figure 191Figure 192Figure 193Figure 194Figure 195Figure 196Figure 197Figure 198Figure 199Figure 200Figure 201Figure 202Figure 203Figure 204Figure 205Figure 206Figure 207Figure 208Figure 209210; plates 17–21; plate 38M

Figure 187

Morphology of Dioptis (♂♂). A, D. cyma head, lateral view; B, D. cyma head, lateral view; C, D. cyma head, frontal view; D, D. cyma head, posterior view; E, D. subalbata head, lateral view; F, D. longipennis head, lateral view; G, D. candelaria head, lateral view; H, D. otanes head, lateral view; I, head, thorax, and A1 of D. trailii, lateral view (illustration by J.S. Miller, except A by S. Goodman).

i0003-0090-321-1-1-f187.gif

Figure 188

Scanning electron micrographs of Dioptis trailii. A, ♂ head, frontal view; B, ♂ eye (frontal view), showing short interfacetal setae; C, ♂ antenna in ventral view; D, single flagellomere from C (ventral view), showing bases of four rami; E, ♀ antenna in ventral view; F, two flagellomeres of ♀ antenna, showing four rami per segment.

i0003-0090-321-1-1-f188.gif

Figure 189

Scanning electron micrographs of Dioptis trailii. A, large sensillum styloconicum on ♀ antenna (ventral surface), located between distal pair of rami (figs. 188E, F); B, metathorax and first abdominal segment of ♂ in lateral view (anterior at left), showing depression of metathoracic tympanum; C, close-up showing absence of tympanal membrane; D, femur and tibia of ♂ right foreleg (mesal view); E, epiphysis in mesal view; F, serrate apex of metathoracic tibial spur.

i0003-0090-321-1-1-f189.gif

Figure 190

Morphology of Dioptis. A, D. phelina tegula; B, D. otanes tegula; C, D. longipennis tegula; D, D. subalbata ♂ wings; E, D. otanes ♂ wings; F, D. trailii ♂ wings; G, D. trailii ♀ wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f190.gif

Figure 191

Scanning electron micrographs of Dioptis trailii ♂ wings. A, HW dorsal surface, showing wide scales along wing vein and thin scales between veins; B, thin scales on HW dorsal surface; C, thin scale on FW dorsal surface; D, surface of thin scale in C; E, base of thin scale on HW dorsal surface; F, thin and vein scales on HW ventral surface.

i0003-0090-321-1-1-f191.gif

Figure 192

Genitalia of Dioptis chloris (♂ JSM-1047, ♀ JSM-1048). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia; F, ♀ St7.

i0003-0090-321-1-1-f192.gif

Figure 193

Genitalia of Dioptis subalbata (holotype ♂ JSM-1045, ♀ JSM-1046). A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, aedeagus; E, ♀ genitalia; F, ♀ St7.

i0003-0090-321-1-1-f193.gif

Figure 194

Genitalia of Dioptis butes (JSM-459, 460). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♀ genitalia; E, ♂ St8 (illustration by A. Trabka).

i0003-0090-321-1-1-f194.gif

Figure 195

Genitalia of Dioptis longipennis (♂ JSM-855, ♀ JSM-856). A, ♂ genitalia; B, aedeagus; C, ♀ genitalia; D, ♂ St8; E, ♂ Tg8.

i0003-0090-321-1-1-f195.gif

Figure 196

Genitalia of Dioptis, Phelina Group. A, holotype ♂ of D. candelaria (JSM-1770); B, ♀ of D. candelaria (JSM-750); C, aedeagus of D. candelaria; D, ♂ St8 of D. candelaria; E, ♂ Tg8 of D. candelaria; F, ♂ of D. vacuata (JSM-735); G, ♂ Tg8 of D. vacuata; H, ♂ St8 of D. vacuata; I, aedeagus of D. vacuata.

i0003-0090-321-1-1-f196.gif

Figure 197

Genitalia of Dioptis phelina (♂ JSM-1185, ♀ JSM-1186). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f197.gif

Figure 198

Male genitalia of Dioptis obliquaria (JSM-1625). A, genitalia; B, Tg8; C, aedeagus; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f198.gif

Figure 199

Genitalia of Dioptis otanes (♂ JSM-162, ♀ JSM-422). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ St7; E, ♂ Tg8; F, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f199.gif

Figure 200

Genitalia of Dioptis vitrifera (♂ JSM-739, ♀ JSM-740). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♀ genitalia; E, ♂ Tg8.

i0003-0090-321-1-1-f200.gif

Figure 201

Genitalia of Dioptis zarza (♂ JSM-1177, holotype ♀ JSM-1176). A, ♂ genitalia; B, ♀ genitalia; C, aedeagus; D, ♂ Tg8; E, ♂ St8, ventral view.

i0003-0090-321-1-1-f201.gif

Figure 202

Genitalia of Dioptis fatima (♂ JSM-1203, ♀ JSM-1204). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f202.gif

Figure 203

Male genitalia of Dioptis tessmanni (JSM-1173). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f203.gif

Figure 204

Genitalia of Dioptis beckeri, sp. nov. (♂ JSM-833, ♀ JSM-834). A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, ♀ genitalia; E, aedeagus.

i0003-0090-321-1-1-f204.gif

Figure 205

Male genitalia of Dioptis curvifascia (JSM-737). A, genitalia; B, aedeagus; C, St8; D, Tg8.

i0003-0090-321-1-1-f205.gif

Figure 206

Genitalia of Dioptis fratelloi (paratype ♂ JSM-835, paratype ♀ 1464). A, ♂ genitalia; B, aedeagus; C, ♀ genitalia; D, ♂ St8; E, ♂ Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f206.gif

Figure 207

Genitalia of Dioptis (Cyma Group). A, ♂ of D. ilerdina (JSM-864); B, ♂ Tg8 of D. ilerdina; C, aedeagus of D. ilerdina; D, ♂ St8 of D. ilerdina; E, ♀ of D. incerta (JSM-1189); F, ♀ Tg7 (left) and St7 (right) of D. incerta.

i0003-0090-321-1-1-f207.gif

Figure 208

Syntype ♂ genitalia of Dioptis paracyma (JSM-1628). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f208.gif

Figure 209

Male genitalia of Dioptis trailii (JSM-129, 1792). A, genitalia; B, aedeagus; C, St8; D, Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f209.gif

Figure 210

Dioptis female genitalia. A, D. trailii (JSM-130); B, St7 of D. trailii; C, D. nr. trailii (JSM-1196) in lateral view, showing positions of Tg7, St7 and postvaginal plate (A and B, J.S. Miller, illustr; C, illustration by A. Trabka).

i0003-0090-321-1-1-f210.gif

Dioptis Hübner, 1818: 9. Type species: Dioptis cyma Hübner, 1818 (by subsequent designation by Kirby, 1892: 413).

Paradioptis Hering, 1925: 521. Type species: Dioptis otanes Druce, 1893 (by monotypy of Eudioptis Prout, 1918). New synonymy.

Eudioptis Prout, 1918: 416. Type species: Dioptis otanes Druce, 1893 (by monotypy); a junior homonym of Eudioptis Hübner, 1823; Lepidoptera, Pyralidae. Paradioptis Hering, 1925 is the objective replacement name (Watson et al., 1980). New synonymy.

Authyala Warren, 1905: 311. Type species: Authyala obliquaria Warren, 1905 (by monotypy). New synonymy.

Diagnosis

Dioptis spans a broad range in almost all morphological features. For example, the metathoracic tympanum varies in its degree of development, being present (but small) in some members of the genus, but absent in the majority of species. Wing patterns differ considerably (pls. 17–21), and male genital morphology is particularly diverse. Nevertheless, most Dioptis species are easy to recognize as such. They exhibit the following characteristics: antenna quadripectinate in male and female (fig. 188C–F); labial palpus moderately long (fig. 187A, B, E, G, H), porrect and usually thin, rarely long and wide (D. longipennis; fig. 187F); wings partially to mostly transparent, veins dark brown to black; HW of many species with an ochreous orange submarginal band (e.g., plate 20); FW vein M1 arising from DC widely separate from base of radial sector, UDC long, usually obliquely angled (fig. 190E–G); FW and HW veins M3 and CuA1 stalked, rarely separate in HW (D. otanes; fig. 190E) or in both wings (D. obliquaria); most species with DC approximately one-half FW length, no male stridulatory organ present, except in Chloris Group (fig. 190D); tegula usually small (figs. 187I, 190A, B); metathoracic tympanum highly reduced, in most species absent altogether (Forbes, 1916, 1922, 1931; Miller, 1991; figs. 187I, 189B, 189C).

Other Dioptinae with hyaline wings—such as Phanoptis (pl. 9), the Limbaria Group of Hadesina (pl. 14) and Monocreaga (pl. 21)—exhibit a bipectinate or ciliate antenna, and the metathoracic tympanum is large.

Redescription

Male. FW length  =  12.5–23.0 mm. Head (figs. 187, 188A–D, 189A): Labial palpus moderately long, thin, porrect, curving gently upward, barely reaching above clypeus (longer, wider and more strongly curved in Butes Group); Lp1 short to moderately long, curved upward, loosely scaled; Lp2 narrow, tightly scaled, slightly shorter than Lp1 (e.g., D. subalbata), approximately equal in length to Lp1 (most species), or rarely one and a half times as long (e.g., D. longipennis); Lp3 short, ovoid, sometimes elongate (e.g., D. candelaria); scales of front pointing inward from lateral margins, meeting at midline, oriented almost horizontally, slightly upward, sometimes forming a small tuft between antennal bases; eye variable in size, from small to large, surrounded by a narrow scaleless area, wider above and below; postgena wide; scales of vertex slightly erect, pointing anteriorly; antenna quadripectinate, each annulation with basal pair of rami arising opposite one another, distal pair slightly offset.

Thorax (187I, 189B–F, 190A–C): Epiphysis variable in length, short, barely one-half length of tibia and falling well short of tibia apex (e.g., D. trailii, D. subalbata), or long, well over three-fourths length of tibia and extending beyond tibia apex (e.g., D. candelaria); tegula short and wide, often less than one-third length of mesoscutum, distal portion and ventral angle blunt, transverse sulcus absent; metathoracic tympanum extremely small with a shallow depression and small, round membrane oriented lateroventrally (Chloris and Butes groups), or metathoracic tympanum absent (all other Dioptis species).

Forewing (figs. 190D–G, fig. 191A,B, E, F; pls. 17–21): Triangular, sometimes elongate (Butes Group); vein Rs1 stalked with Rs2–Rs4, base of radial sector often arched anteriorly; veins Rs2–Rs4 branching in the pattern [2+3]+4; M1 arising from DC, widely separate from base of Rs1–Rs4, UDC long, obliquely angled; stridulatory organ present in Chloris Group, absent in all other Dioptis species; DC slightly less than one-half FW length (much less than one-half in Chloris Group); veins M3 and CuA1 long stalked, rarely separate (D. authyala); ground color dark brown to blackish brown; hyaline areas located in basal third, in a transverse band beyond DC (this sometimes white; e.g., D. nigrivenis), often with a smaller, transverse, subapical hyaline band; some species with ochreous orange or brownish subapical spots (e.g., D. beckeri) or a large, ochreous orange, comma-shaped transverse band (e.g., D. egla).

Hind wing (figs. 190D–F, 191C, 191D; pls. 17–21): Broad and rounded, occasionally somewhat elongate; M3 and CuA1 long stalked, rarely separate (D. otanes; D. obliquaria); ground color, including veins, dark brown to blackish brown, central area hyaline, many species with an ochreous orange submarginal band, lined on inner and outer margins with thin, dark brown bands.

Abdomen: Elongate and often thin, bent downward distally.

Terminalia (figs. 192A–D; 193A–D; 194A–C, E; 195; 196A, C–I; 197A–D; 198; 199A–C, E; 200A–C, E; 201A, C–E; 202A–D; 203; 204A–C, E; 205; 206A, B, D, E; 207A–D; 208; 209): Tg8 longer and narrower than Tg7, lightly sclerotized; Tg8 gradually tapered posteriorly, anterior margin simple or rarely with short, blunt lateral apodemes, posterior margin gently convex, sometimes forming a mesal point (e.g., D. chloris; D. otanes); St8 longer than Tg8, gradually tapered posteriorly, lateral margins often gently convex, anterior margin with a short, blunt mesal apodeme, forming a tonguelike dorsal fold; posterior margin of St8 variable, usually with a shallow mesal excavation, sometimes with a deep, V-shaped notch and elongate lateroposterior angles forming a Y-shaped structure (Chloris and Butes groups); socii/uncus complex extremely variable in size and shape, either narrowly or broadly attached to tegumen; uncus apparently absent, rarely present (e.g., D. phelina); socii extremely variable in shape, usually heavily sclerotized, fused along midline; fused socii sometimes forming a robust, triangular or elongate structure, bifid at its apex (e.g., D. fatima), more frequently a pair of small, digitate processes (e.g., D. beckeri); tegumen extremely variable, sometimes narrow and relatively tall (Chloris and Butes groups), in others extremely wide, expanded dorsally (e.g., D. candelaria, D. charila), frequently with elongate dorsal processes arising on either side of socii/uncus complex (e.g., D. fratelloi); vinculum shorter than tegumen, usually extremely wide, rarely narrow (Vitrifera Group); saccus wide and broad, dorsal margin forming a large triangular sclerite between valva bases, ventral margin of genitalia often with a deep mesal notch; valva usually broad, tightly attached to ring, mostly membranous; BO large, occupying most of valva, ventrolateral margin greatly expanded; costa of valva highly variable, often heavily sclerotized, serrate and extremely complex; apex of valva usually forming a robust, heavily sclerotized, coarsely dentate structure, variable in shape, this process ranging from concave club shaped (e.g., D. ilerdina) or wing shaped (e.g., D. tessmanni), to digitate (e.g., D. beckeri), sometimes narrow and greatly elongate (e.g., D. zarza); lateral area below apex forming a membranous or lightly sclerotized appendix, this attached to dorsal portion of BO by a narrow, straplike sclerite; arms of transtilla extremely variable in width and shape, almost always wide, angled sharply downward, meeting at midline to form a large, U-shaped sclerite; base of transtilla sometimes with dorsal margin serrate (e.g., D. butes) or with robust denticles (e.g., D. fratelloi); aedeagus almost always extremely narrow and elongate (e.g., D. candelaria), sometimes sinuate (e.g., D. longipennis), wider at base; apex of aedeagus usually simple, less frequently with a tiny ventral point (e.g., D. tessmanni); some species (e.g., D. beckeri, D. trailii) with a long, curved process, its outer surface finely spiculate, arising before apex of aedeagus; vesica extremely small, usually much less than one-half length of aedeagus; cornuti usually absent, sometimes comprising a pair of dentate sclerites, rarely a brush of short, fine spines (e.g., D. phelina).

Female (fig. 188E, 188F, 189A, 190G). FW length  =  14.0–25.0 mm. Head, thorax, and abdomen similar to male, except: antenna quadripectinate, rami slightly shorter and more delicate; wings longer and broader, frequently lighter in color, more sparsely scaled; frenulum comprising 4–6 bristles.

Abdomen: Wider than male, St7 sclerotized, scaleless, setose, ostium often displaced anteriorly to near anterior margin of St7.

Terminalia (figs. 192E; 193E, F; 194D; 195C; 196B; 197E; 199D, F; 200D; 201B; 202E–G; 204D; 206C; 207E, F; 210): Tg7 long and wide, quadrate, rarely slightly tapered posteriorly (e.g., D. phelina), anterior margin simple, posterior margin simple, sometimes slightly convex (e.g., D. fatima); Tg7 occasionally with long setae along posterior margin (e.g., Chloris Group); St7 wide, usually equal in length to Tg7, sometimes shorter, surface sparsely covered with long setae, especially along posterior margin, anterior margin simple or broadly convex; posterior margin of St7 often broadly sclerotized, concave or with a U-shaped mesal excavation varying in length and width; Tg8 short, lightly or moderately sclerotized, posterior margin simple; AA varying in length, often short and wide (Butes Group), or moderately long and thin (D. otanes, Charila, and Cyma groups); A8 pleuron membranous, sometimes sclerotized (Phelina Group); PP usually moderately long, thin, sometimes extremely short and wide, or reduced to tiny nubs (Phelina Group); PA highly variable in size and shape, ranging from extremely large, sclerotized (Butes and Phelina groups), to moderate in size and membranous (Cyma Group), posterior margin usually convex, sometimes angulate (Vitrifera Group), some species with ventrolateral portion of PA heavily sclerotized, forming a large protrusion (e.g., D. areolata); PVP either extremely small (e.g., D. phelina), or long and wide (e.g., D. trailii); ostium small, frequently funnel shaped; DB short, either membranous or sclerotized, rarely forming a long, narrow, sclerotized tube (Vitrifera Group); CB variable in size, membranous, almost always round to ovoid in anterior one-half to two-thirds, posterior portion then abruptly constricted to form a long, narrow, membranous tube; CB sometimes small (D. longipennis), often slightly constricted anteriorly, this portion bent downward (Cyma and Fatima groups); signum often absent (Butes, Phelina, and Vitrifera groups), or more frequently small and figure-eight shaped, its internal surface sparsely dentate (Chloris, Fatima, and Cyma groups); DS arising dorsally a short distance from ostium, at junction of CB and DB.

Distribution

Dioptis species occur from southern Mexico and Belize south to Bolivia and southeastern Brazil. Certain members of the Chloris, Butes, and Phelina groups occur at midelevations, but this is not the norm; most live in lowland rainforests. The taxa most lepidopterists recognize as Dioptis—in the Vitrifera, Fatima, and Cyma groups—are almost universally found in Amazonia. Exceptions include the following Cyma Group species: D. fratelloi, collected at 1500 meters in Guyana; D. cheledonis, which occurs at approximately 1200 m in southeastern Ecuador; and D. uniguttata, recently captured at San Rafael Falls (1500 m) in northeastern Ecuador (pl. 41A). The remaining species in these three groups are found well below 500 m.

Biology

The first Dioptis species for which host plant associations became known is D. longipennis, in the Butes Group. Caterpillars of this taxon have been reared on numerous occasions at two separate Costa Rican sites, both on the Caribbean slope of the Cordillera Central (Dyer and Gentry, 2002; J.S. Miller, unpubl., 2007; Janzen and Hallwachs, 2008). Dioptis longipennis larvae have so far been found in association with four understory palm genera—Asterogyne (pl. 48B), Calyptrogyne (pl. 48C), Geonoma, and Prestoea. These are some of the same palm hosts that are utilized by Isostyla, Stenoplastis, and Tithraustes (table 4).

It was not until January 2009, that immature stages of additional Dioptis species were discovered (table 4). During an Ecuadorian expedition, we found caterpillars of a rare, upland Dioptis, D. uniguttata in the Cyma Group, feeding on Geonoma at San Rafael (S00°06′09″, W77°35′22″; 1300 m). Later during that trip, larvae of D. egla (Cyma Group) were found in association with the same palm genus—Geonoma—this time on the Río Shiripuno, a site in Amazonian Ecuador (S01°06′17″, W76°43′54″; 230 m). Taken together, these findings firmly establish understory palms as important Dioptis host plants, probably for all 45 included species.

The larvae of D. longipennis (pl. 38M) show body coloring and head patterning similar to caterpillars of Tithraustes and Isostyla (pl. 39A, D, E). In all of these, the color is grayish, with cream-colored dorsal, subdorsal and lateral stripes running the length of the body. The head capsule is yellowish with conspicuous black markings; A8 is similarly patterned, seemingly creating a “false head”. Thus, future phylogenetic analyses for the Dioptinae employing characters from larval morphology may support a closer relationship between these genera than is reflected in the cladogram based soley on adult morphology alone (fig. 7).

Discussion

An important difference between the dioptine classification proposed here and previous ones is that the boundaries of Dioptis are broadened to include two small clades—the Central American Butes Group (pl. 17), and the South American Chloris Group (pl. 17). The members of these were formerly placed in Tithraustes (Bryk, 1930), a “garbage can” genus, used by previous authors to place any dioptine species whose generic affinities were unclear (see Discussion: Classification, and fig. 354). These newer additions to Dioptis do not have quite the same general appearance as their congeners; the FW is more elongate, and the transparent areas of the wings are smaller. Nevertheless, cladistic analyses demonstrate membership in this genus (fig. 3); these taxa exhibit obvious synapomorphies for Dioptis, such as quadripectinate antennae, an extremely small tympanum, and a long, obliquely angled UDC in the FW.

My analyses also show that Dioptis is paraphyletic with respect to two monobasic genera of earlier authors—Authyala Warren (1905) and Paradioptis Hering (1925). Each of these was erected to include a single species with wing venation atypical for Dioptis. In Authyala obliquaria, veins M3 and CuA1 are separate in the FW and HW, rather than being stalked in both wings as they are elsewhere in Dioptis. Similarly, Paradiotis otanes is unusual for having M3 and CuA1 stalked in the FW, but separate in the HW (fig. 190E). When a comprehensive analysis of adult morphology is undertaken, these two species fall within Dioptis (fig. 3). Such results highlight the need for inclusive analyses, rather than the use of single-character systems, such as wing venation, when attempting to define a classification comprising monophyletic entities.

From these results, it can be inferred that two important dioptine characters show evolutionary reduction within Dioptis. First, the male FW stridulatory organ is well developed in the Chloris Group; the DC is approximately one-third the FW length (fig. 190D), the bases of veins M1 and M2 are swollen, and the surface of the fascia area is corrugated. This structure is absent in more derived Dioptis taxa, such as members of the Fatima and Cyma groups (fig. 190F). Secondly, the metathoracic tympanal organ is present but small in the Chloris Group, becoming reduced within Dioptis until, in the most derived taxa such as D. trailii (Cyma Group), the tympanum is represented by a shallow depression (figs. 187I, 189B, 189C), but the membrane is absent altogether. The underlying biological reason for these reductions is unclear. Perhaps the two losses are correlated, since absence of the FW stridulatory organ could make a hearing organ obsolete.

As is noted in the general Discussion (Character Evolution: Sound Production and Hearing) below, Forbes (1916) chose a species of Dioptis to represent the Dioptinae (then “Dioptidae”) in his early attempt to outline the phylogeny of the Noctuoidea. Structure of the metathoracic tympanum, then regarded as a monolithic character system in noctuoid systematics, formed the basis of his arguments. Because of its absence in Dioptis, his only dioptine exemplar, he regarded the Dioptidae as the basal group of the entire Noctuoidea. Forbes (1922) later recanted, acknowledging presence of a tympanum in other dioptines.

Variation in genitalia within Dioptis is exceptional. Species with seemingly identical wing patterns often show extremely different genital anatomy. The case of Dioptis trailii (Butler, 1877b) and D. fatima (Möschler, 1877) provides an example. The wings of these two are so similar that D. fatima had traditionally been regarded as a synonym of D. trailii (Prout, 1918; Hering, 1925; Bryk, 1930). However, genital structure shows that, not only are the two distinct, but they belong in different species groups within Dioptis (appendix 2). Similar cases abound. Female genitalia are less variable than those of males, but still provide useful features for defining species-group relationships within Dioptis. The eight species groups created here reflect an abundance of morphological differences within Dioptis.

Species identifications in Dioptis are usually extremely difficult. In the Cyma Group, the largest and most complex Dioptis subclade, identifications are nearly impossible without study of genitalia. Even then, the chances of assigning a name to any given specimen are remote. Species boundaries in Dioptis will only be fully resolved through future revisionary work. This must entail dissecting large numbers of specimens across wide-ranging localities, and will of necessity include study of genital morphology for all the primary type material. Such research is beyond the scope of this project, but I have attempted to stabilize Dioptis nomenclature as best I can.

My collecting experience suggests the existence of a great many undescribed, cryptic Dioptis species at some lowland localities. For example, in December 1996, a team of lepidopterists from the AMNH (New York) and MUSM (Lima) collected intensively at Tambopata Reserve in Amazonian Peru (200 m). At this site, Dioptis is abundant, flying during the day in the forest understory. We collected hundreds of specimens in a relatively short period of time. My studies later revealed that we had captured 10 described species. However, this material also included at least five undescribed species, separable from the various described taxa only by comparisons of genitalia.

Undertaking a revision of Dioptis, with an included species level cladogram, will be challenging, but the payoff could be considerable. Such research would allow one to outline the evolutionary loss of the tympanum and male stridulatory in Dioptis. With such a framework in hand, it will be fascinating to study the natural history of the genus in hopes of explaining the biological meaning of these evolutionary events.

In addition, a cladogram for Dioptis will help unravel the evolution of wing pattern in the genus, which could have broad implications for understanding mimicry. Bates (1862), in his seminal paper describing mimetic resemblance in Amazonian Lepidoptera, included Dioptis among his examples. As part of that paper, he described three Dioptis species—aeliana, ilerdina, and onega. Each was named for its mimetic resemblance to a particular species of ithomiine butterfly (Nymphalidae). For example, Dioptis aeliana was so-called because it is “deceptively like” Brevioleria aelia (Bates, 1862: 565). Bates' publication is one of the most influential natural history papers ever written; it spearheaded an entire field of endeavor, the study of mimicry.

KEY TO DIOPTIS SPECIES GROUPS

1. Metathoracic tympanum shallow, with a small round membrane facing posteroventrally2

Metathoracic tympanum comprising a shallow, sclerotized depression, membrane absent (fig. 187I, 189B, 189C)5

2. Forewing DC much shorter than one-half FW length; male FW stridulatory organ present (fig. 190D), bases of veins M1 and M2 swollen on wing's ventral surfaceChloris Group

FW DC approximately one-half wing length; male FW stridulatory organ absent (fig. 190E, F), base of M1 and M2 not swollen3

3. Labial palpus relatively short and straight, porrect (fig. 187A, B, E, G, H), ascending to slightly above clypeus; Lp2 narrow, curving gently upward4

Labial palpus long, held close to face, ascending to well above middle of front (fig. 187F); Lp2 wide, curving strongly upwardButes Group

4. Forewing and HW veins M3 and CuA1 stalked; FW with a large, white, transverse subapical band (pl. 18), a faint white spot in hyaline area beyond DC between bases of radius and M1, and a second white spot near tornusPhelina Group

FW and HW veins M3 separate; FW without white spots of any kind; wings mostly hyaline, with thin blackish-brown outer marginsD. obliquaria (Warren)

5. Hind wing veins M3 and CuA1 stalked (fig. 190F)6

HW veins M3 and CuA1 separate (fig. 190E)D. otanes (Druce)

6. Tegumen without dorsal processes; socii/uncus process not comprising short, paired, digitate processes7

Tegumen with a pair of dorsal processes arising from either side of socii/uncus complex near base (e.g., figs. 206A, 207A), processes sometimes greatly elongated; socii/uncus complex comprising paired, apressed, usually digitate processesCyma Group

7. Apex of valva forming a greatly elongate, curved, process (figs. 200A, 201A); tegumen extremely wide, expanded laterally; socii/uncus complex somewhat triangular, narrow at base, bifid at apex, serrate belowVitrifera Group

Apex of valva forming a narrow, usually C-shaped process (fig. 203A), its mesal surface coarsely dentate; tegumen moderately wide, not expanded laterally; base of socii/uncus complex forming a long, necklike structure (figs. 202A, 203A)Fatima Group

1. CHLORIS GROUP

The two members of the Chloris Group—D. chloris and D. subalbata—have variously been placed in Dioptis and Tithraustes, most recently (Bryk, 1930) in the latter. Based on the results of my cladistic analyses, I here move them to Dioptis, with Dioptis subalbata (Dognin) a new combination. The rationale for this transfer is supported by numerous synapomorphies of the genitalia, as well as by the presence of quadripectinate antennae. Warren (1905: 313) considered chloris to be a species of Dioptis, but noted that it “differs from other Dioptis in having the [FW discal] cell shorter, scarcely more than one-third of wing”. According to my results, the Chloris Group is a clade arising at the base of the generic phylogeny (fig. 3). Their short DC, associated with presence of a FW stridulatory organ, is apparently plesiomorphic; these traits were lost in more-derived members of Dioptis.

The Chloris Group contains the smallest species in Dioptis (pl. 17), with FW lengths ranging between 12.5 and 15.5 mm. Their wings are strongly triangular, and the pattern is delicate. These fascinating taxa are also extremely rare. The sum of known material for the Chloris Group includes only 12 specimens—two from Ecuador (BMNH); one from Peru (USNM), and the remaining nine from Bolivia (AMNH, BMNH, USNM, ZMH). I was unable to find unequivocal characters for separating the two included species, other than in features of their genitalia, which provide clear diagnostic differences.

KEY TO CHLORIS GROUP SPECIES (MALES)

1. Apex of valva with a long, bristly digitate process (fig. 192A); uncus without a dorsal process; posterior margin of male St8 with a large, wide V-shaped mesal excavation (fig. 192D); scales of front mostly white, a few light brown scales (Ecuador)chloris Druce

Valva widened at apex, without a digitate process (fig. 193A), apex covered with long, curved setae; uncus with a delicate, thin dorsal process; posterior margin of St8 with a small, narrow V-shaped mesal excavation (fig. 193C); front white on lateral portions, gray-brown in central area (Bolivia)subalbata (Dognin)

SPECIES INCLUDED AND MATERIAL EXAMINED

Dioptis chloris Druce, revised combination

Figure 192; plate 17

Dioptis chloris Druce, 1893: 295.

Type Locality

Ecuador, Chiguinda.

Type

Syntype ♂, leg. C. Buckley (BMNH).

Discussion

Although the species key above uses genital characters to separate D. chloris and D. subalbata, coloration differences are promising. A possible distinguishing feature of the wings is the following: The HW discocellular veins, closing the DC distally, are completely dark in D. subalbata, whereas in D. chloris these veins are white (pl. 17). Furthermore, in D. chloris veins M1 and M2 are white as they run through the FW fascia immediately beyond the DC. In D. subalbata these veins tend to be dark. Another possible difference is that the front is almost completely white in D. chloris, whereas its central area is gray-brown in D. subalbata. More specimens of both species are needed to test the veracity of these diagnostic traits.

A female USNM specimen from Peru (JSM-1048), although figured here as chloris (pl. 17), seems to differ from both described Chloris Group species and may represent an undescribed taxon.

Distribution

Ecuador (BMNH); Peru (USNM).

Dissected

♂, Ecuador, Chiguinda, leg. C. Buckley, BMNH (genitalia slide no. JSM-1047); ♀, Peru, 1895, leg. Hagné, USNM (genitalia slide no. JSM-1048).

Dioptis subalbata (Dognin), new combination

Figures 187E, 190D, 193; plate 17 [EX]

Tithraustes subalbata Dognin, 1904: 358.

Type Locality

Bolivia, Yungas de La Paz, 1000 m.

Type

Holotype ♂ (USNM type no. 30956).

Discussion

Dioptis subalbata, from Bolivia, and its sister species, D. chloris from southern Ecuador, are easily separable by differences in genital morphology (see species key). Nevertheless, it should be noted that the taxonomy of the Chloris Group needs work. For example, my dissections reveal the existence of an as yet undescribed Bolivian species; the male genitalia of a BMNH example from the Río Songo (JSM-1049) are markedly different from those of the subalbata holotype (JSM-1045). In addition, I note above the possible existence of a cryptic Peruvian species related to D. chloris. Nevertheless, I hesitate to erect new species until additional material of these taxa becomes available for study.

Distribution

Bolivia (AMNH, BMNH, USNM, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1045); ♂, Bolivia, Río Songo, 750 m, leg. Fassl, BMNH (genitalia slide no. JSM-1049, wing slide no. JSM-1661); ♀, Bolivia, Cochabamba, Yunga del Espiritu Santo, 1888–89, leg. P. Germain, BMNH (genitalia slide no. JSM-1046).

2. BUTES GROUP

My new, more inclusive concept of Dioptis supports inclusion of three closely related species—butes, longipennis, and eteocles—in the genus. These I designate the Butes Group. Like the Chloris Group, all three were placed in Tithraustes by previous authors (Prout, 1918; Hering, 1925; Bryk, 1930). Butes Group members exhibit a habitus atypical for Dioptis: their wings are more elongate (pl. 17), and they show only a few small hyaline areas; the metathoracic tympanum is small, and the FW stridulatory organ is of intermediate development; the DC is not as short as in the Chloris Group (fig. 190D), but it is shorter than one-half the wing length, and veins M1 and M2 are swollen at their bases. These two Dioptis species groups differ from one another in another important respect—the Butes Group is endemic to Central America, whereas the Chloris Group is strictly South American.

KEY TO BUTES GROUP SPECIES

Plate 17

1. Forewing with a conspicuous, quadrate, white submarginal spot straddling vein M2; HW with an ovoid, hyaline white spot beyond apex of DC, in addition to large basal streak; FW length  =  19.0–23.0 mm (Nicaragua S to Panama)longipennis (Schaus)

FW without a conspicuous submarginal spot on M2; HW without an ovoid spot beyond apex of DC2

2. Forewing outer margin lacking markings of any sort; FW ground color brown to blackish brown, veins concolorous with ground color; FW length  =  14.0–17.0 mm (Mexico S to Costa Rica)butes (Druce)

FW with a diffuse whitish band along margin between veins Rs3 and M2; FW ground color chocolate brown, veins conspicuously lighter; FW length  =  20.0–22.0 mm (Guatemala S to Nicaragua)eteocles (Druce)

SPECIES INCLUDED AND MATERIAL EXAMINED

Dioptis butes (Druce), new combination

Figure 194; plate 17 [EX]

Tithraustes butes Druce, 1885a: 159.

Type Locality

Guatemala, Cubilguitz.

Type

Syntype ♂/♀, leg. Champion (BMNH).

Phaeochlaena basalis Warren, 1900: 128.

Type Locality

Honduras, San Pedro Sula.

Type

Holotype ♀, ex Fruhstorfer Collection (BMNH).

Discussion

Druce (1885a) did not figure this species in the Biologia, but the two specimens used for his original description, a male and a female from Cubilguitz (“Vera Paz.”) Guatemala, are at the BMNH. Neither has been given formal type designation, but Druce's description is clearly written and corresponds perfectly with those two specimens. The identity of this species is not in question. Dioptis butes is known from Costa Rica north to Belize and Veracruz Mexico, but the moth is not common in collections.

Dioptis butes is the smallest member of the Butes Group (see species key). The male genitalia possess a serrate dorsal margin of the large, transtillar arms (fig. 194A), a feature unique for the Dioptinae. I did not dissect the BMNH type of basalis Warren, but there is little doubt, based on wing-pattern similarities, that this taxon is a junior synonym of butes Druce, as previous authors have presumed.

Distribution

Mexico (LACM, USNM); Guatemala (BMNH, USNM); Honduras (BMNH); Belize (PMNH); Costa Rica (INBio).

Dissected

♂, Guatemala, Cayuga, May, Schaus & Barnes coll., USNM (genitalia slide no. JSM-459); ♂, Mexico, Chiapas, Rancho Santa Rosa, 10 Jun 1965, leg. Peter Hubbell, LACM (genitalia slide no. JSM-1677); ♀, Guatemala, Cayuga, Sep, Schaus & Barnes coll., USNM (genitalia slide no. JSM-460).

Dioptis eteocles (Druce), new combination

Plate 17

Tithraustes eteocles Druce, 1885a: 159.

Type Locality

Guatemala, Cubilguitz, 1000 ft (leg. Champion); Chontales, Nicaragua (leg. Belt).

Type

2 Syntype ♂♂, 1 Syntype ♀ (BMNH).

Discussion

Druce described eteocles and butes in the Biologia Centrali-Americana, placing both in Tithraustes. As is the case with D. butes, he did not designate a type for D. eteocles. Regardless, the BMNH specimens on which Druce based his description are clearly labeled. They include two males, both with abdomens missing, and a single female. Each was collected in a different Central American country. These are the only known examples of D. eteocles.

This species is larger than D. butes, but is roughly similar in size to D. longipennis. The HW of D. eteocles lacks the hyaline fascia beyond the DC found in D. longipennis (pl. 17). A unique feature of D. eteocles is its short, diffuse white band at the FW outer margin, located between Rs3 and M2. There is no white in this area in D. butes (pl. 17), and D. longipennis instead has a round, white submarginal spot straddling M2.

Distribution

Nicaragua (BMNH); Honduras (BMNH); Guatemala (BMNH).

Dissected

None.

Dioptis longipennis (Schaus), new combination

Figures 187F, 190C, 195; plates 17, 38M [EX]

Tithraustes longipennis Schaus, 1913: 382.

Type Locality

Costa Rica, Juan Viñas.

Type

Syntype ♀ (USNM type no. 18037).

Discussion

I here transfer D. longipennis from Tithraustes, where it was originally described and has always been placed, to Dioptis. Among other features, such as the presence of quadripectinate male antennae, membership in Dioptis is supported by synapomorphies of the male and female genitalia. Of the three Butes Group taxa, D. longipennis is by far the most common in collections. In Costa Rica, the moth has been collected with considerable frequency on the Caribbean slope of the central Cordillera, at low to midelevations.

Dioptis longipennis caterpillars have been collected at two Costa Rican sites—Estación Pitilla and La Selva. The larvae of D. longipennis (pl. 38M) exhibit coloration on the body and head similar to those in Tithraustes (pl. 39A, D, E). They also share the same host plants, understory palms in the genera Asterogyne (pl. 48B), Calyptrogyne (pl. 48C), Geonoma and Prestoea (see table 4).

Distribution

Costa Rica (AMNH, BMNH, INBio, LACM, SMNS, USNM, ZMH); Panama (ZMH); Nicaragua (BMNH).

Dissected

Syntype ♀ (genitalia slide no. JSM-1184); ♂, Costa Rica, Guanacaste, Estación Pitilla, 9 km S Sta. Cecilia, 700 m, 22 Aug 1993, leg. C. Moraga, L N 330200 380200, #2322, INBio (genitalia slide no. JSM-855); ♂, Nicaragua, San Ramon, R. Wanks, 375 ft, May 1905, leg. M.G. Palmer, BMNH (genitalia slide no. JSM-405); ♀, Costa Rica, Limón, Amubri, 70 m, 1–22 Dec 1994, leg. C. Gallardo, L S 385000 578100, #4387, INBio (genitalia slide no. JSM-856); ♀, Costa Rica, Guanacaste, Estación Pitilla, 9 km S Sta. Cecilia, 700 m, 9–20 Nov 1993, leg. C. Moraga, L N 330200 380200, #2449, INBio (genitalia slide no. JSM-817); ♀, Costa Rica, Port Limón, Mar 1907, leg. W. Schaus, USNM (genitalia slide no. JSM-404).

3. PHELINA GROUP

The Phelina Group contains four medium-sized to large dioptine species (pl. 18). It includes D. candelaria and D. vacuata, the largest species in Dioptis. This group can be recognized by their FW, which shows a broad, transverse, white subapical band, accompanied by two smaller white spots, one beyond the DC and the other near the tornus. There is never an orange submarginal HW band (Fatima and Cyma groups), although some specimens of D. pellucida show a wide, brown marginal HW band (pl. 18). The metathoracic tympanum of Phelina Group species bears a small, round membrane. In males, the four antennal rami on each annulation are long, whereas in females the basal pair of rami is long, but the distal pair is short. Additional diagnostic characters include: anterior margin of male Tg8 with short, blunt lateral apodemes (figs. 196E, G; 197D); papillae anales of female genitalia large (figs. 196B, 197E), A8 pleuron sclerotized, AA and PP short.

Phelina Group taxa are difficult to separate using wing pattern, so the key below relies heavily on male genitalia. The taxonomy of these species is in a rudimentary stage. Part of the problem is that, other than D. phelina, the taxa are extremely rare in collections, with poor geographical representation.

KEY TO PHELINA GROUP SPECIES (MALES)

Plate 18

1. Cell of HW formed by fork of M3+CuA1 opaque, covered with dark brown scales, conjoined with brown marginal band; uncus long, lanceolate (fig. 197A); tegumen moderately wide; FW length  =  18.0–20.0 mm (Colombia)phelina C. and R. Felder

Cell of HW formed by M3+CuA1 hyaline to semihyaline from fork to brown marginal band; uncus small or absent; tegumen extremely wide2

2. Socii/uncus complex comprising two huge, C-shaped structures (fig. 196F); arms of transtilla bearing large, sclerotized teeth near base; apex of valva smoothly curved, densely setose, without a process; FW length  =  21.5–25.0 mm (Panama, Pacific side)vacuata Warren

Socii/uncus complex small, not C-shaped (fig. 196A); arms of transtilla simple; apex of valva not setose, bearing a sclerotized, hook-shaped process; FW length 22.0–23.0 mm3

3. Male Tg8 gently concave along lateral margins; lateral margin of tegumen concave (Panama, SE Costa Rica, Caribbean side)candelaria Druce

Male Tg8 deeply concave along lateral margins; lateral margin of tegumen convex (W Colombia)pellucida Warren

SPECIES INCLUDED AND MATERIAL EXAMINED

Dioptis candelaria Druce

Figures 187G, 196A–E; plate 18 [EX]

Dioptis candelaria Druce, 1885a: 157, pl. 14, fig. 16.

Type Locality

Panama, Río Candelaria.

Type

Holotype ♂, leg. Ribbe (ZMH).

Dioptis nivea Hering, 1925: 521, fig. 69k.

Type Locality

Colombia, San Miguel.

Type

Holotype ♂, 1 May 1924 (ZMH).

Discussion

Dioptis candelaria was described from the region of Bocas del Toro, Panama; the Río Candelaria is part of the Caribbean drainage. My knowledge of this species in Costa Rica is based on a single INBio specimen, collected at Estación Hitoy Cerere (100 m) in Limón Province, an area essentially contiguous with Bocas del Toro. I traveled to Hitoy Cerere in January 2007 hoping to collect additional specimens of D. candelaria, but none was found.

The holotype of Dioptis candelaria, described from the Staudinger collection, is one of the few Druce types housed at the ZMH rather than the BMNH. The label simply reads “Panama”, but the original description in the Biologia Centrali-Americana lists the type locality more precisely as “Río Candelaria”.

Hering's taxon, D. nivea (San Miguel, Colombia), is described from a male that I studied but did not dissect. In that specimen, the white subapical band is much wider and more oval shaped than in the D. candelaria type. My assessment suggests that D. nivea should more appropriately be associated with D. pellucida Warren, also from Colombia, and may, in fact, be a synonym of it. Dissection of the D. nivea type will be required to correctly determine the status of that name.

Distribution

Panama (AMNH, BMNH, USNM, ZMH); Costa Rica (INBio).

Dissected

Holotype ♂ (JSM-1770); ♀, Panama, Bocas del Toro, Apr 1907, Wm. Schaus Collection, USNM (genitalia slide no. JSM-750).

Dioptis pellucida Warren

Plate 18

Dioptis pellucida Warren, 1901: 438.

Type Locality

Colombia, Río Dagua.

Type

Holotype ♀, leg. W. Rosenberg (BMNH).

Discussion

I did not dissect the female holotype of D. pellucida, but did dissect a male specimen from Colombia (BMNH) exactly matching its wing pattern. Synapomorphies of the male genitalia (JSM-406) support placement of D. pellucida, known exclusively from western Colombia, in the Phelina Group.

Two BMNH specimens exhibit a FW identical with that of the D. pellucida type, but show a much wider brown band along the HW margin (pl. 18). Their label data are exactly the same as that of the dissected male (JSM-406), and their genitalia are inseparable; I regard them as conspecific with D. pellucida. According to K. Willmott (personal commun.), the brown-HW examples of D. pellucida belong in a mimicry complex with several ithomiines, including Hypoleria lavinia, Ithomia diasia, Oleria amalda and Pseudoscada timna. Dioptis pellucida is apparently sympatric with these butterflies, which occur in Cauca and adjacent Choco. The novel D. pellucida phenotype may have arisen through the evolution of mimetic resemblance.

Distribution

Colombia (BMNH, ZMH).

Dissected

♂, Colombia, Cauca, Nouvelle Grenade, Juntas, Dec 1897–Jan 1898, leg. M. de Mathan, BMNH (genitalia slide no. JSM-406).

Dioptis phelina C. and R. Felder

Figure 190A, 197; plate 18 [EX]

Dioptis phelina C. and R. Felder, 1874: pl. 105, fig. 6.

Type Locality

Colombia, “Bogotá”.

Type

Not seen.

Tithraustes impleta Warren, 1900: 129.

Type Locality

“Colombia”.

Type

Holotype ♀ (BMNH).

Dioptis pandates Druce, 1893: 294.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♂, leg. Carder (BMNH).

Discussion

Dioptis phelina, endemic to the region of Bogotá, Colombia, is relatively common in collections. In addition to its fairly large size and distinctive FW pattern, the species can be recognized by the dark scaling in the fork of HW veins M3 and CuA1. Although I have not seen the D. phelina type, the identity of this species is not in doubt. I follow previous authors (Prout, 1918; Hering, 1925) in retaining impleta Warren and pandates Druce as synonyms of phelina, but have not verified these by morphological study. Wing-pattern similarities support the synonyms.

Members of a BMNH series from the Río Magdalena exhibit wings in which the ground color is warm chocolate brown, rather than dark brown to black as in most other specimens of D. phelina. However, the male and female genitalia (JSM-1187, JSM-1188) of chocolate-brown and blackish-brown examples are identical, suggesting that all this material is conspecific.

Distribution

Colombia (AMNH, BMNH, CAS, CMNH, CUIC, MUSM, MPM, NMW, OUMNH, USNM, ZMH).

Dissected

♂, Colombia, leg. Felipe Ovalle, AMNH (genitalia slide no. JSM-420); ♂, Colombia, Villavicencio, Dognin Collection, USNM (genitalia slide no. JSM-1185); ♂, Colombia, Nouvelle Grenade, Río Magdalena at Bogotá, 8 Sep 1877, leg. Dr. O. Thieme, BMNH (genitalia slide no. JSM-1187); ♀, “Colombia”, Dognin Collection, USNM (genitalia slide no. JSM-1186); ♀, Colombia, leg. Felipe Ovalle, AMNH (genitalia slide no. JSM-421); ♀, Colombia, Nouvelle Grenade, Río Magdalena at Bogotá, 8 Sep 1877, leg. Dr. O. Thieme, BMNH (genitalia slide no. JSM-1188).

Dioptis vacuata Warren, revised status

Figure 196F–I; plate 18

Dioptis vacuata Warren, 1905, 313.

Type Locality

Panama, Chiriquí.

Type

Syntype ♂/♀ (BMNH).

Discussion

Dioptis vacuata is the largest member of the genus, with females reaching a FW length of 25.0 mm. This taxon is extremely rare. Other than the BMNH male and female syntypes, I was able to locate only two specimens (USNM), both collected by Gordon Small. It will be difficult to firmly establish the identity of D. vacuata, since the abdomen of the type (BMNH) has been reattached with glue backward onto the body, making dissection difficult. The USNM male of what I am assuming is D. vacuata (JSM-735) exhibits genitalia startlingly different from those of D. candelaria (see fig. 196), which also occurs in Panama but on the opposite side of the Cordillera Central. The female genitalia of D. vacuata (JSM-736) also show differences from D. candelaria females, but these are much less dramatic. It will be interesting to learn more about this moth, and all members of the Phelina Group, as additional specimens are brought to light.

Warren (1905) described this taxon as a species, but authors since Prout (1918) regarded it as a synonym of D. candelaria. I here return it to species status.

Distribution

Panama (BMNH, USNM).

Dissected

♂, Panama, Panama, Cerro Jefe, 2000 ft, Mar 1974, leg. G.B. Small, USNM (genitalia slide no. JSM-735); ♀, Panama, Darién, Cana, 400 m, 16 Jul 1981, leg. G.B. Small, USNM (genitalia slide no. JSM-736).

4. DIOPTIS OBLIQUARIA (WARREN)

Warren (1905: 311), in describing the genus Authyala to include a single species—obliquaria Warren—distinguished it from Dioptis and Monocreaga because veins M3 and CuA1 of obliquaria arise separately from the DC in both the FW and HW. Typically in Dioptis, these are stalked in both wings (fig. 190D, F, G). However, as is the case with D. otanes, previously placed in its own genus Paradioptis based on wing venation (fig. 190E), such traits alone do not justify generic status. My character analysis suggests that Dioptis is paraphyletic with respect to obliquaria, and I therefore place Authyala in synonymy. Authyala was established by Warren (1905) in the Cyllopodinae (now Geometridae, Sterrhinae), and was subsequently transferred to the Dioptinae by Prout (1918).

Dioptis obliquaria exhibits the following characteristics: antenna quadripectinate; labial palpus thin, porrect; eye relatively small; metathoracic tympanum with a small membrane, facing posterolaterally; veins M3 and CuA1 separate in FW and HW; male Tg8 with a wide, shallow U-shaped mesal excavation on posterior margin (fig. 198B), St8 gradually tapered distally (fig. 198D); male genitalia with tegumen extremely wide, lacking dorsal processes (fig. 198A); socii/uncus complex comprising a pair of robust, curved dorsal processes; inner surface of valva coarsely dentate; aedeagus long, narrow (198C), bent upward near apex; vesica small, cornuti absent.

Dioptis obliquaria (Warren), new combination

Figure 198; plate 18

Authyala obliquaria Warren, 1905: 312.

Type Locality

Peru, Cuzco.

Type

Holotype ♂, leg. Garlepp, Apr 1901 (BMNH).

Discussion

This species is extremely rare, being currently known from three males collected in southeastern Peru—the BMNH type, one example at the ZMH from Chanchamayo (missing its abdomen), and a third at the CUIC (JSM-1625). The holotype of D. obliquaria was broken and in poor condition. I therefore made a balsam slide mount of the metathorax, along with an abdomen/genitalia slide. The CUIC specimen, also dissected, bears a label indicating that W.T.M. Forbes identified it in 1933. Based on the scant data at hand, D. obliquaria occurs at a higher altitude than most Dioptis species.

Because the wing venation of obliquaria is atypical for Dioptis, Warren (1905) placed this taxon in its own genus—Authyala. Subsequent authors retained it there (Prout, 1918; Hering, 1925; Bryk, 1930). However, Dioptis is paraphyletic with respect to obliquaria, so Authyala is here placed in synonymy, making Dioptis obliquaria (Warren) a new combination. The morphology of D. obliquaria, including its male genitalia (fig. 198), does not offer clues regarding membership within a particular species group, so this taxon remains set aside. Acquiring additional material, especially females, will be important as we attempt to unravel the phylogeny of Dioptis.

Distribution

Peru (BMNH, CUIC, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1211, thorax slide no. JSM-1212); ♂, Peru, Río Perene, CUIC (genitalia slide no. JSM-1625).

5. DIOPTIS OTANES DRUCE

Prout (1918: 416) erected the genus Eudioptis for a single species—otanes Druce—because he claimed it differs from Dioptis in the following ways: “[discal] cell of hind wing longer, [M3] well separate”; and “palpus longer than most Dioptis”. Hering (1925) proposed the name Paradioptis to replace Eudioptis because the latter is preoccupied (Hübner, 1816). My cladistic analyses show that Dioptis is paraphyletic with respect to P. otanes (fig. 3), and that the species should again be subsumed, as Druce (1893) had originally proposed. Dioptis otanes exhibits a host of traits found in derived members of Dioptis, but is unique within the genus in having veins M3 and CuA1 stalked in the FW but separate in the HW (fig. 190E). These wing-venation traits show homoplasy throughout the Dioptinae, and are difficult to rely upon without additional character support. The labial palpi of D. otanes (fig. 187H) are not noticeably longer than in most other Dioptis species (fig. 187A, B, E), and are in fact shorter than some (fig. 187F, G).

Dioptis otanes Druce, revised status

Figures 187H, 190B, 190E, 199; plate 17 [EX]

Dioptis otanes Druce, 1893: 294.

Type Locality

Ecuador, Río Napo.

Type

Syntype ♂ (BMNH).

Discussion

The wing pattern (pl. 17) and genital morphology of Dioptis otanes (fig. 199) suggest a close relationship with D. restricta of the Cyma Group (pl 19). Prout (1918) claimed that in D. otanes the labial palpi are longer than in other Dioptis species. While I did not find this to be the case, the palpi of D. otanes are unusual in their horizontal orientation (fig. 187E).

Although this species is well represented in museum collections, the majority of material was captured in the Upper Amazon Basin of eastern Peru. The only examples known from Ecuador, where the type was collected, are four males and a female at the BMNH. I did not dissect Ecuadorian specimens to investigate whether they are conspecific with material from Peru.

Distribution

Ecuador (BMNH); Peru (AMNH, BMNH, LACM, MUSM, USNM, ZMH).

Dissected

♂, Peru, Middle Río Marañon, 22 Dec 1924, H. Bassler Collection, AMNH (genitalia slide no. JSM-662); ♂, Peru, Middle Río Marañon, 22 Dec 1924, H. Bassler Collection, AMNH (genitalia slide no. JSM-423); ♂, Peru, Cavallo Cocho, Amazonas, May–Jul 1884, leg. M. de Mathan, BMNH (genitalia slide no. JSM-162, wing slide no. JSM-170); ♀, Peru, Middle Río Marañon, 22 Dec 1924, H. Bassler Collection, AMNH (genitalia slide no. JSM-422).

6. VITRIFERA GROUP

Features of the male genitalia best characterize the three members of the Vitrifera Group. These include the configuration of the valva apex, which bears an elongate, sclerotized process, dentate along its lateral margin (figs. 200A, 201A). In addition, there is a large bladelike process near the base of the valva where the transtillar arms join. Both of these features occur nowhere else in Dioptis. Female genitalia (figs. 200D, 201B) do not provide obvious species group synapomorphies.

KEY TO VITRIFERA GROUP SPECIES

Plate 18

1. Forewing with a wide, white transverse band in distal half; area immediately beyond DC dark brown2

FW with a narrow, comma-shaped, hyaline to whitish transverse maculation near apex; area immediately beyond DC hyaline (Venezuela and Guyana's S to Brazil and Peru)charila Druce

2. Bladelike basal process of valva with dorsal margin serrate (fig. 200A), apical process of valva robust; female ovipositor lobes triangular (fig. 200D), DB forming an elongate, slightly curved tube (E Peru)vitrifera Warren

Bladelike basal process of valva with dorsal margin smooth (fig. 201A), apical process of valva thin; female ovipositor lobes ear shaped, excavated along posterior margin (fig. 201B), DB forming a short, strongly curved tube (E Ecuador)zarza (Dognin)

SPECIES INCLUDED AND MATERIAL EXAMINED

Dioptis charila Druce

Plate 18

Dioptis charila Druce, 1893: 292, pl. 20, fig. 1.

Type Locality

Guyana.

Type

Syntype ♂, leg. Whitely (BMNH).

Discussion

Material in collections suggests that D. charila occurs across northern South America and south into the Amazon Basin, at least as far as Loreto, Peru. Its wing pattern differs from that of other Vitrifera Group species in lacking a wide white FW band (pl. 18). However, the genital morphology is fundamentally the same, strongly supporting placement of D. charila in this clade.

The abdomen of the male syntype of Dioptis charila is missing, but the male and female specimens dissected here (JSM-1170, 1171) show close wing-pattern resemblance with the type, and I am relatively confident regarding the identity of this taxon.

Distribution

Guyana (BMNH); French Guiana (AMNH, BHC, NMW); Venezuela (FNHM, USNM); Brazil (BMNH, CUIC, USNM, ZMH); Peru (AMNH, BMNH, MUSM).

Dissected

♂, Brazil, Amazonas, Rio Maves, USNM (genitalia slide no. JSM-1170); ♀, French Guiana, Environs de la Montagne des Simges, 15 Jul 1988, leg. B. Hermier, BHC (genitalia slide no. JSM-1171).

Dioptis vitrifera Warren, revised status

Figure 200; plate 18 [EX]

Dioptis vitrifera Warren, 1905: 43–44.

Type Locality

Peru, Department Huanuco, Pozuzo.

Type

Holotype ♂, leg. Hoffmanns (BMNH).

Dioptis albifasciata Druce, 1907: 309.

Type Locality

Peru, La Merced, 2000–3000 ft.

Type

Syntype ♂, leg. Watkins (BMNH).

Discussion

Although previously regarded as a synonym of D. zarza (Bryk, 1930), I have reinstated Dioptis vitrifera to species status. Whereas this name is here applied to material from Amazonian Peru, specimens from Ecuador retain the name D. zarza. Using these species concepts, D. vitrifera is more common in collections than D. zarza. A note of caution should be voiced, however, since I have not dissected the type of D. vitrifera.

Based on comparison of the vitrifera and albifasciata types at the BMNH, the latter is confirmed as a synonym. I dissected a BMNH male (JSM-845) exactly matching the type of albifasciata and bearing the same label data. Its genitalia are indistinguishable from those of vitrifera. So-called “albifasciata” material was collected at a higher elevation (approximately 1000 m) than most examples of D. vitrifera.

Distribution

Peru (AMNH, BMNH, MUSM, ZMH).

Dissected

♂, Peru, Madre de Dios, Tambopata Reserve, 200 m, Nov 1994, leg. S. Fratello, day coll., AMNH (genitalia slide no. JSM-739); ♂, Peru, La Merced, Upper Río Toro, 3000 ft, Aug–Nov 1901, leg. Simons, BMNH (genitalia slide no. JSM-845); ♀, Peru, Madre de Dios, Tambopata Reserve, 200 m, Nov 1994, leg. S. Fratello, day coll., AMNH (genitalia slide no. JSM-740).

Dioptis zarza (Dognin)

Figure 201; plate 18

Monocreaga zarza Dognin, 1894: 23.

Type Locality

Ecuador, “Environs de Loja”.

Type

Holotype ♀, leg. 1887 (USNM type no. 30940).

Discussion

Material identified in collections as Dioptis zarza constitutes two species—Ecuadorian specimens are zarza (Dognin), whereas specimens from Peru are vitrifera Warren, formerly a synonym of D. zarza (Bryk, 1930). The two are superficially similar, but differ in the shape of the white transverse FW band. Dioptis zarza also appears to have a slightly longer wingspan. Differences in their male and female genitalia abound (see species key, and figs. 200, 201). The female holotype, a male at the OUMNH, and an AMNH male collected in Napo Province, eastern Ecuador (JSM-1177) were the only specimens of D. zarza available for study.

Distribution

Ecuador (AMNH, OUMNH, USNM).

Dissected

Holotype ♀ (genitalia slide no. JSM-1176); ♂, Ecuador, Napo, 24 km N Cotundo, Tena-Baeza Road, 1097–1219 m, 4 May 1982, leg. F. Sperling & H.E. Frania, forest path, AMNH (genitalia slide no. JSM-1177).

7. FATIMA GROUP

The Fatima Group contains five species (appendix 2), all of which have corresponding taxa in the Cyma Group with essentially identical wing patterns. For example, D. charon, D. indentata, and D. tessmanni, in the Fatima Group (pls. 18, 19), look remarkably similar to D. incerta and D. curvifascia, from the Cyma Group (pl. 19). Similarly, D. fatima (pl. 18) and D. angustifascia (pl. 19), Fatima Group species, have wings bearing detailed resemblance to D. trailii in the Cyma Group (pl. 20).

Both species groups are defined on the basis of synapomorphies from genitalia. Although no additional morphological features were found to delimit these clades, genitalia provide convincing supportive evidence. For example, the male socii/uncus complex in all Fatima Group species extends dorsally, forming an unusual, elongate, necklike structure (figs. 202A, 203A). This configuration does not occur elsewhere in Dioptis, or elsewhere in the Dioptinae. Tests of my Dioptis species group hypotheses will provide a challenging project for future research, as will developing an understanding of relationships between them.

KEY TO FATIMA GROUP SPECIES (MALES)

1. Distal half of FW dark brown to blackish brown, enclosing a large, wide, white transverse band extending from subcosta to near tornus (e.g., D. charon, pl. 18); FW hyaline areas limited to basal half2

Distal half of FW with two transverse, hyaline bands (e.g., D. fatima, pl. 18), the first immediately beyond the DC and a second smaller one near the apex, veins dark as they pass through; FW without a white transverse band4

2. Serrate apex of male valva broadly C-shaped (fig. 203A), with a small subapical process on mesal surface; uncus bearing a pair of small dorsal hooks in addition to larger distolateral processes3

Serrate apex of valva straight, not C-shaped, simple, without a small subapical process; uncus without dorsal hooks, bearing distolateral processes only (Amazon)indentata Hering

3. Tegumen of male genitalia wide, short (fig. 203A); sclerotized apex of valva narrow, elongate, mesal surface finely dentate (E Peru)tessmanni Hering

Tegumen moderately wide, tall; sclerotized apex of valva short, mesal surface coarsely dentate (Bolivia, Peru, Brazil)charon Druce

4. Subapical hyaline area of FW narrow, comma shaped (pl. 18); base of socii/uncus complex extremely long and narrow (fig. 202A), curving downward; sclerotized apex of valva short; aedeagus short (fig. 202C) (Northern South America S to Peru)fatima (Möschler)

Subapical hyaline area of FW wide, ovoid (pl. 19); base of socii/uncus complex wide, not curved; sclerotized apex of valva long, C-shaped; aedeagus moderately long (E Peru)angustifascia Hering

SPECIES INCLUDED AND MATERIAL EXAMINED

Dioptis angustifascia Hering

Plate 19

Dioptis angustifascia Hering, 1925: 522, fig. 70a.

Type Locality

Peru, Iquitos.

Type

Holotype ♀, leg. Michael, 1895 (ZMH).

Discussion

Dioptis angustifascia is close in superficial appearance to D. trailii (pl. 20). One difference is that the region between the forks of FW veins M3 and CuA1 is hyaline in D. trailii, but is almost entirely blackish brown, contiguous with the FW cross-band, in D. angustifascia. The hyaline subapical FW band is also larger in D. angustifascia. When their male genitalia are compared, dramatic differences are apparent. In fact, the two taxa belong in different Dioptis species groups.

Separating D. angustifasica from its species group member, D. fatima (pl. 18), based on wing pattern is even more difficult, since in both the area in the fork of M3 and CuA1 is mostly blackish brown. Again, however, the hyaline subapical band is helpful; in D. fatima the band is narrow, whereas in D. angustifascia it is large, almost ovoid. By far the most revealing differences can be found in their male genitalia. The base of the socii/uncus complex is wide in D. angustifascia, but is extremely narrow, curving downward in D. fatima (fig. 202A). The apices of the socii/uncus complexes in the two species show completely different shapes, with that of D. angustifascia bearing a small mesal notch, but that of D. fatima shaped like a fishtail, with a pair of small dorsal hooks. I am aware of only two specimens of D. angustifascia—the ZMH holotype and an AMNH male (JSM-1166) from the Río Santiago in eastern Peru (JSM-1166).

Distribution

Peru (AMNH, ZMH).

Dissected

♂, Peru, Río Santiago, 19 Nov 1924, H. Bassler Collection, AMNH (genitalia slide no. JSM-1166).

Dioptis charon Druce

Plate 18

Dioptis charon Druce, 1893: 294, pl. 20, fig. 6.

Type Locality

“Bolivia”.

Type

Syntype ♀, leg. Buckley (BMNH).

Discussion

Comparison of AMNH material, collected at Tambopata (1996), with the BMNH type of D. charon suggests that, in addition to Bolivia, this species occurs in the lowlands of southeastern Peru. Dioptis charon, with its wide white transverse FW band and ochreous orange, submarginal HW band, exhibits a wing pattern closely resembling D. ilerdina and D. nigrivenis (pl. 20), both in the Cyma Group. These can be separated by the scales in the large triangle formed in the basal half of the FW, subtended by the cubital vein: in charon, this region is hyaline with a sparse covering of long, dark, hairlike scales; in contrast, the corresponding region in D. ilerdina and D. nigrivenis is covered with white, pedicellate scales. The genitalia of these taxa are strikingly different.

Dioptis charon is also similar to D. tessmanni (pl. 19). Their distributions appear to overlap in Peru. Dissection of material precisely matching the types of each hints at differences in their male genitalia, particularly regarding the shape of the valva apex. However, I say this with reservation. It may be that, upon more comprehensive study, D. tessmanni should be placed as a junior synonym of D. charon. I leave that issue for future research.

It is clear that D. charon belongs in a tight-knit clade with D. fatima and D. angustifascia, two species showing hyaline wings without a broad white FW band. This case highlights the remarkable wing-pattern convergence within Dioptis.

Distribution

Bolivia (BMNH); Peru (AMNH, MUSM, ZMH); Brazil (CUIC).

Dissected

♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. J. Grados, day coll., AMNH (genitalia slide no. JSM-863); ♀, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. J.S. Miller, day coll., AMNH (genitalia slide no. JSM-1172).

Dioptis fatima (Möschler), revised status

Figure 202; plate 18 [EX]

Hyrmina fatima Möschler, 1877: 665.

Type Locality

Suriname, Paramaribo.

Type

Holotype ♂, “Stde.”, 1876 (ZMH).

Discussion

Material identified as Dioptis trailii (pl. 20) in collections invariably includes specimens of a second species, to which the name Dioptis fatima (Möschler) is here applied. Möschler's taxon has been regarded as a synonym of D. trailii by previous authors (Prout, 1918; Hering, 1925; Bryk, 1930). Even though D. fatima and D. trailii are nearly inseparable by wing pattern, their genitalia are different enough to demonstrate membership in separate Dioptis species groups—the Fatima and Cyma groups. Dioptis fatima (pl. 18) is somewhat larger and more robust than D. trailii, the wing veins are darker, and the FW is slightly acute near its apex, rather than quadrate. Means for separating these two species are treated further in the discussion of D. trailii (below).

The two taxa overlap in distribution—occurring together in Brazil, Venezuela, and Peru—but D. fatima ranges north into the Guiana Shield, whereas D. trailii, at least to my knowledge, does not. Unfortunately, the ZMH holotype of Dioptis fatima, which I have examined (March 2004), is missing its abdomen, so the moth's genital configuration will never be known. Nevertheless, I feel confident in having established the identity of D. fatima. My dissections include a Suriname specimen (JSM-1201) from near the type locality, Paramaribo.

As so often seems to be the case in Dioptis, at least one cryptic taxon occurs among material currently subsumed under the name “fatima”. The sclerotized, dentate portion of the valva apex is much longer in males collected in Amazonian Brazil (JSM-1199, 1200, 1202) than in those from the Guyana Shield (JSM-1203). Brazilian material undoubtedly represents an undescribed species.

As an aside, the first dioptine specimen I ever encountered was the CUIC Suriname female of D. fatima noted above (pl. 18). This took place in 1983, while I was a graduate student at Cornell studying swallowtail butterflies with Paul Feeny, and learning moth systematics with John G. Franclemont using the CU insect collection. The curiosity piqued by that specimen began my nearly 30-year involvement with the Dioptinae.

Distribution

Brazil (AMNH, NMW, OUMNH, USNM, VOB); Venezuela (USNM); Guyana (USNM); Suriname (CUIC); French Guiana (AMNH, BHC, CAS, NMW, USNM); Peru (AMNH).

Dissected

♂, Brazil, Amazonas, Tefé, Sep, leg. Fassl, USNM (genitalia slide no. JSM-1199); ♂, Brazil, Amazonas, Tefé, Sep, leg. Fassl, USNM (genitalia slide no. JSM-1200); ♂, Brazil, Rondônia, 62 km S Ariquemes, Fazenda Rancho Grande, 165 m, 10°32′S, 62°48′W, 14–25 Nov 1993, leg. Ron Leuschner, AMNH (genitalia slide no. JSM-1202); ♂, Guyana, Julietta, Dognin Collection, USNM (genitalia slide no. JSM-1203); ♀, Suriname, Saramacca, Voltz Berg near Coppename River, 15 Apr 1980, leg. Deborah Trail, CUIC (genitalia slide no. JSM-1201); ♀, French Guiana, Cayenne, Hy. Edwards Collection, AMNH (genitalia slide no. JSM-1204).

Dioptis indentata Hering

Plate 19

Dioptis indentata Hering, 1925: 522, fig. 70a.

Type Locality

“Amazon”.

Type

Holotype ♂, Sello, Coll. Staudinger (ZMH).

Discussion

Dioptis indentata, known to me exclusively from the holotype (pl. 19), exhibits a distinctive FW pattern in which the white transverse band is minutely scalloped along its inner and outer margins. The male genitalia of D. indentata are also distinct from all other Fatima Group taxa. For example, the valva apex is more acute, and the uncus does not bear the unusual dorsal hooks that appear elsewhere in this species group (fig. 203A). The type's locality label simply states “Amazon”. Most likely its provenance is thus somewhere in Brazil.

Distribution

Brazil (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1777).

Dioptis tessmanni Hering

Figure 203; plate 19

Dioptis tessmanni Hering, 1925: 522; fig. 70a.

Type Locality

Peru, Río Pachitea.

Type

Holotype ♂, leg. G. Tessmann (ZMH).

Dioptis opaca Hering, 1925: 522.

Type Locality

Peru, Ucayali, ca. 9° S.

Type

Holotype ♂, leg. Michael (ZMH).

Discussion

In wing pattern, D. tessmanni is extremely similar to D. charon (pl. 18), although there seems to be a subtle difference in the shape of the white FW band. The best way to separate the two species is by the shape of the valva apex in the male genitalia, which is more coarsely dentate in D. charon. Until revisionary studies indicate otherwise, I retain D. tessmanni as a valid species, following previous authors (Hering, 1925; Bryk, 1930).

Hering (1925) described opaca as a subspecies of tessmanni. The type of opaca differs only in that the dark marginal band of the HW is slightly broader, and the white subapical FW cross-band is narrower. Pending dissection of the opaca type, I retain that name as a synonym (Bryk, 1930).

Distribution

Peru (AMNH, ZMH).

Dissected

♂, Peru, Madre de Dios, Parque Manu, Pakitza, 12°07′, 70°58′, 400 m, 13 Sep 1989, leg. R. Robbins, AMNH (genitalia slide no. JSM-743); ♂, Peru, Río Pachitea, leg. G. Tessmann, ZMH (genitalia slide no. JSM-1173).

8. CYMA GROUP

Forbes (1931) attempted to synthesize the works of Prout (1918) and Hering (1925), and using material available at the USNM and CUIC, wrote species keys for two difficult dioptine genera—Dioptis and Josia—relying exclusively on wing pattern. His key to Dioptis species left important identification issues unresolved, but nevertheless provided a solid starting point. Many of Forbes' traits are employed in the Cyma Group key below.

The male genitalia of some Cyma Group species exhibit a trait unique in the Dioptinae. Here, the dorsolateral portion of each tegumen arm, immediately below its junction with the socii/uncus complex, bears an elongate dorsal process. These structures vary in length: fairly long in D. fratelloi (fig. 206A), for example, but much shorter in D. beckeri (fig. 204A). They are found in most, but not all, Cyma Group species; for example, they are absent in D. curvifascia (fig. 205A) and D. paracyma (fig. 208A).

Like Forbes (1931), I place considerable emphasis on wing pattern in constructing a species key, since I have studied the wings of each type but not their genitalia. In the future, it will be crucial to examine the genital morphology of every Dioptis type. As I stress throughout treatment of the Cyma Group, the species identifications below should be considered provisional at best. Ultimately, a revision of this difficult clade will be required to stabilize the situation.

KEY TO CYMA GROUP SPECIES

1. Hind wing with an ochreous orange submarginal band (e.g., pl. 20), its inner and outer margin bordered with brown6

HW margin entirely brown (e.g., D. areolata, pl. 19), no ochreous band2

2. Blackish-brown marginal band of HW wide; cell formed by fork of veins M3 and CuA1 completely, or almost completely blackish brown in FW and HW3

HW with a narrow brown to blackish-brown marginal band; cell formed by fork of veins M3 and CuA1 at least partly hyaline in FW and HW4

3. Hyaline area beyond FW DC comprising a transverse band between base of radial sector and fork of M3+CuA1 (pl. 19), and an ovoid spot near tornus between CuA1 and CuA2; subapical FW spot small (E Brazil)areolata Walker

Hyaline area beyond DC of FW comprising two small spots between bases of radial sector and M2 (pl. 19), and a large ovoid spot between CuA1 and CuA2; subapical FW spot large (Amazonian Brazil)onega Bates

4. Subapical band of FW ovoid, long, extending from base of Rs2+Rs3 to beyond M2; FW completely blackish brown, never with ochreous scales near tornus; FW length  =  18.5–20.0 mm5

Subapical band of FW narrow (pl. 19), comprising three small whitish spots, posterior one located anterior to M2; FW with a few scattered ochreous scales near tornus; FW length  =  19.0–21.0 mm (Guyana)fratelloi, sp. nov.

5. Hyaline transverse FW band beyond DC extremely wide (pl. 19), fork of FW veins M3 and CuA1 hyaline except at outer margin; PA of female with rounded ventrolateral projections (E Brazil)restricta Warren

Hyaline transverse FW band beyond DC narrow (pl. 19), fork of veins M3 and CuA1 covered with brown scales; PA without ventrolateral projections; female Tg8 membranous (W Colombia)columbiana Hering

6 (1). Central area of HW hyaline7

Central area of HW ochreous orange (pl. 21) (Amazonian Brazil)aeliana Bates

7. Forewing with ochreous orange or reddish-brown markings, varying in size and location8

FW without ochreous orange or reddish-brown markings15

8. Forewing and HW markings orange to ochreous orange; FW without a large white transverse band, area beyond DC usually hyaline9

FW and HW markings reddish brown, brown of FW located near apex and along anal margin (pl. 19); FW with a large white transverse band beyond DC, as well as a white spot at tornus; wings relatively large, FW length  =  20.0–21.0 mm (SE Ecuador)cheledonis Druce

9. Region beyond distal margin of FW DC with hyaline areas of varying size; subcostal area of FW brown, radius frequently lined with white scales; FW anal margin brown, sometimes with scattered white scales10

Region beyond FW DC without hyaline areas; majority of FW ochreous orange (pl. 21), including region beyond DC, subcostal area, and area between CuA2 and 1A+2A (Amazonian Brazil)climax Prout

10. Distal third of FW, beyond transverse hyaline band, with a large, curved, ochreous orange band11

Distal third of FW, beyond transverse hyaline band, with a small, ovoid or wedge shaped, hyaline subapical band, ochreous areas small13

11. Hyaline FW area beyond DC comprising two small spots, one behind base of Rs1–Rs4, the other behind M1; cell formed by fork of FW veins M3+CuA1 brown at base; female PVP extremely large and wide, ostium sclerotized12

Hyaline FW area beyond DC forming a wide transverse band (pl. 21); cell formed by fork of FW veins M3+CuA1 partially hyaline; female PVP small (fig. 204D), ostium membranous (W Brazil)beckeri, sp. nov.

12. Veins in HW central area blackish brown (pl. 20) (E Peru, Brazil)egla Druce

Veins in HW central area white (pl. 20) (E Peru)egla ab. phaedima Prout

13. Forewing with a small patch of ochreous orange scales basal to apex, located at base of Rs2+4 anterior to hyaline subapical band; no ochreous scales near FW tornus14

FW with a diffuse submarginal band of ochreous orange scales near tornus (pl. 21), located between M3 and CuA2, a second small patch below tornus, between anal fold and 1A+2A; no ochreous scales near FW apex (Venezuela, Guyana, N Brazil)roraima Druce

14. Ochreous orange FW patch extremely small (pl. 20), located between Rs1 and base of Rs2; cell formed by fork of M3+CuA1 completely brown; apex of male valva elongate and robust, spatulate, its inner surface coarsely dentate (Guyana Shield, N Brazil)paracyma Prout

Ochreous orange FW patch large (pl. 21), located between Rs1 and base of Rs4; cell formed by fork of M3+CuA1 hyaline at base; apex of male valva short, digitate, its inner surface smooth (French Guiana, Amazonian Brazil)cyma Hübner

15 (7). Distal half of FW with a single, wide, white transverse band located beyond DC, no other contrasting markings16

Distal half of FW with various small, contrasting white or hyaline markings, in addition to a large white or hyaline transverse band beyond DC21

16. White FW band extending from subcosta to anal fold near tornus, tornus without a separate, diffuse patch of white scales; base of cell between FW veins CuA1 and CuA2 brown18

White FW band extending from Sc to CuA1 (pl. 20), tornus with a separate, diffuse patch of white scales near wing margin; base of cell between FW veins CuA1 and CuA2 hyaline17

17. Female St7 with huge, sclerotized anterolateral pockets, posterior margin of St7 without a mesal excavation; female CB without a bend in distal third; FW length  =  20.0 mm (E Peru)proix Prout

Female St7 without pockets, posterior margin of St7 with an extremely wide mesal excavation; female CB bent downward in distal third; FW length  =  15.5 mm (E Peru)incerta Hering

18. White transverse FW band strongly curved, sinuate on inner margin; band relatively narrow19

White transverse FW band not strongly curved, straight on inner margin (pl. 20); band wide20

19. White transverse FW band relatively narrow (pl. 20), veins M3 and CuA1 thinly lined with brown scales as they pass through band (Guyana and Suriname)meon (Cramer)

White transverse FW band wide (pl. 19), veins M3 and CuA1 white as they pass through band (E Peru, Amazonian Brazil)curvifascia Prout

20. Costa of male valva long, becoming slightly wider distally, sclerotized apex forming a narrow dentate structure, flattened on its inner surface (E Peru, Amazonian Brazil)ilerdina Bates

Costa of male valva short, sclerotized apex forming a robust, C-shaped dentate structure (E Ecuador, E Peru)nigrivenis Hering

21 (15). Forewing region distal to DC with three relatively large hyaline cells, formed between bases of Rs1–Rs4, M1, M2 and stem of M3+CuA122

FW region distal to DC with two or fewer hyaline cells, area between base of M2 and stem of M3+CuA1 always dark, never hyaline24

22. Forewing with an isolated, round white spot at tornus (pl. 20), located between CuA1 and CuA2 near outer margin, posterior to white transverse band (Colombia, NE Ecuador)uniguttata Warren

FW without a round white spot at tornus near outer margin23

23. Forewing with a long white transverse band located immediately beyond hyaline cells (pl. 20), extending from base of radial sector to CuA1 or beyondperegrina Hering

FW with a small subapical band located well beyond hyaline cells (pl. 20), band extending from stem of Rs2+Rs3 to M3 (Venezuela S to E Peru and Amazonian Brazil)trailii (Butler)

24. Forewing with tiny round, whitish hyaline spots immediately beyond DC, or no spots at all25

FW with two relatively large, rectangular, conjoined hyaline areas immediately beyond DC (pl. 19), these separated by base of M1 (Amazonian Brazil, E Peru)leucothyris (Butler)

25. Forewing area between DC and white transverse band without white spots, completely dark brown (pl. 20); transverse band wide; apex of male valva forming a fishtail-shaped, dentate structure (E Ecuador, E Peru)pallene Druce

FW area between distal margin of DC and white transverse band with one or two tiny white spots; transverse band narrow; valva apex not fishtail-shaped26

26. Two tiny, white spots beyond distal margin of FW DC (pl. 20), one located between bases of radial sector and M1, the second between M1 and M2; FW veins M1 and M2 brown as they pass through white transverse band; sclerotized apex of male valva forming a hammer-shaped, dentate process (E Peru)dentistriga Hering

A single tiny spot beyond distal margin of FW DC (pl. 20), this located between bases of radial sector and M1; FW veins M1 and M2 white as they pass through transverse band, except on band's inner margin; sclerotized apex of valva forming a club-shaped, dentate process (Amazonian Brazil, E Peru)stenothyris Prout

SPECIES INCLUDED AND MATERIAL EXAMINED

Dioptis aeliana Bates

Plate 21

Dioptis aeliana Bates, 1862: 565, pl. 55, fig. 10.

Type Locality

Brazil, Amazonas, Ega.

Type

Syntype ♀ (BMNH).

Discussion

When Bates (1862) described aeliana, along with D. ilerdina and D. onega, he did not designate types, but noted that the material was deposited at the BMNH. A careful search through their holdings (February 2005), with the gracious help of Martin Honey, revealed a specimen with labels suggesting it to be the syntype of Dioptis aeliana; it matches the description, albeit brief, as well as the color figure in the original publication. The label and accession numbers provide further indication that this is the specimen upon which the description of D. aeliana is based. The species is highly distinctive: the only Dioptis so far known in which the HW is almost completely ochreous orange (pl. 21).

Dioptis aeliana is extremely rare. My search of the world's collections revealed only seven specimens, including the syntype—five at the BMNH (two of which were collected by Bates himself), one at the OUMNH, and one at the CMNH. All are females, and all were collected at lowland sites in Amazonian Brazil. The most recent specimen was captured in 1913 by E.H.W. Wickham (BMNH) at Labrea, Amazonas, on the Río Purus.

The mimetic association between D. aeliana and Brevioleria aelia, the butterfly that led Bates to name this dioptine, is more extensive; it contains additional ithomiine species, such as Hyposcada illinissa, Napeogenes sylphis, Oleria gunilla, and Oleria ilerdina. All of these taxa are endemic to a relatively small area of the Amazon (K. Willmott, personal commun.).

Distribution

Brazil (BMNH, CMNH, OUMNH).

Dissected

None.

Dioptis areolata Walker

Plate 19

Dioptis areolata Walker, 1854: 332.

Type Locality

“Brazil”.

Type

Syntype ♂ (BMNH).

Discussion

The terminal portion of the abdomen of the BMNH male syntype of D. areolata is missing. However, I dissected material closely matching the type in wing pattern. Based on a comparison of those dissections (JSM-1167, 1169) with other Dioptis species, D. areolata is a relative of D. restricta (pl. 19). However, these two are easily separated by wing pattern, with D. areolata showing wider, bolder dark markings in the FW and HW, especially along the wing margins. The male genitalia of the two species provide distinctive characters for separation.

Distribution

Brazil (AMNH, BMNH, LACM, MPM, NMW, OUMNH, USNM, VOB, ZMC); Venezuela (USNM).

Dissected

♂, Brazil, Petropolis, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1167); ♀, Brazil, Sao Paulo, Bertioga, 5 m, 5 Nov 1995, leg. V.O. Becker, VOB (genitalia slide no. JSM-1169).

Dioptis beckeri, new species

Figures 52, 204; plate 21

Diagnosis

The wing pattern of D. beckeri, from Rondônia, Brazil, most closely resembles that of D. egla (pl. 20), known from western Brazil as well as Amazonian Ecuador and Peru. Both species are unusual among Dioptis in possessing a broad, ochreous orange subapical FW band, wide anteriorly but tapering toward the tornus. The main difference between the two is that the FW area between the DC and the orange distal band shows larger hyaline areas in D. beckeri than in D. egla.

Museum collections of D. egla predominantly contain females. A comparison of the female PVP (in intact, pinned specimens) shows strong differences between those of D. egla and D. beckeri. In D. beckeri the scaleless region posterior to the ostium is small (fig. 204D) with a deep, U-shaped mesal notch. In D. egla this region is large, with a tiny mesal notch, and its surface is strongly rugose. Using these wing-pattern and genitalia differences, the two species cannot be confused.

Description

Male. Forewing length  =  15.5–18.0 mm. Head: Labial palpus moderately long, strongly curved upward to immediately above clypeus, Lp1 and Lp2 of almost equal length, Lp1 slightly longer, Lp3 short, bullet shaped; Lp1 white; Lp2 and Lp3 dark brown on lateral surface, white on mesal surface; front white, scales pointed toward midline, a few gray-brown scales near antennal sockets; occiput white; vertex dark brown, with a white posteromedial spot; antenna quadripectinate, rami moderately long; antennal scape dark brown, with a few white scales below; dorsal surface of antenna dark brown.

Thorax: Coxa white, with cream-colored scales interspersed; femur, tibia, and tarsus white on inner surface, light brown on outer one; spurs short, mostly brown with a few lighter scales on inner surfaces; pleural region covered with long, cream-colored scales; patagium dark brown with a white central spot; prothoracic midline with a small white spot; tegula white at inner angle, orange at base, then fringed with long, dark brown scales; dorsum dark brown, with a few white scales above wing base, and a white medial stripe; tympanum absent.

Forewing: (Dorsal) Hyaline, with veins dark brown as they pass through hyaline areas (pl. 21); costal margin, outer margin and anal margin bordered by an even band of dark brown; a dark brown, transverse band passing inside distal margin of DC, extending from radial sector to anal fold at lower angle; distal third of FW dark brown, with a wide, ochreous orange transverse band extending from costa to M3; veins thinly lined with dark brown scales as they pass through orange band; fork of M3+CuA1 more widely lined with dark brown than other veins; radial sector from base to end of DC lined with white scales; hyaline cells immediately beyond DC sparsely covered with long, thin white scales; hyaline cell near tornus, formed by CuA1 anteriorly and CuA2 posteriorly, lightly covered with thin, white scales; a diffuse streak of white scales from base to one-fourth out along vein 1A+2A. (Ventral) Similar to dorsal surface, except brown areas and orange band less intensely pigmented, and hyaline areas sparsely clothed with white, hairlike scales; subcostal area dusted with white in basal half.

Hind wing: (Dorsal) Hyaline, with veins in hyaline area dark brown (pl. 21); outer margin with an ochreous orange band, extending from apex to 3A; orange band bordered inside and out with slightly thinner, dark brown bands; veins thinly lined with dark brown scales as they pass through orange band; anterior margin white to light brown in basal third, dark brown beyond; anal margin hyaline, fringed with long white scales. (Ventral) Similar to dorsal surface, except brown and orange areas less intensely pigmented and anterior margin whiter.

Abdomen: Dorsum completely dark, gray-brown; venter white, sterna with buff-colored scales along posterior margins.

Terminalia (fig. 204A–C, E): Tg8 bell shaped, widest anteriorly, posterior margin with a few longitudinal wrinkles; St8 ovoid, widest in anterior one-third, posterior margin slightly concave; anterior margin of St8 with a broadly convex mesal apodeme, folded to form a quadrate sclerite; socii/uncus complex extremely small; uncus apparently absent, socii small, knob shaped; tegumen wide, narrowing below, with a dorsal process below each socius; vinculum wide, concave; saccus extremely large and broad, quadrate below, folded upward to form a tall, mesal sclerite reaching upward to valva bases; valva mostly membranous, a wide central sclerite on each, tapered below to meet mesally at valva bases; BO large, membrane extremely fragile, expanded below, androconia long, hairlike; a short, sclerotized, knoblike process near valva apex, each process minutely dentate; transtillar arms extremely wide, flat, broadly joined at midline to form a V-shaped central sclerite; aedeagus long and thin, curving gently upward; a thin, curved process near apex of aedeagus above, its surface spiculate; vesica small, narrow, cornuti absent.

Female. Forewing length  =  19.0–20.0 mm. Antenna quadripectinate, rami slightly shorter than in male. Wing pattern similar to male, but orange subapical FW band wider, extending further around anal angle of wing.

Terminalia (204D): Tg7 large, roughly quadrate but slightly wider in posterior half, anterior and posterior margins simple; St7 wide, widest at anterior margin, posterior margin with a shallow, U-shaped mesal excavation; surface of St7 covered with long, hairlike setae; Tg8 fairly wide but short, slightly emarginate along posterior margin; PP long, thin; PVP wide, short, emarginate posteriorly, margin sinuate; ostium small, shallow, with paired central flanges at opening; DB short and narrow, membranous; DS arising from junction of DB and CB; CB large, membranous, ovoid in distal two-thirds, basal one-third narrow, tapering to DB; CB with a single, small signum distally above, near midline.

Etymology

This species is named in honor of Vitor Osmar Becker, from Serra Bonita, Brazil, who has contributed greatly to our knowledge of Lepidoptera systematics, especially regarding the neotropical fauna. He brought his expertise to bear on this publication in an incredibly careful review. Furthermore, he graciously made his fabulous moth collection, containing material from throughout Central and South America, available for study. In it were several undescribed species of Dioptinae in beautiful series, including examples of Dioptis beckeri.

Distribution

All known specimens of D. beckeri were collected at a single lowland site (fig. 52) in western Brazil, in the state of Rondônia near the border with Bolivia. The names Cacaulandia and Fazenda Rancho Grande refer to the same locality, situated on the Rio Jamari, which empties into the Rio Madeira near Pôrto Velho.

Discussion

Although the species diagnosis (above) notes wing-pattern similarities between D. beckeri and D. egla, their genitalia are not at all similar. Instead, the male genitalia of D. beckeri indicate a close relationship with D. trailii, a species lacking an orange FW maculation (pl. 20). This provides further indication that wing pattern is an unreliable indicator of species relationships within Dioptis.

Examples of D. beckeri are unknown in older collections; all 18 specimens listed below were collected between the years 1991 and 1996. The CUIC contains a single specimen from Maues, Brazil, captured in 1937 by F. Wucherpfennig, whose wing pattern is seemingly identical to D. beckeri. Maues is located on the Rio Maués (3°22′25″S, 57°43′50″W; elevation  =  15 m), a tributary of the Amazon that joins it approximately 200 km downriver from Manaus. The site is over 1000 km east of the Rondônia locations where D. beckeri has been collected. Upon dissection (JSM-1686), the CUIC specimen is revealed to be an undescribed species distinct from D. beckeri. The affinities of this undescribed taxon are unclear, but lie somewhere within the Cyma Group.

Holotype

Male (pl. 21). Brazil: Rondônia: Cacaulandia, 140 m, Nov 1991, leg. V.O. Becker. The type is deposited in the Vitor Becker Collection, Serra Bonita, Brazil.

Paratypes

Brazil: Rondônia: 1♂, Cacaulandia, 140 m, Nov 1991, leg. V.O. Becker (VOB); 1♂, 15–18 Oct 1993, leg. V.O. Becker (VOB); 1♀, Nov 1994, leg. V.O. Becker (VOB); 2♂♂, 62 km S Ariquemes, Fazenda Rancho Grande, 165 m, 10°32′S, 62°48′W, 18–29 Sep 1996, leg. Ron Leuschner (AMNH); 1♂, 1♀, 14–25 Nov. 1993, leg. Ron Leuschner (AMNH; female genitalia slide JSM-834); 3♂♂, 2♀♀, 29 Sep–10 Oct 1992, leg. Brian Harris (LACM); 1♂, 29 Sep–10 Oct 1992, leg. R. Leuschner (LACM); 2 ♂♂, 1♀, 29 Oct–10 Nov 1991, leg. Ron Leuschner (LACM); 1♂, C-20, 22 km W B-364, 10°32′S, 62°48′W, 11 Aug 1995, leg. A.D. Warren (AMNH, genitalia slide JSM-833).

Other Specimens Examined

None.

Dissected

1♂, 1♀.

Dioptis cheledonis Druce

Plate 19

Dioptis cheledonis Druce, 1893: 293, pl. 20, fig. 5.

Type Locality

Ecuador, Intag.

Type

Syntype ♀, leg. Buckley (BMNH).

Discussion

Dioptis cheledonis is unmistakable. It can be distinguished by the presence of a diffuse, brownish-orange marking near the FW apex, by a large, ovoid white transverse FW band, and by a small round white spot near the tornus. The species is known to me almost exclusively from females (n  =  13): the BMNH syntype; one LACM example (JSM-1627); a ZMH specimen from Rosario (St. Inez); a FNHM example from Río Pindo Grande (Pastaza); and nine additional specimens at the BMNH (Rosario, St. Inez, 1250 m, Aug–Dec 1899, leg. Haensch). The only known male (SMNS; JSM-1626) was collected along the Río Bombuscara (pl. 46C) near Podocarpus National Park, in southern Ecuador.

This species, recorded from as high as 1250 meters, occurs at higher elevations than most members of the Cyma Group, the majority of which are found below 500 m. An unusual feature of the male genitalia in D. cheledonis, presence of an elongate, finely spiculate process arising from the aedeagus, suggests membership in a clade with D. beckeri, D. trailii, and others. This structure (figs. 204E, 209B) is found nowhere else in the Dioptinae.

Distribution

Ecuador (BMNH, FNHM, SMNS); Peru (BMNH, LACM, MUSM, ZMH).

Dissected

♂, Ecuador, Zamora-Chinchipe, Parque Nacional Podocarpus, Río Bombuscara, N.P. station, 4°06″S, 78°57″W, 1000–1200 m, 5–6 Dec 1999, leg. D. Bartsch & C. Häuser, day, SMNS (genitalia slide no. JSM-1626); ♀, Peru, Perené no. 3, 21 May 1926, LACM (genitalia slide no. JSM-1627).

Dioptis climax Prout

Plate 21

Dioptis climax Prout, 1918: 418.

Type Locality

Brazil, Amazonas, Pebas.

Type

Holotype ♀, leg. M. de Mathan, Dec 1906 (BMNH).

Discussion

The only specimen of D. climax I have seen is the female holotype (pl. 21). The species is distinctive in showing a profusion of orange in the FW, as well as in having a particularly wide orange stripe along the HW margin. Characters listed in the Cyma Group key (above) instantly distinguish D. climax from all other Dioptis species.

Distribution

Brazil (BMNH).

Dissected

None.

Dioptis columbiana Hering

Plate 19

Dioptis columbiana Hering, 1925: 521.

Type Locality

Colombia, Llanos de San Martín.

Type

Syntype ♂/♀, leg. Hübel (ZMH).

Discussion

Except for the syntype in Berlin, I have not seen males of this taxon. Females from the BMNH (JSM-414) and AMNH (JSM-1175), both previously misidentified in their collections as D. onega, exactly match the female ZMH syntype of D. columbiana. This species is somewhat nondescript, making it difficult to recognize. The female genitalia provide inconclusive evidence regarding the relationship of D. columbiana to other Dioptis species, except to confirm that the taxon belongs in the Cyma Group. Unfortunately, the abdomens on both ZMH syntypes have been lost. Stabilizing the identity of this name will require dissection of additional specimens captured at or near the type locality. Maassen (1890) collected this species in Colombia, but misidentified it as D. phelina (Hering, 1925).

Distribution

Colombia (AMNH, BMNH, ZMH).

Dissected

♀, Colombia, San Martín, Llanos of Río Meta, leg. G.D. Child, BMNH (genitalia slide no. JSM-414); ♀, Colombia, Meta, Río Guayuriba, Dec 1946, leg. L. Richter, AMNH (genitalia slide no. JSM-1175).

Dioptis curvifascia Prout, revised status

Figure 205; plate 20

Dioptis curvifascia Prout, 1918: 417.

Type Locality

Brazil, Humayta, Río Madeira.

Type

Syntype ♂, leg. W. Hoffmanns, Jul–Sep 1906 (BMNH).

Discussion

Prout (1918) described this taxon as a subspecies of D. ilerdina Bates. However, specimens from the BMNH precisely matching the type of D. curvifascia in wing pattern (pl. 20), exhibit male genital morphology (fig. 205) dramatically different from that of D. ilerdina (fig. 207A–D). The genitalia of these examples also appear to be distinct from other members of Dioptis. I therefore elevate D. curvifascia to species status for the first time.

Distribution

Brazil (BMNH); Peru (BMNH).

Dissected

♂, Peru, Tarapoto, May–Aug 1886, leg. M. de Mathan, BMNH (genitalia slide no. JSM-737); ♀, “Peru?”, BMNH (genitalia slide no. JSM-738).

Dioptis cyma Hübner

Figure 187A–D; plate 21

Dioptis cyma Hübner, 1818: 1, pl. 9, figs. 17, 18.

Type Locality

Brazil, Pará.

Type

Not seen.

Discussion

Dioptis cyma is the only Dioptis species in which the FW bears a small ochreous orange subapical patch between the bases of veins Rs1 and M1, in addition to a transverse hyaline area posterior to that, between Rs4 and M3. The species with which D. cyma might most easily be confused is D. paracyma (pl. 20). There, the orange FW spot is extremely small, being restricted to the area between the base of Rs1 and the stem of Rs2+Rs3. A more reliable way to separate the two taxa is to examine the fork between FW veins M3 and CuA1. This region is hyaline in D. cyma, but dark in D. paracyma.

Their male genitalia differ markedly. Notably, D. cyma bears an elongate process near the apex of the aedeagus, absent in D. paracyma. The two species co-occur in French Guiana. The BMNH houses a large Brazilian series of D. cyma, the majority of which was captured by A.M. Moss at Pará, the type locality.

Two AMNH males from Loreto, Peru exhibit a wing pattern almost identical to that of D. restricta (pl. 19), with absolutely no orange in the FW or HW. Upon dissection (JSM-1191), these prove to be an undescribed species with genitalia extremely similar to D. cyma, which shows orange in both wings. Presence or absence of orange FW and HW maculations is thus a poor indicator of species relationships within Dioptis.

Distribution

Brazil (CAS, BMNH, CUIC, NMW, PMNH, USNM, ZMH); Peru (OUMNH); French Guiana (BHC, USNM).

Dissected

♂, Brazil, Pará, leg. M. de Mathan, BMNH (genitalia slide no. JSM-846); ♀, Brazil, Pará, leg. M. de Mathan, BMNH (genitalia slide no. JSM-847).

Dioptis dentistriga Hering

Plate 20

Dioptis dentistriga Hering, 1925: 522; fig. 70a.

Type Locality

Peru, Yurimaguas.

Type

Holotype ♂ (ZMH).

Discussion

An AMNH male from Achinamiza in eastern Peru, matching the type of Dioptis dentistriga, has genitalia (JSM-870) differing slightly from material collected at Tambopata, further south in Peru (JSM-861, JSM-871). The two phenotypes also differ in that the FW veins passing through the white subapical cross band are dark in the dentistriga type and the Achinamiza specimen, but white in Tambopata material. I suggest that this first example (JSM-870) is D. dentistriga, but here refer the Tambopata material to the same name until a more comprehensive study has been done. In all probability, specimens from Tambopata represent an undescribed species. Resolving the taxonomy of these taxa is beyond the scope of the current project.

Distribution

Peru (AMNH, ZMH).

Dissected

♂, Peru, Achinamiza, 8 Jan 1926, “F6001”, H. Bassler Collection, AMNH (genitalia slide no. JSM-870); ♂, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′W, 4 Dec 1996, leg. J.S. Miller, day coll., AMNH (genitalia slide no. JSM-861); ♂, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′W, 4 Dec 1996, leg. A.V.Z. Brower, day coll., AMNH (genitalia slide no. JSM-871); ♀, Peru, Madre de Dios, Tambopata Reserve, 200 m, 12°51′S, 69°18′W, 10 Dec 1996, leg. Miller/Brower/Snyder/Green, AMNH (genitalia slide no. JSM-1178).

Dioptis egla Druce

Plate 20

Dioptis egla Druce, 1893: 293, pl. 20, fig. 4.

Type Locality

Brazil, Tonantins.

Type

Syntype ♀, Bates Collection (BMNH).

Dioptis phaedima Prout, 1918: 418.

Type Locality

Peru, Río Marañon.

Type

Holotype ♀, leg. 1913 (BMNH).

Discussion

Dioptis egla is characterized by having an extremely wide, comma-shaped ochreous subapical FW band (pl. 20). In addition, it exhibits small hyaline FW spots immediately beyond the upper and middle discocellular veins, and a larger ovoid spot near the tornus. Prout (1918: 418) noted the absence of D. egla males in the BMNH collection and postulated, “the supposed species may possibly prove a remarkable mimetic female form of some species of the cyma group”. My search of the world's collections confirms that females are relatively common, whereas only a single male was found. That example (JSM-1809) disproves Prout's theory. The male of D. egla shows much less orange along the FW outer margin, but its wing pattern clearly corresponds with females. Its genitalia suggest a relationship not with D. cyma or D. beckeri, with which its wings are similar, but rather with D. fratelloi (pl. 19) and D. ilerdina (20), two species showing patterns different from D. egla (pl. 20).

Prout (1918) described phaedima (pl. 20) as an aberration of D. egla (pl. 21). In D. phaedima, the veins passing through the HW central area are white, whereas these are dark in D. egla. There also seem to be slight differences between the female genitalia of D. egla (JSM-1180) and material corresponding with D. phaedima (JSM-1181). The most obvious of these is the size and shape of the U-shaped mesal excavation along the posterior margin of St7. In D. egla the excavation is relatively narrow, whereas in D. phaedima it is wider. However, rather than describe a new species for D. phaedima, I have chosen to follow previous authors (Hering, 1925; Bryk, 1930) in retaining it as an “aberration”; males remain unknown for phaedima, and the two color forms co-occur at precisely the same localities. The AMNH collection contains specimens of D. egla and “D. phaedima” taken in the same series, on the Río Marañon. Resolving the status of D. phaedima should be the subject of a species-level revision.

The USNM collection includes a female specimen from Caqueta, Colombia (leg. Duckworth & Dietz, Jan. 1969) that undoubtedly represents an undescribed species, apparently related to D. egla. The orange subapical area of this example is larger than in D. egla.

In January 2009, caterpillars of Dioptis egla were found feeding on an as yet unidentified species of Geonoma (Arecaceae) at Shiripuno, in Amazonian Ecuador (see table 4).

Distribution

Brazil (BMNH, CMNH, NMW); Peru (AMNH, BMNH, CMNH, MUSM); Ecuador (BMNH, FNHM USNM).

Dissected

♂, Brazil, Amazonas, S. Felippe, Rio Juruà, 20 Dec 1901, leg. J.G. Foetterle, NMW (genitalia slide no. JSM-1809); ♀, Brazil, Tonantins, Amazon River, Aug 1923, leg. S. Klages, CMNH (genitalia slide no. JSM-1180); ♀, Peru, Iquitos, 14 Jan 1887, leg. [“Giwahl”?], BMNH (genitalia slide no. JSM-1181).

Dioptis fratelloi, new species

Figures 52, 206; plate 19

Diagnosis

Wing pattern and genitalia morphology confirm placement of this moth in the Cyma Group of Dioptis. Within the clade, D. fratelloi is similar in appearance to D. columbiana, D. areolata, and D. restricta (see pl. 19). The new species can be distinguished from D. areolata and D. restricta in having thinner, more sharply defined, dark lining of the FW and HW veins, and in having thinner dark marginal band in the HW. It differs from all three in two unmistakable traits: first, the FW of D. fratelloi is more triangular than in the other taxa, which have a somewhat oblong-shaped FW; second, the hyaline FW cell, formed between veins CuA1 anteriorly and CuA2 posteriorly, is elongate in D. fratelloi, whereas this cell is shorter, being teardrop- or oval-shaped in areolata, columbiana, and restricta. Additionally, and perhaps most importantly, D. fratelloi is so far known exclusively from western Guyana (Mt. Wokomung and Mt. Roraima), whereas the three Dioptis species above occur extensively in Brazil, Colombia, and Venezuela.

Description

Male. Forewing length  =  19.0–19.5 mm. Head: Labial palpus moderate in length, porrect, relatively thin, curving only slightly upward to immediately above clypeus; Lp1 curved, slightly longer than Lp2, Lp2 almost straight, Lp3 short, bullet shaped; all three palpus segments white on their inner and dorsal surfaces, chocolate brown laterally; scales of front erect, pointing inward toward center, a scaleless seam running along midline from clypeus to vertex; front with a ventral border of white scales immediately above clypeus, and a dorsal border of white scales below antennal bases, central area chocolate brown; occiput with long, immaculate white scales in lower two-thirds, shorter chocolate-brown scales in upper third; eye moderately large, surrounded by a scaleless area, gena wide and covered with fine spicules; vertex covered with long, anteriorly directed, chocolate-brown scales, antennal bases white; antenna quadripectinate, rami moderately long; scape chocolate brown, with a few white scales ventrally and laterally; dorsum of antennal shaft gray-brown.

Thorax: Coxa white on anterior and posterior surfaces, gray-brown on mesal and lateral surfaces; femur and tibia mostly white, gray-brown on outer surfaces; spurs fairly short, gray-brown with whitish scales on inner surfaces; tarsus entirely gray-brown; pleuron mostly covered with hairlike white scales, meso- and metameron surfaces with long gray-brown scales; patagium covered with long, upwardly pointing brown scales, a few white scales anteriorly; prothoracic midline with a white spot; tegula orange with a few brown and white scales at inner angle, apex with white scales on inner surface and a distal fringe of long, brown, hairlike scales; dorsum chocolate brown, with diffuse white spots at midline and laterally above wing bases; tympanum comprising a scaleless depression in the metepimeron, membrane absent.

Forewing: (Dorsal) Hyaline, with veins blackish brown as they pass through hyaline areas (pl. 19), veins CuA1 and CuA2 widely lined; outer margins of wing banded with blackish brown; DC less than one-half FW length; distal margin of DC with a blackish brown, comma-shaped spot; distal third of FW blackish brown, with a short, subapical band extending from stem of Rs2+Rs3 to M2, veins Rs4 and M1 blackish brown as they pass through band; subapical band mostly hyaline, with a scattering of short white scales; hyaline cell immediately beyond apex of DC, formed anteriorly by radial sector and posteriorly by base of M1, with a scattering of thin white scales; a faint white spot in tornus, located in hyaline cell formed anteriorly by base of M3+CuA1 and posteriorly by CuA2; costa gray-brown; anal margin dark brown, with scattered white scales lining vein 1A+2A; a few ochreous orange scales in blackish brown margin near tornus. (Ventral) Similar to dorsal surface, except brown areas slightly lighter in shade, vein SC lined with white scales in basal half.

Hind wing: (Dorsal) Hyaline, with veins in hyaline area blackish brown (pl. 19); outer margin with a well defined, moderately thin, blackish brown band, band ending at vein 1A+2A; a faint dusting of white scales in hyaline area near apex, inside marginal band; anal margin hyaline, with a fringe of whitish brown hairlike scales. (Ventral) Similar to dorsal surface, except cell along anterior margin, formed by costa and Sc, covered with thin and spatulate white scales.

Abdomen: Dorsum gray-brown, tinged with blue gray; venter white; pleuron with a thin, lateral stripe composed of mixed white and gray-brown scales.

Terminalia (fig. 206A, B, D, E): Tg8 with anterior and posterior margins simple, widest anteriorly, slightly narrowed distally; St8 ovoid, widest near middle; posterior margin of St8 slightly concave, membrane immediately beyond margin bearing a transverse row of robust setae; posterior margin of St8 with lateral angles acute, mesal apodeme short, rounded, folded at midline to form a “tongue”; uncus apparently absent; socii reduced to form a pair of apposed, thumblike structures, their apices striated; tegumen relatively wide, forming a pair of robust, dorsolateral processes at junction with socii/uncus complex; vinculum wide, concave; saccus widest ventrally, narrowing dorsally, folded upward at valva bases, ventral margin with a small indentation at midline; juxta narrow, concave; valva robust, with a setose, membranous central lobe approximately two-thirds from base; BO large, membranous, expanded below, androconia long and hairlike; valva apex forming a large, sclerotized, dentate knob; costa heavily sclerotized, upper margin serrate; transtilla thick, heavily sclerotized, each arm bearing a large, sclerotized, hornlike process near midpoint, its surface dentate; transtillar arms meeting to form a large, anteriorly directed, central sclerite; aedeagus relatively long, fairly thin, widest at base, apex blunt; vesica moderate in size, cornuti comprising two small sclerites, one ovoid the other elongate, near vesica base; surface of each cornutus with three denticles.

Female (pl. 19): Forewing length  =  21.0 mm. Wing and body characters similar to male, except for the following: labial palpus projecting anteriorly, not curving upward; Lp2 much shorter than Lp1; antenna quadripectinate, rami delicate and fairly short; FW upper angle more rounded than male; blackish brown distal third of FW with inner margin concave, not straight (as in male); FW (above and below) with a diffuse patch of ochreous orange scales near tornus located between 1A+2A and anal fold, a second patch of ochreous orange scales near outer margin located between M3 and CuA1, and a tiny splash of ochreous orange scales between M2 and M3; HW (above and below) with a thin, diffuse, submarginal band of ochreous orange scales extending from apex to tornus.

Terminalia (fig. 206C): Tg7 large, much longer than Tg6, roughly quadrate, anterior and posterior margins gently convex, lateral margins slightly excavated; St7 much wider than St6, shorter than Tg7, anterior margin gently convex, posterior margin with an extremely wide, shallow excavation; surface of St7 with a covering of setae in posterior two-thirds; Tg8 membranous, apparently absent; AA short, thin, bent slightly downward; PVP large, wide, with a keel-shaped central ridge as well as a single ridge on either side of that; posterior margin of PVP strongly emarginate; DB heavily sclerotized, dorsoventrally compressed, with a transverse ventral flange; CB large and membranous, roughly ovoid, narrowed at base; signum, located dorsally in midportion of DB, figure-eight shaped, with a central fold; DS thin, attached dorsally at junction of CB and DB; PP moderately long, thin, curved slightly upward; PA membranous, slightly angulate dorsally.

Etymology

This species is named in honor of Steve Fratello (Long Island, NY), who, through his field trips and curation efforts, has made important contributions to the AMNH Lepidoptera collection. Steve has undertaken demanding trips to remote parts of Guyana, where he collected valuable material, including many undescribed species of butterflies, moths, and plants. On one such trip, Steve captured the type series of Dioptis fratelloi.

Distribution

Dioptis fratelloi is known from two localities in far western Guyana: Mt. Wokomung (fig. 52) and the north slope of Mt. Roraima. Both are part of the Pakaraima Mountains, near the border of northern Brazil. Mt. Wokomung, the type locality for D. fratelloi, is approximately 50 km E of Mt. Roraima. The latter, a famous site among early South American insect collectors, is the type locality for Dioptis roraima Druce.

Discussion

Dioptis fratelloi is unusual because male wing markings are completely blackish brown, whereas females shows a pair of small ochreous patches near the FW tornus, as well as a thin band of ochreous scales along the HW outer margin. These wing-pattern traits tempt speculation that D. fratelloi could be a close relative of D. roraima (pl. 21), whose females exhibit similar markings. Comparison of their female genitalia provides further support; they show significant differences, but also exhibit potential synapomorphies, such as the presence of a ventral flange on the DB (fig. 206C), and a similarly shaped sigma of the CB. Males of D. roraima are unknown, so no comparisons can be made.

Holotype

Male (pl. 19). Guyana: Mt. Wokomung, 5000 ft, Nov 1993, leg. S. Fratello. The type is deposited at the AMNH.

Paratypes

Guyana: 1♂, Mt. Wokomung, 5000 ft, Nov 1993, leg. S. Fratello (AMNH; genitalia slide no. JSM-835); 1♀, Mt. Wokomung, 5000 ft, Nov 1993, leg. S. Fratello (AMNH; genitalia slide no. JSM-1464).

Other Specimens Examined

Guyana: N slope Mt. Roraima, 2nd Camp, 1300 m, 05°16′N, 60°44′W, 12 Mar–16 Apr 2001, leg. W. Hinds & R. Williams (USNM).

Dissected

1♂, 1♀.

Dioptis ilerdina Bates

Figure 207A–D; plate 20

Dioptis ilerdina Bates, 1862: 503, 565, pl. 55, fig. 11.

Type Locality

Brazil, São Paulo.

Type

Not seen.

Laurona herdina Walker, 1864: 149.

Type Locality

Brazil, Ega.

Type

Not seen.

Discussion

Material sorted in collections as D. ilerdina presents complex identification problems. Several species are invariably confused under that name. I was unable to locate the D. ilerdina type. My identification of this species is therefore based on the color plate in Bates (1862). Unfortunately, the moth figured there exhibits a concave FW cross-band, unlike any specimen I have seen. Furthermore, it does not match “D. ilerdina” as depicted by Hering (1925: fig. 70b). Among the material I have studied, the closest match to the Bates figure is a USNM male from São Paulo de Olivença (JSM-1182). The genitalia of that Brazilian moth correspond to Peruvian material from Madre de Dios, Peru (JSM-864, JSM-873).

Two names, previously regarded as synonyms of ilerdina (Bryk, 1930), I here elevate to species status: Prout (1918) described curvifascia as an ilerdina subspecies. My rationale for considering it a species is given in the discussion for D. curvifascia (above). Hering (1925) subsequently described another subspecies of ilerdina: nigrivenis. My rationale for raising that name to full species status is based on numerous distinctions between the genitalia of material matching D. nigrivenis (Ecuador and Peru) with that of D. ilerdina (Brazil and Peru). The two phenotypes are almost impossible to distinguish based on wing pattern. I reiterate that this entire species complex is in dire need of revision.

The remaining ilerdina synonym, herdina Walker, I have retained. After several visits to the BMNH, I was unable to locate the herdina type. A potential candidate was found (February 2005), but its locality label (“St. Paulo”) does not match that listed in the original description (“Ega”).

Distribution

Brazil (BMNH, CUIC, NMW, OUMNH, USNM); Peru (AMNH, BMNH, MUSM).

Dissected

♂, Brazil, São Paulo de Olivença, Amazonas, Nov–Dec, leg. Fassl, USNM (genitalia slide no. JSM-1182); ♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 12 Dec 1996, leg. A.V.Z. Brower, day coll., AMNH (genitalia slide no. JSM-864); ♂, Peru, Madre de Dios, Tambopata Reserve, 200 m, Dec 1994, leg. S. Fratello, day coll., AMNH (genitalia slide no. JSM-873).

Dioptis incerta Hering

Figure 207E, F; plate 19

Dioptis incerta Hering, 1925: 522, fig. 70a.

Type Locality

Peru, Río Pachitea.

Type

Holotype ♂ (ZMH).

Discussion

Dioptis incerta is a close relative of D. proix (pl. 20), but is much smaller and has a different configuration of the female PVP. Both are unusual in exhibiting a tiny white spot near the FW tornus, slightly separated from the white transverse band. The white FW band of D. incerta is slightly concave, whereas that of D. proix is almost straight. Both taxa appear to belong in a clade with Dioptis pallene Druce. Identifying these species is a challenging taxonomic problem whose resolution will require additional collecting at sites in eastern Peru and Amazonian Brazil. Numerous dissections will also be needed, especially for the relevant types. Ultimately, the problem may be tractable through analysis of DNA sequence data.

Bob Robbins (Smithsonian Institution) collected the only specimen of D. incerta I have seen (pl. 20), other than the type.

Distribution

Peru (AMNH, ZMH).

Dissected

♀, Peru, Madre de Dios, Parque Manu, Pakitza, 12°07′, 70°58′, 400 m, 20 Sep 1989, leg. R. Robbins, AMNH (genitalia slide no. JSM-1189).

Dioptis leucothyris (Butler)

Plate 19

Hyrmina leucothyris Butler, 1876: 117.

Type Locality

Brazil, Ega.

Type

Holotype ♂, Bates Collection (BMNH).

Discussion

The male holotype (pl. 19) and two Peruvian females are the only confirmed examples of Dioptis leucothryis I have seen. The wing pattern of D. leucothyris is extremely similar to that of D. trailii (pl. 20). The most obvious difference is that the small area immediately beyond the FW DC, between the base of M2 and the stem of M3+CuA1, is hyaline in D. trailii, but opaque brown in D. leucothyris. Several differences in their female genitalia can be used to separate the two species: the posterior margin of St7 bears a U-shaped mesal excavation in D. leucothryis, but a quadrate one in D. trailii (fig. 210B); the signum is larger in D. leucothyris; and the surface of the postvaginal plate is smooth in D. trailii (fig. 210A), but striate in D. leucothyris.

Males from Venezuela (MPM, BMNH), dissected and listed below (JSM-1629), are of doubtful identity. Their wing pattern differs slightly from that of D. leucothyris, and the genitalia are distinct from any other Dioptis. This material potentially represents an undescribed taxon.

Distribution

Brazil (BMNH); Peru (BMNH, MUSM).

Dissected

♂, Venezuela, Suapure, 22 Feb 1899, leg. Klages, BMNH (genitalia slide no. JSM-1629); ♀, Peru, UC, Río Utoquinia, Santa Soria, 29–31 Aug 1974, leg. G. Lamas, MUSM (genitalia slide no. 1183).

Dioptis meon (Cramer)

Plate 20

Bombyx meon Cramer, 1775: 1, pl. 71.

Type Locality

“British and Dutch Guiana” (Prout, 1918: 417).

Type

Not seen.

Dioptis beroea Möschler, 1877: 664–665, pl. 9, fig. 31.

Type Locality

Suriname, Paramaribo.

Type

Holotype ♂ (ZMH).

Discussion

The BMNH collection contains a male (missing its abdomen) and a female (pl. 20) identified as Dioptis meon, both from Rio Demerara, Guyana. Other than those, the only specimen I have seen is the type of beroea Möschler at the ZMH. None of this material was dissected. However, the species is distinctive in its large size, and can be recognized by the expanse of dark brown at the FW apex, as well as by the wide ochreous submarginal bands in the HW.

The type of beroea Möschler (1877) exactly matches the figure of meon in Cramer (1775), so I accept this synonymy, first proposed by Prout (1918).

Distribution

Guyana (BMNH); Suriname (ZMH).

Dissected

None.

Dioptis nigrivenis Hering, revised status

Plate 20 [EX]

Dioptis nigrivenis Hering, 1925: 523, fig. 70c.

Type Locality

Ecuador, Sarayacu.

Type

Holotype ♂ (ZMH).

Discussion

Based on dissections of Ecuadorian and Peruvian material, including the D. nigrivenis holotype, I elevate this taxon to species status instead of following previous authors (Hering, 1925; Bryk, 1930), who placed it as a subspecies of ilerdina Bates (pl. 20). The male genitalia of D. nigrivenis and D. ilerdina are fundamentally similar, but differ in the shape of the valva apex, as well as in the shape of the dorsolateral processes of the tegumen. I was unable to find consistent wing-pattern differences. Hering (1925) claimed that D. nigrivenis is distinct in having black HW veins in the central area, whereas the veins are supposedly white in D. ilerdina. My dissections instead suggest that both HW phenotypes occur in each of the species.

Two paratypes of D. nigrivenis—both from Peru—were deposited by Hering in the BMNH collection. These may or may not, in fact, be conspecific with the Ecuadorian type.

Distribution

Ecuador (AMNH, LACM, ZMH); Peru (AMNH, BMNH, MPM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1174); ♂, Ecuador, Sucumbíos, Garza Cocha-Anyagu, 175 km ESE Coca, 25 Jul 1996, leg. P.J. DeVries, 10:50am, AMNH (genitalia slide no. JSM-867); ♂, Ecuador, Sucumbíos, Garza Cocha-Anyagu, 175 km ESE Coca, La Selva, 10 Aug 1994, leg. P.J. DeVries, AMNH (genitalia slide no. JSM-794); ♂, Peru, Río Santiago, AMNH (genitalia slide no. JSM-131); ♀, Ecuador, Sucumbíos, Garza Cocha-Anyagu, 175 km ESE Coca, La Selva, 14 Jun 1994, leg. P.J. DeVries, AMNH (genitalia slide no. JSM-868); ♀, Ecuador, Sucumbíos, Garza Cocha-Anyagu, 175 km ESE Coca, La Selva, 31 Aug 1994, leg. P.J. DeVries, AMNH (genitalia slide no. JSM-744); ♀, Peru, Río Santiago, 10–24 Oct 1924, H. Bassler Collection, AMNH (genitalia slide no. JSM-132).

Dioptis onega Bates

Plate 19

Dioptis onega Bates, 1862: 503, 565, pl. 55, fig. 12.

Type Locality

Brazil, Ega, Upper Amazonas.

Type

Syntype ♀ (BMNH).

Discussion

The BMNH collection contains eight specimens identified as Dioptis onega (2♂♂, 6♀♀), and there are four additional specimens (3♂♂, 1♀) at the ZMH. Careful scrutiny of the material at both museums (March 2005), including comparison with the figure of D. onega in Bates (1862), suggests that the majority of these are not conspecific with D. onega. Their true identity is uncertain. However, one of the BMNH specimens appears to be the syntype of D. onega; it matches the figure and description well, but not perfectly. The BMNH accession records give further evidence that this specimen, illustrated here (pl. 19) as D. onega, is the one Bates referred to in his 1862 publication. Based on the amount of dark brown in the FW and HW, D. onega appears to be a close relative of D. areolata (pl. 19). Dioptis onega bears remarkable resemblance to its comimic, Oleria onega, a member of the Ithomiinae (Bates, 1862).

Hering was also confused concerning the identity of D. onega; the moth he figured (Hering, 1925: fig. 69l) does not remotely resemble the species depicted in Bates (1862: fig. 12).

Distribution

Brazil (BMNH).

Dissected

None.

Dioptis pallene Druce

Plate 20

Dioptis pallene Druce, 1893: 293, pl. 20, fig. 3.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♂, leg. C. Buckley (BMNH).

Discussion

Other than type material (pl. 20), the identity of D. pallene is in doubt; none of the specimens I studied precisely match the type wing pattern. The closest approximation is found among AMNH material, collected at Tambopata, Peru. I have tentatively identified these as Dioptis pallene. The species is characterized by the absence of white spots beyond the FW DC. Although the species was described from Ecuador, all material of so-called pallene in collections comes from Peru.

Two additional Cyma Group taxa—D. dentistriga and D. stenothyris (pl. 20)—exhibit wing patterns nearly identical with that of D. pallene, except that these show tiny FW spots beyond the DC. It will be impossible to stabilize the names in this intimidating species complex until all the relevant types have been dissected.

Distribution

Ecuador (BMNH), Peru (AMNH, BMNH, MUSM).

Dissected

♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 11 Dec 1996, leg. A. Brower, day coll., AMNH (genitalia slide no. JSM-862); ♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. J. Grados, day coll., AMNH (genitalia slide no. JSM-869).

Dioptis paracyma Prout

Figure 208; plate 20

Dioptis paracyma Prout, 1918: 417.

Type Locality

Suriname, Upper Suriname River.

Type

Syntype ♂, leg. Aug 1892 (BMNH).

Discussion

The male genitalia of the D. paracyma syntype dissected for this study (fig. 208) are radically different from those of D. cyma, the moth with which it could most easily be confused (pl. 21). The orange subapical spot is smaller in D. paracyma (see species key), but the best way to separate these two taxa is by examining the fork between FW veins M3 and CuA1. This region is dark in D. paracyma, but hyaline in D. cyma. Male genital differences between the two abound. Both species co-occur in French Guiana and Brazil. Dioptis paracyma is rare, known from fewer than 10 specimens worldwide.

Distribution

Suriname (BMNH); Guyana (USNM); French Guiana (BHC); Brazil (BMNH, ZMH).

Dissected

Syntype ♂, Suriname, Upper Suriname River, Aug 1892, BMNH (genitalia slide no. JSM-1628).

Dioptis peregrina Hering

Plate 20

Dioptis peregrina Hering, 1925: 523, fig. 70b.

Type Locality

Peru, Ucayali.

Type

Holotype ♂, “Mich.”, Coll. Staudinger (ZMH).

Discussion

Hering (1925), in his description of Dioptis peregrina, indicated that it is “similar to charon”. My examination of the holotype of D. peregrina (ZMH) suggests that the species belongs in the Cyma Group with D. trailii, rather than in the Fatima Group with D. charon. Examination of a ZMH female from Ucayali, mentioned by Hering as conspecific with D. peregrina, suggests that this example probably represents a different taxon altogether. As I have noted in discussion of various Dioptis species, precise resolution of such taxonomic problems falls outside the scope of this study.

Distribution

Peru (ZMH).

Dissected

None.

Dioptis proix Prout

Plate 20

Dioptis proix Prout, 1918: 417.

Type Locality

Peru, Río Ucayali, “Amazons”.

Type

Syntype ♂, leg. 1912–1913 (BMNH).

Discussion

An AMNH female (pl. 20; JSM-1190) precisely matches Dioptis proix type material in wing pattern. Other than the type series at the BMNH (1♂, 2♀♀), this is the only specimen of D. proix I have seen. Dioptis proix shares pattern similarities with D. incertae (pl. 20), also from eastern Peru, but it is larger (see Cyma Group key). Their female genitalia differ dramatically. Females of D. proix exhibit deep, sclerotized pockets on St7, apparently unique for the Cyma Group.

Distribution

Peru (AMNH, BMNH).

Dissected

♀, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. J.S. Miller, AMNH (genitalia slide no. JSM-1190).

Dioptis restricta Warren

Plate 19

Dioptis restricta Warren, 1901: 439.

Type Locality

Brazil, Petropolis.

Type

Syntype ♀ (BMNH).

Epilaus melda Boisduval, 1870: 78.

Type Locality

“Nicaragua”.

Type

Not seen.

Discussion

Dioptis restricta seems to be endemic to eastern Brazil, the type locality being near Rio de Janeiro. Peruvian specimens matching D. restricta in size and wing pattern (AMNH, MUSM) are almost certainly an undescribed species. The male and female of D. restricta dissected for this paper (JSM-409, 410) do not match the type precisely; in the latter the FW is somewhat more rounded at its apex. However, until the type has been dissected, I presume these represent D. restricta.

Prout (1918) and subsequent authors (Hering, 1925; Bryk, 1930) questioned the identity of melda Boisduval, essentially leaving the name in limbo, and listing it as a synonym of restricta Warren, even though meldo is the senior name. Prout (1918: 416) also voiced concern about the type locality of melda, given as Nicaragua in the original description. He noted that Boisduval's localities “were often wrong”. It seems doubtful that the melda type is from Nicaragua. In the meantime, I retain melda as a synonym of restricta.

Distribution

Brazil (AMNH, BMNH, CUIC, MCZ, MPM, NMW, OUMNH, USNM, ZMC, ZMH); Peru (AMNH, MUSM).

Dissected

♂, Brazil, Brazilia, ex Fruhstorfer, BMNH (genitalia slide no. JSM-409); ♀, Brazil, Brazilia, ex Fruhstorfer, BMNH (genitalia slide no. JSM-410); ♀, Brazil, Sta. Catharina, 29 Dec 1907, leg. Fritz Hoffmann, USNM (genitalia slide no. JSM-1168).

Dioptis roraima Druce

Plate 21

Dioptis roraima Druce, 1893: 292, pl. 20, fig. 2.

Type Locality

Guyana, Roraima.

Type

Syntype ♀, leg. Whitely (BMNH).

Discussion

A female of D. roraima (pl. 21) bearing labels identical with the type was dissected for this study (JSM-1192). Two females in the CUIC, collected on the Caura River, Suapure, Venezuela, I also regard as being examples of D. roraima. That site, on the western side of the same mountain range that includes Mount Roraima, is part of the Orinoco drainage. Roraima, on the other hand, is above the Río Negro, which feeds into the Amazon. Nevertheless, these Venezuelan examples exhibit a patch of ochreous orange scales at the FW tornus similar to the D. roraima type, and female genitalia of moths from the two sites are identical. Males of D. roraima are unknown.

Distribution

Guyana (BMNH); Venezuela (BMNH, CUIC).

Dissected

♀, Guyana, Roraima, leg. Whitely, BMNH (genitalia slide no. JSM-1192); ♀, Venezuela, Suapure, Caura River, 22 Dec 1899, leg. E.A. Klages, CUIC (genitalia slide no. JSM-1194).

Dioptis stenothyris Prout

Plate 20

Dioptis stenothyris Prout, 1918: 416.

Type Locality

Brazil, Humayta, Rio Madeira.

Type

Syntype ♂, leg. W. Hoffmanns, Jul–Sep 1906 (BMNH).

Discussion

The identity of D. stenothyris is problematic. Unfortunately, I did not dissect the type. My attempts to locate specimens matching the wing pattern of Prout's type suggest that AMNH material (pl. 20) from Tambopata, Peru, has the highest probability of being conspecific with D. stenothyris. The wings of these exhibit a darker ground color than the type, with less white at the FW base. However, geographical evidence also comes into play. Tambopata is on the Río Madre de Dios (fig. 6), an upper tributary of the Rio Madeira, which eventually joins the Amazon east of Manaus. The type locality for D. stenothyris, “Humayta” (currently Humaitá) thus belongs in the same drainage. Humaitá is roughly 800 km NE of Tambopata. This argument is obviously a convoluted (and unreliable) way to identify a species, but is the best I can offer at the present time.

Two BMNH specimens from Huallaga, Peru (JSM-1206, 1207) are closer in appearance to the type of D. stenothyris. To complicate matters, their genitalia are completely different from Tambopata specimens, indicating membership in the Fatima Group. The Río Huallaga, in Loreto, is an upper tributary of the Río Marañón (fig. 6), which flows east to Iquitos, a separate river system from the Madre de Dios. These specimens, I conclude, are not D. stenothyris, but instead represent an undescribed Dioptis species closely related to D. charon. Dissection of the stenothyris type is required to resolve this problem.

This discussion showcases the enormous complexity of Dioptis taxonomy, particularly regarding the Cyma Group. Dissections for the Huallaga material are as follows: ♂, Peru, Huallaga, Chambireyacù, near Yurimaguas, Jun–Aug 1885, leg. M. de Mathan, BMNH (genitalia slide no. JSM-1206); ♀, Peru, Huallaga, Chambireyacù, near Yurimaguas, Jun–Aug 1885, leg. M. de Mathan, BMNH (genitalia slide no. JSM-1207).

Distribution

Brazil (BMNH); Peru (AMNH, MUSM).

Dissected

♂, Peru, Madre de Dios, Tambopata Reserve, 200 m, Nov 1994, leg. S. Fratello, day coll., AMNH (genitalia slide no. JSM-745); ♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 7 Dec 1996, leg. J.S. Miller, day coll., AMNH (genitalia slide no. JSM-872); ♀, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. A.V.Z. Brower, day coll., AMNH (genitalia slide no. JSM-1195).

Dioptis trailii (Butler)

Figures 187I, 188, 189, 190F, 190G, 209, 210A, 210B; plate 20 [EX]

Hyrmina trailii Butler, 1877b: 56, pl. 19, fig. 9.

Type Locality

Brazil, “forest behind Manaos”, Amazonas.

Type

Syntype ♀, 26 Aug 1874, leg. J.W.H. Trail (BMNH).

Discussion

Establishing the identity of Dioptis trailii, the type species of Dioptis, proved to be one of the most difficult species problems in the Dioptinae. Long ago I determined that material identified in collections as D. trailii represented more than one species, but attempting to resolve the situation over the years has been taxing. After a large number of genitalia dissections for specimens from various South American countries, I conclude the following: Dioptis trailii is a relatively small, delicate species (pl. 20); the male genitalia are characterized by a highly reduced uncus consisting of two tiny, fused lobes (fig. 209A); the valva apex bears a small, dentate knob, and the aedeagus (fig. 209B) bears a long digitate distal process. Dioptis trailii occurs at localities throughout the upper Amazon Basin of Brazil and Peru, and is known from at least one locality in central Venezuela (the Caura River, Bolívar).

A second taxon is invariably confused with D. trailii in collections. Here, the FW is more acute near the apex, the FW veins are darker, and the body is generally (but not always) larger than in D. trailii. The genitalia of this taxon differ dramatically; in males the heavily sclerotized valva apex is elongate with robust denticles (fig. 202A), and the uncus is drawn into a long neck with winglike lateral processes near the apex. To these specimens I apply the name Dioptis fatima (Möschler), formerly regarded as a synonym of D. trailii (Prout, 1918; Hering, 1925; Bryk, 1930). Morphological differences between the two taxa include different configurations of their female PVP (compare figs. 202E, 210A). Cladistic analyses (fig. 3) show that they belong in different species groups within DioptisD. trailii in the Cyma Group and D. fatima in the Fatima Group.

The two species appear to be roughly sympatric, occurring across northern South America south into Brazil and Amazonian Peru. Both have been collected at Manaus, Brazil, the type locality for D. trailii. Adults of D. trailii and D. fatima are nearly impossible to separate without study of their genitalia. Luckily, the dramatic genitalia differences can often be observed in pinned specimens, simply by removing scales from the apex of the abdomen with a brush.

Distribution

Brazil (AMNH, BMNH, LACM, SDNH, USNM); Venezuela (AMNH, CUIC); Peru (AMNH, MUSM).

Dissected

♂, Brazil, Amazonas, Teffé, Egas, Sep 1920, leg. “Mr. Fasol”, SDNH (genitalia slide no. JSM-1198); ♂, Venezuela, Suapure, Caura River, 21 Apr 1899, leg. E.A. Klages, CUIC (genitalia slide no. JSM-129); ♂, Venezuela, Suapure, Caura River, 23 Jul 1900, leg. E.A. Klages, CUIC (genitalia slide no. JSM-1193); ♂, Peru, Madre de Dios, Parque Manu, Pakitza, 11°53′S, 70°58′W, 400 m, 6 Oct 1990, leg. R. Robbins, AMNH (genitalia slide no. JSM-741); ♂, Peru, Madre de Dios, Tambopata Reserve, 12°51′S, 69°18′W, 200 m, 6 Dec 1996, leg. J.S. Miller, day coll., AMNH (genitalia slide no. JSM-1205); ♀, Brazil, Amazonas, Río Madeira, Jul–Aug, leg. Fassl, USNM (genitalia slide no. JSM-1196); ♀, Venezuela, Suapure, Caura River, 28 Mar 1899, leg. E.A. Klages, CUIC (genitalia slide no. JSM-130, wing slide no. JSM-168); ♀, Brazil, Amazonas, Río Manes, Dognin Collection, USNM (genitalia slide no. JSM-1197); ♀, Peru, Madre de Dios, Parque Manu, Pakitza, 11°53′S, 70°58′W, 400 m, 5 Oct 1990, leg. R. Robbins, AMNH (genitalia slide no. JSM-742).

Dioptis uniguttata Warren

Plate 20

Dioptis uniguttata Warren, 1901: 439.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♂ (BMNH).

Dioptis quirites Druce, 1907: 308.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♂ (BMNH).

Discussion

The prominent, round white spot at the FW tornus, posterior to the white transverse band, is an excellent diagnostic feature for D. uniguttata (pl. 20). This maculation is more distally located than spots in most other Dioptis species. The species most similar in wing pattern is D. cheledonis (pl. 19), from southern Ecuador. That taxon also exhibits a white spot at the tornus, but differs in showing ochreous FW shading at the apex and along the anal margin. Dioptis uniguttata can also be distinguished by its FW shape, which is distinctly quadrate near the apex. Dioptis quirites Druce was placed as a junior synonym of D. uniguttata by Prout (1918: 417). Comparison of the BMNH types supports his synonymy.

Other than the male holotype of D. uniguttata (missing its abdomen) and the syntypes of D. quirites, the only specimens of this taxon known comprise a female from the CAS collection (JSM-1206), as well as recent reared material collected as caterpillars on the palm genus Geonoma at San Rafael Falls, Ecuador (pl. 40A; and see table 4). Dioptis uniguttata is notable in being one of the few Cyma Group species endemic to the region of northeastern Ecuador and Colombia. It is also unusual in occurring at a higher altitude (1300 m) than is typical for Dioptis.

Distribution

Colombia (BMNH, CAS); Ecuador (AMNH, USNM).

Dissected

♀, Colombia, Villavicencio, 10 Sep 1943, leg. Forzosa, ex Wm. Hovanitz Collection, CAS (genitalia slide no. JSM-1206).

The following species has been transferred from Dioptis: symoides Strand to Isostyla Prout (as a synonym of I. zetila).

MOMONIPTA WARREN, 1897

Figures 211Figure 212Figure 213214; plate 21

Figure 211

Morphology of Momonipta onorei, sp. nov. (♂). A, head, lateral view; B, head, frontal view; C, head, posterior view; D, head, lateral view; E, wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f211.gif

Figure 212

Holotype ♂ genitalia of Momonipta albiplaga (JSM-277). A, genitalia; B, aedeagus; C, St8; D, Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f212.gif

Figure 213

Genitalia of Momonipta onorei, sp. nov. (♂ JSM-1430, ♀ JSM-1431). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia in ventral view (illustration by J.S. Miller).

i0003-0090-321-1-1-f213.gif

Figure 214

Ecuador, showing the known distribution of Momonipta onorei, sp. nov.

i0003-0090-321-1-1-f214.gif

Momonipta Warren, 1897: 421. Type species: Momonipta albiplaga Warren, 1897 (by original designation).

Diagnosis

The two Momonipta species exhibit quite different wing patterns (pl. 21). On the surface, they seem unlikely congeners. However, numerous synapomorphies demonstrate an extremely close relationship between them. Momonipta is characterized by the following set of traits: labial palpus short and thin, porrect (fig. 211A, D), curving upward to immediately above clypeus; eye large, bulging outward (fig. 211A–D), gena completely obscured; each annulation of antenna with two transverse whirls of setae born on short, flangelike processes; FW and HW broad (pl. 21); male FW stridulatory organ present (fig. 211E), DC much shorter than one-half FW length; veins M1 and M2 swollen at their bases, arising close together from DC.

The male genitalia in Momonipta are highly unusual; they exhibit traits occurring nowhere else in the Dioptinae. For example, Tg8 is long and narrow with parallel sides (figs. 212D, 213D); St8 is short and wide (figs. 212C, 213B). The socii/uncus complex (figs. 212A, 213A)—with its long narrow base, sicklelike, upturned socii, and beaklike uncus with a strange dorsal process—is unique. Females are known for M. onorei only. Their genitalia are unusual among Dioptinae in showing asymmetry in the area surrounding the ostium (fig. 213E).

Redescription

Male. FW length  =  17.0–20.0 mm. Head (fig. 211A–D): Labial palpus short, curving upward to immediately above clypeus; Lp1 curved, narrow, with a loose, short fringe below; Lp2 slightly longer than Lp1, narrow, parallel-sided, closely scaled, without a distal tuft; Lp3 bullet shaped; scales of front short, pointing dorsomedially, not forming a dorsal tuft between antennal bases; eye extremely large, bulging, sparsely covered with short setae; scales of vertex pointing anteriorly; antenna subserrate, each annulation bearing two transverse rows of setae, the basal row set on a short, flangelike process.

Thorax: Epiphysis wide, flat, its apex falling well short of tibial apex; tegula small, shorter than one-half length of mesoscutum, distal portion rounded, ventral process blunt, the two parts separated by a weak sulcus; metathoracic tympanum moderate in size, set in a shallow depression, tympanal area scaleless; tympanal membrane small, ovoid, facing posteroventrally.

Forewing (fig. 211E; pl. 21): Broad; vein Rs1 arising from radial sector; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC, widely separate from base of radial sector; M1 and M2 arising close together; stridulatory organ present, M1 and M2 swollen at bases, wing surface between them sparsely covered with short scales, and with a short, prominent fold on ventral surface; DC less than one-half FW length; veins M3 and CuA1 arising together from posterolateral angle of DC, barely forming a stalk, or (in one specimen) forming a short stalk; light-colored areas of wing semihyaline.

Hind wing (fig. 211E; pl. 21): Broad, outer margin rounded; M3 and CuA1 stalked; wing either white with a dark outer margin, or dirty white with dark veins.

Abdomen: Elongate, narrow.

Terminalia (figs. 212, 213A–D): Tg8 longer than St8, narrow, lateral margins parallel, anterior margin with small lateral apodemes, posterior margin either with a deep, V-shaped mesal excavation (M. albiplaga) or rounded (M. onorei); St8 short, lateral margins convex, anterior margin broadly rounded, with a small, tongue-shaped mesal fold, posterior margin simple; socii/uncus complex elongate at base, with a narrow attachment to tegumen; uncus beak shaped, downcurved, with a bifid, winged dorsal process; socii thin, sickle shaped, sharply upcurved; tegumen thin, taller than vinculum, slightly wider below; vinculum narrow in dorsal portion; saccus large and wide, ventral margin roughly horizontal, dorsal margin curving gradually upward, covering ventral portion of valva bases; valva long and narrow; BO small to moderately large, occupying one-third of valva or less, with long, hairlike lateral androconia and a group of shorter, dorsal ones; costa sclerotized, wide, upper margin straight; a wide, flat sclerotized ridge running length of valva, its apex forming a knoblike or flat process; apex of valva lightly sclerotized; arms of transtilla narrow, straplike, curving abruptly downward from valva bases; aedeagus narrow in basal fourth, then sharply bent in distal three-fourths, distal portion boat shaped; an extremely long, narrow, gently curving process arising from aedeagus above bend, its upper surface finely striate, its lower surface tightly packed with long spicules; apex of aedeagus blunt; vesica large, approximately three-fourths as long as aedeagus, rounded in basal half, narrower beyond; cornuti absent.

Female. FW length  =  21.5–23.0 mm. See species description for M. onorei.

Distribution

Both Momonipta species occur on the western slope of the Andes at midelevations, one in Colombia and the other in Ecuador. So far, no members of the genus have been recorded from Central America, and none is known from Peru or Bolivia.

Biology

Nothing is known concerning the biology of Momonipta.

Discussion

Momonipta is a fascinating genus because of the taxonomic mystery surrounding it. Of the two included species, one is known exclusively from the BMNH type (pl. 21). On the basis of that specimen, Warren (1897) described albiplaga, erecting for it the genus Momonipta. The other taxon, Momonipta onorei, described here, was first brought to my attention by John Rawlins (CMNH), who loaned three males captured in Esmeraldas, western Ecuador. I subsequently located a female of M. onorei among unsorted Ecuadorian Geometridae, collected by J. Wojtusiak (Jagiellonian University, Krakow, Poland), while the two of us were visiting the BMNH (March 2005). During that same visit, I discovered three BMNH specimens of M. onorei in their unsorted accessions, collected in 1992 (by A. Spalding) at Los Cedros Ecological Reserve in western Ecuador. Finally, a female was discovered at the AMNH in August 2008, curated in the Geometridae under the genus Leucula Guenée (Larentiinae). Thus, the genus Momonipta comprises two obscure species, described over 100 years apart, known from a total of nine specimens worldwide.

Warren's (1897) generic description of Momonipta was remarkably accurate, especially considering that his characterization was constructed on the basis of a single, badly damaged specimen—the type of albiplaga. He noted (1897: 421) that the FW discal cell is “hardly half the length of the wing”. He described the male antennae as being “sub-serrate, with paired fascicles of cilia”, and the labial palpi as “porrect, second joint long, third shorter, upturned”. Warren also outlined general features of Momonipta wing venation and wing shape. The generic descriptions of most early authors, at least for the Dioptinae, are not nearly this thorough.

Subsequent to Warren's description, the taxonomic history of Momonipta became convoluted. Prout (1918) placed Stenoplastis C. and R. Felder (1874), which at that time contained only its type species—satyroides—in synonymy with Momonipta. Even though the Felder genus is older than Warren's, no description accompanies Stenoplastis, so apparently Prout chose Momonipta as the valid name. He also broadened the taxonomic boundaries of the genus considerably, adding 17 species along with satyroides and albiplaga. Essentially all of these were dioptines with subserrate male antennae. Hering (1925) instead recognized Stenoplastis as valid, thus placing Momonipta in synonymy. Hering retained the species list of Prout, but enlarged the genus even more, describing four new Stenoplastis species, and adding pellucida Dognin (1910a). Bryk (1930) followed Hering precisely. Finally, I got into the act (Miller, 1989), removing grandimacula Dognin and euchonthoides Prout from Stenoplastis, and placing them in Pareuchontha Miller, created to accommodate those taxa. By 1989, Stenoplastis contained 22 species.

In the current paper, even more drastic changes are made. First, having dissected the BMNH types of satyroides C. and R. Felder and albiplaga Warren, I conclude that Momonipta and Stenoplastis constitute separate genera. Furthermore, according to my concepts both are small in membership, containing two and three species respectively (appendix 2). Support for a Momonipta + Monocreaga clade (fig. 7) is extremely strong (BS  =  13; fig. 2). Stenoplastis is not a particularly close relative, instead belonging in a monophyletic group (Clade 17; fig. 7) that includes Isostyla and Tithraustes. The 17 remaining species previously in Momonipta/Stenoplastis are here distributed across the Dioptinae (see general Discussion: Classification; and fig. 354). One can hope that these genera are now stabilized to some extent.

KEY TO MOMONIPTA SPECIES

Plate 21

1. Forewing and HW dirty white, veins lined with dark brown; bifid dorsal process of uncus with narrow lateral arms (fig. 213A); dorsal process of aedeagus sinuate (fig. 213C); ♂ FW length  =  18.5–20.0 mm (W Ecuador)onorei, sp. nov.

FW dark brown, with a white basal triangle along anal fold and a transverse white band beyond DC; HW with a white central area and dark brown marginal band; bifid dorsal process of uncus with wide lateral arms (fig. 212A); dorsal process of aedeagus curved gently downward (fig. 212B); ♂ FW length  =  17.0 mm (W Colombia)albiplaga Warren

SPECIES INCLUDED AND MATERIAL EXAMINED

Momonipta albiplaga Warren

Figure 212; plate 21

Momonipta albiplaga Warren, 1897: 421.

Type Locality

Colombia, Río Dagua.

Type

Holotype ♂, leg. W. Rosenberg (BMNH).

Discussion

The holotype of M. albiplaga (pl. 21), from Río Dagua on the western slope of the Colombian Andes, is the only known example of this species. That specimen is missing its antennae, except for a short section near the base. Furthermore, its wings are badly worn, making the pattern difficult to discern. After studying the type superficially during visits to the BMNH in November 1996 and February 2005, I speculated that albiplaga might be closely related to Stenoplastis decorata and S. flavinigra (pl. 23). All these species possess subserrate male antennae and a well-developed FW stridulatory organ. My hypothesis roughly followed Prout (1918) and Hering (1925), both of whom believed that Momonipta and Stenoplastis were synonyms (see above). However, once I dissected the albiplaga type it became clear that these hypotheses were mistaken. Its male genitalia (fig. 212) exhibit a large set of apomorphic features, none of which appear in Stenoplastis (figs. 264Figure 265266). Among other traits, the rooflike process on the uncus and the shape of the socii give the genitalia of albiplaga a highly unusual appearance. The male of M. onorei (fig. 213A–D) exhibits these same modifications, and in fact differs from M. albiplaga in only subtle respects.

It will be interesting to learn more about this species. One would predict, based on the morphology of M. onorei, that females of M. albiplaga will be similar in showing asymmetrical genitalia (see below).

Distribution

Colombia (BMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-277).

Momonipta onorei, new species

Figures 211, 213, 214; plate 21 [EX]

Diagnosis

Momonipta onorei is highly distinctive (pl. 21). The moth can be recognized by its dirty white, semitransparent FW and HW, with all veins, including the anal fold, lined by dark brown scales. The fringe at the outer edge of the wings is dark brown. The elongate abdomen and whitish brown body, with yellow-orange tegulae standing out in sharp contrast, are diagnostic. The labial palpus is short (fig. 211A, D), reaching upward only to the clypeus. The female antennae are ciliate, whereas those of males show two transverse rows of cilia on each annulation.

Description

Male. Forewing length  =  18.5–20.0 mm. Head (fig. 211A–D): Lp1 white, fringed with long scales below; Lp2 and Lp3 dark brown; front clothed with short white scales, pointing dorsomedially toward midline; frontal scales not reaching antennal bases; occiput covered with short, white scales; vertex with pristine white scales pointing anteriorly, a small patch of gray-brown scales behind each antennal base; antenna subserrate, each segment with two transverse rows of cilia set on raised protuberances; scape dark brown above, a few scattered white scales below; antennal shaft dark brown.

Thorax: Procoxa white on inner surface, gray-brown laterally; meso- and metacoxae white; femur, tibia and tarsus gray-brown on upper and outer surfaces, white on inner one; pleuron covered with long white scales, a few short, light brown scales along anterior margin of each thoracic segment; patagium white, with a few light brown scales mixed in; tegula, including lower angle, completely orange, a few extremely long, whitish scales distally; dorsum completely white.

Forewing (fig. 211E; pl. 21): (Dorsal) Semitransparent, no spots or pattern of any kind; ground color white, dusted with brown scales, especially in outer third; all veins, including costa and anal fold, lined with dark brown scales; bases of veins M1 and M2 swollen immediately beyond DC; fringe along outer margin dark brown to light brown; anal margin white. (Ventral) Similar to upper surface, but more densely dusted with brown scales, ground color darker; veins more widely lined with brown than on upper surface.

Hind wing (fig. 211E; pl. 21): (Dorsal) Semitransparent; ground color whiter than forewings; basal third, to distal margin of DC, almost completely white; veins, including anal fold, lined with dark brown scales, more thickly near margin, especially CuA1 and CuA2; dark brown fringe along outer margin thicker than in FW; anterior margin white from base, outer fifth to apex dark brown; anal margin completely white. (Ventral) Similar to upper surface, slightly dirtier; veins more thickly lined.

Abdomen: Dorsum brownish white along midline, white laterally, gradually becoming darker toward apex; venter white; a dark brown stripe along pleuron on each side.

Terminalia (fig. 213A–D): Tg8 narrow, longer than St8, sides roughly parallel; St8 roughly ovoid, sides slightly convex, posterior margin simple, anterior margin simple, with a small, triangular mesal sclerite folded posteriorly; socii/uncus base elongate; uncus beaklike, crenulate on dorsum, apex forming a downcurved hook; uncus with a widely bifurcate, dorsal process; socii moderately long, slightly upturned, sickle shaped; tegumen tall, narrow; vinculum narrow; saccus large, broadly transverse below, upper margin convex, not touching valva bases; valva long, relatively wide; BO moderate in size, membrane not curled, pleats short; costa of valva wide, expanded along dorsal margin; valva apex sclerotized, rounded; a raised flange along valva midline, terminating at apex; transtillar arms thin, straplike, arching slightly upward near base, then curving down to meet at midline; basal one-fourth of aedeagus short, cylindrical, distal three-fourths wide, membranous above; apex of aedeagus without a hook or tooth; a long, recurved process arising from basal one-fourth above, its lower surface covered with a brush of spicules, its dorsal surface striate at base; vesica relatively large, bulbous, lacking cornuti.

Female (pl. 21). Forewing length  =  21.5–23.0 mm. Characters differing from male in the following: labial palpus shorter, thinner, upturned to immediately above clypeus; eye smaller, gena narrow, scaleless; antenna simple, without flanges, ventral surface of each annulation with a few sparse bristles in a single, transverse row; wings longer, broader, margins more rounded; FW stridulatory organ absent, DC approximately one-half FW length, veins M1 and M2 not swollen at bases; wing veins less darkly lined with brown scales; frenulum comprising 4–6 bristles; abdomen shorter, St7 heavily sclerotized, scaleless.

Terminalia (fig. 213E): Tg7 large, twice as long as Tg6, longer than St7, arching upward, anterior margin simple, posterior margin broadly rounded; St7 large, expanded laterally near posterolateral angles; posterior margin of St7 broadly excavated, excavation asymmetrical, displaced laterally to left side to accommodate asymmetrical ostium; Tg8 short, bulging upward at midline, forming a rooflike structure over PA, surface densely spiculate; AA short, delicate; PA relatively large, margins simple, bearing long, hairlike setae; PP long, tapered, sclerotized; PVP densely sclerotized, forming a broad ring below PA, its posterior margin rounded, surface coarsely spiculate; ostium oval shaped, asymmetrical, strongly displaced to left of midline; DB heavily sclerotized, forming an asymmetrical funnel, narrowly attached to CB; CB large, roughly ovoid, with a conical appendix on right side near base; signum tiny, concave, located dorsally on right side, its internal surface spiculate.

Etymology

This species is named in honor of Giovanni Onore. He has hosted my various expeditions to Ecuador, as well as those of countless other scientists from around the world. Giovanni has worked tirelessly to promote conservation and natural history studies in Ecuador. His hospitality and generosity are legendary, his smile is infectious, and his energy boundless. It is largely thanks to him that working in Ecuador is one of the most pleasurable field experiences one could hope to have. Giovanni currently devotes his time to developing La Otonga, a beautiful cloud-forest reserve in Cotopaxi Province.

Distribution

So far, this moth is known from three Ecuadorian provinces (fig. 214)—Esmeraldas, Imbabura and Pichincha. However, the sites are close together. As additional specimens come to light, it will undoubtedly be revealed that M. onorei occurs more widely at midelevations (between approximately 600 and 1500 m) along the western slope of the Andes, perhaps extending north into Colombia.

Discussion

My first glance at specimens of M. onorei in January 2004, loaned to me by John Rawlins (CMNH), led me to doubt that the moth belonged in the Dioptinae—I had never seen anything like them. In general appearance, M. onorei is remarkably similar to species in the genus Xenosoma (Arctiidae: Pericopinae); it is sympatric with X. nigromarginatum Druce. However, upon closer inspection, a wealth of morphological characters assures its position in the Dioptinae. I further assumed, because of its unusual habitus, that placing the species in an existing dioptine genus would be problematic. Again, however, I was surprised to discover a large suite of characteristics shared between Momonipta onorei and M. albiplaga, especially in their male genitalia (compare figs. 212, 213).

One wing-venation trait of M. onorei does not precisely match that of M. albiplaga: in M. albiplaga, FW veins M3 and CuA1 are stalked for a fairly long distance from the lateroposterior angle of the DC; in M. onorei these veins are fused at their bases, but are typically not stalked (fig. 211E). Oddly, among the specimens of M. onorei known, a single female in the series from Los Cedros Ecological Reserve shows FW veins M3 and CuA1 with a long stalk, so variation occurs within the species. This observation is reminiscent of the findings of Albrecht and Kaila (1997), who discovered significant variation in wing vein–branching patterns within species of Elachistidae.

Momonipta onorei shows a trait highly unusual in the Dioptinae; the female genitalia are strongly asymmetrical, a feature observable in intact, pinned specimens. The ostium is located a considerable distance to the left of the midline, and the DB is concordantly distorted (fig. 213E). Genital asymmetry occurs elsewhere in the Notodontidae (Weller, 1992), and also appears in disparate groups of the Noctuoidea, such as the genus Zale (Noctuidae: Catocalinae). However, this is the first documented case of female genital asymmetry for the Dioptinae. Males of M. onorei are not asymmetrical in the valvae, but the aedeagus is highly modified, exhibiting a greatly elongate dorsal process that is twisted and displaced to the right side. This structure is perhaps modified to correspond with the shapes of the female ostium and ductus bursae.

Holotype

Male (pl. 21). Ecuador: Esmeraldas: Río de Christal, Cotacachi-Cayapas Reserve, 1650 m, 21 Aug 1996, leg. J. Hillman, virgin submontane forest (CMNH). The type is deposited at the CMNH.

Paratypes

Ecuador: Esmeraldas: 2 ♂♂, Río de Christal, Cotacachi-Cayapas Reserve, 1650 m, 21 Aug 1996, leg. J. Hillman, virgin submontane forest (CMNH; genitalia slide no. JSM-1300, wing slide no. JSM-1458). Pichincha: 1♀, Pacto, Río Mashpi, N00°09′21″ W78°51′48″, 1150 m, 8 Feb 2004, leg. R. Garlacz (ZMJU; genitalia slide no. JSM-1430); 1♀, Tinalandia, 16 km E Santo Domingo de Los Coloradas, 600 m, 5–11 May 1990, leg. R.H. Leuschner (AMNH). Imbabura: 1♂, Los Cedros Ecological Reserve, nr. Sanguangal, 60 km NW Quito, 100 km SE Esmeraldas, 1550 m, 29 Aug 1992, leg. A. Spalding, day collecting (BMNH; genitalia slide no. JSM-1431); 1♀, 24 Aug 1992, leg. A. Spalding, at lights (BMNH; genitalia slide no. JSM-1414); 1♀, 1450 m, 22 Aug 1992, leg. A. Spalding, at lights (BMNH).

Other Specimens Examined

None.

Dissected

2♂♂, 2♀♀.

MONOCREAGA C. AND R. FELDER, 1874

Figures 215Figure 216Figure 217Figure 218Figure 219220; plate 21

Figure 215

Morphology of Monocreaga (♂♂). A, head of M. pheloides, lateral view; B, head of M. pheloides, frontal view; C, head of M. pheloides, posterior view; D, head of M. unimacula, lateral view; E, M. unimacula tegula; F, M. unimacula wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f215.gif

Figure 216

Scanning electron micrographs of Monocreaga orthyades ♂. A, head in lateral view; B, sensillum styloconicum near apex of proboscis; C, antenna in ventrolateral view, distal at right; D, antenna in lateral view, distal at left; E, sensillum styloconicum near apex of antennal flagellomere; F, dorsal portion of metathorax in lateral view (anterior at left), showing tympanum.

i0003-0090-321-1-1-f216.gif

Figure 217

Scanning electron micrographs of Monocreaga orthyades ♂, HW dorsal surface. A, broad scales along wing vein and thin scales between veins; B, thin and vein scales; C, thin scales from B; D, base of thin scale.

i0003-0090-321-1-1-f217.gif

Figure 218

Male genitalia of Monocreaga orthyades (JSM-572). A, genitalia; B, Tg8; C, aedeagus; D, St8, ventral view.

i0003-0090-321-1-1-f218.gif

Figure 219

Genitalia of Monocreaga pheloides (♂ JSM-1316, ♀ JSM-429). A, ♂ genitalia; B, ♂ Tg8; C, ♂ St8; D, ♀ genitalia; E, aedeagus.

i0003-0090-321-1-1-f219.gif

Figure 220

Genitalia of Monocreaga unimacula (♂ JSM-570, ♀ JSM-571). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f220.gif

Monocreaga C. and R. Felder, 1874: pl. 105, fig. 8. Type species: Monocreaga pheloides C. and R. Felder, 1874 (by monotypy).

Euforbesia Kiriakoff, 1950: 77. Type species: Tanaostyla unimacula Warren, 1897 (by original designation). New synonymy.

Diagnosis

Although Monocreaga species possess hyaline wings, giving them superficial resemblance to Dioptis, Phanoptis, Hadesina, and some Tithraustes, they can be separated from those taxa by their wing venation and antennal morphology. In Monocreaga, FW veins M3 and CuA1 arise separately from the discal cell (fig. 215F), and although the DC is longer than one-half the FW length, there is a conspicuous male stridulatory organ, with veins M1 and M2 swollen at their bases. Hind wing veins M3 and CuA1 are stalked. This combination of traits quickly separates Monocreaga from Hadesina (fig. 137F) and Tithraustes (fig. 268G), in which FW veins M3 and CuA1 are stalked and the DC is shorter than one-half the wing length. It also distinguishes Monocreaga from Phanoptis, where HW veins M3 and CuA1 are widely separate and there is no stridulatory organ (fig. 64K). The male antenna in Monocreaga lacks pectinations (fig. 216C–E), each annulation instead exhibiting paired transverse rows of cilia set on short, flangelike processes. All Dioptis exhibit quadripectinate antennae (fig. 188C, D), and in most species there is no male FW stridulatory organ (fig. 190E, F).

The only remaining source of potential confusion is how to separate females of Monocreaga and Dioptis. Luckily, the solution is straightforward. First, of the 45 described Dioptis species, in all but one of those—D. obliquaria—FW veins M3 and CuA1 are stalked (fig. 190G). Examination of the radial systems reveals that all Dioptis, including obliquaria, exhibit the branching pattern typical for the Dioptinae, [Rs2+Rs3]+Rs4, whereas Monocreaga species (fig. 215F) show the less common arrangement, Rs2+[Rs3+Rs4]. However, there is an even easier method for separation. Dioptis females are unusual in having quadripectinate antennae (fig. 188E, F); the antennae of Monocreaga females lack pectinations, but instead show a single, sparse, transverse row of bristles on each annulation.

Redescription

Male. FW length  =  15.0–19.0 mm. Head (figs. 215A–D, 216A–E): Labial palpus short and thin, curving upward only to clypeus or slightly below; Lp1 curved, fairly long, with a short, loose, white fringe below; Lp2 thin, almost straight, shorter than Lp1; Lp3 extremely short, almost quadrate; scales of front short, pointing downward from antennal bases, then horizontally to meet at midline, forming a low, mesal ridge, no dorsal tuft between antennal bases; scales below antennal bases white, other scales of front blackish brown, clypeus scaleless; eye extremely large, bulging, gena absent, no scaleless region below; antenna subserrate, each annulation with a pair of transverse, dense rows of setae, set on short, flangelike processes.

Thorax (215E, 216F): Epiphysis wide, flat, its apex falling well short tibial apex; tegula small, shorter than one-half length of mesoscutum, distal portion rounded, ventral process blunt, the two parts separated by a weak sulcus; metathoracic tympanum comprising a relatively deep, scaleless cavity, moderately large, its outer margins angulate; tympanal membrane large and enclosed, ovoid, facing posteroventrally.

Forewing (fig. 215F, pl. 21): Roughly triangular; vein Rs1 stalked with Rs2–Rs4; Rs2–Rs4 in the pattern 2+[3+4]; M1 arising from DC, separate from base of radial sector, UDC present; stridulatory organ present, M1 and M2 swollen at their bases; a short, indistinct fold between bases of M1 and M2 on ventral surface; DC much longer than one-half FW length; veins M3 and CuA1 arising separately from DC, set widely apart; wings hyaline in basal two-thirds, veins lined with dark scales, distal one-third dark brown to blackish brown, with a large, white subapical spot.

Hind wing (fig. 215F, pl. 21): Broad, outer margin rounded; M3 and CuA1 long stalked; central area broadly hyaline, veins lined with dark brown to blackish brown, a moderately wide, dark brown to blackish-brown marginal band.

Abdomen: Moderate in length, apex truncate, dorsum brown to blackish brown, venter white.

Terminalia (figs. 218, 219A–C, 219E, 220A–D): Tg8 narrower than Tg7, gradually narrower posteriorly, anterior margin simple, posterior margin broadly rounded; St8 shorter than Tg8, lightly sclerotized, almost ovoid, anterior margin either simple or with an extremely short, wide mesal apodeme, posterior margin simple, almost transverse; socii/uncus complex small; uncus elongate at base, hoodlike in middle, apex narrowly truncate; socii arising near middle of uncus, extremely small, wide at base, upturned near apex; tegumen moderately wide, much taller than vinculum; vinculum narrow; ventral margin of genitalia gently convex, either simple or with a small mesal bump; saccus wide, transverse, upper margin barely extending upward, not covering valva bases; valva simple, moderately long, margins roughly parallel; BO small, occupying one-third of valva or less, pleats few in number; costa of valva wide, weakly sclerotized; apex of valva lightly sclerotized, quadrate; arms of transtilla narrow, curving upward from valva base, then sharply downward to form a narrow, transverse sclerite at midline; aedeagus relatively short, wide, narrowed in basal fourth, somewhat sinuate in distal three-fourths, apex acute; an extremely long, narrow, gently curving process arising from dorsum of aedeagus, its upper surface finely striate, its lower surface tightly packed with long spicules; vesica slightly more than one-half aedeagus length, wider than aedeagus; cornuti absent.

Female. FW length  =  18.5–24.0 mm. Head: Labial palpus shorter and thinner than male, porrect, barely curving upward, not reaching clypeus; antenna ciliate, each annulation bearing a single, sparse row of bristles.

Thorax: Similar to male.

Forewing: Much longer and broader than male; pattern similar, colors slightly less intense.

Hind wing: Longer and broader than male, pattern similar; frenulum comprising 4–6 bristles.

Abdomen: Extremely wide, lateral portions of St7 wrapping upward, yellowish brown, scaleless, densely spiculate.

Terminalia (figs. 219D, 220E): Tg7 longer than Tg6, slightly longer than St7, widest at anteriorly; anterior margin of Tg7 simple, lateral margins slightly concave, posterior margin gently convex; much wider than posterior; St7 wide, widest at posterolateral angles, anterior margin simple, posterior margin with a deep, wide U-shaped mesal excavation; surface of St7 densely spiculate, especially along posterior margin; Tg8 membranous, comprising short, narrow lateral sclerites; AA short, weakly sclerotized; pleuron of A8 membranous; PP thin, relatively short; PA moderate in size, surfaces densely spiculate, margins rounded; PVP wide, lightly sclerotized, surface spiculate, ostium funnel shaped; DB extremely short, narrow, membranous; DS arising from a small, triangular dorsal appendix near base of CB; CB large, ovoid, membranous; signum small, figure-eight shaped, located on right side of CB, surface dentate; a second larger, ovoid, concave sclerite on left side, its internal surface coarsely dentate, especially along posterior margin.

Distribution

Except for a single AMNH female from Guatemala, provisionally identified as M. orthyades but representing an undescribed species, all Monocreaga material has been collected on the eastern slope of the Andes, from Colombia south to Bolivia. As far as I am aware, none has been recorded from the west. Monocreaga pheloides, the taxon for which we have the greatest quantity of detailed locality data, occurs in eastern Ecuador at elevations ranging from 500 to 1500 meters. It is most frequently encountered at approximately 1000 meters.

Biology

Monocreaga species often occurs in sympatry with mimetic Geometridae. Moths collected at San Rafael Falls in eastern Ecuador (November 2004, J.S. Miller and E. Tapia) provide a beautiful example. Zeuctostyla rubricollis (pl. 21) in the Ennominae (Pitkin, 2002), an almost perfect mimic of M. pheloides, was captured at lights on the same night as several examples of M. pheloides.

Nothing is known concerning the host plants or larval biology of Monocreaga. The adults are attracted to lights more readily than most Dioptinae.

Discussion

The three described species of Monocreagaorthyades, pheloides, and unimacula—differ only slightly from one another. These differences, which concern the amount of white in the FW fascia beyond the DC, are employed in the species key. However, I have little confidence regarding species boundaries in Monocreaga. Seitz (1925) chose M. pheloides as an example of extreme intraspecific wing-pattern variability in his introduction to the Dioptidae in volume 6 of Macrolepidoptera of the World. Male and female genitalia, when examined across wing-pattern phenotypes, show few distinguishing features. When a revision of Monocreaga is undertaken, I predict that the species will be circumscribed differently than they are at present.

The morphology of hyaline wings in Monocreaga (fig. 217) is seemingly identical with that found in Phanoptis (fig. 65) and Dioptis (fig. 191). The wing surface in the hyaline regions between veins is sparsely covered with thin, curved scales. The veins themselves are covered with large, wide scales. Despite their identical morphologies, each of these cases appears to have evolved by convergence (see general Discussion: Hyaline Wings; fig. 355).

My phylogenetic analyses suggest that Monocreaga and Momonipta are sister genera (figs. 3, 7). The two share a long list of characteristics (appendix 4), including: presence of large, rounded eyes; relatively short, thin labial palpi; male antennae lacking pectinations, but with bristles born on short, flangelike processes; and a FW stridulatory organ in males. Structure of the aedeagus in Monocreaga and Momonipta is unique for the family, and provides strong support for a sister-group relationship between these genera. Here, the most obvious synapomorphy is the presence of a long, curved process arising near the base of the aedeagus on its dorsum (figs. 212B, 213C, 218C, 219E, 220C). The ventral surface of this process is minutely spiculate. Monocreaga and Momonipta are distinguished by, among other things, the length of the FW DC, which is longer than one-half the wing length in Monocreaga (fig. 215F), but shorter than one-half in Momonipta (fig. 211E).

The key below was designed with respect to primary type material for each Monocreaga species. However, many specimens, especially from southeastern Peru, show wing patterns that do not conform perfectly to the type. Species identifications then become nearly impossible.

KEY TO THE SPECIES OF MONOCREAGA C. AND R. FELDER

Plate 21

1. Forewing fascia beyond DC completely white, veins M1 and M2 white as they pass through2

FW fascia mostly hyaline with a scattering of white scales, veins M1 and M2 dark as they pass through fasciaorthyades Druce

2. White FW fascia large, cell between M3 and CuA1 mostly white, M3 thinly lined with brown scales as it passes through fasciapheloides C. and R. Felder

FW fascia small, cell between M3 and CuA1 hyaline to gray-brown, concolorous with remainder of wingunimacula (Warren)

SPECIES INCLUDED AND MATERIAL EXAMINED

Monocreaga orthyades Druce

Figures 216, 217, 218; plate 21

Monocreaga orthyades Druce, 1893: 295, pl. 20, fig. 7.

Type Locality

Ecuador, Intaj.

Type

Syntype ♀, leg. Buckley (BMNH).

Discussion

Druce, in his original description (1893: 295), claimed that M. orthyades could be distinguished from M. pheloides “by the entire absence of the white band on the primaries [ =  forewings]”. My examination of the BMNH orthyades type, the only example of this species in their collection, reveals a more ambiguous situation. The type exhibits a mostly hyaline FW fascia with a faint dusting of white scales. Veins M1 and M2 are dark as they pass through the fascia. I found material matching the type of M. orthyades in the PTC, AMNH, and USNM, in each case represented by a single specimen. Careful study, including comparison of genital morphology, suggests that M. orthyades is simply a wing-pattern variant of M. pheloides; I found no consistent morphological distinctions. However, rather than formalize this thesis by placing orthyades in synonymy, I have chosen to retain species status pending comprehensive revisionary research on Monocreaga.

An AMNH female, clearly labeled “Guatemala” (JSM-573) and originally from the Henry Edwards Collection, shows a wing pattern conforming to that of M. orthyades. This specimen exhibits genitalia distinct from all South American Monocreaga, and seems to represent an undescribed species. As far as I know, this is the only specimen of Monocreaga from Central America.

Distribution

Ecuador (AMNH, BMNH, PTC, ZMH); Peru (USNM).

Dissected

♂, Ecuador, Morona-Santiago, Rte. Gualaquiza-Limón, Km 23, 1610 m, 11 Feb 1983, leg. C. Lemaire & P. Thiaucourt, PTC (genitalia slide no. JSM-572); ♀, Guatemala, AMNH (genitalia slide no. JSM-573).

Monocreaga pheloides C. and R. Felder

Figures 215A–C, 219; plate 21 [EX]

Monocreaga pheloides C. and R. Felder, 1874: pl. 105, fig. 7.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♂ (BMNH).

Tanaostyla conjunctiva Warren, 1900: 129.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♂/♀ (not seen).

Tanaostyla dilucida Warren, 1897: 422.

Type Locality

Colombia, Popayán.

Type

Holotype ♂, leg. Lehmann (BMNH).

Discussion

The BMNH holotype of pheloides, dissected over 60 years ago by Baron de Worms (his dissection number 421/50), exhibits an entirely white FW fascia, with M1 and M2 white as they pass through it. Vein M3 is dark, while the cell posterior to that, formed between M3 and CuA1, is almost entirely white. Moths matching this wing pattern, common in most museum collections, are widespread along the eastern slope of the Andes from central Colombia south into Peru. However, this material shows two conspicuous phenotypes—in one, which includes the type, the FW and HW ground color is brownish gray, while in the other the ground color is dark blackish brown. I was unable to identify additional morphological traits correlated with this pattern difference, but my suspicion is that more than one species is involved. Resolution of this issue must await future research. The two Warren names listed above, conjunctiva and dilucida, have been regarded as synonyms of M. pheloides by all authors since Prout (1918).

Distribution

Colombia (AMNH, BMNH, MNHN, OUMNH, UCB, USNM, ZMH); Ecuador (AMNH, BMNH, CMNH, LACM, MNHN, NMW, OUMNH); Peru (AMNH, BMNH, MUSM, NMW).

Dissected

♂, Ecuador, Morona-Santiago, Morona de Santiago, 12 km W Santiago military camp, 550 m, 10 Aug 1996, leg. Jan Hillman, lowland forest, CMNH (genitalia slide no. JSM-1316); ♂, Colombia, leg. Felipe Ovalle, Q., Acc. 33501, AMNH (genitalia slide no. JSM-428); ♂, Colombia, Medina, Mar 1920, leg. Apollinaire, USNM (wing slide no. JSM-1440); ♀, Colombia, leg. Felipe Ovalle, Q., Acc. 33501, AMNH (genitalia slide no. JSM-429).

Monocreaga unimacula (Warren), revised combination

Figures 215D–F, 220; plate 21 [EX]

Tanaostyla unimacula Warren, 1897: 423.

Type Locality

Bolivia, Reyes.

Type

Holotype ♀, leg. Stuart, 7 Aug 1895 (BMNH).

Discussion

Kiriakoff (1950) created the genus Euforbesia for a single species—unimacula Warren—stating that this taxon differs from Monocreaga, where it had previously been placed, in possessing a reduced tympanum, lacking a membrane. On that basis Kiriakoff associated Euforbesia with Dioptis, since some Dioptis have reduced metathoracic tympana (Forbes, 1916, 1922). Kiriakoff's argument is confusing. Having examined the BMNH type of unimacula (pl. 21), I can state that it clearly possesses a tympanum. My studies also confirm that unimacula is congeneric with M. pheloides and M. orthyades, as all authors previous to Kiriakoff had supposed. Thus, Euforbesia is here placed in synonymy.

Monocreaga species in fact possess a well-developed metathoracic tympanum, in which the membrane is oriented posteroventrally (fig. 216F). One can only assume that Kiriakoff's generic concept for Euforbesia was based on misidentified material. He was perhaps mistakenly examining a species of Dioptis, where the tympanum is indeed absent (fig. 189B, C).

Monocreaga unimacula differs from M. pheloides (pl. 21), the other species with a completely white FW fascia, in that the spot of M. unimacula is mostly confined to a single, ovoid maculation located above vein M3. In M. pheloides, on the other hand, the white fascia is joined by a second smaller spot below M3. However, as I have noted throughout the discussion for Monocreaga, species boundaries within the genus are extremely vague.

Distribution

Bolivia (BMNH, MNHN, USNM); Peru (AMNH, BMNH, CUIC, MNHN, MUSM, ZMH).

Dissected

♂, Peru, Cuzco, Cosñipata Valley, Río San Pedro, San Pedro Lodge, S13°01′21″, W71°29′52″, 1400 m, 21 Oct 2005, MV light, leg. J.S. Miller, A. Asenjo & J.J. Ramírez, AMNH (JSM-1637); ♂, Peru, Junín, Estancia Naranjal, San Ramon, 1000 m, 20–27 Jul 1965, leg. P. & B. Wygodzinsky, AMNH (genitalia slide no. JSM-570); ♂, Peru, Col. Perene, El Campamiento, 4–7 Jun 1920, Cornell Univ. Expedition, lot-607 sub-71, CUIC (genitalia slide no. JSM-159); ♂, Bolivia, Yungas de la Paz, 1000 m, USNM (wing slide no. JSM-1441); ♀, Peru, Chanchamayo, La Merced, Alexander B. Klots Collection, AMNH (genitalia slide no. JSM-571); ♀, Peru, Puerto Bermudez, Río Pichis, 13 Jul 1920, Cornell Univ. Expedition, lot-607 sub-135, CUIC (genitalia slide no. JSM-160, wing slide no. JSM-184).

The following species has been transferred from Monocreaga: disconnexa Dognin to Polypoetes (Rubribasis Group)

DOLOPHROSYNE PROUT, 1918

Figures 221Figure 222Figure 223Figure 224Figure 225226; plates 21, 22

Figure 221

Male morphology of Dolophrosyne coniades (Druce). A, head, lateral view; B, head, frontal view; C, head, posterior view; D, head, lateral view; E, tegula; F, wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f221.gif

Figure 222

Paratype ♂ genitalia of Dolophrosyne elongata (JSM-733). A, genitalia; B, Tg8; C, aedeagus; D, St8.

i0003-0090-321-1-1-f222.gif

Figure 223

Male genitalia of Dolophrosyne mirax (JSM-1022). A, genitalia; B, Tg8; C, aedeagus; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f223.gif

Figure 224

Genitalia of Dolophrosyne coniades (♂ JSM-695, ♀ JSM-1658). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f224.gif

Figure 225

Male genitalia of Dolophrosyne sinuosa (JSM-1553). A, genitalia; B, Tg8; C, St8; D, aedeagus (illustration by J.S. Miller).

i0003-0090-321-1-1-f225.gif

Figure 226

Peru and Ecuador, showing the known distributions D. coniades (Druce), Dolophrosyne sinuosa, sp. nov., and Scoturopsis franclemonti, sp. nov.

i0003-0090-321-1-1-f226.gif

Dolophrosyne Prout, 1918: 396 (p. 403). Type species: Dolophrosyne mirax Prout, 1918 (by original designation).

Euscoturopsis Bryk, 1930: 17. Type species: Scoturopsis elongata Hering, 1925 (by original designation). New synonymy.

Diagnosis

Species in Dolophrosyne are small and delicate, often with drab wing coloration (pls. 21, 22). The genus contains among the smallest of all Dioptinae; the FW length of D. elongata (Hering) is only 9.0 mm. In some Dolophrosyne species, the wings are hyaline or partly transparent. The antennae are coarsely ciliate in both sexes. The eyes are usually extremely small (fig. 221A–D), and the labial palpi are small, delicate, and porrect. Frequently, the head is covered with partially erect scales (fig. 221D), giving the face a somewhat rough appearance (Prout, 1918). The DC is longer than one-half the FW length (fig. 221F), without a male stridulatory organ, and veins M3 and CuA1 are stalked in both the FW and HW.

An important diagnostic character for Dolophrosyne is the apparent loss of a vein in the FW radial sector (fig. 221F). This trait also occurs in one species of Xenormicola, a close relative of Dolophrosyne. There, FW vein Rs1 arises from the DC (fig. 232), rather than being stalked with the radial sector (fig. 221F).

The other genus with which Dolophrosyne could be confused is Scoturopsis Hering. That genus also contains small to medium-sized, high-altitude Andean species with ciliate male antennae. The two genera can be separated because Scoturopsis exhibits the plesiomorphic condition of the FW radial sector—presence of five veins (fig. 227C, D). An autapomorphy of Scoturopsis, not present in Dolophrosyne, can also be used to separate the two genera. The frons in Scoturopsis species bulges anteriorly (fig. 227A, B), whereas in Dolophrosyne it does not (fig. 221A, D).

Some Dolophrosyne are similar in habitus to Phryganidia (pl. 8), whose wings are often uniformly drab gray or gray-brown. However, Phryganidia exhibits the typical five FW radials (fig. 60C), and the species occur from Guatemala north to Oregon (Miller, 1987a). In addition to showing only four FW radials, Dolophrosyne is exclusively South American.

Redescription

Male. FW length  =  9.0–11.5 mm. Head (figs. 221A–D): Labial palpus short, porrect, loosely scaled, barely curving upward, falling short of clypeus; Lp1 short and wide, curved, with a ventral group of long scales; Lp2 as long as or slightly longer than Lp1; Lp3 tiny, bullet shaped, distal scales forming an acute apex; frontal scales pointing dorsally from clypeus, upper scales pointing dorsomedially, meeting at midline to form a short, loose tuft between antennal bases; eye small and round, completely surrounded by a scaleless band, wider above; gena broadly scaleless, heavily sclerotized, shiny; postgena extremely wide, bulging laterally; scales of vertex long or moderately so, pointing anteriorly, sometimes loosely arranged (D. mirax); antenna lacking pectinations, ventral surface of each annulation densely covered with long cilia arranged in two transverse rows, dorsal surface of antennal shaft sometimes scaleless (D. elongata, D. mirax), covered in cilia as well.

Thorax (fig. 221E): Epiphysis short and wide, foliate; tibia sometimes exceptionally long (D. mirax); tegula extremely short and wide, shorter than one-half length of mesoscutum; metathoracic tympanum open, cavity extremely shallow, membrane almost flush with surface of metepimeron; tympanal membrane variable in size, either small and half-moon shaped (D. mirax), or large and ovoid (D. coniades), oriented posterolaterally.

Forewing (fig. 221F; pls. 21, 22): Shape variable, either broad and triangular (e.g., D. coniades) or elongate (D. elongata); R1 arising from anterior margin of DC; vein Rs1 short stalked with radial sector (Mirax Group), or arising far out on radial sector (Coniades Group); only four radial veins present, veins Rs2 and Rs3 apparently fused, Rs2+Rs3 and Rs4 subtending apical angle; M1 arising from DC separate from base of radial sector, UDC long; stridulatory organ absent; DC longer than one-half FW length; M3 and CuA1 long stalked; ground color evenly gray to gray-brown, semihyaline, with wing veins lighter reddish brown (Mirax Group), or ground color dark slate gray with a long white triangle along anal margin (Coniades Group).

Hind wing (fig. 221F; pls. 21, 22): Small, angled at apex, outer margin rounded; M3 and CuA1 fused for a long distance from DC; ground color gray-brown to dark gray, central area broadly hyaline (Mirax Group), or ground color white (Coniades Group).

Abdomen: Short or moderately long, narrow, Tg8 longer than St8, with scales of Tg8 forming a short, acute distal tuft above.

Terminalia (figs. 222, 223, 224A–D, 225): Tg8 long, much longer Tg7, greatly tapered distally, anterior margin simple or with a pair of short, rounded apodemes and a shallow mesal excavation (D. coniades), posterior margin of Tg8 sometimes sclerotized (D. coniades), always with a small U-shaped mesal excavation; St8 much shorter than Tg8, wide, expanded at anterolateral angles, tapered distally, anterior margin simple, posterior margin with a U-shaped mesal excavation or simple; socii/uncus complex relatively large, with an extremely narrow, or somewhat narrow attachment to tegumen; uncus short and hoodlike, apex variable, smoothly rounded (Coniades Group), or with a small ventral ridge (Mirax Group); socii longer than uncus, curved sharply upward, apices blunt or bladelike; tegumen narrow at junction of valva, wider above, much taller than vinculum; vinculum narrow; saccus small or absent, lower margin of genitalia transverse or gently convex; valva short and wide (Mirax Group), or greatly elongate (Coniades Group); BO extremely small, represented by a few short pleats or wrinkles (D. elongata), or completely absent (D. mirax, D. coniades); costa of valva extremely thin or apparently absent; valva apex simple and smoothly rounded (Mirax Group), or sclerotized and acute (Coniades Group); arms of transtilla extremely thin, curving upward near base, then meeting at midline to form a long, strutlike sclerite, projecting anteriorly; aedeagus relatively short, widest at base, slightly tapered distally; apex of aedeagus with a small dorsal opercular sclerite, and a small, blunt ventral process; vesica shorter than length of aedeagus, simple; cornuti minutely spiculate (Coniades Group), or completely absent (Mirax Group).

Female (known for D. coniades only). FW length  =  11.0–12.0 mm. Head, thorax, and wing characters similar to male, except: each annulation of antenna with only four cilia on ventral surface, not densely covered with cilia; wing equal in size and shape to males, but dark areas light gray-brown rather than dark gray; frenulum comprising three bristles.

Terminalia (fig. 224E): Tg7 large, wide, slightly tapered posteriorly, with a shallow transverse groove in anterior third, anterior margin simple, gently convex, posterior margin simple, with shallow crenulations; St7 long, extremely wide, with a shallow transverse groove in posterior fourth, anterior margin simple, posterior margin with a wide U-shaped mesal excavation; surfaces of Tg7 and St7 shagreened, especially along posterior margins; Tg8 long and wide, lightly sclerotized; AA short and blunt; A8 pleuron lightly sclerotized; PP short, acute; PA moderately large, membranous, posterior margin simple; PVP apparently absent, this area membranous; DB short, somewhat swollen, lightly sclerotized; CB small, completely membranous, abruptly narrowed in basal third; signum absent; DS arising dorsally at junction of DB and narrow basal section of CB.

Distribution

Dolophrosyne species are endemic to cloud forests along the eastern Andes from Ecuador south to Bolivia, at relatively high elevations. The lowest altitude yet recorded for the group is from D. mirax, collected at 1800 meters, and the highest is represented by D. elongata, from 3000 meters. It is interesting that no members of the genus have so far been found on the western side of the mountains. However, it should be remembered that most Dolophrosyne are extremely rare; of the four described species, only two—D. coniades and D. sinuosa—are known from more than two specimens. Intensive sampling may yet reveal western taxa belonging in this genus.

Biology

Like other members of the larger clade to which it belongs (Clade 14; fig. 7), Dolophrosyne caterpillars have been recorded on the cloud-forest bamboo genus Chusquea (Poaceae), the host plant of Xenomigia and Scoturopsis (table 4). It seems likely that Xenormicola, the fourth genus in this clade, feeds on Chusquea as well.

Most Dolophrosyne species are extremely elusive. I have searched intensively for D. mirax adults at Peruvian localities where other collectors had captured examples, only to leave completely discouraged. Dolophrosyne coniades, on the other hand, is locally common. During the course of a day at Yanayacu Biological Station (pl. 43), hundreds of adults can sometimes be observed, fluttering approximately 3 to 5 m above the ground. Invariably the moths are found near dense stands of Chusquea (pl. 44C, E, F) growing along roadsides and trails.

Discussion

Three small genera (totaling 11 described species) belong in a tight-knit clade—Dolophrosyne, Scoturopsis, and Xenormicola—all endemic to the high Andes. Together, these obscure taxa form a fascinating group, and one that has confounded previous systematists (Prout, 1918; Hering, 1925; Bryk, 1930). A significant obstacle in resolving their classification and taxonomy has been the incredible rarity of available material. For example, Dolophrosyne mirax Prout is known from only three males. Similarly, the two described species of Xenormicola are known from a total of six males. Of the 11 species in these three genera, females are known for only two.

I have attempted to stabilize the classifications of Dolophrosyne, Scoturopsis, and Xenormicola based on the scant material at hand. Ultimately, a more lasting solution would be to disregard existing generic boundaries and examine species-level relationships for the entire clade. For example, synapomorphies in the male genitalia of Dolophrosyne elongata (fig. 222A), Scoturopsis basilinea (fig. 228A), and Xenormicola extensa (fig. 233A) are suggestive that these three share a more recent common ancestor than they do with their respective congeners. It is my belief that when additional character information becomes available, either in the form of female specimens, immature stages, or the acquisition of molecular data, these three genera may be subsumed within a single genus, the senior name being Dolophrosyne Prout.

When Prout (1918: 403) erected Dolophrosyne it was monobasic—containing D. mirax Prout. His list of diagnostic characters for the genus included: “face broad, with appressed scales”; eye small; “antenna in male with fascicles of fine cilia”; “palpus rather short, rough-scaled”; “wings with scaling thin and hair-like”. This is an accurate characterization, to which can be added the many features listed in the Redescription (above).

The only trait defining Bryk's (1930: 17) genus Euscoturopsis was tersely given as “R5 atr.” Bryk was effectively raising one subgroup of Scoturopsis Hering (1925) to full generic status. Hering (1925) had earlier described Scoturopsis, breaking it into subgroups defined as follows: (1) “Fifth radial present”; and (2) “Fifth radial fused”. In Group 2, Hering (1925) placed three taxa that he described at that time—elongata, extensa, and uniformis. At its inception (Bryk, 1930), the genus Euscoturopsis contained these three species, with elongata Hering as its type. However, confusion reigned supreme. For example, Bryk and previous authors (Prout, 1918; Hering, 1925) had overlooked the fact that the wings of Dolophrosyne mirax exhibit only four FW radials.

Comparative morphological analysis shows that elongata Hering, the type of Euscoturopsis, is congeneric with D. mirax Prout. I here place Euscoturopsis Bryk as a new junior subjective synonym of Dolophrosyne Prout. The names elongata and uniformis are thus assigned to Dolophrosyne. However, the picture is not as tidy as it could be; the other species with four radials, extensa Hering (fig. 232C)—also placed by Bryk (1930) in Euscoturopsis—is here referred to the genus Xenormicola (see below). Strangely, loss of a FW radial seems to have evolved separately in two closely related dioptine genera. To my knowledge, no other Notodontidae lack a FW radial, but elsewhere in the Noctuoidea, loss of Rs2 is an important character in the systematics of the arctiid genus Virbia Walker (Zaspel and Weller, 2006).

To Dolophrosyne I also add D. coniades (Druce). Druce (1893) described that unusual species in the geometrid genus Trochiodes, but it was subsequently moved (Prout, 1918) to Tithraustes in the Dioptinae. Among other traits of Dolophrosyne, D. coniades exhibits four FW radials (fig. 221F), and the male antenna is coarsely ciliate. I also describe a new Dolophrosyne species, D. sinuosa, the apparent sister taxon to D. coniades. Thus, according to my classification (appendix 2), Dolophrosyne, once monobasic, now includes four taxa in two species groups—the Mirax and Coniades groups.

The clade Dolophrosyne + Scoturopsis + Xenormicola is the apparent sister group to Xenomigia (figs. 2, 3), a taxonomically complex Andean genus.

KEY TO DOLOPHROSYNE SPECIES GROUPS

1. Forewing with a large, white basal triangle, this extending from anterior margin of DC to anal margin (pl. 22); HW almost entirely white, either with a blackish-brown marginal band or a blackish-brown spot at apexConiades Group

FW without a white basal triangle; wings uniformly gray or gray-brown (pl. 21), without conspicuous markingsMirax Group

1. MIRAX GROUP

The Mirax Group contains two species—D. mirax, the type species of Dolophrosyne, as well as D. elongata Hering. The latter was described in Scoturopsis (Hering, 1925), then moved to Euscoturopsis (Bryk, 193) as its type species, and is here placed in Dolophrosyne as a new combination. It is hoped that D. elongata has finally found a home.

KEY TO MIRAX GROUP SPECIES

Plate 21

1. Forewing elongate; FW veins dark gray, concolorous with ground color; FW vein Rs1 short stalked with radial sector; valva long and narrow (fig. 222A); aedeagus narrow (fig. 222C); ♂ FW length  =  9.0 mm (E Peru)elongata (Hering)

FW relatively broad; FW veins brown, contrasting with dark gray ground color; FW vein Rs1 long stalked with remaining radials; valva short and wide (fig. 223A); aedeagus wide (fig. 223C); ♂ FW length  =  9.0–10.0 mm (SE Peru, NE Bolivia)mirax Prout

SPECIES INCLUDED AND MATERIAL EXAMINED

Dolophrosyne elongata (Hering), new combination

Figure 222; plate 21

Scoturopsis elongata Hering, 1925: 508.

Type Locality

Peru, Vilcanota, 3000 m, (Pr. Cuzco).

Type

Syntype ♂, leg. O. Garlepp, 1898 (ZMH).

Discussion

Dolophrosyne elongata, here transferred to Dolophrosyne with the new synonymy of Euscoturopsis, is the apparent sister species of D. mirax (pl. 21). The two are extremely similar in general appearance, but their male genitalia show major differences, especially in the size and shape of the valvae (figs. 222A, 223A).

I know D. elongata from four males—the two ZMH syntypes, and two examples at the NMW. All were collected near the turn of the 20th century, and all but one were captured in Peru at an elevation of approximately 3000 meters. One of the NMW males, originally from the Staudinger Collection, was taken at Mapiri, Bolivia. As Hering (1925) noted, the FW of Dolophrosyne elongata, which at that time he placed in Group 2 of Scoturopsis, exhibits only four radial veins. The vestiture of the head, thorax, and abdomen of D. elongata is completely dark chocolate brown, and there are essentially no markings on the wings (pl. 21). The labial palpus is short and porrect, and the eye is small.

Distribution

Peru (NMW, ZMH); Bolivia (NMW).

Dissected

Syntype ♂, Peru, Vilcanota, leg. Garlepp, ZMH (genitalia slide no. JSM-733).

Dolophrosyne mirax Prout

Figure 223; plate 21

Dolophrosyne mirax Prout, 1918: 403.

Type Locality

Peru, Huancabamba [“near Cerro de Pasco, E. Peru”], 6–10,000 ft.

Type

Holotype ♂ (BMNH).

Scoturopsis uniformis Hering, 1925: 508. New synonymy.

Type Locality

Bolivia, San Antonio, 1800 m (Yungas).

Type

Holotype ♂, leg. Garlepp, 1895–1896 (ZMH).

Discussion

Dolophrosyne mirax is known from only three specimens—the BMNH holotype, the ZMH holotype of uniformis Hering, and an AMNH male collected by Andy Brower (JSM-1022). In Prout's (1918) description of Dolophrosyne, he characterized the FW venation as having Rs2–Rs4 “very long stalked”. This implies that in D. mirax, the only included species at that time, all five FW radials are present. Having carefully studied wing venation in the D. mirax type and in the AMNH example, I can confirm that only four FW radials are present.

In addition to differences in their male genitalia (figs. 222, 223), D. mirax and D. elongata can be distinguished because the FW veins of D. mirax are lined with ochreous brown scales, whereas those of D. elongata are concolorous with the dark, blackish-brown ground color. Both species occur at fairly high elevations, up to 3000 meters, though this is well below the record altitude for Dioptinae (4200 m for Polypoetes aborta, above).

Study of the ZMH holotype of Euscoturopsis uniformis Hering, including genital dissection (JSM-1410), confirms this name to be a new synonym of Dolophrosyne mirax. Hering's type is identical to the type of mirax in wing pattern, wing venation, head and thoracic characters, and in male genitalia. With this synonymy, the range of D. mirax now extends from northern Peru south into Bolivia.

Distribution

Peru (AMNH, BMNH); Bolivia (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1409); ♂ Holotype of uniformis Hering, Bolivia, Yungas, San Antonio, 1800 m, 1895–1896, leg. Garlepp, ZMH (genitalia slide no. JSM-1410); ♂, Peru, Huanuco, Pachachupan, Paso Karpish, 2650–2750 m, 21 Dec 1996, leg. A.V.Z. Brower, AMNH (genitalia slide no. JSM-1022).

2. CONIADES GROUP

The two Coniades Group members are easily separated from Mirax Group species by their white FW and HW markings (pl. 22). No patterns occur in the Mirax Group (pl. 21). Male genitalia in the two groups also differ markedly. The most obvious differences include the long narrow socii and greatly elongate, abruptly narrowed valvae of the Coniades Group (figs. 224A, 225A). In contrast, the socii are short in members of the Mirax Group (figs. 222A, 223A), and the valvae are relatively broad.

KEY TO CONIADES GROUP SPECIES

Plate 22

1. Markings of FW and HW immaculate white; lateral margin of basal FW triangle sinuate; outer margin of HW with a blackish-brown band, extending from apex to tornus; valva apex boot shaped (fig. 225A); socii narrow, with a small ventral flange (SE Peru)sinuosa, sp. nov.

Markings of FW and HW creamy white; lateral margin of basal FW triangle straight; HW with a blackish-brown spot at apex; valva apex only slightly bent (fig. 224A); socii wide, with a large ventral flange (NE Ecuador)coniades (Druce)

SPECIES INCLUDED AND MATERIAL EXAMINED

Dolophrosyne coniades (Druce), new combination

Figures 221, 224, 226; plate 22 [EX]

Trochiodes coniades Druce, 1893: 309, pl. 21, fig. 21.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♂, leg. C. Buckley (BMNH; abdomen missing).

Discussion

Here, coniades is transferred from Tithraustes to Dolophrosyne. Its genitalia (fig. 224) differ somewhat from other members of Dolophrosyne, but absence of a FW radial vein (fig. 221F), among other characters, indicates that the species belongs here. It certainly was misplaced in Tithraustes (figs. 3, 354): The male FW of D. coniades lacks the stridulatory organ found in Tithraustes (fig. 268G); the eye is small (fig. 221D), instead of large and bulging (fig. 268E); and the male antenna is ciliate, rather than being bipectinate.

Less than 15 years ago, this species was known solely from two syntype males at the BMNH. My first experience with D. coniades came when I captured a small series in October 1988, while day-collecting near Baeza, Ecuador. Subsequent trips to that same locale (fig. 226) have shown that the moth is extremely common in its cloud-forest habitat. Adults can be seen in the late morning and late afternoon, flying next to gravel roads (pl. 43B, D) and along forest trails; dense thickets of Chusquea (pl. 44C, E, F) invariably grow in the immediate vicinity wherever D. coniades adults are found. The caterpillars were reared by Dyer et al. (2009) on C. scandens (table 4).

Distribution

Ecuador (AMNH, BMNH).

Dissected

♂, Ecuador, Napo, 5.5 km S Baeza on Baeza-Tena Road, 5800 ft, 30 May 1993, leg. J.S. Miller and E. Tapia, AMNH (genitalia slide no. JSM-695); ♂, Ecuador, Napo, Yanayacu Biol. Stn., 5 km W Cosanga on Cosanga-Río Aliso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 4 Mar 2006, day collecting, leg. J.S. Miller, AMNH (genitalia slide no. JSM-1657); ♂, Ecuador, Napo, Yanayacu Biological Station, 5 km W Cosanga, Cosanga-Río Alíso Rd, 2200 m, 25 Sep 2004, day-collecting, leg. J.S. Miller and E. Tapia, AMNH (wing slide no. JSM-1449); ♀, Ecuador, Napo, Yanayacu Biol. Stn., 5 km W Cosanga on Cosanga-Río Aliso Rd., 00°35.9′S, 77°53.4′W, 2163 m, 1 Mar 2006, day collecting, leg. J.S. Miller & E. Tapia, AMNH (genitalia slide no. JSM-1658); ♀, Ecuador, Napo, 52 km N Tena on Tena-Baeza Road, 1980 m, 24 May 1993, leg. J.S. Miller, on composite flowers, AMNH (genitalia slide no. JSM-696).

Dolophrosyne sinuosa, new species

Figures 225, 226; plate 22

Diagnosis

Dolophrosyne sinuosa is the sister species of D. coniades. The two taxa have similar wing patterns and are approximately the same size (pl. 22), but are easily separated: The white areas of the FW and HW are cream colored in D. coniades, but immaculate white in D. sinuosa; the conspicuous white, basal triangle on the FW anal margin has a straight, oblique lateral margin in D. coniades, whereas this margin is sinuate oblique in D. sinuosa (thus giving the species its name); the HW is white with a large, blackish-brown spot near the apex in D. coniades, this spot terminating posteriorly at vein CuA1, whereas in D. sinuosa the white HW bears a wide, blackish band running along the outer margin from the apex to the tornus. Male genitalia in the two species show similar construction, but differ in numerous respects, such as the shape of Tg8 (figs. 224C, 225B), as well as the configuration of the uncus, socii, and valva apex (figs. 224A, 225A).

Description

Male. Forewing length  =  11.0–11.5 mm. Head: Labial palpus thin, relatively short, curving strongly upward but reaching only to immediately above clypeus; Lp1 curved, loosely covered with white scales, a loose ventral fringe of longer scales; Lp2 shorter than Lp1, ventral surface covered with short white scales, dorsal surface dark brown; Lp3 short, quadrate, white ventrally, dark brown above; clypeus scaleless; frontal scales pointing downward from below antennal bases, horizontally and mesally from sides, and slightly upward from clypeus, all coalescing near center; central area of front dark brown, lateral areas with long, white scales, pointing toward midline; occiput tightly covered with short, anteriorly directed scales, dark brown in upper two-thirds, white in lower third; eye small, ovoid, completely surrounded by a scaleless area, narrow anteriorly and posteriorly, wide above, gena broadly scaleless; surface of eye sparsely covered with extremely short setae; vertex with long, dark coppery brown, anteriorly pointing scales, a narrow band of white behind each antennal base; antenna subserrate, each annulation with setae on raised ridges in two transverse whirls; scape glossy dark brown; dorsum of antennal shaft glossy brown.

Thorax: Legs, including tibial spurs, gray to gray-brown on outer surfaces, white on inner one; tarsus gray-brown with a few scattered cream-colored scales on inner surfaces; pleuron covered with a mixture of gray and long white scales; patagium with a fan of long, erect white scales on anterior surface, gray scales posteriorly; tegula short, wide, covered with a mixture of white and dark gray scales, scales longest distally; dorsum dark gray-brown, with a pair of wide, white longitudinal bands on either side of midline; tympanum large, open, metepimeron with an extremely shallow scaleless depression; tympanal membrane extremely large, almost round, oriented lateroposteriorly.

Forewing: (Dorsal) Triangular, somewhat narrow, outer margin gently convex (pl. 22); only four radials present; ground color dark charcoal gray, with a large white triangle extending from wing base to slightly less than halfway out; posterior side of triangle contiguous with FW anal margin, anterior side running through DC immediately behind radius, lateral side running obliquely from central area of DC to anal margin, joining anal margin approximately three-fourths out on wing; lateral margin of white triangle sinuate, indented inward at base of CuA2, and again as margin crosses 1A+2A; cubitus scaleless as it passes through white triangle. (Ventral) Identical to dorsal surface, except ground color slightly glossier charcoal gray.

Hind wing: (Dorsal) Broadly rounded (pl. 22); white from base to beyond distal margin of DC, white extending past forks of Rs+M1 and M3+CuA1; outer margin with a wide, dark charcoal-gray band extending from apex to tornus, widest at wing anterior margin, narrowed posteriorly; posterior portion of white area with a dusting of dark gray scales distally between CuA2 and tornus; anal margin with long white scales and a few scattered dark gray scales. (Ventral) Identical to dorsal surface, except anal margin with more dark gray scales.

Abdomen: Dorsum evenly covered with glossy, dark gray scales; venter white from base to middle of St8, distal half of St8 dark gray.

Terminalia (fig. 225): Tg8 lightly sclerotized, longer than Tg7, almost as wide as Tg7 anteriorly, then gradually narrowed distally; anterior margin of Tg8 simple, posterior margin convex; St8 wider and slightly shorter than Tg8, roughly ovoid, widest near middle, lateral margins convex, then abruptly narrowing in distal third; anterior margin of St8 gently convex, with an extremely short, wide mesal apodeme, posterior margin transverse, minutely serrate; socii/uncus complex wide, broadly attached to ring; uncus short, extremely wide at base, gradually rounded above; socii extremely long, widest at base then abruptly narrowing, with a small bladelike ventral flange two-thirds out, apices minutely spatulate; tegumen much taller than vinculum, greatly expanded laterally in lower three-quarters, then abruptly narrowed above; vinculum short, narrow, ventral margin slightly concave; saccus narrow, folding upward to enclose lower angles of valvae, dorsal margin convex; juxta forming a deeply concave, cuplike structure; valva sclerotized, widest at base, then abruptly narrowed in distal third; BO absent; costa narrow, sides parallel; apex of valva sharply upturned at an almost 90° angle, forming a foot-shaped structure with a sclerotized flange at its heel; inner surface of valva with a few long setae along ventral margin; transtillar arms somewhat wide, sides roughly parallel, curved slightly upward from base, then meeting at midline to form a prominent, concave, U-shaped sclerite above aedeagus; aedeagus small, widest in basal two-thirds, distal portion narrow, slightly sinuate; apex of aedeagus simple; vesica an elongate, narrow tube, its surface evenly covered with minute, denticulate cornuti.

Female. Unknown.

Etymology

This species name is taken from the Latin word, sinuosus, meaning “many bends”. It refers to the sinuate lateral margin of the white FW triangle in this taxon, one of the most obvious features distinguishing it from D. coniades, where the lateral margin of the triangle is straight (pl. 22).

Distribution

Dolophrosyne sinuosa is known exclusively from the type locality, in the Cosñipata Valley (1650 m) east of Cuzco, Peru (fig. 226). Its sister species, D. coniades, is endemic to the vicinity of Baeza, Ecuador (fig. 226)—over a thousand miles north—at elevations of roughly 2000 meters. The intriguing possibility exists that additional undescribed Coniades Group species await discovery in cloud forests along the eastern slopes of the Andes in Colombia, Ecuador, Peru, and Bolivia.

Discussion

This taxon was one of the most exciting finds on a trip to southeastern Peru in October 2005. I collected all known specimens of D. sinuosa (7♂♂) on a single afternoon, between 2:00 p.m. and 4:30 p.m., along a stretch of gravel road running above the Río Cosñipata. The moths were caught less than 100 m apart, with five of them flying at a single spot less than 10 m wide. Chusquea, the host plant of D. coniades (table 4), was abundant at that location. Some of the males seemed to be hovering around the Chusquea plants, perhaps searching for females. However, no females of D. sinuosa were either collected or observed. This parallels the situation for D. coniades, where females are exceptionally rare compared to males.

Holotype

Male (pl. 22). Peru: Cuzco: Cosñipata Valley, Pillahuata-Pilcopata Rd., Puente Unión, 4 km W Río San Pedro, 1650 m, S13°04′03″, W71°34′02″, 27 Oct 2005, leg. J.S. Miller, 2:00 p.m. The type is at the AMNH.

Paratypes

Peru: Cuzco: 4♂♂, Cosñipata Valley, Pillahuata-Pilcopata Rd., Puente Unión, 4 km W Río San Pedro, 1650 m, S13°04′03″, W71°34′02″, 27 Oct 2005, leg. J.S. Miller, 4:30 p.m. (genitalia slide no. JSM-1553); 2♂♂, [same data], 2:00 p.m.

Other Specimens Examined

None.

Dissected

1♂.

SCOTUROPSIS HERING, 1925

Figures 227Figure 228Figure 229Figure 230231; plate 22

Figure 227

Morphology of Scoturopsis (♂♂). A, head of S. franclemonti, sp. nov., lateral view; B, head of S. coras, lateral view; C, S. coras wings; D, S. basilinea wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f227.gif

Figure 228

Paratype ♂ genitalia of Scoturopsis basilinea (JSM-1457). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f228.gif

Figure 229

Genitalia of Scoturopsis (♂ JSM-532, ♀ JSM-1021). A, ♂ of S. coras; B, aedeagus of S. coras; C, ♂ St8 of S. coras; D, ♂ Tg8 of S. coras; E, ♀ of S. flaviplaga (illustration by J.S. Miller).

i0003-0090-321-1-1-f229.gif

Figure 230

Paratype ♂ genitalia of Scoturopsis franclemonti, sp. nov. (JSM-1018). A, genitalia; B, aedeagus; C, Tg8; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f230.gif

Figure 231

Holotype ♂ genitalia of Scoturopsis unifascia (JSM-1411). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f231.gif

Scoturopsis Hering, 1925: 508. Type species: Scoturopsis basilinea Hering, 1925 (by original designation).

Diagnosis

Three genera—Scoturopsis, Dolophrosyne, and Xenormicola (pls. 21, 22)—form a tight clade, exhibiting roughly the same set of external features: the male antennae lack pectinations, but are densely covered with long setae; the labial palpi are short (figs. 221A, 221D, 227A, 227B, 232A, 232B); and the FW DC is long, without a stridulatory organ (figs. 221F, 227C, 227D, 232C). An important apomorphic feature sets Scoturopsis apart from Dolophrosyne, Xenormicola, and all other Dioptinae: in Scoturopsis species, the frons is swollen, bulging forward (fig. 227A, B).

Scoturopsis coras and S. flaviplaga (pl. 22) have wing patterns reminiscent of Stenoplastis (pl. 23), and all exhibit ciliate male antennae, so these taxa could potentially be confused. However, males of the latter possess a FW stridulatory organ (fig. 262H), whereas a stridulatory organ is absent in Scoturopsis (fig. 227C, D). Females can be separated because there is a large, conspicuous corethrogyne in Stenoplastis (fig. 263B–F), but not in Scoturopsis.

Redescription

Male. FW length  =  10.0–13.5 mm. Head (fig. 227A, B): Labial palpus short, curving upward to immediately above clypeus; Lp1 curved, wide, with a loose fringe of long scales below; Lp2 extremely short, much shorter than Lp1, with a ventral fringe of long scales; Lp3 minute, conical or quadrate; frons sclerotized, bulging forward; scales of front short, apressed, pointing upward from clypeus in lower half, toward midline in upper half; eye small, round, completely surrounded by a scaleless band, wider between antennal base and upper margin of eye; a wide, quadrate scaleless area in anterior portion of gena between proboscis and lower margin of eye; postgena extremely wide, bulging laterally; scales of vertex short to moderately long, pointing anteriorly; antenna ciliate, ventral surface densely covered with long setae arranged in two transverse rows; antennal shaft evenly scaled above.

Thorax: Epiphysis short to moderately long, not extending beyond apex of tibia; tegula small and wide, shorter than one-half length of mesoscutum, constricted in lower fifth, ventral angle acute; metathoracic tympanum open, cavity extremely shallow, membrane almost flush with surface of metepimeron; tympanal membrane extremely large, ovoid to subtriangular, oriented laterally.

Forewing (fig. 227C, D; pl. 22): Relatively broad; five radial veins present; Rs1 stalked with Rs2–Rs4; veins Rs2–Rs4 in the pattern [2+3]+4, rarely 2+[3+4] (S. basilinea); stridulatory organ absent; DC longer than one-half FW length; veins M3 and CuA1 long stalked; ground color dark brown to chocolate brown, veins lighter, reddish brown; pattern variable, with a basal streak behind DC and an ovoid fascia beyond DC (S. coras, S. franclemonti), with a diffuse, light yellow triangle along posterior margin and a diffuse fascia beyond DC (S. basilinea), or with an oblique, paddle-shaped transverse band (S. unifascia).

Hind wing (fig. 227C, D; pl. 22): Large and full, outer margin rounded; M3 and CuA1 long stalked; pattern variable; ground color brown to dark brown, central area concolorous (S. basilinea, S. unifascia) or broadly yellow (e.g., S. franclemonti).

Abdomen: Short or moderately long, narrow, Tg8 longer than St8, with scales of Tg8 forming a short, acute distal tuft above.

Terminalia (figs. 228, 229A–D, 230, 231): Tg8 moderately long, tapered posteriorly, anterior margin with a pair of short, blunt apodemes on either side of midline or simple; posterior margin of Tg8 variable, sometimes sclerotized (S. basilinea), usually with a small U-shaped mesal excavation, in S. unifascia forming a narrow, rounded central process; St8 much shorter than Tg8, gradually tapered distally, anterior margin either sinuate with a shallow mesal excavation, or gently convex; lateral margins of St8 expanded outward in S. franclemonti and S. basilinea, the latter with shallow posterolateral pockets; socii/uncus complex relatively large, with a narrow attachment to tegumen; uncus moderately long, variable in shape, apex acute, rarely spoon shaped (S. unifascia), sometimes with a tiny ventral process below apex (S. unifascia, S. basilinea); socii long, curving upward but not extending beyond apex of uncus, shape variable, apices spatulate or acute; tegumen taller than vinculum, wide in lower third, then becoming narrow above; vinculum narrow and short; saccus small, lower margin of genitalia transverse (S. franclemonti), concave (S. basilinea) or convex (S. coras); valva long and narrow, mostly sclerotized; BO variable in size, fairly large in S. unifascia, occupying roughly one-third of valva with lateral margins curled anteriorly, others with BO small and sclerotized bearing few pleats (S. basilinea, S. franclemonti), or sometimes completely absent (S. coras, S. flaviplaga); costa of valva wide (e.g., S. unifascia) or apparently absent (e.g., S. basilinea); apex of valva sclerotized and convex, occasionally simple (S. coras); arms of transtilla extremely narrow, arching sharply upward near base, then curving downward, meeting at midline to form a long, narrow sclerite; aedeagus short to moderately long, wider at base; apex of aedeagus variable, simple (S. coras), with a ventral tooth (S. basilinea, S. unifascia) or with unusual lateral processes (S. franclemonti); vesica short and small, rarely wider than aedeagus (S. unifascia); cornuti absent.

Female (known for S. coras and S. flaviplaga only). FW length  =  11.0–12.5 mm. Head, thorax, and wing characters similar to male, except: labial palpus thinner; wings longer and broader, much lighter in color, thinly scaled, semihyaline; antenna bearing 4–5 setae per annulation, not densely covered with setae; frenulum comprising three bristles.

Terminalia (fig. 229E): Tg7 long, as wide as Tg6, anterior margin simple, posterior margin gently convex, lateral margins slightly excavated near middle; St7 long, but shorter and much narrower than Tg7, anterior margin simple, convex, posterior margin simple, slightly concave; St7 widest near posterior margin; Tg8 forming a short, wide, lightly sclerotized, transverse band extending laterally to the base of each anterior apophysis; AA extremely short and wide, acute distally; A8 pleuron membranous; PP thin and straight, moderately long; PA large, membranous, posterior margin convex, with a shallow dorsal hump; PVP lightly sclerotized, short and somewhat wide, convex, posterior margin simple (S. coras) or with a mesal notch (S. flaviplaga); DB extremely short, lightly sclerotized, ostium forming a transverse oval; CB small, completely membranous, narrowed abruptly in basal half; signum small or absent; DS arising ventrolaterally on right side, at junction of narrow portion of CB and DB.

Distribution

As is typical of the broader clade to which they belong (Clade 14; fig. 7) Scoturopsis species are cloud-forest endemics. Scoturopsis is strictly Andean, occurring from central Colombia south to northern Bolivia. Like Dolophrosyne, the genus is apparently restricted to the eastern slope, with one possible exception: Scoturopsis flaviplaga is from the area of Tolima in the Central Cordillera of Colombia. While not technically a west-facing locale, Tolima differs from the strictly eastern exposures on which Dolophrosyne and other Scoturopsis are found.

Biology

In May 2005, Dyer et al. (2009) discovered caterpillars of Scoturopsis coras at Yanayacu Biological Station (Napo, Ecuador) feeding on Chusquea (Poaceae), a ubiquitous cloud forest bamboo genus containing an estimated 180 species, distributed from Mexico south to Argentina and Chile (Clark, 1995). Over 30 species are endemic to Ecuador (Clark et al., 2007). Chusquea is particularly common in disturbed habitats at altitudes between 2000 and 3000 meters, growing along roadsides and trails (pl. 44C, E, F). Three dioptine genera have now been recorded from ChusqueaXenomigia, Dolophrosyne, and Scoturopsis (table 4). All of these moth taxa co-occur at Yanayacu.

In October 2004, Elicio Tapia and I collected S. coras in fairly large numbers at Yanayacu, flying during the day along roadsides and forest trails near stands of its bamboo host. The moths were also observed resting on moist gravel road surfaces, presumably drinking. Adults appear to be active in late afternoon between the hours of 4 p.m. and 6 p.m. Dolophrosyne coniades was observed at the same time and in the same places. On an earlier trip to Ecuador (May 1993), I captured two females of S. coras feeding on flowers during the day along the banks of the Río Quijos near Baeza, a site less than 20 km from Yanayacu.

Discussion

At first glance, the genus Scoturopsis constitutes a somewhat ragtag collection of taxa; their wing patterns are quite different (pl. 22). However, male genital morphology unites these species. It is hoped that the classification proposed here is an improvement on previous arrangements, but it should nevertheless be considered provisional. As is the case with Dolophrosyne, Scoturopsis species are extremely rare; only S. coras and S. flaviplaga are known from more than two specimens. Discovery of Scoturopsis females may provide characters that can shed more light on the group's taxonomy.

Hering (1925) described Scoturopsis with five included species, designating S. basilinea Hering as the type. Bryk (1930) subsequently erected the genus Euscoturopsis, placing three of Hering's taxa there and leaving only two species in Scoturopsisbasilinea and seitzi Hering. My classification is considerably different (appendix 2). I place S. seitzi (pl. 25) incertae sedis, and further suggest that the species should be removed from the Dioptinae altogether, perhaps to the Lymantriidae. That leaves only S. basilinea. However, to Scoturopsis I here add three species formerly in Stenoplastiscoras (Druce), flaviplaga (Dognin), and unifascia (Hering)—presumably placed there because of their ciliate male antennae (Prout, 1918). A fifth Scoturopsis species, S. franclemonti, is newly described.

KEY TO SCOTUROPSIS SPECIES (MALES)

Plate 22

1. Forewing with an elongate, narrow, yellow or orange basal dash along anal fold, extending outward almost to CuA2; HW variable, often with a yellow central area of varying size; Lp1 light brown to creamy white; FW length  =  10.0–12.5 mm2

FW without a basal dash, with a light yellow, hourglass-shaped transverse band extending from Sc to near tornus; HW completely brown; Lp1 light orange-yellow; FW length  =  13.5 mm (N Bolivia)unifascia (Hering)

2. Hind wing central area whitish yellow to orange; FW with a conspicuous, transverse ovoid, light yellow fascia beyond DC; FW basal dash not surrounded by brown scales3

HW completely dark brown; FW with a small, inconspicuous fascia beyond DC; FW basal dash surrounded by dark brown scales (N Bolivia)basilinea Hering

3. Hind wing central area whitish yellow to lemon yellow, with a wide brown marginal band; front dark brown, a transverse band of creamy white to light yellow scales above clypeus; valva simple, not concave (fig. 229A), BO completely absent; aedeagus without spinose processes near apex (fig. 229B)4

HW broadly orange-yellow, with a dark brown marginal band, widest at apex; front uniformly chocolate brown; valva broadly concave (fig. 230A), BO bearing a pair of ridges near base; aedeagus with a pair of spinose processes near apex (fig. 230B) (SE Peru)franclemonti, sp. nov.

4. Forewing and HW ground color dark chocolate brown, with lemon yellow markings; base of tegula orange-yellow (E central Colombia)flaviplaga (Dognin)

FW and HW ground color olive brown to dark brown, with creamy white to light yellow markings; base of tegula light yellow (NE Ecuador)coras (Dognin)

SPECIES INCLUDED AND MATERIAL EXAMINED

Scoturopsis basilinea Hering

Figure 227D, 228; plate 22

Scoturopsis basilinea Hering, 1925: 508; fig. 68k.

Type Locality

Bolivia, La Paz, Río Tanampaya.

Type

Holotype ♂, leg. Garlepp, 1894 (ZMH).

Discussion

This is the type species of Scoturopsis. Having carefully examined two paratypes of S. basilinea as well as the holotype, I can verify Hering's (1925) statement that the FW has the “fifth radial present” (fig. 227D). I know this species from four specimens: the ZMH type, two BMNH paratypes (JSM-732, 1457), and a fourth example at the USNM. Its male genitalia (fig. 228) indicate a close relationship with S. franclemonti, sp. nov. (fig. 230). Among other synapomorphies, both species posses a pair of thornlike processes near the apex of the aedeagus.

A single USNM specimen from Cillutincara, Bolivia (JSM-1455) represents an undescribed species sympatric with, and closely related to, S. basilinea. It differs in having extensive orange-brown in the HW basal area. Its male genitalia are vastly different. Females are unknown for both taxa.

Distribution

Bolivia (BMNH, USNM, ZMH).

Dissected

Paratype ♂, Bolivia, Cuesta von Cillutincara, 3000–3200 m, leg. Fassl, BMNH (genitalia slide no. JSM-732, wing slide no. JSM-1451); Paratype ♂, Bolivia, Tanampaya, leg. Garlepp, BMNH (genitalia slide no. JSM-1457).

Scoturopsis coras (Druce), new combination

Figures 227B, 227C, 229A–D; plate 22

Trochiodes coras Druce, 1893: 310.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♂ (BMNH).

Stenoplastis biplaga Dognin, 1902: 475.

Type Locality

“Miss. cathol.”, Ecuador.

Type Locality

Syntype ♂ (USNM type no. 30953).

Discussion

This species was formerly placed in Stenoplastis (Bryk, 1930). Judging from my dissections, D. coras and D. biplaga, both from Ecuador, are conspecific, as Prout (1918) and subsequent authors had assumed (Hering, 1925). On the other hand, a Colombian taxon—flaviplaga Dognin—formerly treated as a second synonym of coras (Bryk, 1930), differs slightly from these. Its male genitalia differ in the shape of Tg8 and St8, as well as in configuration of the uncus and socii. The wings of S. flaviplaga (pl. 22) show a darker brown ground color and the marking are more yellow. On these grounds, I here raise the latter to species status.

The provenance of the S. coras syntype will never be known with accuracy, but “Sarayacu”, a lowland Amazonian site, is undoubtedly incorrect (see Pseudoricia, Distribution). Scoturopsis coras is a common member of the diurnal moth community in the areas surrounding Baeza and Cosanga, Ecuador (Napo Province), but has not been captured elsewhere. Caterpillars were reared at Yanayacu Biological Station on Chusquea scandens in the Poaceae (table 4).

Distribution

Ecuador (AMNH, BMNH, USNM).

Dissected

♂, Ecuador, Baños, BMNH (genitalia slide no. JSM-532); ♂ syntype of biplaga, USNM (genitalia slide no. JSM-1020); ♂, Ecuador, Napo, Yanayacu Biological Station, 5 km W Cosanga, Cosanga-Río Alíso Rd, 2200 m, 25 Sep 2004, day-collecting, leg. J.S. Miller and E. Tapia, AMNH (wing slide no. JSM-1448); ♂, Ecuador, Napo, Yanayacu Biological Station, 5 km W Cosanga, Cosanga-Río Alíso Rd, 2200 m, 25 Sep 2004, day-collecting, leg. J.S. Miller and E. Tapia, AMNH (genitalia slide no. JSM-1456, wing slide no. JSM-1453); ♀, Ecuador, Napo, 7.7 km E Papallacta on the Río Chalpi Grande, 8600 ft, 27 May 1993, leg. J.S. Miller, AMNH (genitalia slide no. JSM-747).

Scoturopsis flaviplaga (Dognin), new combination, revised status

Figure 229E; plate 22

Scotura flaviplaga Dognin, 1911b: 6.

Type Locality

Colombia, El Eden, 2500 m.

Type

Syntype ♂, leg. Fassl, Dec 1909 (USNM type no. 30954).

Discussion

Scoturopsis flaviplaga (Dognin), formerly a subspecies of S. coras Druce (Bryk, 1930), is here placed in Scoturopsis for the first time along with coras, and is raised back to species status following the original author (Dognin, 1911b). In addition to genital traits, this species can be distinguished from S. coras in having darker yellow wing markings (pl. 22). Dolophrosyne flaviplaga is known exclusively from the Central Cordillera of Colombia in the area of Tolima, whereas S. coras is from the Oriente of Ecuador. Only two institutions, the BMNH and USNM, house specimens of S. flaviplaga. As with so many other Dioptinae, the vast majority of this material was collected by Anton Fassl.

Distribution

Colombia (BMNH, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-1019); ♀, Colombia, Monte Tolima, Central Cordillera, 3200 m, leg. Fassl, USNM (genitalia slide no. JSM-1021, wing slide no. JSM-1452).

Scoturopsis franclemonti, new species

Figures 226, 227A, 230; plate 22

Diagnosis

Scoturopsis franclemonti exhibits a more contrasting and colorful wing pattern than other Scoturopsis species (pl. 22). However, S. franclemonti shows all the characters of the genus, an important one being the bulging frons (fig. 227A). The FW pattern of S. franclemonti shows the basic pattern elements of S. flaviplaga. Both exhibit a chocolate-brown ground color with a yellow or yellowish orange basal dash, as well as an ovoid, light yellow fascia immediately beyond the DC. However, the HW of franclemonti is unique among Scoturopsis in having a broad, yellow-orange central area surrounded by a dark chocolate-brown margin.

Description

Male. Forewing length  =  11.0–11.5 mm. Head (fig. 227A): Labial palpus short, curving upward to well below middle of front, Lp2 much shorter than Lp1, Lp3 small, conical; Lp1 covered with cream-colored scales, a ridge of longer scales below; Lp2 light brown on lateral surfaces, creamy yellow on inner ones; Lp3 light brown; front bulging anteriorly, bearing short, tightly packed, light brown to brown scales; scales pointing horizontally toward midline, coming together in a small scaleless area near center of front; occiput brown in upper two-thirds, cream colored in lower one-third; eye small, completely surrounded by a narrow, scaleless band; vertex covered with brown scales, a few scattered cream-colored scales near midline; antenna ciliate; antennal scape and dorsum of shaft brown.

Thorax: Coxae of pro- and mesothoracic legs cream colored, femur light brown on outer surface, cream colored on inner one, tibia and tarsus mostly light brown, with a few scattered cream-colored scales; metathoracic leg, including spurs, mostly cream colored, with scattered light brown areas; pleural region covered with long, cream-colored scales and shorter, light brown ones; patagium with long, brown scales; central area of tegula bearing long, cream to light creamy yellow scales, fringed on outer margins with long brown to light brown hairlike scales; dorsum brown, with a few scattered creamy yellow scales; tympanum not enclosed; tympanal membrane large, almost round, fully exposed, facing posterolaterally.

Forewing: (Dorsal) Ground color rich, dark chocolate brown (pl. 22); a clearly defined, light yellow-orange dash along anal fold from base to short of CuA2, its anterior margin touching cubitus and its posterior margin falling slightly short of 1A+2A; an ovoid, light yellow fascia immediately beyond DC, its anterior margin touching base of Rs1–Rs4 and its posterior margin touching fork of M3+CuA1. (Ventral) Similar to upper surface except ground color lighter; basal dash brighter yellow, slightly larger than on upper surface, its margins more diffuse.

Hind wing: (Dorsal) Central area broadly yellow-orange (pl. 22); outer margin broadly banded with dark chocolate brown, band widest near apex, slightly narrower near lower angle; anal margin broadly light brown, inside edge of band a mixture of yellow-orange and brown scales. (Ventral) Yellow-orange central area and brown outer margin similar to upper surface, colors slightly less intense (pl. 22); anterior margin yellow-orange from base to near apex; anal margin light yellow to orange.

Abdomen: Dorsum chocolate brown; a cream-colored lateral line along pleuron from base to slightly short of terminus; venter cream colored to buff.

Terminalia (fig. 230): Tg8 long, widest near anterior margin, gradually tapered distally, terminating in a rounded mesal process; dorsum of Tg8 curved slightly upward, anterior margin with a pair of short, widely spaced apodemes near lateral angles; St8 much shorter than Tg8, lateral margins expanded in distal two-thirds, then gradually narrowing posteriorly; anterior margin of St8 with an extremely short, wide apodeme with a shallow mesal excavation; posterior margin of St8 with an extremely deep, quadrate mesal excavation; socii/uncus complex large, thinly attached to ring; uncus large, laterally compressed, dorsum arching upward, apex curving downward to form a truncate point; socii long, widest at base, curving slightly upward, narrowly spoon shaped and finely setose at apices; tegumen much taller than vinculum, narrow at dorsum, widened below; vinculum extremely short, narrow; saccus small, forming a narrow, horizontal band below valva bases; juxta extremely small, U-shaped; lateral surface of valva sclerotized, inner surface membranous; BO small, comprising a few short pleats and long, curved androconia arising from ventral margin near valva base; area of BO with a pair of short, transverse ridges on inner surface, upper ridge emarginate, bearing a dense brush of setae; costa narrow, short, extending less than halfway out from valva base; apex sclerotized, somewhat cup shaped; inner surfaces of valva with long, sparsely scattered setae; transtillar arms extremely long, thin, arched sharply upward near base, joining at midline to form a long, anteriorly directed strut; aedeagus relatively short, thin, widest in basal third; a pair of long, slightly curved, thornlike processes arising near apex of aedeagus; vesica short, no wider than aedeagus, cornuti absent.

Female. Unknown.

Etymology

This species is named in honor of John G. Franclemont (see Dedication). It is Franclemont who inspired me to become a systematist. Furthermore, he is the person who suggested the Dioptinae as a group for study. Little did I know that his casual suggestion would lead to nearly 30 years of intensive research. It is Franclemont to whom this paper is dedicated, as a testament to his incredible ability to foster love for the study of Lepidoptera in the many students who followed in his footsteps.

Distribution

Only two specimens of Scoturopsis franclemonti are known—both from the eastern Andes of southern Peru near the city of Cuzco (fig. 226). One was collected at Machu Picchu (2700 m), and the other was captured near the small town of Alfamayo (2400 m), roughly 30 km E of Machu Picchu.

Discussion

This moth shows all the characters of Scoturopsis and undoubtedly belongs in the genus. Among described Scoturopsis species, the male genitalia of S. franclemonti (fig. 230) most closely resemble those of S. basilinea (fig. 228). However, they differ in a multitude of ways, including the shapes of Tg8, St8, the socii/uncus complex and the valvae.

Holotype

Male (pl. 22). Peru: Cuzco: Alfamayo, 2400 m, 13°04′S, 72°24′W, 22 Feb 1996, leg. Brower/Lamas/Sime/Snyder. The type is deposited at the AMNH.

Paratypes

Peru: Cuzco: 1♂, Machu Picchu, 22 Mar 1947, leg. J.C. Pallister (AMNH; genitalia slide no. JSM-1018).

Other Specimens Examined

None.

Dissected

1♂.

Scoturopsis unifascia (Hering), new combination

Figure 231; plate 22

Stenoplastis unifascia Hering, 1925: 518.

Type Locality

Bolivia (“La Paz?”), Cillutincara, 3000 m.

Type

Holotype ♂, leg. Garlepp, Jan 1896 (ZMH).

Discussion

This taxon, known exclusively from the male holotype (pl. 22; fig. 231), has long been a mystery. It exhibits a confusing set of wing pattern and body characteristics. However, after careful study, including dissection of the type, I have concluded that unifascia—formerly in Stenoplastis (Hering, 1925; Bryk, 1930)—belongs in Scoturopsis. The moth exhibits the following characters of Scoturopsis: male antenna ciliate; labial palpus short, porrect, Lp2 shorter than Lp1; eye small; tympanum large, open, membrane facing posterolaterally. Importantly, unifascia also exhibits one of the key synapomorphies for Scoturopsis, a bulging frons (see fig. 227A, B).

The male genitalia of S. unifascia (fig. 231) share certain features with those of S. basilinea (fig. 228), but alternatively, show similarities to the genitalia of Xenormicola (figs. 233, 234) as well. For example, in S. unifascia and Xenormicola the socii are long, curving strongly upward. Furthermore, in these taxa the uncus bears a small, wedge-shaped ventral process. Features of the aedeagus and eighth segment also suggest that S. unifascia might be most closely related to Xenormicola. While acknowledging that S. unifascia may be misplaced in Scoturopsis, I have chosen to assign it here nevertheless, in large part because of its bulging frons. The frons of Xenormicola is flat (fig. 232A, B).

Two characters of S. unifascia are unique for Scoturopsis. First, the light yellow, club-shaped FW cross band (pl. 22) is not found elsewhere in the genus. Furthermore, in other Scoturopsis species the abdominal venter is concolorous with the rest of the abdomen, or is slightly lighter, whereas in S. unifascia the dorsum is dark brown, but the venter is buff colored.

Distribution

Bolivia (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1411).

The following species has been removed from Scoturopsis: seitzi Hering (1925: 508) to incertae sedis

XENORMICOLA HERING, 1928

Figures 232Figure 233234; plate 22

Figure 232

Morphology of Xenormicola (♂♂). A, head of X., sp. (Cuzco), lateral view; B, head of X. extensa, lateral view; C, X. extensa wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f232.gif

Figure 233

Male genitalia of Xenormicola extensa (JSM-1812). A, genitalia; B, aedeagus; C, St8, D, Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f233.gif

Figure 234

Holotype ♂ genitalia of Xenormicola prouti Hering (JSM-1454). A, genitalia; B, aedeagus; C, Tg8; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f234.gif

Xenormicola Hering, 1928: 271. Type species: Xenormicola prouti Hering, 1928 (by original designation).

Diagnosis

Xenormicola (pl. 23), containing two species described by Hering (1925)—X. prouti and X. extensa—is closely related to Dolophrosyne and Scoturopsis (pls. 21, 22). Among other traits, it shares with them the presence of short, porrect labial palpi (e.g., figs. 221A, 227B, 232A, B) and ciliate male antennae. There is no FW stridulatory organ (fig. 232C). Xenormicola species can be recognized by the light brown FW with a long, faint, light-colored basal dash between the cubitus and 1A+2A, and by a large, rounded, gray-brown HW. When their male genitalia are examined, X. prouti and X. extensa show an unusual configuration of the valva (fig. 233A, 234A). Eye size (fig. 232A, B) and wing venation vary within Xenormicola; X. extensa shows only four FW radials (fig. 232C), whereas X. prouti has five.

Xenormicola bears a general resemblance to Phryganidia (pl. 8), but the two are impossible to confuse. The male antennae of the latter are widely bipectinate, whereas in Xenormicola they are densely ciliate. Furthermore, their geographical distributions are completely different, with Phryganidia being found from Guatemala north to Oregon, but Xenormicola being endemic to the Andes of Peru and Bolivia.

Redescription

Male. FW length  =  16.0 mm. Head (fig. 232A, B): Labial palpus short, porrect, curving upward, barely reaching above clypeus; Lp1 short, curved upward, loosely scaled; Lp2 thin, slightly longer than Lp1; Lp3 short; scales of front moderately long, pointing dorsomedially; eye large and bulging outward (X. prouti), or small (X. extensa); scales of vertex loosely arranged, pointing anteriorly; antenna ciliate, ventral surface densely covered with long, curved setae arranged in two transverse rows; dorsum of antennal shaft evenly scaled.

Thorax: Epiphysis short, flat, acute at apex, less than one-half length of tibia; tibia extremely long; tegula short, less than one-half length of mesoscutum; metathoracic tympanum exposed, in a shallow cavity, membrane almost flush with surface of metepimeron; tympanal membrane extremely large, ovoid, facing lateroposteriorly.

Forewing (fig. 232C; pl. 22): Broad, apical angle almost 90°; vein Rs1 arising near anterolateral angle of DC, stalked for an extremely short distance with base of radial sector; veins Rs2–Rs4 in the pattern [2+3]+4, or Rs2 and Rs3 fused; M1 arising from near upper angle of DC, separate from base of radial sector, UDC long; stridulatory organ absent; DC much longer than one-half FW length; veins M3 and CuA1 arising together at posterolateral angle of DC, or stalked; wing pattern similar to Scoturopsis basilinea, but lighter and fainter.

Hind wing (fig. 232C; pl. 22): Large and broad, outer margin rounded; M3 and CuA1 long stalked; ground color slightly darker than in FW, but wings more thinly scaled, semihyaline.

Abdomen: Moderately long, uniformly light gray-brown.

Terminalia (figs. 233, 234): Tg8 long, roughly ovoid, tapering distally; lateral margins of Tg8 convex, anterior margin with a pair of short, blunt apodemes on either side of midline, posterior margin with a small, U-shaped mesal excavation, or pointed; St8 shorter than Tg8, tapered distally, anterior margin gently sinuate, posterior margin strongly tapered with a deep, U-shaped mesal excavation, its sides forming thin ribbonlike processes; socii/uncus complex large, broadly attached to tegumen; uncus long, wide, concave, broady truncate at apex; ventral surface of uncus bearing a long, digitate process; socii long and thin, apices acute, bearing club-shaped distal setae (X. prouti) or smooth (X. extensa); tegumen much taller than vinculum, moderately wide in basal half, becoming narrower above; vinculum short, thin; saccus absent, ventral margin of genitalia slightly convex at midline; valva moderately long, simple, lightly sclerotized; BO small, comprising a few short, sclerotized pleats on ventral margin near valva base; a setose, cup-shaped sclerite present near base of valva above BO; costa extremely thin, simple; apex smoothly rounded, simple; arms of transtilla long and thin, curving abruptly upward from base, then joining at midline to form a long thin, strutlike sclerite, this sclerite projecting anteriorly; aedeagus moderately long, simple, widest at base, gradually tapering distally; apex of aedeagus with a short toothlike process below; vesica short, less than one-third aedeagus length, narrow; cornuti absent.

Female. Unknown.

Distribution

Xenormicola shows a restricted distribution, extending from Cuzco, Peru, south to Cochabamba, Bolivia. As with its close relatives, Dolophrosyne and Scoturopsis, the genus appears to be confined to the eastern slope of the Andes, at elevations between 1000 and 3500 meters.

Biology

Nothing is known concerning the biology of Xenormicola, but one could predict, based on the host plant of Dolophrosyne and Scoturopsis (table 4), that the larvae are associated with Chusquea (Poaceae).

Discussion

Xenormicola is one of the most obscure genera in the Dioptinae. My attempts to evaluate its status had long been confounded by the fact that the type species, X. prouti, is known solely from the holotype (pl. 22). Finally, I borrowed that type and am able to at least partially resolve the position of Xenormicola. Numerous characters support a relationship between this genus and Scoturopsis + Dolophrosyne. In fact, the male genitalia of X. prouti (fig. 234) could potentially indicate a congeneric relationship with Dolophrosyne elongata (fig. 222A) and Scoturopsis basilinea (fig. 228A). Ultimately, the systematics of this entire clade should be revisited and reassessed.

A loan from the Naturhistorisches Museum Wien (January 2008) contained three males of what had formerly been called Euscoturopsis extensa Hering (Bryk, 1930), previously known to me exclusively from type material. Dissection of the NMW specimens (fig. 233; pl. 22) provided convincing evidence that extensa is congeneric with X. prouti. Finally, two additional Xenormicola specimens came to light—one lurking in the AMNH collection, and the other from unsorted material at the BMNH. Interestingly, each of these represents an undescribed taxon closely related to X. prouti. There are thus at least four species in Xenormicola, but the sum of known material totals only eight specimens. Females have not yet been discovered. It is hoped that future collecting in the Andes of Peru and Bolivia will yield more clues regarding this remarkable group.

KEY TO THE SPECIES OF XENORMICOLA

Plate 22

1. Forewing with only four radial veins, Rs2 and Rs3 conjoined (fig. 232C); Rs1 arising from DC, separate from remaining radials; socii acute at their apices, smooth (fig. 233A); ♂ FW length  =  11.0–12.0 mm (Bolivia)extensa (Hering)

FW with a full complement of radials, Rs2 and Rs3 separate; Rs1 stalked for a short distance with base of radial sector; socii blunt at their apices, bearing short setae (fig. 234A); ♂ FW length  =  16.0 mm (Bolivia)prouti (Hering)

SPECIES INCLUDED AND MATERIAL EXAMINED

Xenormicola extensa (Hering), new combination

Figures 232B, 232C, 233; plate 22

Scoturopsis extensa Hering, 1925: 508.

Type Locality

Bolivia, San Antonio, Yungas, 1800 m.

Type

Holotype ♂, leg. Garlepp, 1895–1896 (ZMH).

Discussion

This species was described in Scoturopsis (Hering, 1925), then moved to Euscoturopsis (Bryk, 1930). Here, extensa is assigned to Xenormicola as a new combination. The only known examples of X. extensa are the ZMH holotype, a paratype Hering deposited at the BMNH (lacking its abdomen), and three males at the NMW. All of this material was collected between 1895 and 1910.

The wings of X. extensa show the same size, pattern elements, and basic coloration as those of Scoturopsis basilinea (pl. 22). These two taxa are undeniably related; Xenormicola and Scoturopsis are perhaps sister genera. Furthermore, X. extensa diverges from its congener, X. prouti, in wing venation and head structure. I have nevertheless chosen to place extensa in Xenormicola to reflect remarkable similarities in the male genitalia of the two species (figs. 233, 234). Future research, including discovery of females, may call for various reassignments throughout the Xenormicola/Scoturopsis clade.

The two NHW examples of so-called “X. extensa” dissected (JSM-1808, 1812) were captured at different elevations (3500 m and 1000 m). Male genital differences indicate that two species are involved; they differ in the shape of the socii, uncus, and valvae. Clearly, these taxa deserve further study. Most importantly, additional material is required.

Xenormicola extensa exhibits a short haustellum (fig. 232B). A reduced tongue is prevalent in certain subfamilies of the Notodontidae (Miller, 1991), particularly the Notodontinae, but within the Dioptinae, this trait is apparently unique to X. extensa.

Distribution

Bolivia (BMNH, NMW, ZMH).

Dissected

Paratype ♂, Bolivia, “(La Paz ?)”, Cillutincara, 3000 m, Jan 1896, leg. Garlepp, BMNH (wing slide no. JSM-1450); ♂, Bolivia, Cuesta von Cillutincara, 3500 m, leg. Fassl, NMW (genitalia slide no. JSM-1812); ♂, Bolivia, Yungas de La Paz, 1000 m, leg. Seebold, NMW (genitalia slide no. JSM-1808).

Xenormicola prouti Hering

Figure 234; plate 22

Xenormicola prouti Hering, 1928: 271.

Type Locality

Bolivia, San Antonio, Yungas, 1800 m.

Type

Holotype ♂, leg. Garlepp, 1895–1896 (ZMH).

Discussion

Xenormicola prouti, known exclusively from the holotype, is larger than other species in Xenormicola, Dolophrosyne, or Scoturopsis (pls. 21, 22). It is similar in size to many Xenomigia (pls. 22, 23), with which it also shares a drab wing pattern. However, based on my character assessment, X. prouti is more closely related to these smaller taxa than to Xenomigia. The FW of X. prouti exhibits a faint, long basal triangle located along the anal fold, undoubtedly homologous with the basal triangles in X. extensa and Scoturopsis (pl. 22).

An AMNH Xenormicola specimen from Bolivia (JSM-775) is listed as a dissection of X. prouti here, but its genitalia show subtle differences from those of the ZMH type. It differs most markedly in the shape of the valva apex, and in having a sharp spine at the apex of each socius, the latter not present in X. prouti (fig. 234A). Description of this taxon will await the discovery of additional material.

Another undescribed Xenormicola comes from a single example at the BMNH. That taxon, illustrated here (fig. 232A) to represent head structure in Xenormicola, is larger (FW length  =  17.0 mm) and even drabber than X. prouti, but its male genitalia are distinctive. Label data are as follows: Peru, Cuzco, Pillahuata, 2600 m, 14–18 Aug 1982, leg. M. Matthews & M. Packer, BM 1982-495 (genitalia slide no. JSM-408). In October 2005, I visited that locality, a beautiful setting in the Cosñipata Valley, following in the footsteps of Marcus Matthews and hoping to capture additional Xenormicola specimens. Unfortunately, two days and one night spent collecting on the fog-covered mountain yielded no material. The light traps attracted a phenomenal diversity of cloud-forest moths, the most I have seen for a site at that altitude (2600 m), but, alas, not a single Xenormicola.

Distribution

Bolivia (ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1454); ♂, Bolivia, Cochabamba, south of Corani, Yungas del Chapare, 2900 m, 28–31 Jan 1976, leg. L.E. Peña, AMNH (genitalia slide no. JSM-775).

XENOMIGIA WARREN, 1906

Figures 235Figure 236Figure 237Figure 238Figure 239Figure 240Figure 241Figure 242243; plates 22, 23, 38N, 39C

Figure 235

Morphology of Xenomigia (♂♂). A, head of X. involuta, sp. nov., lateral view; B, head of X. involuta, lateral view; C, head of X. involuta, frontal view; D, head of X. involuta, posterior view; E, X. consanguinea labial palpus; F, X. involuta tegula; G, X. involuta wings; H, X. consanguinea wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f235.gif

Figure 236

Male genitalia of Xenomigia brachyptera (JSM-900). A, genitalia; B, St8; C, aedeagus; D, Tg8, dorsal view.

i0003-0090-321-1-1-f236.gif

Figure 237

Genitalia of Xenomigia (♂ JSM-164, ♀ JSM-228). A, aedeagus of X. consanguinea; B, ♂ of X. consanguinea; C, ♂ St8 of X. consanguinea; D, ♂ Tg8 of X. consanguinea; E, ♀ of X. fassli (illustration by A. Trabka).

i0003-0090-321-1-1-f237.gif

Figure 238

Male genitalia of Xenomigia nubilata (JSM-936). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f238.gif

Figure 239

Genitalia of Xenomigia pinasi, sp. nov. (♂ JSM-1635, ♀ JSM-938). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♀ genitalia; E, ♂ St8; F, ♀ Tg7; G, ♀ St7.

i0003-0090-321-1-1-f239.gif

Figure 240

Holotype ♂ genitalia of Xenomigia concinna (JSM-933). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f240.gif

Figure 241

Holotype ♂ genitalia of Xenomigia cuneifera (JSM-935). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f241.gif

Figure 242

Genitalia of Xenomigia involuta, sp. nov. (JSM-477, 478). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f242.gif

Figure 243

Ecuador, showing the known distributions of Xenomigia involuta, sp. nov., and X. pinasi, sp. nov.

i0003-0090-321-1-1-f243.gif

Xenomigia Warren, 1906: 413. Type species: Xenomigia veninotata Warren, 1906 (by original designation).

Ceraeotricha Hering, 1925: 519. Type species: Xenomigia cuneifera Dognin, 1913 (by original designation). New synonymy.

Tolimicola Prout, 1918: 403. Type species: Tolimicola fassli Prout, 1918 (by original designation). New synonymy.

Diagnosis

Members of Xenomigia (pls. 22, 23) bear strong superficial resemblance to Geometridae. In almost all Xenomigia species the wings are broad. The FW is usually marked with a combination of earth tones in subtle, intricate patterns. The HW is drab gray, brown, or buff, with few markings. Xenomigia wing venation is atypical for Dioptinae, but typical of many Lepidoptera, with veins M3 and CuA1 separate, rather than stalked, in the FW and HW (fig. 235G, H). When alive, Xenomigia adults rest with their wings folded rooflike over the back, betraying membership in the Notodontidae. The majority of geometrids rest with upright wings.

With scrutiny, specimens of Xenomigia can easily be placed in the Dioptinae. Using the following set of characters, they can be identified to genus: labial palpus short to moderately long (fig. 235A, B), upturned to immediately above clypeus; eye large, bulging (fig. 235A–D); male antenna quadripectinate, pectinations long or, less commonly, short; female antenna without pectinations, each annulation instead bearing a single transverse row of stout bristles; scales of thorax and abdomen generally long, giving body a hairy appearance; body color light brown or brownish gray; tympanal cavity large and deep; tympanal membrane large, oriented horizontally; wings broad; M3 and CuA1 in FW and HW widely separated (fig. 235G, H); male FW stridulatory organ weakly developed, M1 and M2 slightly swollen beyond DC, but DC much longer than one-half FW length; wing colors subdued; FW veins often yellow or orange; HW brown to brownish gray, often translucent, the only discernible pattern a diffuse marginal band and a series of dashes along outer margin.

Redescription

Male. FW length  =  7.5–21.5 mm. Head (figs. 235A–E): Labial palpus relatively short, upturned to immediately above clypeus; Lp1 quite long, upcurved; Lp2 shorter than Lp1, barely upcurved; Lp3 short and subcylindrical, apex quadrate; Lp1 frequently covered with yellow scales; eye extremely large, bulging; gena absent; scales of front not elongate, but pointing inward toward midline and slightly upward; vertex with long scales pointing anteriorly to form a small cap between antennal bases; antenna quadripectinate, rami long in some species (e.g., X. consanguinea), short in others; rami covered with bristles.

Thorax (fig. 235F): Foreleg epiphysis short to moderately long, never extending beyond apex of tibia; apex of epiphysis acute, recurved, base wider than middle; tegula relatively small, dorsal arm broadly rounded; tegula almost always covered with long, dark brown scales at margins, and with shorter, orange-yellow scales at base; metathoracic tympanum large, cavity deep; membrane large, oriented horizontally, completely enclosed by tympanal sclerites.

Forewing (fig. 235G, H; pls. 22, 23): Broad, outer margin gently convex; ground color usually dark brown, overlaid with a complex pattern of light brown and white markings; wing veins frequently orange; interspecific pattern differences subtle; R1 arising from DC, Rs1 arising from radial sector near upper angle of DC; Rs2–Rs4 in one of two arrangements—2+[3+4] (Concinna Group) or [2+3]+4 (Monticolata Group); DC longer than one-half FW length; stridulatory organ poorly developed, M1 and M2 slightly swollen, melanized beyond DC; M3 arising from lower angle of DC, widely separate from CuA1.

Hind wing (fig. 235G, H; pls. 22, 23): Broad, often extremely so; generally translucent with few markings, entire wing light brown, gray, or beige, occasionally with darker dashes along outer margin; Rs and M1 stalked; M2 from middle of DC, M3 arising from lower angle of DC, widely separate from CuA1.

Abdomen: Relatively short, truncate; lacking pattern.

Terminalia (figs. 236, 237A–D, 238, 239A–C, 239E, 240, 241, 242A–D): Tg8 roughly quadrate, but posterior margin narrower than anterior one; posterior margin of Tg8 heavily sclerotized, occasionally with a shallow medial excavation; St8 highly variable, but often forming a characteristic Y-shape (in ventral view), almost always relatively short, with anterior margin much wider than posterior one, anterolateral angles frequently drawn out and acute, sometimes bearing paired pockets; posterior margin of St8 heavily sclerotized, frequently with a deep medial notch; anterior apodeme of St8 variable, usually robust, wide at base and ending in a blunt point; genitalia with socii/uncus complex small, junction with tegumen narrow; uncus short, lateral margins acute; socii small and delicate, slightly upturned; tegumen tall, usually narrow, rarely moderately wide; vinculum narrow above, broadly sclerotized below to form saccus; saccus distinctive, wide, and sometimes quite tall, lateroventral angles blunt; saccus with a shallow medial ventral excavation; valva variable in shape, always heavily sclerotized, usually quite narrow; saccus sclerotized, fused with valva, BO absent; apex of valva heavily sclerotized, frequently hook shaped or spatulate; lower margin of valva often with a small, sclerotized, setose process of variable size and shape; aedeagus short, distinctive in shape, usually constricted near middle, base with broad lateral flanges; distal end of aedeagus narrow, sharply recurved (lateral view) and drawn to a fine point; vesica small, either with minute spinelike cornuti, or cornuti absent; aedeagus with an unusual dorsal appendix approximately halfway to apex, appendix surface comprising a set of spiculate, sclerotized folds.

Female. FW length  =  15.5–22.0 mm. Head: Labial palpus almost identical to male; other features of head similar to male, except antenna lacking rami, instead bearing a transverse row of stout bristles arising from near base of each annulation.

Thorax: Similar to male.

Forewing: Broader and somewhat longer than in male, other features the same; pattern similar to male except markings generally less distinct, not as contrasting; frenulum comprising approximately 6–8 bristles.

Hind Wing: Broader than male; ground color generally darker than male, usually a dusky gray-brown, pattern less distinct.

Abdomen: Large and wide, lacking pattern.

Terminalia (figs. 237E, 239D, 239F, 239G, 242E): Tg7 large and broad, slightly narrower at posterior margin, not heavily sclerotized, sometimes with a membranous band along midline starting at posterior margin; St7 approximately as long as Tg7, but much wider; posterior margin of St7 more heavily sclerotized than rest of sternum, with a shallow, but well-defined medial excavation; some species with a sclerotized, transverse groove running width of St7; Tg8 quite long or moderately so, but usually narrow; posterior margin of Tg8 with a small, spiculate, medial notch, more melanized than rest of tergum; AA moderately long, or extremely short; PVP small; region surrounding ostium spiculate, protruding; DB elongate and narrow, completely membranous, usually with an elbow-shaped kink near midpoint; CB an elongate oval, frequently tapering gradually toward base, completely membranous; signum absent; DS usually arising near ostium; junction of DS and DB slightly swollen; PP short and thin, except moderately long in X. consanguinea; PA quite large, somewhat melanized; membrane surrounding PA invaginated to form a deep pocket.

Distribution

Xenomigia is strictly Andean. Species occur from western Venezuela west into Colombia, and south to Ecuador. The southernmost limit is in the area of Loja, Ecuador (fig. 5), near the Peruvian border, but no Xenomigia are as yet known from Peru itself.

Xenomigia species generally occur at high altitudes. The lowest recorded elevation is an undescribed Ecuadorian taxon, collected at 550 meters (AMNH; leg. J.S. Miller & E. Tapia; Tena-Tulag road). The highest elevation comes from a specimen of X. monticolata (FPC), collected by F. Piñas at 3940 meters northwest of Papallacta, Ecuador. This falls somewhat below the highest elevation so far known for the Dioptinae—4200 meters for Polypoetes aborta, from Monte Tolima, Colombia.

Biology

The caterpillar research group at Yanayacu Biological Station in eastern Ecuador (Dyer et al., 2009) has made a raft of recent discoveries regarding the larval biology of cloud forest Lepidoptera. They discovered the caterpillars of four Xenomigia species feeding on Chusquea, the scandent cloud-forest bamboo (pl. 44C, E, F) so common throughout the Andes. All four of these Xenomigia species are undescribed. The larvae (pl. 38N) show a pattern of spots on the head capsule similar to that in Tithraustes (e.g., pl. 39E), while their body coloring is unlike other Dioptinae.

The discovery of Xenomigia brachyptera (Sattler and Wojtusiak, 2000), found at Páramo El Batallón in Táchira, Venezuela (3400–3600 m), is remarkable. The tiny moth, with stubby, nonfunctional wings (pl. 22), is the first known brachypterous notodontid. This case is all the more unusual because in X. brachyptera the males are flightless, whereas wing reduction in Lepidoptera is generally restricted to females (Sattler, 1991; Wagner and Liebherr, 1992).

Discussion

Historically, Xenomigia has been a taxonomic conundrum. Bryk (1930) listed six species, but even my early forays into Xenomigia systematics suggested that Bryk's concept was badly in need of revision. First, three species were improperly placed, and I have removed them: pallinervis Felder and villiodes Prout are now in Polypoetes, whereas disciplaga Hering is placed incertae sedis. Second, in this paper I place two genera—Tolimicola Prout (four species) and Ceraeotricha Hering (one species)—as junior synonyms of Xenomigia. These changes, along with the addition of newly described taxa, produce a list of 11 Xenomigia species, only three of which were included in the genus by Bryk (1930).

Prout (1918) erected Tolimicola for a single species—fassli Prout—but gave no defining features for the genus other than traits widespread in the Dioptinae. Oddly, he did not recognize an affiliation between Tolimicola and Xenomigia. Similarly, Hering (1925) created the genus Ceraeotricha for a single species, cuneifera Dognin. He placed Ceraeotricha in his classification scheme close to Phanoptis, presumably because FW and HW veins M3 and CuA1 are separate in both genera (see fig. 64K). Hering did not notice the more compelling morphological similarities between cuneifera and members of Xenomigia, or Prout's Tolimicola for that matter. My research suggests a much simpler arrangement: The type species of these three genera—fassli (Prout), cuneifera Dognin and veninotata Warren—are congeneric, and I therefore recognize a single genus, Xenomigia.

Members of Xenomigia are drab (pls. 22, 23). Furthermore, like geometrids and unlike most dioptines, Xenomigia species seem largely nocturnal or crepuscular. I have collected a few individuals on flowers during the day, but the vast majority of material in collections was captured at light traps. At some localities, Xenomigia are common. Undoubtedly, many specimens are currently residing in museum and private collections as unidentified Geometridae.

By far the most striking attribute of Xenomigia is the vast number of undescribed species that exist. Distinguishing these on the basis of wing pattern proves to be extremely difficult. Genitalia dissection, on the other hand, reveals an extraordinary diversity of Xenomigia in the cloud forests of Colombia and Ecuador. In this paper, I describe two new species, both from Ecuador—involuta from the western slope and pinasi from the east. However, at least 20 additional undescribed Ecuadorian species exist. Samples from Colombia are essentially confined to material captured at the turn of the 20th century by Anton Fassl. When Colombia is comprehensively surveyed, its Xenomigia fauna will almost certainly be larger than Ecuador's. Discovery of Xenomigia brachyptera, a flightless páramo species from western Venezuela (Sattler and Wojtusiak, 2000), contributes even further to the amazing story of biodiversity that will unfold through future study of Xenomigia. I estimate that, when this genus is ultimately revised, it will total between 50 and 60 species, perhaps even more.

Prout (1918: 406), while admitting that Xenomigia is “not positively known to me”, nevertheless divided the genus into two sections—one in which FW and HW veins M3 and CuA1 are not stalked, and the second with M3 and CuA1 stalked. In his Section II (veins stalked) he placed pallinervis Felder and villiodes Prout. Hering (1925) and Bryk (1930) subsequently followed this scheme. However, Prout would have been better advised to remove those species from Xenomigia altogether, since they share no derived characters with X. veninotata, the type of the genus. I have placed them in the Persimilis Group of Polypoetes, far removed from Xenomigia (fig. 3).

In an attempt to provide a provisional taxonomic framework for Xenomigia, I have outlined three subclades within the genus. The first includes only X. brachyptera (see below). The other, two—the Monticolata and Concinna groups—can be distinguished based on the configuration of FW veins Rs2–Rs4 (fig. 235G, H). Throughout this work, I have stressed the phylogenetic instability of wing-venation characters. However, Xenomigia is such an imposing clade that discovery of any morphological differences is encouraging. The veracity of my species groups should be evaluated in light of a comprehensive analysis, ideally involving additional character sets from DNA and immature morphology.

There is virtually no way to identify Xenomigia species without reference to their genitalia. Wing patterns are nearly impossible to interpret. All seem to employ the same pattern elements, with subtle variations on a theme. Trying to isolate useful diagnostic markings for unraveling this miasma has proved to be a frustrating, mind-bending exercise. I have spent many fruitless hours studying Xenomigia FW patterns, hoping to find features for characterizing particular species, only to realize later that my efforts were in vain. The wings of Xenomigia females are particularly difficult; their patterns are almost always more diffuse than those of males. Perhaps an analysis of wing-pattern elements, analogous to the studies done on butterflies (e.g., Nijhout, 1991, 2003; Nijhout and Wray, 1986, 1988), will someday allow these to be used as key characters in Xenomigia.

When male genitalia are examined, the keys below function relatively well, at least with regard to the described species of Xenomigia. Unfortunately, there are many more undescribed taxa than named ones—probably by a four-to-one ratio. This key should thus be regarded as a first approximation. So far, my survey of Xenomigia genital morphology comprises over 90 dissections, but a revision will require literally hundreds more. Perhaps that information could someday serve as a platform from which to re-examine wing patterns.

Subgroups within Xenomigia are proposed here, the major distinction—between the Monticolata and Concinna groups—is based on differing arrangements of the FW radials. However, in certain cases, genital morphology flies in the face of species placement based on FW radials. For example, the male genitalia of X. nubilata (fig. 238) and X. involuta (fig. 242A–D) are similar, but FW radials place them in different species groups. Ultimately, a complete, species-level revision of Xenomigia may require abandoning these subgroups.

KEY TO XENOMIGIA SUBGROUPS

1. Forewings long and broad, HW large, rounded; CuA1 and CuA2 present in FW and HW; valva variable in shape, frequently narrow with margins irregular; valva apex sclerotized, often spatulate2

FW and HW short, lanceolate; only a single cubital vein present in FW and HW; valva extremely wide, margins simple; valva apex not sclerotized, angulate (NW Venezuela)Xenomigia brachyptera Sattler and Wojtusiak

2. Forewing veins Rs2–Rs4 in the arrangement [2+3]+4 (fig. 235H); FW pattern subdued, diffuse, whitish lines delicateMonticolata Group

FW veins Rs2–Rs4 in the arrangement 2+[3+4] (fig. 235G); FW pattern contrasting, whitish lines and spots often boldConcinna Group

1. XENOMIGIA BRACHYPTERA

Xenomigia brachyptera, unique in a multitude of ways, does not show characters associating it with either of the two Xenomigia species groups. It therefore sits in a category of its own. Hopefully, future faunal surveys of Andean mountaintops, using focused collecting techniques, will reveal additional relatives of X. brachyptera. At that point, a separate Xenomigia species group could be established for flightless taxa.

Xenomigia brachyptera Sattler and Wojtusiak

Figure 236; plate 22

Xenomigia brachyptera Sattler and Wojtusiak, 2000: 436–440.

Type Locality

Venezuela, Táchira, Parque Nacional Batallón, Páramo El Batallón, Via Laguna El Cenegón, 3350 m.

Type

Holotype ♂ (not seen), leg. Wojtusiak, 2 Mar 1996 (MALUZ).

Discussion

Xenomigia brachyptera, by far the smallest species in the genus (pl. 22), is even more notable in being the only known brachypterous notodontid. Males were collected by sweep-netting in the low, moist vegetation of Páramo El Batallón, in the Andes of western Venezuela (Sattler and Wojtusiak, 2000). Females of X. brachyptera, undoubtedly also flightless and perhaps wingless, have not yet been found. The exciting possibility exists that many more, as yet undescribed, brachypterous Xenomigia await discovery throughout the Andes.

The male genitalia of X. brachyptera are simpler than those of most Xenomigia species, and the valva is particularly broad (fig. 236A). Nevertheless, the aedeagus exhibits the highly characteristic shape (fig. 236C) and large dorsal appendix that serve as synapomorphies for Xenomigia.

Since the cloud-forest bamboo Chusquea is the sole recorded host for Xenomigia (see Biology, above), it will be interesting to discover whether the larvae of X. brachyptera feed on a low, crawling páramo bamboo, or alternatively, on a non-bamboo grass.

Distribution

Venezuela (AMNH, BMNH, MALUZ).

Dissected

Paratype ♂, Venezuela, Táchira, Páramo El Batallón, Laguna Grande, 3400–3600 m, 16–18 Dec 1994, leg. M. Garcia, AMNH (genitalia slide no. JSM-899, wing slide no. JSM-884); paratype ♂, Venezuela, Táchira, Páramo El Batallón, Laguna Grande, 3400–3600 m, 16–18 Dec 1994, leg. M. Garcia, AMNH (genitalia slide no. JSM-900).

2. MONTICOLATA GROUP

In the Monticolata Group, FW veins Rs2–Rs4 occur in the arrangement [2+3]+4 (fig. 235H), typical of the Dioptinae. The Monticolata Group is also characterized by subdued, often nondescript wing patterns. Several of the included taxa are almost completely gray-brown, with semihyaline wings, much like the habitus of Phryganidia (pl. 8).

Of the five Monticolata Group species, three are newly combined in Xenomigia with synonymy of the genus Tolimicola Prout. These are: consanguinea Dognin, monticolata Maassen, and nubilata Dognin. Dognin (1913) originally described the fourth, sordida, in Xenomigia, while a fifth species, X. pinasi, is described here.

KEY TO MONTICOLATA GROUP SPECIES (MALES)

Plate 22

1. Dorsum of uncus simple; ventral angles of socii not elbowlike2

Dorsum of uncus bearing a pair of small, earlike processes; ventral angles of socii strongly elbowed (Colombia)sordida Dognin

2. Valvae narrow (fig. 237A); posterior margin of St8 heavily sclerotized, with a narrow U-shaped mesal excavation bearing large posterolateral processes4

Valvae wide (fig. 238A); posterior margin of St8 lightly sclerotized, with a wide U-shaped mesal excavation lacking posterolateral processes3

3. Forewing with barely a hint of pattern, postmedial and subterminal lines only slightly darker than gray-brown ground color; ventral margin of valva gradually excavated basal to apex in distal two-thirds; FW length  =  16.5–18.0 mm (Colombia, Ecuador)monticolata (Maassen)

FW with a noticeable pattern, postmedial and subterminal lines contrasting dark brown against light brown ground color, FW anal margin beige; ventral margin of valva strongly excavated basal to apex in distal two-thirds (fig. 238A); FW length  =  18.0–18.5 mm (Colombia)nubilata (Dognin)

4. Hind wing uniformly light brown, scaling in basal half somewhat thinner; posterior margin of male St8 with a relatively shallow U-shaped mesal excavation (fig. 237C); dorsum of Tg8 barely arching upward in distal third (fig. 237D); valva gradually narrowed distally (fig. 237A), apex spoon shaped (Colombia)consanguinea (Dognin)

HW creamy white to buff colored, with a faint, gray-brown postmedial band and a gray-brown marginal band from apex to anal fold; posterior margin of St8 with an extremely deep U-shaped mesal excavation (fig. 239E); dorsum of Tg8 arching strongly upward in distal third (fig. 239B); valva constricted distally (fig. 239A), apex spatulate (NE Ecuador)pinasi, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Xenomigia consanguinea (Dognin), new combination

Figures 235E, 235H, 237A–D; plate 22 [EX]

Tithraustes consanguinea Dognin, 1911a: 22.

Type Locality

Colombia, Páramo del Quindiu, 3800 m.

Type

Syntype ♀, leg. Fassl, Sep 1909 (USNM type no. 30970).

Discussion

Xenomigia consanguinea has had a checkered taxonomic history. Dognin (1911a) originally described the species in Tithraustes, suggesting that it might be a close relative of fumosa Warren (pl. 15). I place the latter in the unrelated genus Chrysoglossa. At first, Prout (1918) retained consanguinea in Tithraustes, though noting that it might be conspecific with Tolimicola fassli Prout. He later formalized that suggestion (Prout, 1920), moving consanguinea to Tolimicola and treating fassli as a junior synonym. Here, Tolimicola Prout is placed in synonymy with Xenomigia Warren. I furthermore regard consanguinea and fassli as distinct species, and have placed them in separate species groups.

Xenomigia consanguinea, one of the largest described species in the genus (FW length  =  20.0–22.0 mm), occurs at upper elevations in the central Andes of Colombia. Although only five specimens are known, all but one of those was collected at or above 3500 meters. This taxon is not known south of Tolima, Colombia. Male genitalia suggest that X. pinasi, sp. nov. (pl. 22), is its sister species (figs. 237A–D, 239). The latter occurs approximately 600 km south in northeastern Ecuador. In addition to being a slightly smaller moth (FW length  =  18.0–21.5 mm), X. pinasi lives at lower altitudes, ranging from 2200 to 2800 meters.

Distribution

Colombia (BMNH, USNM).

Dissected

Syntype ♀ (genitalia slide no. JSM-1036); ♂, Colombia, Central Cordillera, Paso del Quindiu, 3500 m, leg. Fassl, BMNH (genitalia slide no. JSM-164, wing slide no. JSM-195); ♂, Colombia, BMNH (genitalia slide no. JSM-497); ♀ co-type, Colombia, Páramo del Quindiu, 3800 m, 1909, leg. Fassl, USNM (genitalia slide no. JSM-956).

Xenomigia monticolata (Maassen), new combination

Plate 22

Lignyoptera monticolata Maassen, 1890: 42, n. 29, p. 163, pl. 8, fig. 27.

Type Locality

Colombia, Páramo de Pasto, 3200 m.

Type

Syntype ♂ (ZMH).

Discussion

The identity of Xenomigia monticolata had long been a mystery. The species was originally described in Lignyoptera (Maassen, 1890), a genus of Geometridae. At first, neither Prout (1918) nor Hering (1925) recognized it as a member of the Dioptinae. Later, Hering (1928), following informal discussions with Prout, wrote that monticolata should be included in the Dioptinae, placing it in Tolimicola, where it has remained (Bryk, 1930). Since Tolimicola is here placed in synonymy with Xenomigia, Xenomigia monticolata (Maassen) becomes a new combination.

The only confirmed examples of X. monticolata are the two Maassen syntypes at the ZMH. One is in horrible condition, being badly rubbed and missing its abdomen, while the other (pl. 22) is in reasonably good condition. Both bear identical label data. My examination of those specimens confirms membership in Xenomigia. Their antennae are quadripectinate with extremely short pectinations, the tympana are open, and veins M3 and CuA1 are separate in the FW and HW. The male genitalia of X. monticolata (JSM-1420) are, in fact, extremely similar to those of X. nubilata (fig. 238). They differ most notably in valva shape; the lower valva margin in X. monticolata is less strongly excavated and the process at the apex is shorter and less pronounced. Xenomigia monticolata also resembles X. nubilata in exhibiting a nondescript, semihyaline FW and HW. I conclude that the two are separate species.

Two Ecuadorian males closely resemble X. monticolata. Their genitalia (JSM-774, 1636) differ from the X. monticolata syntype in subtle, but seemingly consistent, ways. Nevertheless, I have chosen to treat these as X. monticolata rather than describe them as new. One was collected near the headwaters of the Río Papallacta (3840 meters) in northeastern Ecuador (CMNH). The second specimen, in the collection of F. Piñas (Quito, Ecuador), was captured near the same locality but at a slightly higher elevation—3940 meters.

According to this interpretation, X. monticolata is the only Xenomigia species occuring in both Colombia and Ecuador. All others are restricted to one of the two countries.

Distribution

Colombia (ZMH); Ecuador (CMNH, FPC).

Dissected

Syntype ♂ (genitalia slide no. JSM-1420); ♂, Ecuador, 12 km NW Papallacta, 3840 m, 11–12 Oct 1987, leg. C. Young, R. Davidson & J.E. Rawlins, subparamo mixed grass/woodland, CMNH (genitalia slide no. JSM-774); ♂, Ecuador, Pichincha, Papallacta, 3940 m, 19 Feb 1998, leg. F. Piñas, FPC (genitalia slide no. JSM-1636).

Xenomigia nubilata (Dognin), new combination

Figure 238; plate 22

Tithraustes nubilata Dognin, 1912: 133.

Type Locality

Colombia, Páramo del Quindiu, 3800 m.

Type

Syntype ♂, leg. Fassl, Sep 1909 (USNM type no. 30971).

Discussion

This is the third species, formerly in Tolimicola Prout, now transferred to Xenomigia. The only confirmed specimens of X. nubilata are the two male syntypes, collected by Fassl at Páramo del Quindiu. This is an extremely important site, home to five additional Xenomigia species—concinna, consanguinea, cuneifera, fassli, and sordida. Some of the most fascinating Dioptinae, in a wide range of genera, are currently known exclusively from material collected by Anton H. Fassl, between the years 1909 and 1910, in the area of Quindiu. The majority of his specimens are housed at the BMNH, NMW, and USNM.

A third USNM specimen (JSM-1816), from Nevado del Huila on the western slope of the Colombian Andes (02°55′11.25″N, 76°02′59.85″W), shows an exaggerated valva apex compared to the X. nubilata syntypes, but its genitalia are otherwise similar. It is listed here as X. nubilata, but may represent a closely related, undescribed species.

Xenomigia nubilata is a close relative of X. monticolata (pl. 23). Both show a faint wing pattern, the FW and HW being drab light brown. Xenomigia nubilata exhibits a vague, jagged, dark brown submarginal line in the FW, and its wings (FW length  =  18.0–18.5 mm) are slightly longer than those of X. monticolata (FW length  =  16.5–18.0 mm). Genitalia differences between the two are noted in my discussion of the latter (above).

Distribution

Colombia (USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-936); Syntype ♂, Colombia, Páramo del Quindiu, 3800 m, Sep 1909, leg. Fassl, USNM (genitalia slide no. JSM-955); ♂, Colombia, Cauca, Nevado del Huila, 5 Jan 1970, 13,200 ft, leg. R.E. Deitz IV, at light, USNM (genitalia slide no. JSM-1816).

Xenomigia pinasi, new species

Figures 239, 243; plate 22

Diagnosis

Xenomigia pinasi (pl. 22) is characterized by the following traits: Wings relatively long and broad (FW length  =  19.0–21.5 mm); FW ground color dark brown, veins delicately lined with orange-yellow; FW postmedial and subterminal lines thin, wavy; HW semihyaline, gray buff colored (males) with a faint, gray-brown marginal band, tapering from apex to tornus; posterior margin of male St8 with a deep, U-shaped medial excavation (fig. 239E), its posterolateral angles heavily sclerotized and curled outward; valva long and thin (fig. 239A), apex spatulate; and finally, female CB elongate (fig. 239D), membranous, ostium simple, its external surface finely spiculate.

Description

Male. Forewing length  =  19.0–19.5 mm. Head: Labial palpus moderate in length, upturned to immediately above clypeus, apices pointing slightly in toward midline, all segments light gray-brown to gray-brown; Lp1 long, curving upward, ventral margin loosely fringed with long scales; Lp2 short, much shorter than Lp1, curving upward, ventral margin bearing longer scales; Lp3 short, bullet-shaped; front gray-brown to light brown, scales pointing dorsomedially; frontal scales moderate in length, longer dorsally, reaching to antennal bases but not beyond; occiput covered with erect, brown to gray-brown scales; eye large, bulging, completely surrounded by scales, gena absent; vertex covered with long, semierect, light brown to gray-brown scales, pointing anteriorly; antenna quadripectinate, rami short, distal pair slightly narrower than proximal pair; scape glossy brown to gray-brown; dorsum of antennal shaft tightly covered with appressed, glossy, light gray-brown scales.

Thorax: Legs uniformly covered with light brown to gray-brown scales; pleuron clothed in long, hairlike, light gray-brown to buff-colored scales; patagium covered with long, erect, gray-brown to dark brown scales, anterior margins lighter; tegula glossy brown to gray-brown, a small epaulette of yellow-orange scales near base, distal margins of tegula fringed with hairlike scales; mesoscutum light brown to chocolate brown, lateral margins yellow-orange; mesoscutellum light gray-brown, lateral margins buff colored; tympanal cavity extremely large and deep, outer opening rectangular, relatively small; tympanal membrane extremely large, ovoid, facing ventrally.

Forewing: (Dorsal) Ground color chocolate brown to dark brown (pl. 22); veins, excluding costa and R1 but including anal fold, delicately lined with orange-yellow scales; orange lining of anal fold, 1A+2A and bases of CuA1 and CuA2 interrupted by chocolate brown; costa gray-brown; subcosta intermittently whitish orange and chocolate brown; area surrounding subcosta, between costa and DC, comprising wide, intermittent bands of chocolate brown and light gray-brown; a small, creamy white, hook-shaped mark near base behind DC; a diffuse, creamy white chevron within DC in position of antemedial line; medial line a short, conspicuous, creamy white band, beginning posteriorly at anal margin, curving slightly outward and terminating at cubitus near base of CuA2; a small, quadrate, light gray-brown fascia beyond DC, its anterior margin touching base of radial sector, posterior margin extending behind base of M2, fascia surrounded by a thin creamy white border; area anterior to fascia gray-brown, base of radial sector conspicuously orange-yellow; a diffuse, wavy, creamy white postmedial line extending from subcosta to anal margin, line curving outward around fascia; subterminal line comprising a series of small, creamy white wedges in cells between Rs2 and anal fold; fringe glossy gray-brown, with whitish yellow bands at vein apices; stridulatory organ present; DC long, much greater than one-half FW length. (Ventral) Ground color uniformly gray-brown, veins briefly lined with yellowish buff-colored scales near outer margin; medial, postmedial, and subterminal lines showing slightly through from above; stridulatory organ comprising a small, sparsely scaled fascia beyond DC, M1 and M2 swollen with a short fold between their bases; fringe light gray-brown with conspicuous, yellowish buff-colored stripes at vein apices.

Hind wing: (Dorsal) Surface semihyaline (pl. 22), ground color dusty white, veins yellowish to cream colored; anterior margin light gray-brown; a faint, gray-brown band at outer margin extending from apex to tornus, widest near apex, tapering posteriorly; a second, extremely faint gray-brown postmedial band, this curving around distal margin of DC. (Ventral) Similar to dorsal surface.

Abdomen: Clothed entirely with long, glossy, light gray-brown to gray-brown scales, lighter near base.

Terminalia (fig. 239A–C, E): Tg8 moderately long, one and a half times as long as Tg7, slightly constricted in posterior third, with a wide dorsal hump extending to posterior margin; anterior margin of Tg8 with an extremely shallow mesal excavation, posterior margin gently concave; St8 extremely wide, longer than Tg8, lateral angles expanded greatly outward; anterior margin of St8 with a long, wide, abruptly tapered mesal process, its apex almost reaching anterior margin of St7; lateral margins of St8 expanded into concave, winglike processes; posterior margin of St8 with a deep U-shaped mesal excavation, on either side of which are long, robust, heavily sclerotized processes, their apices flanged, curling outward; socii/uncus complex relatively small, roughly diamond shaped, narrowly attached to ring; uncus ovoid, short, apex tiny and wedge shaped; socii small, elbowed strongly upward at bases, apices narrow, delicate; arms of tegumen narrow, much taller than vinculum; arms of vinculum narrow; saccus forming a large, wide quadrate structure below, dorsal margin not reaching valva bases, ventral margin slightly concave at meson; juxta small, V-shaped; valva long and narrow, mostly sclerotized; BO absent, that region sclerotized; inner surface of valva with a large ridge running from base of costa out to lateral margin immediately below apex; a dense tuft of setae on ridge near lateral margin of valva; costa wide, lightly sclerotized, arching gently upward; apex heavily sclerotized, narrow at base, scoop shaped, curving inward; arms of transtilla thin, delicate, arching strongly upward from bases, forming a U-shaped junction at midline above aedeagus; aedeagus short, abruptly constricted in basal third, widest two-thirds out; apex of aedeagus narrowed to a recurved point; vesica small, narrow, covered with tiny thornlike cornuti; dorsum of aedeagus with an appendix beyond two-thirds point, its surface sclerotized, bearing finely dentate, complex folds.

Female. Forewing length  =  21.5 mm. Body coloring similar to male; labial palpus shorter and thinner than male; antenna ciliate, base of each annulation bearing a set of coarse bristles.

Forewing: Longer and broader than male, pattern less contrasting; frenulum comprising four bristles.

Hind wing: Ground color light gray-brown, marginal and submarginal bands slightly darker.

Terminalia (fig. 239D, F, G): Tg7 trapezoidal, gradually narrowing distally, a membranous region along midline, anterior margin simple, posterior margin gently convex; St7 wider than Tg7, anterior margin simple, posterior margin broadly concave, a wide, sclerotized transverse groove near margin; Tg8 relatively long, lightly sclerotized, posterior margin forming a small, rooflike structure; AA minute, acute; A8 pleuron lightly sclerotized; area surrounding ostium bulbous, sclerotized, surface finely setose, sparsely rugose; ostium tiny, membranous; DB short and narrow, membranous; DS arising from dorsum of DB near base of CB; CB long, ovoid in distal two-thirds, gradually narrowed in basal one-third, constricted near DB; CB completely membranous, signum absent; PA lightly sclerotized, more heavily sclerotized near bases, their posterior margins gently rounded outward; PP extremely wide at their bases, apices forming tiny nubs.

Etymology

This species is named in honor of Francisco Piñas, from Quito, Ecuador. Padre Piñas, who has been collecting Ecuadorian moths for over 20 years, possesses the largest Lepidoptera collection in that country. It contains invaluable material, including innumerable undescribed species from all moth families. Padre Piñas has generously allowed me access to his material over the years. He studied at the AMNH for several weeks in 1994. Ten years later (October 2004), I visited his collection in Quito to find that it had grown at an incredible rate. His holdings have become an amazing repository, showcasing the biodiversity of Ecuador.

Distribution

Xenomigia pinasi occurs in a narrow altitudinal band on the eastern slope of the Ecuadorian Andes (fig. 243). The known specimens were collected along the valley of the Río Papallacta, on the road from Quito to Baeza. The type locality is at the confluence of the Río Chalpi Grande and the Río Papallacta.

Discussion

An undescribed cryptic species exists, nearly identical in size and wing pattern to X. pinasi. The unnamed taxon (FW length  =  21.0 mm), known from a single female, was collected at lower elevation: Napo, 12.8 km SE Papallacta on rd. to Baeza, 8000 ft, 30 May 1993, at light, leg. J.S. Miller, AMNH. Interestingly, its FW veins are in the pattern Rs2+[Rs3+Rs4], whereas X. pinasi shows the [Rs2+Rs3]+Rs4 arrangement. This trait would place the undescribed taxon in a separate species group from X. pinas. The only other discernible difference between them is that the FW DC contains two small whitish spots near its midpoint in the undescribed species, rather than only one as in X. pinasi.

Holotype

Male (pl. 23). Ecuador: Napo: Río Chalpi Grande, 10 km W Cuyaja on Papallacta-Baeza Rd., 00°23′S, 78°00′W, 2800 m, 3 Mar 2006, MV light, leg. J.S. Miller, E. Tapia, S. Rab Green & D. Wagner. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 1♂, Río Chalpi Grande, 10 km W Cuyaja on Papallacta-Baeza Rd., 00°23′S, 78°00′W, 2800 m, 3 Mar 2006, MV light, leg. J.S. Miller, E. Tapia, S. Rab Green & D. Wagner (AMNH; genitalia slide no. JSM-1635); 1♂, Papallacta, 2780 m, 8 Jun 1997, leg. F. Piñas (FPC; genitalia slide no. JSM-944); 1♀, Papallacta, 2780 m, 8 Jun 1997, leg. F. Piñas (FPC; genitalia slide no. JSM-938).

Other Specimens Examined

None.

Dissected

2♂♂; 1♀.

Xenomigia sordida Dognin

Plate 22

Xenomigia sordida Dognin, 1913: 7.

Type Locality

Colombia, Monte Tolima, Central Cordillera, 3200 m.

Type

Holotype ♂, leg. Fassl (USNM type no. 33120).

Discussion

The only specimen of X. sordida I have been able to locate is the holotype (pl. 22). An undescribed taxon from the area of Cosanga, Ecuador (Napo Province) exhibits male genitalia (JSM-932, 946, 1651) extremely similar to those of X. sordida (JSM-934). In both species there is a small process on the dorsum of the uncus. This structure, unique for the genus as far as I am aware, is bifid in X. sordida, whereas it is thumblike in Cosanga material. The Ecuadorian taxon also has darker, narrower wings and occurs at a lower elevation (2000–2200 m).

Distribution

Colombia (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-934).

3. CONCINNA GROUP

In the Concinna Group, FW veins Rs2–Rs4 appear in the arrangement 2+[3+4], a relatively uncommon configuration among Dioptinae. It also occurs in some species within the sister group to Xenomigia, the Dolophrosyne + Scoturopsis clade (fig. 227D), as well as in several species groups of Polypoetes. A more subtle difference between the Concinna and Monticolata groups involves FW pattern, which is more contrasting in the former, often with complex combinations of dark brown, olive-brown and creamy white marks and lines. The FW veins of Concinna Group species are usually highlighted with orange scales. It should be noted, however, that my confidence in species membership for these two groups, as currently defined, is low; for certain taxa, genitalia seem to contradict wing venation and wing pattern.

KEY TO CONCINNA GROUP SPECIES (MALES)

Plates 22, 23

1. Forewing ground color brown to dark brown; HW creamy white to light gray-brown, thinly scaled, translucent; FW length variable (14.5–22.0 mm)2

FW ground color yellowish beige (pl. 23); HW slate gray, densely scaled; FW length  =  17.0 mm (Colombia)veninotata Warren

2. Ventrolateral margin of valva simple (fig. 240A), valva gradually narrowing toward apex; posterior margin of St8 forming a robust Y-shaped structure (fig. 240D), with a deep, V-shaped mesal excavation4

Ventrolateral margin of valva deeply excavated (figs. 241A, 242A), valva irregular in shape; posterior margin of St8 forming an inverted “V” (figs. 241B, 242C), without a deep mesal excavation3

3. Valva strongly bipartite, ventral two-thirds extremely wide, expanded below; valva apex broad, curving strongly downward (fig. 241A); FW with a diffuse, mottled pattern; FW length  =  20 mm (central Colombia)cuneifera Dognin

Ventral margin of valva strongly sinuate, deeply excavated distally; valva apex narrow, spatulate, curving sharply upward (fig. 242A); FW with an intricate, contrasting pattern; FW length  =  15.0–17.0 mm (western Ecuador)involuta, sp. nov.

4. Dorsal appendix of aedeagus extremely large, folds robust, surfaces sclerotized and coarsely dentate; apex of uncus large, arching strongly upward; FW pattern diffuse; FW length  =  22.0 mm (Monte Tolima, Colombia)fassli (Prout)

Dorsal appendix of aedeagus moderate in size (fig. 240B), folds fine, surfaces minutely spiculate; apex of uncus narrow, acute; FW with contrasting pattern; FW length  =  11.0 mm (Monte Socorro, Colombia)concinna Dognin

SPECIES INCLUDED AND MATERIAL EXAMINED

Xenomigia concinna Dognin

Figure 240; plate 22

Xenomigia concinna Dognin, 1911a: 22.

Type Locality

Colombia, Monte Socorro, 3400–3800 m.

Type

Holotype ♂, leg. Fassl (USNM type no. 33119)

Discussion

I have seen only one verified specimen of X. concinna—the holotype (pl. 22). A series of moths from Napo Province in Ecuador exhibits male genitalia (JSM-937, 949, 950, 951, 952, 953, 954) extremely similar to those of the X. concinna type. They differ in the shape of the anterior apophysis on St8, wide in the Ecuadorian taxon but narrow in X. concinna (fig. 240D). The valva of the Ecuadorian material is also wider. I conclude that there are two separate species, with the Napo taxon being undescribed.

A second undescribed species from Napo, relatively common at Yanayacu Biological Station, has male genitalia (JSM-931, 947, 948, 1473) similar to X. concinna, but differing in the shape of the valva apex and in the configuration of the posterior margin of St8. The wings of this taxon show more delicate patterning, their wing length (male FW  =  14.0–16.0 mm) is shorter than that of X. concinna (FW length  =  17.0 mm), and the HW is slightly darker. Otherwise, there are no striking differences. This second undescribed species is notable in that its larvae have been reared by Dyer et al. (2009) at Yanayacu on Chusquea (table 4). This same plant is undoubtedly the host for X. concinna as well.

Distribution

Colombia (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-933).

Xenomigia cuneifera Dognin, revised status

Figure 241; plate 22

Xenomigia cuneifera Dognin, 1913: 7.

Type Locality

Colombia, Monte Tolima, Central Cordillera, 3200 m.

Type

Holotype ♂, leg. Fassl (USNM type no. 33123)

Discussion

Hering (1925) erected the genus Ceraeotricha, with cuneifera as its only included species. Hering's generic diagnosis is based entirely on features of the wing venation, none of which are unique to Ceraeotricha. I am unsure what species Hering was using as his example of so-called cuneifera. Having examined the ZMH specimen labeled as “Ceraeotricha cuneifera”, I can state that it bears little resemblance to the USNM type, the only known example of cuneifera. The specimen Hering studied, collected in Colombia (2800 meters) and figured in his contribution to Seitz (Hering, 1925: fig. 68k), appears to be an undescribed Xenomigia species. Regardless, there are no grounds for creating a separate genus. I here place Ceraeotricha in synonymy, thus moving cuneifera back to Xenomigia, where it was originally described (Dognin, 1913).

Xenomigia cuneifera shows wing pattern resemblance to X. fassli (pl. 22), also known from above 3000 meters on Monte Tolima. Although the male genitalia of X. cuneifera (fig. 241) exhibit the basic synapomorphies of Xenomigia, they are also highly unusual, especially with regard to shape of the valva. Its genitalia set this species apart from other members of the genus.

Distribution

Colombia (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-935).

Xenomigia fassli (Prout), new combination revised status

Figure 237E; plate 22

Tolimicola fassli Prout, 1918: 404.

Type Locality

Colombia, Monte Tolima, 3800 m.

Type

Holotype ♂, leg. A.H. Fassl, Feb 1910 (BMNH).

Discussion

Previous authors have been enormously confused regarding the taxonomic status of most Xenomigia species. Xenomigia fassli is a prime example. When Prout (1918) described fassli, he erected the monobasic genus Tolimicola for it. Prout (1920) subsequently placed his own species fassli in synonymy with consanguinea Dognin, retaining the moth in Tolimicola. Hering (1925) then added nubilata Dognin. Bryk (1930) followed Hering, and added a third species, monticolata Massen. Overwhelming evidence shows that Tolimicola is a junior synonym of Xenomigia, so I have sunk it, thus uniting all its members with X. veninotata and relatives. There is a final twist: I here reinstate Prout's fassli to full species status. My reasons for doing so are outlined below.

I did not dissect the fassli type, but did study a BMNH male whose wing pattern matches it precisely, and which I regard to be conspecific. This example is from the same locality as the type, Monte Tolima, Colombia, but at a slightly lower elevation—3500 m as opposed to 3800 m. The wing pattern of X. fassli clearly differs from consanguinea, and its male genitalia (JSM-476) differ as well. I therefore conclude that the two are distinct, each deserving species status. I have, in fact, placed them in separate Xenomigia species groups (appendix 2). At the BMNH I discovered what I believe is a female of X. fassli (fig. 237E), also from Tolima (2700 m). The BMNH holdings contain a third male of X. fassli, bringing the total of known specimens to four.

Xenomigia fassli (pl. 22) can be recognized by its long, broad wings (FW length  =  22.0 mm; equal to those of X. consanguinea), in conjunction with having the FW strongly mottled with white. The unusual, folded dorsal appendix of the aedeagus, characteristic of Xenomigia, is hugely developed in X. fassli.

It is highly appropriate that Prout named this Xenomigia species in honor of Anton Hermann Fassl (1876–1944), the German collector. Of the nine previously described species in Xenomigia, the types of seven were collected by Fassl. Our knowledge of diversity in this genus, as well as in others throughout the Dioptinae, is thanks largely to him. Not only was Fassl a preeminent collector and explorer, he is also well known for providing important field observations on butterfly biology and life history, some of which stand even today as the sole source of information for certain species (see DeVries, 1997).

Distribution

Colombia (BMNH).

Dissected

♂, Colombia, Monte Tolima, 3500 m, Feb 1910, leg. A.H. Fassl, BMNH (genitalia slide no. JSM-476); ♀, Colombia, Cañon del Tolima, 2700 m, Dec 1909, leg. A.H. Fassl, BMNH (genitalia slide no. JSM-228, wing slide no. JSM-186).

Xenomigia involuta, new species

Figures 235A–D, 235G, 235F, 242, 243; plate 23

Diagnosis

The FW in Concinna Group species exhibits numerous pattern similarities. In all, the ground color is brown, the veins are lined to varying degrees with yellow or light orange, and there is a complex series of whitish markings, arranged in transverse lines. The HW is cream colored to light brown in color, usually without obvious markings. Xenomigia involuta has a more vibrant wing pattern than most other species in the Concinna Group, with more contrasting markings overall. Nevertheless, the most reliable way to distinguish X. involuta is by comparison of genital morphology.

The description below essentially follows the wing-pattern nomenclature of Forbes (1948, 1954, 1960), then conceived as a generalized pattern for moths, including the Notodontidae and Noctuidae.

Description

Male. Forewing length  =  14.5–16.0 mm. Head (fig. 235A–D): Labial palpus moderate in length, upturned to immediately above clypeus; all segments light brown to brown, lightest near base of Lp1; Lp1 elongate, curving upward, fringed below with longish, erect scales, Lp2 shorter than Lp1, Lp3 moderately long, bullet shaped; front entirely clothed in brown scales, pointing dorsomedially; frontal scales moderate in length, reaching dorsally to antennal bases, not beyond; occiput clothed in erect, brown scales; eye large, bulging, completely surrounded by scales, gena apparently absent; vertex covered with long brown scales posteriorly and short, light brown scales anteriorly; antenna quadripectinate, rami short; distal pair of rami slightly narrower than proximal pair; scape brown to light brown; dorsum of antennal shaft light brown.

Thorax: Legs, including spurs, brown to light silvery brown, metathoracic leg slightly lighter than others; pleural region covered with long, light brown to buff-colored scales, and a lower layer of short, buff-colored scales; patagium clothed with erect, brown scales; tegula whitish to orange-yellow in basal third, distal two-thirds covered with brown to dark brown hairlike scales, these longest at apex; dorsal areas of mesothorax clothed with long, posteriorly directed, dark brown scales; a pair of large, orange-yellow patches, lined with white scales, on lateroposterior regions of mesoscutum; anterolateral portions of mesoscutum white to light gray-brown; tympanal cavity large and deep, outer opening an upright, elongate rectangle, opening fairly small; tympanal membrane large, enclosed, subtriangular in shape, facing ventrally.

Forewing: (Dorsal) Ground color chocolate brown (pl. 23); veins, excluding costa but including anal fold, lined with orange-yellow scales; orange veins sometimes disrupted as they pass through brown areas; costa gray-brown; a small, white triangle near base behind DC; a faint white patch within DC in position of antemedial line; a thin, white, longitudinal line immediately behind costa in region between basal and medial lines; medial line creamy white, comprising two slightly disjointed parts, upper part thin, extending from anterior margin of DC to cubitus, lower part wider, extending from base of CuA2 to 1A+2A; a white patch beyond dorsolateral angle of DC, merging with semitransparent fascia to form an irregular, rectangular maculation, this rectangle extending from slightly short of costa to immediately below M2, SC and radial sector widely lined with orange-yellow as they pass through, M1 and M2 thinly orange-yellow; a thin, wavy, creamy white postmedial line extending from subcosta to anal margin, wider in posterior half; subterminal line comprising a series of small, creamy white wedges in cells between Rs4 and anal fold; outer margin thinly lined with white; fringe gray-brown with narrow, whitish yellow bands at vein apices; veins Rs2–Rs4 in the arrangement 2+[3+4]; stridulatory organ present, fascia small, veins M1 and M2 swollen; DC greater than one-half FW length. (Ventral) Uniformly gray-brown to light gray-brown, veins faintly lined with buff-colored scales, slightly more contrasting at outer margin; medial, postmedial, and subterminal lines showing slightly through from above; stridulatory organ comprising an ovoid fascia beyond DC, M1 and M2 swollen with a short fold between their bases; fringe light gray-brown with thin, buff-colored stripes at vein apices.

Hind wing: (Dorsal) Ground color creamy white (pl. 23), veins light cream; anterior margin light gray-brown; a faint, gray-brown band at outer margin extending from apex to CuA2, widest near apex, tapering posteriorly; outer margin thinly lined with yellow buff; fringe light gray-brown, with thin, yellow buff dashes beyond vein apices. (Ventral) Similar to dorsal surface.

Abdomen: Clothed entirely with long, gray-brown scales, lighter near base.

Terminalia (fig. 242A–D): Tg8 widest at base, narrower posteriorly, slightly concave on lateral margins; posterior half of Tg8 somewhat more sclerotized than anterior half, anterior margin simple, posterior margin with a slight mesal depression; St8 wider than Tg8, roughly triangular in shape, widest at lateral margins; anterior margin of St8 with an extremely large, broad triangular apodeme, almost as wide at tergum itself, posterior margin with a large, raised central process, wide at base, gradually narrowing distally, apex of process with a small, V-shaped mesal excavation; uncus/socii complex moderately large, narrowly attached to ring; uncus moderately wide, minutely truncate at apex; socii short, elbowed abruptly upward near bases, apices narrow, delicate; arms of tegumen narrow, much taller than vinculum; vinculum narrow, short; saccus forming a quadrate structure below, dorsal margin not reaching valva bases; juxta robust, with a V-shaped dorsal excavation; valva relatively long, complex in shape, mostly sclerotized; BO absent, pleats absent, a raised ridge present on valva inner surface, ridge covered with fine setae; costa of valva sclerotized, wide, arching gradually upward toward apex; ventral margin of valva complex, a small U-shaped depression near base, a large, blunt setose process one-half way out, a necklike constriction below apex; valva apex heavily sclerotized, broadly spatulate, margin bladelike, apex curved sharply inward; transtilla apparently absent; aedeagus short, sharply constricted in basal third, widest two-thirds out; apex of aedeagus abruptly narrowed to a recurved point; vesica minute, lacking cornuti; dorsum of aedeagus bearing a large appendix beyond two-thirds point, its surface lightly sclerotized, finely dentate, with complex folds.

Female. Forewing length  =  16.0–17.5 mm. Body coloring similar to male; labial palpus slightly shorter and thinner than male; antenna ciliate, base of each annulation bearing a set of coarse bristles.

Forewing: (Dorsal) Longer and broader than male; pattern similar to male, but ground color lighter brown and markings less contrasting; lower half of medial line thin, rather than wide as in male; frenulum comprising approximately five bristles. (Ventral) Similar to male.

Hind wing: (Dorsal) Ground color light gray-brown to slate gray; a diffuse, dark gray-brown marginal band, widest near apex; a second faint, transverse band near center of wing; fringe gray-brown with buff-colored dashes at vein apices. (Ventral) Similar to dorsal surface, but ground color slightly lighter.

Terminalia (fig. 242E): Tg7 roughly trapezoidal, widest at anterior margin, gradually narrower at posterior margin, distal half with a pair of large, ovoid sclerotized areas, separated near midline; anterior and posterior margins of Tg7 simple; St7 wide, shorter than Tg7, anterior margin simple; posterior margin of St7 smoothly concave, with a wide, sclerotized transverse groove near margin; Tg8 relatively long, lightly sclerotized, posterior margin forming a small, rooflike structure with a V-shaped notch at midline; AA absent; A8 pleuron sclerotized, forming a fairly narrow band, wider below; area surrounding ostium bulbous, surface finely setose; ostium itself small, membranous; DB short and narrow, membranous; DS arising from dorsum of DB; CB long, ovoid in distal two-thirds, narrow in basal one-third, constricted near DB; CB completely membranous, signum absent; PA lightly sclerotized, more heavily sclerotized near bases, their posterior margins produced slightly; PP extremely wide at their bases, apices forming tiny nubs.

Etymology

This name comes from the Latin word involuta, meaning “intricate” or “complex”, in reference to the FW pattern of this species. The complex appearance is derived from the contrasting markings in X. involuta; most other Xenomigia species show more subdued patterns (pls. 22, 23).

Distribution

Xenomigia involuta is endemic to cloud forests on the western slope of the Ecuadorian Andes (fig. 243). The majority of described Xenomigia species occur on the eastern slope. Of the 23 known X. involuta specimens, most were collected at approximately 2000 meters, but the species shows a fairly broad altitudinal range; the lowest recorded altitude is 475 meters, while the highest comes from a CMNH example captured in Carchi Province, 50 km W of Tufiño at 2510 meters. This Carchi locality is in extreme northern Ecuador on the Colombian border. The moth undoubtedly occurs into southern Colombia. So far, the southernmost limit of the species' range is El Chorro, in Cañar Province. Thus, based on available samples, X. involuta occurs in the northern three-fourths of Ecuador.

Discussion

The Xenomigia species most similar to X. involuta in wing pattern is X. concinna (pl. 22). The male genitalia of these two taxa share basic similarities, but are easily distinguishable. Most obviously, the lower margin of the valva is abruptly excavated below the apex in X. involuta (fig. 242A), whereas in X. concinna the valva's lower margin is essentially straight (fig. 240A).

Holotype

Male (pl. 23). Ecuador: Pichinchia: 35 km E Quito-Sto. Domingo Rd. on road to Chiriboga, 00°14.9′S, 78°48.8′W, 2010 m, 18 Mar 2006, cloud forest, MV light, leg. J.S. Miller & E. Tapia. The type is deposited at the AMNH.

Paratypes

Ecuador: Carchi: 1♂, 50 km W Tufiño, west slope, 2510 m, 19 Nov 1987, leg. R. Davidson, C. Young, cloud forest (CMNH). Pichinchia: 9♂♂, 1♀, 35 km E Quito-Sto. Domingo Rd. on road to Chiriboga, 00°14.9′S, 78°48.8′W, 2010 m, 18 Mar 2006, cloud forest, MV light, leg. J.S. Miller & E. Tapia (AMNH; ♂ genitalia slide no. JSM-1649); 4♂♂, 26 km WNW Machachi, 1900 m, 12 Nov 1987, leg. J. Rawlins, C. Young & R. Davidson, humid primary forest (CMNH; genitalia slide nos. JSM-477, JSM-898, JSM-1802); 2♂♂, La Virgen, main road 24 km E Toachi, S00°26.3′, W78°44.4′, 866 m, 26 Apr 2000, at light UV/MV, leg. S. Rab Green & I. Tapia (AMNH); 1♀, Las Palmeras, 59 km W Quito, 8 km W Chiriboga, 6400 ft, 25 Oct 1988, leg. J.S. Miller (AMNH; genitalia slide no. JSM-478). Cotopaxi: 2♂♂, 1♀, Reserva Otonga, S 00°25.3′, W 79°00.2′, 2000 m, 20 Aug 2001, at light UV/MV, leg. S. Rab Green & C. Tapia (AMNH). Cañar: 1♂, El Chorro, 20 km from La Troncal, S02°28.6′, W79°16.3′, 475 m, 11 Aug 2001, at light UV/MV, leg. S. Rab Green & M. Tapia (AMNH; genitalia slide no. JSM-1817).

Other Specimens Examined

None.

Dissected

3 ♂♂, 1♀.

Xenomigia veninotata Warren

Plate 23

Xenomigia veninotata Warren, 1906: 414.

Type Locality

“Colombia”.

Type

Holotype ♂ (USNM type no. 9173).

Discussion

Xenomigia veninotata is yet one more Xenomigia taxon known solely from the holotype (pl. 23). Unfortunately, the apex of the type's abdomen is missing. Since veninotata is the type species for Xenomigia, it will ultimately be important to locate a matching specimen for dissection. Otherwise, it will be difficult to stabilize this name, especially considering how difficult species identifications are in Xenomigia; in all cases, study of genitalia is crucial. The wing pattern of X. veninotata is relatively distinctive, with its yellowish overall tone and the presence of two irregular, elongate, whitish submarginal FW markings. However, an exhaustive search through the world's collections has not provided additional examples.

Distribution

Colombia (USNM).

Dissected

None.

The following species have been transferred from Xenomigia: disciplaga Hering to incertae sedis pallinervis Felder to Polypoetes (Persimilis Group) villiodes Prout to Polypoetes (Persimilis Group)

PAREUCHONTHA MILLER, 1989

Figures 244Figure 245Figure 246Figure 247248; plate 23

Figure 244

Morphology of Pareuchontha grandimacula (♂). A, head, lateral view; B, head, lateral view; C, wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f244.gif

Figure 245

Genitalia of Pareuchontha grandimacula (♂ JSM-271, ♀ JSM-272). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f245.gif

Figure 246

Holotype ♂ genitalia of Pareuchontha olibra, sp. nov. (JSM-1687). A, genitalia; B, aedeagus; C, Tg8; D, St8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f246.gif

Figure 247

Map of southern Colombia and northern Ecuador, showing the known distributions of Pareuchontha fuscivena, P. olibra, and Stenoplastis dyeri.

i0003-0090-321-1-1-f247.gif

Figure 248

Paratype ♂ genitalia of Pareuchontha fuscivena, sp. nov. (JSM-1623). A, genitalia; B, St8; C, Tg8; D, aedeagus.

i0003-0090-321-1-1-f248.gif

Pareuchontha Miller, 1989: 30. Type species: Stenoplastis grandimacula Dognin, 1902 (by original designation).

Diagnosis

Pareuchontha is distinguished by elongate wings, roughly quadrate at the outer margin (pl. 23). The FW is light brown to dark chocolate brown, with a well-developed stridulatory organ in males comprising a large, diffuse fascia beyond the DC (fig. 244C). The FW veins are lined with light brown to yellow-brown scales. Pareuchontha albipes (Maassen) is the only member of the genus showing a white basal streak on the FW dorsal and ventral surfaces, although a white streak occurs on the ventral surface in the newly described P. olbra. The HW of Pareuchontha species exhibits a wide, dark brown marginal band and a yellowish or white central area.

Morphological evidence (Miller, 1989), including that presented in the current work, shows that Pareuchontha is the sister genus to Euchontha (fig. 7), but the two can be easily separated: the labial palpus in Pareuchontha is much shorter (compare figs. 244A, B; 249A, B); the wings are narrower (figs. 244C, 249C) with a longer FW DC; and the antenna is densely ciliate, rather than quadripectinate as in Euchontha. The two genera share the presence of small eyes, the gena being broadly scaleless, and both exhibit similar tympanal morphology (Miller, 1989). Males of both are unusual for Dioptinae in possessing a short, conical scale tuft on Tg8 at the abdominal apex.

Redescription

Male. FW length  =  12.5–15.5 mm. Head (fig. 244A, B): Labial palpus short, curving strongly upward, reaching only to slightly above clypeus; Lp1 over one-half palpus length, with a loose, ridgelike ventral fringe of long scales; Lp2 much shorter than Lp1, with a short ventral fringe; Lp3 small, quadrate; scales of front tightly packed, pointing dorsomedially, forming short, triangular tufts between antennal bases; eye small, completely surrounded by a scaleless spiculate area, this area narrow along anterior and posterior margins of eye, wider dorsally and extremely wide ventrally; scales of vertex moderately long, pointing anteriorly; antenna subserrate, each annulation bearing two dense transverse rows of cilia, the basal row set on a short flange.

Thorax: Epiphysis moderately long, approximately one-half length of tibia, its apex falling well short of tibia apex; tegula short, wide, less than one-third length of mesoscutum, distal portion rounded, ventral portion wide and blunt; metathoracic tympanum moderately large, cavity deep, scaleless, area above membrane heavily sclerotized, scaleless, protruding laterally from body to form a shelf; tympanal membrane moderately large, ovoid, oriented horizontally.

Forewing (fig. 244C; pl. 23): Elongate, outer margin quadrate; vein Rs1 arising from DC; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from anterolateral angle of DC close to, or touching, base of radial sector; stridulatory organ well developed; DC short, approximately one-third FW length; a large, diffuse, whitish or yellowish ovoid fascia beyond DC, its surface sparsely covered with short scales; bases of veins M1 and M2 swollen in fascia, protruding from wing surface below, with a distinct fold between them; veins M3 and CuA1 long stalked; ground color light brown to dark chocolate brown, veins lined with light brown to yellow brown scales, especially contrasting beyond fascia.

Hind wing (fig. 244C; pl. 23): Roughly triangular, angulate at apex; M3 and CuA1 long stalked; ground color chocolate brown to dark brown, central area white or light yellow with veins, especially cubitus, sometimes sparsely lined with brown scales (P. fuscivena).

Abdomen: Relatively short, apex acute, with a short, conical dorsal tuft on Tg8.

Terminalia (245A–D, 246, 248): Tg8 longer than Tg7, slightly wider anteriorly, anterior margin with a pair of short, wide apodemes, posterior margin either smoothly rounded (Albipes Group) or with a long, sclerotized central process (Grandimacula Group); St8 shorter than Tg8, narrowing posteriorly, anterior margin broadly convex, posterior margin sclerotized, emarginate; socii/uncus complex narrowly attached to tegumen, wide at base; uncus bifid (Albipes Group) or trifid (Grandimacula Group); socii small, digitate, upturned; tegumen moderately wide, sides roughly parallel, tegumen taller than vinculum; vinculum narrow; saccus large, forming a cone-shaped structure below, ventral margin of cone blunt (P. albipes), truncate (P. olibra) or acute (P. grandimacula, P. albimargo); valva short and wide, simple, evenly sclerotized except membranous in central portion; BO absent; costa of valva wide or obscure; apex simple and rounded (Albipes Group) or with a small spatulate, sclerotized process (Grandimacula Group); arms of transtilla extremely wide, oriented horizontally, meeting at midline to form a small fold; aedeagus relatively long and wide, wider at base; apex of aedeagus with a digitate ventral process; vesica short, ovoid, bearing approximately 15–24 long, narrow, spinelike cornuti.

Female (based on P. grandimacula only). FW length  =  18.0–19.0 mm. Head, thorax, and wings similar to those of male except: antenna finely ciliate; wings longer and broader, HW outer margin more rounded; FW DC longer, slightly less than one-half FW length; frenulum comprising approximately six bristles; abdomen shorter and wider, bearing a large corethrogyne comprising a large, wide mass of deciduous scales on A7 and A8.

Terminalia (fig. 245E): Tg7 large, membranous, bearing a corethrogyne; Tg8 short, lightly sclerotized; a glandular invagination present between Tg8 and PA; AA short, blunt; A8 pleuron membranous; PP long, thin; PA large, ovoid, posterior margin slightly emarginate above; PVP wide, smooth; DB short, sclerotized, ostium funnel shaped; CB ovoid, narrow in basal half; signum absent; DS arising dorsally near junction between narrow portion of CB and DB.

Distribution

Of the five described Pareuchontha species, four are exclusive to the eastern slope of the Andes, at elevations between 800 and 3000 meters. These occur from Ecuador south to Bolivia. The newly described P. fuscivena, recorded at 1700 m in Colombia, is unique in occurring on the Pacific slope. So far, Pareuchontha is not known from Central America or from the Venezuelan Andes.

Biology

Nothing is known concerning the biology of Pareuchontha, except that adult males are frequently observed resting (presumably drinking) on wet rocks along or in quickly moving rivers and streams. This behavior, similar to the puddling behavior observed in Euchontha, may serve the same function—sodium uptake (see Euchontha Biology, below).

Females of Pareuchontha bear a conspicuous corethrogyne on the apex of the abdomen, the deciduous scales of which are presumably used to cover the eggs during oviposition. This structure is not found in Euchontha females, but it does occur in a dioptine clade closely related to Pareuchontha (Clade 17; fig. 7), comprising three genera—Stenoplastis, Isostyla, and Tithraustes. Analogous structures are found in the notodontid subfamily Thaumetopoeinae (Miller, 1991; Weller, 1992; Common, 1979; Floater, 1998), as well as in several other families of the Noctuoidea, including the Noctuidae (e.g., Levine and Chandler, 1976) and Lymantriidae (e.g., Ferguson, 1978). Its function, as well as its distribution across Lepidoptera, are discussed in Methods: Morphology (above).

Discussion

Pareuchontha grandimacula was initially placed in Stenoplastis because of its ciliate or subserrate male antennae (Prout, 1918; Hering, 1925). Miller (1989) erected the genus Pareuchontha to include grandimacula, as well as two species from Ecuador described in that paper—albimargo and wormsi. In what amounts to a humbling new experience, I here synonimize my 1989 name, wormsi, with albipes Maassen (see below). Undaunted, two new Pareuchontha species are described—fuscivena from western Colombia and olibra from Napo, Ecuador. Pareuchontha now totals five species, broken into two species groups based on differences in male genital morphology. The veracity of these subgroups deserves futher testing, but they serve as a starting point for future work; my previous revision (Miller, 1989) is now in serious need of revision.

When first described (Miller, 1989), Pareuchontha was proposed as the sister group to Euchontha. The current data from adult morphology provides only weak support for that hypothesis; the clade comprising Pareuchontha + Euchontha has a BS value of only 2 (fig. 2). The genera differ in fundamental ways. For example, females of Pareuchontha possess a corethrogyne whereas Euchontha does not. Additionally, Pareuchontha is not known from the Amazon Basin, whereas the Frigida Group of Euchontha is well represented there. An analysis of generic interrelationships utilizing a more extensive data set would be informative.

KEY TO PAREUCHONTHA SPECIES GROUPS (MALES)

1. Posterior margin of Tg8 broadly convex (fig. 248C); valva apex rounded, without a distal process (fig. 248A); margins of FW fascia (dorsal surface) poorly definedAlbipes Group

2. Posterior margin of Tg8 bearing a long, spinelike central process (figs. 245C, 246C); valva apex bearing a small spatulate or large triangular process along dorsal margin (figs. 245A, 246A); margins of FW fascia relatively well-definedGrandimacula Group

1. GRANDIMACULA GROUP

The three Grandimacula Group species are united by presence of a long, spinelike process on the posterior margin of male Tg8. This structure can be observed in intact pinned specimens; dissection is not required. Females are known for a single species in Pareuchontha, P. grandimacula. It will be important to find females for the remaining taxa to see whether they provide characters for further elucidating relationships within the genus.

KEY TO GRANDIMACULA GROUP SPECIES (MALES)

1. Hind wing anal margin brown or gray-brown; FW fascia dusted with brown scales, especially along veins M1 and M22

HW anal margin white; FW fascia completely white, veins M1 and M2 white as they pass through (E Ecuador S to Central Peru)albimargo Miller

2. Forewing ground color olive brown; FW fascia and HW central area light yellow; FW ventral surface without a white basal streak; valva (fig. 245A) with a small, spatulate distal process (NE Peru S to NE Bolivia)grandimacula (Dognin)

FW ground color chocolate brown; FW fascia semihyaline, HW central area white; FW ventral surface with a conspicuous white basal streak; valva (fig. 246A) with a large, triangular distal process (E Ecuador)olibra, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Pareuchontha albimargo Miller

Plate 23

Pareuchontha albimargo Miller, 1989: 35–37.

Type Locality

Ecuador, Napo-Pastaza, Puyo, 1000 m.

Type

Holotype ♂ (AMNH).

Discussion

Pareuchontha albimargo differs from other Pareuchontha species in exhibiting a white, rather than brown, HW anal margin. Its male genitalia are extremely similar to those of P. grandimacula, showing only subtle differences. On these grounds, I decided (Miller, 1989) that the two constitute separate species. In retrospect, they may be synonyms; newly discovered material from Peru (LACM) seems to intergrade in wing pattern between P. albimargo and P. grandimacula. Discovery of P. albimargo females may ultimately provide clues for resolving this problem.

Distribution

Ecuador (AMNH); Peru (AMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-274); ♂, Peru, Junín, Satipo, AMNH (genitalia slide no. JSM-280).

Pareuchontha grandimacula (Dognin)

Figures 244, 245; plate 23 [EX]

Stenoplastis grandimacula Dognin, 1902: 474.

Type Locality

Bolivia, Río Songo, La Paz.

Type

Syntype ♂ (USNM Type no. 30950).

Momonipta euchonthoides Prout, 1918: 413.

Type Locality

Bolivia, La Paz, 1000 m.

Type

Holotype ♂ (BMNH).

Stenoplastis inversa Dognin, 1916: 18.

Type Locality

Bolivia, Yungas de La Paz, 1000 m.

Type

Syntype ♂ (USNM Type no. 30952).

Stenoplastis lactigera Hering, 1925: 519.

Type Locality

Peru, Junín, Chanchamayo.

Type

Holotype ♂ (ZMH).

Stenoplastis occlusa Dognin, 1916: 18.

Type Locality

S Peru, Chaquimayo, 2500–3000 ft.

Type

Syntype ♂, leg. H. & C. Watkins, Jun 7 1919 (USNM Type no. 30951).

Discussion

I have here, for the first time, dissected Dognin's (1902) male syntype of P. grandimacula, as well as types for the two subspecies he later described—inversa and occlusa (Dognin, 1916). In Miller (1989), it was hypothesized that all represent a single taxon (grandimacula), although dissections had not then been done. These three vary slightly in the amount of dark pigment present in the FW and HW. Their male genitalia are extremely similar, but slight differences occur. For example, based on a somewhat different valva shape and a shorter, more robust Tg8 spine, the name occlusa (Chaquimayo, Peru) potentially represents a species distinct from grandimacula (La Paz, Bolivia). I leave resolution of the issue for future research, and retain that name in synonymy. I did not dissect the types of euchonthoides Prout or lactigera Hering. To resolve the taxonomy of this group, additional material is sorely needed.

According to the species concept accepted here, P. grandimacula is restricted to southern Peru and Bolivia, whereas the other described members of Pareuchontha are found in Ecuador and Colombia.

Distribution

Bolivia (BMNH, USNM, ZMH); Peru (AMNH, BMNH, USNM, ZMH).

Dissected

Syntype ♂ of grandimacula Dognin, USNM (JSM-1798); syntype ♂ of inversa Dognin, USNM (JSM-1799); syntype ♂ of occlusa Dognin, USNM (JSM-1800); ♂, Bolivia, BMNH (genitalia slide no. JSM-272); ♂, Bolivia, Wm. Schaus Collection, USNM (wing slide no. JSM-1252, genitalia slide no. JSM-1253); ♀, Bolivia, BMNH (genitalia slide no. JSM-271).

Pareuchontha olibra, new species

Figures 246, 247; plate 23

Diagnosis

Pareuchontha olibra possesses a narrower FW than other species in the genus, and its HW apex is more acutely angled (pl. 23). Presence of a spinelike distal process on male Tg8 (fig. 246C) confirms placement in the Grandimacula Group, along with P. grandimacula and P. albimargo. Among other features, it differs from these in showing a more elongate, rather than ovoid, FW fascia. On the FW ventral surface, P. olibra exhibits a white basal streak behind the cubital vein. A similar streak occurs in P. albipes of the Albipes Group. However, the FW of P. albipes—a larger moth—is whiter on both surfaces, and its pattern is irregular (pl. 23).

The front in most Pareuchontha species exhibits a pair of diffuse, light yellow dorsoventral stripes. Pareuchontha olibra is unusual in lacking these stripes; instead the front is evenly covered with a mixture of light yellow and light gray-brown scales. The male genitalia of P. olibra provide the most reliable distinguishing characters. For example, the broadly triangular valva apex (fig. 246A) is unique, as is the shape of the socii/uncus complex.

Description

Male. Forewing length  =  14.0 mm. Head: Labial palpus short, porrect, curving upward to slightly above clypeus; Lp1 moderately long, curving gently upward, light yellow with a loose ventral fringe of longer scales; Lp2 much shorter than Lp1, lateral surfaces light gray-brown, mesal surfaces with bristlelike, creamy white scales; Lp3 tiny, gray-brown with a few cream-colored scales at apex; front tightly scaled, scales pointing dorsomedially, forming a fanlike swirl below antennal bases; central portion of front covered with an even mixture of light gray-brown and creamy white scales, lateral portions light gray-brown; occiput with a narrow band of short white scales immediately behind eye, a wider band of long, light gray-brown scales behind that; eye small, surrounded by a scaleless band, gena wide, quadrate, broadly scaleless; vertex covered with moderately long, gray-brown, anteriorly directed scales, a few creamy white scales behind each antennal base; antenna subserrate, each annulation bearing a pair of transverse whirls of setae, rami absent, the basal whirl set on a raised transverse ridge; dorsum of antennal shaft glossy dark gray-brown.

Thorax: Inner surfaces of legs creamy white, outer surfaces gray-brown; pleuron covered with hairlike gray-brown and cream-colored scales, as well as a layer of short, gray-brown scales; patagium clothed with a mixture of long, erect, light gray-brown and darker gray-brown scales; central area of tegula light orange-yellow, apex with a fringe of long hairlike, gray-brown scales, ventral angle whitish gray-brown; dorsum dark gray-brown with a wide, longitudinal, light gray to reddish brown band on each side of midline; tympanal cavity moderately deep, its surface scaleless; area above tympanal membrane heavily sclerotized, protruding laterally from body; membrane moderate in size, ovoid, oriented horizontally.

Forewing: (Dorsal) Ground color chocolate brown (pl. 23); veins, including anal fold, conspicuously outlined with light reddish-brown scales; a semihyaline, elongate ovoid fascia present immediately beyond DC, its surface sparsely covered with brown scales, bases of M1 and M2 light brown within fascia; basal margin of fascia bordered with dark brown scales; a diffuse, light reddish-brown longitudinal streak lying between cubitus and anal fold, streak extending from base to posterolateral angle of DC. (Ventral) Ground color glossy gray-brown; veins concolorous, not contrasting; fascia larger and better defined than on dorsal surface; fascia evenly covered with pedicellate white scales; a long, white streak located between cubitus and anal fold, extending from base to fork of M3+CuA1; an infusion of white scales within DC.

Hind wing: (Dorsal) A large immaculate white central area extending from base to near fork of M3+CuA1 (pl. 23), touching radius anteriorly, terminating at vein 2A posteriorly; HW outer margin with a wide, dark brown band; anterior margin a mixture of white and light brown scales; anal margin gray-brown, bearing a fringe of long, hairlike scales. (Ventral) Central area silvery white, larger than on dorsal surface, extending from Sc+R anteriorly, to anal margin posteriorly; outer margin dark gray-brown, slightly lighter than on dorsal surface.

Abdomen: Dorsum gray-brown; venter white.

Terminalia (fig. 246): Tg8 relatively small, roughly trapezoidal, narrower and longer than Tg7, anterior margin with a pair of short wide apodemes, lateral margins slightly excavated, posterior margin bearing an extremely long, spinelike mesal process; St8 slightly longer than Tg8 (excluding spinelike process), anterior margin forming a broad, triangular mesal apodeme, with elongate projections at anterolateral angles; lateral margins of St8 forming rounded shoulders in posterior half, then abruptly narrowed, posterior margin transverse, with a tiny mesal excavation; socii/uncus complex relatively small, narrowly joined to arms of tegumen; uncus short and wide, apex truncate with a shallow mesal excavation; socii short, curving upward, their apices digitate; arms of tegumen moderately wide, sides parallel, tegumen taller than vinculum; arms of vinculum narrower than tegumen, forming a large, triangular saccus ventrally, its central process truncate; dorsal margin of saccus triangular, slightly covering ventral angles of valvae; valva broadly rounded, lightly sclerotized, apex forming a large triangular process; inner surface of valva featureless, except for a pair of small transverse folds near ventral margin, and a sparse covering of setae; BO completely absent; costa indicated by a narrow band, falling well short of apex; ventromedial angle of valva narrow, tapered toward midline; juxta apparently absent; arms of transtilla wide, meeting at midline above aedeagus to form a small, concave, triangular sclerite; aedeagus long, roughly cylindrical, gently curved, narrower distally; aedeagus “open” anteriorly, apex bearing a long, narrow, digitate ventral process; vesica short, ovoid, slightly wider than aedeagus, bearing a large cluster of long, thin spinelike cornuti, deciduous cornuti absent.

Female. Unknown.

Etymology

This species name comes from the Greek word olibros, meaning “slippery”. It refers to the large, slippery boulders in the shallows of the Río Hollín (pl. 45C, D), upon which the holotype of P. olibra was captured.

Distribution

Pareuchontha olibra is known from a single example, collected on the eastern slope of the Ecuadorian Andes (fig. 247) at the point where the road heading east from Narupa toward Loreto crosses the Río Hollín (pl. 45B–D). The approximate coordinates of that locale, at roughly 1200 meters elevation, are 0°41′20″S, 77°43′30″W. The species' distribution will obviously expand as additional material comes to light.

Biology

Nothing is known regarding the biology of Pareuchontha olibra, except that the sole known specimen was captured during the day, resting on the wet surface of a large, smooth boulder in the river shallows (pl. 45D). Presumably, this individual was imbibing water to sequester sodium (see Euchontha Biology, below).

Discussion

The habitus of P. olibra is similar to that of P. albipes (pl. 23). The two species exhibit a white HW central area, as well as a white basal streak, present on the FW ventral surface in P. olibra, but on both wing surfaces in P. albipes. The FW of P. albimargo is suffused with white in this region, but there is no coherent streak. In all other described Pareuchontha, only a few white scales are present in this region.

When male genitalia are compared, P. olibra appears to be more closely related to P. grandimacula and P. albimargo than to P. albipes. This statement is supported by valva shape (fig. 246A), and by the configuration of Tg8 (fig. 246C).

Holotype

Male (pl. 23). Ecuador: Napo: Río Hollín, 20 km W Baeza-Tena Rd. on Loreto-Coca Rd., 1150 m, 2 Oct 2004, day collecting, leg. E. Tapia & J.S. Miller (genitalia slide no. JSM-1687). The type is deposited at the AMNH.

Paratypes

None.

Other Specimens Examined

None.

Dissected

Holotype.

2. ALBIPES GROUP

The Albipes Group contains only two species—those lacking a mesal spine on the posterior margin of male Tg8 (fig. 248C), and lacking a distal process of the valva (fig. 248A). The wing patterns of Albipes Group taxa are quite divergent (pl. 23), and seem to better correspond with particular species in the Grandimacula Group: albipes with olibra, and fuscivena with grandimacula. Nevertheless, I here defer to genitalia morphology for species-group assignments.

KEY TO ALBIPES GROUP SPECIES (MALES)

2. Forewing ground color dark brown, dorsal surface with a white streak along anal fold from base to fascia; FW veins narrowly lined with light brown; St8 wide, lateral margins expanded; valva broadly quadrate, with a flange on inner surface near apex; saccus blunt ventrally; aedeagus with a short ventral process; FW length  =  15.0–15.5 mm (E Ecuador)albipes (Maassen)

FW ground color olive brown, dorsal surface without a white streak; FW veins widely lined with light brown; St8 ovoid (fig. 248B), lateral margins gently convex; valva gradually narrowed, with only a tiny transverse fold near apex (fig. 248A); saccus acute ventrally; aedeagus with a relatively long ventral process (fig. 248D); FW length  =  14.0–15.0 mm (W Colombia)fuscivena, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Pareuchontha albipes (Maassen), new combination

Plate 23

Cymopsis albipes Maassen 1890: 130; pl. 4, fig. 23.

Type Locality

Ecuador, btwn. Baños and Jivaría del Píntuc, 900–1500 m.

Type

Holotype ♂, leg. Alphons Stübel (ZMH).

Pareuchontha wormsi Miller, 1989: 37–39. New synonymy.

Type Locality

Ecuador, Tungurahua, Hacienda La Mascota, Río Topo, 4500 ft.

Type

Holotype ♂ (CMNH).

Discussion

In 1989, I described P. wormsi, unaware that Maassen (1890) had described the species a century before. He assigned it to the dioptine genus Cymopsis C. and R. Felder, currently a synonym of Scotura, where it has apparently resided ever since. The name albipes was not mentioned in synthetic publications on the Dioptinae (Prout, 1918; Hering, 1925; Bryk, 1930). Furthermore, the albipes holotype, housed at the ZMH—a collection I have visited on numerous occasions—was not associated with the rest of the Dioptinae, which had been meticulously curated by Martin Hering in the 1920s. Not until August 2007, while inadvertently examining the color illustrations in Maassen (1890), did I realize my error. The holotype of albipes was then borrowed and dissected (JSM-1796), confirming the new synonymy. This finding arouses the nagging suspicion that additional dioptine types may be lurking, unrecognized, in collections around the world.

Pareuchontha albipes (pl. 22) is known from the type, from four additional males—the holotype of wormsi (CMNH), two examples collected by Julian Donohue (LACM), and a specimen at the Naturhistorisches Museum (Vienna)—as well as from a large series in the private collection of Francisco Piñas (Quito, Ecuador). A single individual of P. albipes from Río Suña (LACM) is unusual in being almost completely dark on its wing dorsal surfaces, without the white basal streak or the white HW central area found in other examples. Its wing ventral surfaces typify P. albipes, and its genitalia (not dissected) presumably do as well.

Distribution

Ecuador (CMNH, FPC, LACM, NMW, ZMH).

Dissected

Holotype ♂ (JSM-1796); ♂, Ecuador, Pastaza, Topo, Río Suña, 1250 m, 29 Jun 1980, leg. J.P. & K.E. Donahue, LACM (genitalia slide no. JSM-273).

Pareuchontha fuscivena, new species

Figures 247, 248; plate 23

Diagnosis

The species with which P. fuscivena, from Colombia, could most easily be confused is P. grandimacula (pl. 23), from northern Bolivia and southeastern Peru. In both, the FW is olive brown and the veins stand out in contrast, outlined with light brown. The FW and HW maculations are white to light yellow. The most reliable way to distinguish these two taxa is that the HW central area is uniformly light yellow to whitish yellow in most specimens of P. grandimacula, whereas in P. fuscivena, the cubitus—including the fork of M3+CuA1—is lined with brown scales. The USNM holotype of occlusa Dognin, described as a form of grandimacula and currently placed in synonymy with it, shows an even suffusion of brown scales in the HW central area, but its cubitus is not marked.

A more subtle difference between P. grandimacula and P. fuscivena is that the yellowish FW fascia is clearly defined in the former, but is diffuse and poorly defined in the latter. Their male genitalia are so different as to suggest placement in separate Pareuchontha species groups. For example, the long mesal spine on the posterior margin of Tg8 in P. grandimacula (fig. 245C) is absent in P. fuscivena (fig. 248C). Their valvae differ dramatically in shape (compare figs. 245A and 248A).

Description

Male. Forewing length  =  14.0–15.0 mm. Head: Labial palpus short, curving upward to lower third of front; Lp1 moderately long, curving gently upward, lateral surface lemon yellow to orange-yellow, with a loose ventral fringe of longer scales, mesal surface creamy white; Lp2 much shorter than Lp1, light brown with white scales at base and on mesal surface; Lp3 tiny, light brown with a few yellowish to cream-colored scales at apex; scales of front pointing dorsomesally, forming a fanlike swirl below each antennal base, midline scaleless; front light brown, with light yellow and cream-colored scales mixed in, one specimen with a vertical band of yellow scales on each side of midline; occiput light yellow to creamy white, light brown posteriorly; eye small, surrounded by a narrow scaleless band, gena wide, quadrate, broadly scaleless; vertex covered with moderately long, light brown, anteriorly directed scales; antenna subserrate, each annulation bearing two transverse whirls of setae, the basal whirl set on a raised transverse ridge; dorsum of antennal shaft glossy coppery brown.

Thorax: Inner surfaces of legs white to creamy white, outer surfaces glossy light brown; pleuron mostly covered with hairlike and shorter gray-brown scales, a few cream-colored and light yellow hairlike scales mixed in; patagium covered with erect, light brown scales; central area of tegula orange-yellow, distal portion with a fringe of long hairlike, light brown scales, ventral angle light brown; dorsum brown to light brown; area above tympanal membrane heavily sclerotized, protruding laterally from body; membrane moderate in size, ovoid, oriented horizontally.

Forewing: (Dorsal) Ground color olive brown (pl. 23), slightly darker along anal margin; veins, including anal fold, conspicuously outlined with tan to light brown scales; a diffuse, ovoid fascia present immediately beyond DC, its surface sparsely covered with brown scales, bases of M1 and M2 tan colored within fascia; basal margin of fascia bordered with dark brown scales; a diffuse light brown to semihyaline, longitudinal streak lying between cubitus and anal fold, streak extending from near base to posterolateral angle of DC. (Ventral) Ground color olive brown; veins thinly lined with light brown scales, not as contrasting as on dorsal surface; fascia larger and better defined than on dorsal surface; fascia sparsely covered with long, pedicellate light yellow scales (white in one specimen); an infusion of light yellow (or white) scales within DC, and between cubitus and anal fold.

Hind wing: (Dorsal) Ground color chocolate brown to dark brown (pl. 23), generally darker than in FW; a relatively small central area of light lemon yellow, or in one specimen, immaculate white; cubital vein, including stem of M3+CuA1, lined with dark brown scales as it passes through light-colored area; radius and base of M2 sparsely lined with dark brown scales. (Ventral) Ground color lighter brown than on dorsal surface; light lemon yellow (or white) central area much larger than on dorsal surface, extending from Sc+R anteriorly to 2A posteriorly; veins not dark as they pass through light-colored area.

Abdomen: Dorsum chocolate brown to dark brown; venter creamy white to light lemon yellow; a short, acute brown tuft distally.

Terminalia (figs. 248): Tg8 large, roughly rectangular, almost twice as long as Tg7, anterior margin with a pair of robust, triangular apodemes, lateral margins slightly excavated, posterior margin broadly convex; St8 much shorter and narrower than Tg8, anterior margin with a single wide, blunt mesal apodeme as well as elongate projections at anterolateral angles, lateral margins convex, abruptly narrowed posteriorly, posterior margin of St8 sclerotized, transverse; socii/uncus complex short, robust, broadly joined to arms of tegumen; uncus wide and short, broadly bifid distally, apices rounded; socii relatively short, curled strongly upward, their apices acute; arms of tegumen relatively wide, sides parallel, tegumen slightly taller than vinculum; arms of vinculum forming a large, triangular saccus ventrally, its central process acute, dorsal margin of saccus convex, slightly covering ventral angles of valvae; valva large, lightly sclerotized, apex broadly rounded; inner surface of valva featureless except for a small transverse fold below apex, and a sparse covering of short setae; BO completely absent, that area marked by a narrow, low ridge near valva margin; costa short, wide at base, tapered distally, not reaching apex; ventromedial angle of valva narrow, tapered toward midline; juxta apparently absent; arms of transtilla robust, relatively wide, gently sinuate, meeting at midline above aedeagus to form a small, concave sclerite; aedeagus robust, wide, moderately long, roughly cylindrical, “open” anteriorly; apex of aedeagus bearing a narrow, digitate ventral process, opercular sclerite extremely narrow; vesica short, ovoid, wider than aedeagus, bearing a loose cluster of long, spinelike cornuti, deciduous cornuti absent.

Female. Unknown.

Etymology

This species name combines two Latin words—fuscus, meaning “tawny” or “dark”, and vena, a “vein”. It refers to a diagnostic trait of P. fuscivena, in which the HW cubital vein is lined with dark brown scales as it passes through the light-colored central area.

Distribution

Pareuchontha fuscivena has been recorded from a single site, Tambito, in Departamento Chocó, Colombia (fig. 247). This town, at 4°58′N, 76°29′W, is in the western foothills of the Andes approximately 35 km SE of Istmina. Not only is P. fuscivena the sole Pareuchontha taxon endemic to Colombia, but it is unique in occurring on the Pacific side of the Andes. All other described species occur on the eastern slope, from Ecuador south to Bolivia.

Biology

Nothing is known regarding the biology of P. fuscivena.

Discussion

As is noted in the Diagnosis above, wing-pattern similarities potentially indicate a close relationship between P. fuscivena and P. grandimacula. On the contrary, their genitalia provide characters placing them in different species groups of Pareuchontha. Genital synapomorphies, especially involving the uncus, socii, and valvae, instead demonstrate that P. fuscivena is the sister species to P. albipes, from eastern Ecuador.

Holotype

Male (pl. 23). Colombia: Chocó: Tambito, 1700 m, Aug 1946, leg. Von Schneidern. The holotype is deposited at the AMNH.

Paratypes

Colombia: Chocó: 2♂♂, Tambito, 1700 m, Aug 1946, leg. Von Schneidern (AMNH; genitalia slide no. JSM-1623).

Other Specimens Examined

None.

Dissected

1♂.

EUCHONTHA WALKER, 1865

Figures 249Figure 250Figure 251Figure 252Figure 253254; plate 23

Figure 249

Morphology of Euchontha (♂♂). A, head of E. carboniptera, lateral view; B, head of E. frigida, lateral view; C, E. frigida wings; D, E. frigida tegula (illustration by J.S. Miller).

i0003-0090-321-1-1-f249.gif

Figure 250

Genitalia of Euchontha anomala (♂ JSM-240, holotype ♀ JSM-276). A, ♀ genitalia; B, ♂ St8; C, aedeagus; D, ♂ genitalia (illustration by J.S. Miller).

i0003-0090-321-1-1-f250.gif

Figure 251

Holotype ♂ genitalia of Euchontha carboniptera, sp. nov. (JSM-1561). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f251.gif

Figure 252

Peru, showing the known distribution of Euchontha carboniptera, sp. nov.

i0003-0090-321-1-1-f252.gif

Figure 253

Genitalia of Euchontha ciris Druce. A, ♂ genitalia (JSM-247); B, aedeagus; C, ♀ genitalia (JSM-249) (illustration by J.S. Miller).

i0003-0090-321-1-1-f253.gif

Figure 254

Male genitalia of Euchontha commixta Warren (JSM-1564). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f254.gif

Euchontha Walker, 1865: 383. Type species: E. sublactigera Walker, 1865 (by monotypy); E. sublactigera is a junior subjective synonym of E. frigida Walker (1864).

Diagnosis

Euchontha species (pl. 23) are relatively easy to recognize. The FW is broad and triangular, with an acute apical angle. Usually they are boldly marked with white against a dark brown or blackish-brown ground color. The male FW stridulatory organ is highly developed (fig. 249C), comprising an extremely short DC (approximately one-fifth the wing length) with a prominent, corrugated region in the fascia beyond it. The bases of veins M1 and M2 protrude markedly from the ventral surface of the FW fascia. Euchontha females are unusual in having a highly shortened DC as well (Miller, 1989). However, females do not exhibit the other stridulatory organ modifications, such as the corrugated fascia or swollen M1 and M2. The male antenna in Euchontha is quadripectinate, a derived trait shared with Dioptis (fig. 188C, D) and Xenomigia, but these genera are impossible to confuse; their wing patterns are extremely different. Furthermore, the FW DC in Dioptis and Xenomigia males is longer (figs. 190D–G, 235G, 235H).

Redescription

Male. FW length  =  13.0–18.5 mm. Head (fig. 249A, B): Labial palpus long, joint between Lp1 and Lp2 elbowlike, palpus often held folded over front, apex then reaching to immediately below antennal base; Lp1 long, almost straight, with a loose fringe of scales below; Lp2 long, almost straight, wider and curving slightly upward distally; apex of Lp2 with a large, wide, brushlike scale tuft of long scales, tuft obscuring Lp3; Lp3 short and small; scales of front short, erect, tightly packed, pointing inward to form a raised cone, broadly scaleless at its center; eye small, surrounded dorsally, anteriorly and ventrally by a scaleless area, this becoming extremely wide, quadrate below, surface of scaleless area finely spiculate; scales of vertex moderately long, pointing anteriorly; antenna quadripectinate, rami moderately long, terminal 10–12 annulations simple.

Thorax: Epiphysis long, almost two-thirds as long as tibia, extending slightly beyond tibia apex; tegula short, wide, less than one-third length of mesoscutum, distal portion broadly rounded, ventral portion wide and blunt; metathoracic tympanum small, cavity deep, scaleless, area above membrane heavily sclerotized, scaleless, protruding from body to form a shelf; tympanal membrane large, ovoid, oriented horizontally.

Forewing (fig. 249C; pl. 23): Broad, triangular, apical angle acute; vein R1 arising from DC near its anterolateral angle; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from DC, widely separated from base of radial sector; stridulatory organ highly developed; DC extremely small, less than one-fifth length of FW, membrane beyond DC forming a large fascia with corrugated surface; bases of M1 and M2 protruding from wing surface below, with a distinct, short fold between them; veins M3 and CuA1 long stalked, stalk curved; ground color chocolate brown to blackish brown, fascia and wing base lighter often white; Frigida Group species with a white, transverse subapical bar; Ciris Group with a small, white subapical spot.

Hind wing (fig. 249C; pl. 23): Broad, outer margin rounded; M3 and CuA1 long stalked; central area broadly white or semihyaline, with a wide, dark brown marginal band; sometimes with a large white spot near apex (Frigida Group).

Abdomen: Moderately long, apex acute, with a short, conical dorsal tuft.

Terminalia (figs. 250B–D, 251, 253A, 253B, 254): Tg8 simple, narrower than Tg7, tapered slightly toward posterior margin; anterior and posterior margins of Tg8 simple, E. frigida with a pair of long, lightly sclerotized, ovoid “windows”, one on either side of midline; St8 narrower than Tg8, either rectangular, with anterior and posterior margins simple (Ciris Group), or narrowing slightly posteriorly, anterior margin with a short, wide mesal apodeme (Frigida Group); socii/uncus complex with an extremely narrow attachment to tegumen, or rarely (E. anomala) a wide attachment; uncus small, acute, or rarely (E. anomala) absent; socii small, slightly longer than uncus, or rarely (E. anomala) long; tegumen moderately wide, taller than vinculum; vinculum narrow; saccus absent, ventral margin of genitalia smoothly U-shaped, or with a shallow mesal depression; valva moderately long, lightly sclerotized, simple, narrowing toward apex; BO absent; costa narrow, sides roughly parallel; apex either bluntly rounded (Ciris Group), or short, hook shaped (Frigida Group); arms of transtilla extremely narrow, oriented horizontally, meeting to form a small fold at midline; juxta cup shaped; aedeagus short to moderately long, curved slightly downward; apex of aedeagus with a small, dorsal opercular sclerite and a small, hook shaped ventral tooth; vesica short, less than one-fourth length of aedeagus; cornuti absent.

Female. FW length  =  15.0–19.5 mm. Head, thorax, and wings similar to male, except: labial palpus shorter and narrower; antenna ciliate; wings longer; FW DC larger, approximately one-fourth FW length; frenulum comprising approximately six bristles.

Abdomen: Shorter and wider than male.

Terminalia (figs. 250A, 253C): Tg7 large, anterior margin equal in width to Tg6, narrower posteriorly, anterior and posterior margins simple; St7 large, wider than St6, anterior margin simple, posterior margin with a wide, shallow mesal excavation; Tg8 short, lightly sclerotized, posterior margin slightly rooflike; AA short, extremely thin; A8 pleuron membranous; PP moderately long, thin and straight; PA large, membranous, posterior margin rounded or quadrate; PVP absent; DB sclerotized, extremely short or rarely (E. anomala) long; CB large, membranous, round or ovoid, narrow in basal third; signum absent; DS arising dorsally at junction between narrow portion of CB and DB.

Distribution

Euchontha is restricted to the eastern slope of the Andes, from central Colombia south to northern Bolivia. Members of the Ciris Group occur at elevations between approximately 800 and 3000 meters. The two Frigida Group species are endemic to the Upper Amazon Basin. Euchontha frigida covers a wide altitudinal gradient, being known in Ecuador from near sea level (Garza Cocha) to as high as 1200 m (Río Hollín).

Biology

The only Euchontha species collected with any frequency is E. frigida. Males are quite commonly observed flying in the day along quickly moving streams and rivers. Elicio Tapia and I (October 2004) captured several males of E. frigida, as well as the holotype of Pareuchontha olibra, sp. nov., sitting on the surfaces of large, wet, mossy rocks in the shallow water along the banks of the Río Hollín (pl. 45B–D). All these moths appeared to be drinking.

When caught in an insect net, males of E. frigida make clicking noises with their FW stridulatory organ (Forbes, 1931; personal obs.). The function of these sounds is not known, but since the moths are diurnal, the clicks are obviously not used to confuse bats, the purpose of sounds produced by thoracic structures in arctiids (e.g., see Conner, 1999; Fullard et al., 2000).

During a trip to Peru (October 2005), I captured four males of Euchontha commixta on a single afternoon, within a span of 30 minutes, at precisely the same locality where the holotype of E. carboniptera, sp. nov., had been collected a few days earlier. The site is a bridge spanning Quebrada Quita Calzón, a beautiful mountain stream that feeds into the Río Cosñipata approximately 1000 meters below. Both Euchontha species were caught as they landed to drink from the wet gravel road surface. When the series of E. commixta was collected, almost the entire day had been spent vigorously searching there. It seems unusual that the moths were visibly active for such a short period of time.

Euchontha males also engage in classic “puddling” behavior (see Adler, 1982), and can sometimes be seen at the same puddling sites frequented by butterflies. Along the Río Papancu (pl. 46A), near Galeras, Ecuador, I observed two E. frigida individuals among a large, colorful aggregation of hesperiid, papilionid, and pierid butterflies (pl. 46B, D), drinking at a mud puddle a short distance from the river bank. All these Lepidoptera are apparently imbibing sodium, necessary for adult metabolism, but available in short supply in their larval food plants (Arms et al., 1974; Smedley and Eisner, 1995). Males of day-flying uraniid moths are attracted to urine-soaked sand (Lees and Smith, 1992), presumably for the same reason.

As was noted by Forbes (1931) following his participation on a CUIC expedition to Peru, Euchontha females are rarely collected; I have never observed one in the field.

Discussion

Miller (1989) revised the genus Euchontha, dividing it into the Frigida and Ciris groups. Here, I describe an additional Ciris Group species, E. carboniptera, from southeastern Peru.

KEY TO EUCHONTHA SPECIES GROUPS

1. Forewing with a wide, white subapical band extending from R1 to M3 (pl. 23); HW with a white spot near apex, this placed within the dark brown marginal band; apex of male valva acute, curving downward; FW length  =  16.5–18.5 mmFrigida Group

FW with a small, white subapical spot extending from Rs2–Rs4 to M1 (pl. 23); HW without a white spot near apex; apex of valva rounded; FW length  =  13.0–14.5 mmCiris Group

1. FRIGIDA GROUP

The Frigida Group, containing two species with similar wing patterns, differs from the Ciris Group in occurring at generally lower elevations. Male and female genitalia in the two groups are markedly different (compare figs. 250, 253).

KEY TO FRIGIDA GROUP SPECIES

Plate 23

1. Hind wing central portion, including veins, white; Lp2 longer than Lp1; socii/uncus complex narrow, uncus and socii short; sclerotized portion of female DB short (E Colombia S to E Bolivia)frigida (Walker)

HW central portion semihyaline, veins brown; Lp2 shorter than Lp1; socii/uncus complex wide (fig. 250D), uncus absent, socii long; sclerotized portion of female DB long (fig. 250A) (Amazonian Brazil, E Peru)anomala (Prout)

SPECIES INCLUDED AND MATERIAL EXAMINED

Euchontha anomala (Prout)

Figure 250; plate 23

Hadesina anomala Prout, 1918: 418.

Type Locality

Brazil, Amazonas.

Type

Holotype ♀, Bates Collection (BMNH).

Discussion

At the time of my Euchontha revision (Miller, 1989), all specimens of E. anomala other than the type were known from a single locality on the upper Amazon—São Paulo d'Olivença, in Brazil. A Peruvian site, Achinamiza, can now be added for this species, based on an AMNH specimen (JSM-1688) discovered subsequent to publication of that paper. Achinamiza (Department of San Martín; 150 m) is on the Río Huallaga, which feeds into the Río Marañon, and ultimately the Amazon (see fig. 6).

This species is rare; in addition to the AMNH example, it is known from only nine specimens worldwide. Euchontha anomala shows the same general size and appearance as its sister species, E. frigida, differing in subtle aspects of wing pattern and labial palpus shape (see species key). When genitalia of the two species are compared, they differ drastically (Miller, 1989).

Distribution

Brazil (BMNH, USNM, ZMH); Peru (AMNH).

Dissected

Holotype ♀ (genitalia slide no. JSM-276); ♂, Brazil, Amazonas, São Paulo d'Olivença, Aug–Sep 1878, leg. M. de Mathan, BMNH (genitalia slide no. JSM-240); ♂, Brazil, Amazonas, São Paulo d'Olivença, Jun–Jul 1883, leg. M. de Mathan, BMNH (genitalia slide no. JSM-242, labial palpi slide no. JSM-243, appendage slide no. JSM-244); ♂, Brazil, Amazonas, São Paulo d'Olivença, Jun–Jul 1883, leg. M. de Mathan, BMNH (genitalia slide no. JSM-245); ♂, Peru, San Martín, Achinamiza, 12 Jan 1926, H. Bassler Collection, AMNH (genitalia slide no. JSM-1688); ♂, Brazil, Amazonas, São Paulo d'Olivença, Aug, leg. M. de Mathan, BMNH (genitalia slide no. JSM-241).

Euchontha frigida (Walker)

Figure 249B–D; plate 23 [EX]

Devara frigida Walker, 1864: 185.

Type Locality

Ecuador, Cuenca.

Type

Syntype ♂, ex Fraser Collection (BMNH).

Macroneurodes albimacula Warren, 1900: 127.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♂ (BMNH).

Gnatholophia longinervis C. and R. Felder, 1874: pl. 105, fig. 8.

Type Locality

Not known.

Type

Syntype ♂ (BMNH).

Euchontha sublactigera Walker, 1865: 383.

Type Locality

Colombia, “Bogotá”.

Type

Syntype ♂, ex Stevens Collection (BMNH).

Discussion

Euchontha frigida is broadly distributed along the eastern slope of the Andes from central Colombia south to Bolivia (Miller, 1989). It occurs most commonly at midelevations near 1000 meters. The moth is well represented in major collections.

Distribution

Colombia (AMNH, BMNH, CAS, CUIC, MCZ, USNM, ZMH); Ecuador (AMNH, BMNH, LACM, USNM); Peru (AMNH, BMNH, CAS, MPM, MUSM, NMW, USNM, ZMH); Bolivia (BMNH, USNM); Brazil (OUMNH).

Dissected

♂, Colombia, Muzo, Dognin Collection, USNM (wing slide no. JSM-1251, genitalia slide no. JSM-1250); ♂, Ecuador, Napo, Puyo, 4 Mar 1950, AMNH (genitalia slide no. JSM-1689); ♂, Peru, Upper Río Marañon, 15 Nov 1929, H. Bassler Collection, AMNH (appendage slide no. JSM-232); ♀, Peru, Upper Río Marañon, 28 Oct 1927, H. Bassler Collection, AMNH (wing slide no. JSM-235, appendage slide no. JSM-237, genitalia slide no. JSM-232); ♀, Peru, Chambireyacú, near Yurimaguas, Jun–Aug 1885, leg. M. de Mathan, BMNH (genitalia slide no. JSM-281).

2. CIRIS GROUP

Moths in the Ciris Group (pl. 23) are smaller than those of the Frigida Group. They never exhibit the wide subapical FW band typical of the Frigida Group, but instead show a small white spot near the apex. The newly described species, E. carboniptera, was figured in Miller (1989; figs. 61, 62) as a dark color form of E. memor. After collecting additional material in southeastern Peru, I here recognize that phenotype as distinct from memor.

KEY TO CIRIS GROUP SPECIES (MALES)

Plate 23

1. Central area of HW (dorsal surface) white3

Central area of HW (dorsal surface) beige to dark brown2

2. Central area of HW dorsal surface beige to light brown, a distinct, dark brown region at apex; distal third of valva narrow; setae on inner surface of valva finememor Warren

Central area of HW dorsal surface chocolate brown to dark blackish brown, no darker region at apex; distal third of valva relatively wide; setae on inner surface of valva coarsecarboniptera, sp. nov.

3. Forewing dorsal surface white in basal third; area of FW fascia white, veins brown; subapical FW spot small; Lp1 mostly white, a few brown scales4

FW dorsal surface, including base, almost entirely brown; area of FW fascia semihyaline, dirty white; subapical FW spot large; Lp1 light yellow (SE Peru S to Bolivia)commixta Warren

4. Subapical FW spot lying between Rs2+Rs3 and Rs4, not touching Rs4; FW base white with brown veins; FW with a small, teardrop-shaped white spot beyond white basal area, along anal fold; tegula brownciris Druce

Subapical FW spot lying on Rs4; FW base dirty whitish brown; no FW spot beyond white basal area along anal fold; tegula orangemoyobamba Miller

SPECIES INCLUDED AND MATERIAL EXAMINED

Euchontha carboniptera, new species

Figures 249A, 251, 252; plate 23

Diagnosis

Euchontha carboniptera is most similar in wing pattern, body pattern, and genital morphology to E. memor (pl. 23), also from eastern Peru. Euchontha carboniptera and E. memor can be distinguished by the HW central area, which is beige to light brown in E. memor, but dark brown to charcoal gray in E. carboniptera. The FW ground color of E. carboniptera is consistently darker as well. Genitalia in the Ciris Group are remarkably uniform. However, males of E. carboniptera exhibit features subtly distinguishable from other Ciris Group species. For example, the setae on the valva inner surfaces are more robust (fig. 251A). The valva's distal third is wider in E. carboniptera than in E. memor. Females of both species are unknown.

Description

Male. Forewing length  =  13.0–14.0 mm. Head (fig. 249A): Labial palpus thin, curving sharply upward to immediately above middle of front; Lp1 long, but shorter than Lp2, curved upward, loosely covered with semierect white scales; Lp2 long, curved sharply upward near apex, lateral surface dark gray with a few scattered white scales, mesal surface white; Lp3 short, ovoid, dark gray; apex of palpus with an acute tuft of elongate, dark gray scales; scales of front white to buff above clypeus, pointing dorsomesally, lateral scales black, pointing mesally, a fanlike group of white scales below each antennal base, pointing ventrally and mesally; central portion of front scaleless, sclerotized and shiny; occiput white, with a row of long black scales in dorsal portion behind eye; eye relatively small, completely surrounded by a scaleless band, narrow posteriorly, wider above and anteriorly; gena broadly scaleless, surface spiculate; vertex covered with appressed, dark gray black scales, a white patch on dorsum and white patches behind each antennal base; antenna quadripectinate, rami moderately long; scape steely gray black on dorsum, white with scattered dark gray scales ventrally; dorsum of antennal shaft tightly covered with short, glossy, gray-black scales.

Thorax: Procoxa covered with long white scales, outer surface narrowly gray; rest of legs white on inner surfaces, dark gray to gray on outer ones; spurs white on inner surfaces, dark gray on outer ones; pleuron covered with long, mostly hairlike, immaculate white scales, a few shorter gray scales; patagium covered with long, erect scales, a wide white band at midline, large black patches on either side of that, small white patches laterally; tegula short, ventral angle black fringed with long white scales, base of tegula with erect orange scales, distal portion covered with long, blackish-gray to gray scales, margins fringed white; dorsum closely covered with short black to gray-black scales, a longitudinal light orange-yellow stripe along midline, a few white to gray scales laterally; tympanum with a deeply inset scaleless area below membrane, portion above membrane heavily sclerotized, forming a shelf; tympanal membrane relatively small, ovoid, oriented horizontally.

Forewing: (Dorsal) Ground color dark charcoal gray to black (pl. 23), slightly lighter in basal third; veins evenly lined with chocolate brown scales in distal third, light brown in basal third; a wide, immaculate white, transverse band beyond stridulatory organ, its anterior margin touching costa, its posterior margin crossing 1A+2A but falling short of outer margin near tornus; a small, semihyaline spot straddling Rs4 below apex, its surface sparsely covered with white and blackish gray, pedicellate scales; anterior margin of subapical spot touching Rs3, posterior margin falling short of M1. (Ventral) Similar to dorsal surface except: ground color slightly lighter (pl. 23); veins not lined with brown scales; basal third with mixed white and dark gray scales in area of DC; white transverse band sparsely scaled, M1 and M2 protruding sharply from wing surface in area of stridulatory organ; subapical spot white.

Hind wing: (Dorsal) Ground color dark gray to blackish charcoal gray (pl. 23), lightest near base, darkest near apex; anterior margin with a long white streak from base to short of apex; fringe coppery gray. (Ventral) Ground color dark gray (pl. 23); anterior margin with a wide white streak from base short of apex; a pair of diffuse, wide whitish gray streaks from base to near outer margin, one passing through DC, the other broadly running along anal fold; anal margin fringed with short white and hairlike whitish gray scales.

Abdomen: Dorsum gray black, slightly lighter dark gray to coppery brown at base; venter entirely white.

Terminalia (fig. 251): Tg8 slightly longer than Tg7, as wide anteriorly, abruptly narrowed in distal two-thirds, lateral margins concave; anterior margin of Tg8 simple, slightly convex, anterolateral angles produced, posterior margin simple; St8 slightly narrower distally, approximately equal in length to Tg8; anterior margin of St8 convex, posterior margin gently concave; socii/uncus complex moderately large; uncus curving slightly downward, apex blunt; socii wide and rounded at bases, narrow at apices, extending immediately beyond apex of uncus, lateral surfaces setose; tegumen taller than vinculum, moderately wide; vinculum narrow dorsally, expanded in ventral portion below valva bases; saccus small and wide, ventral margin concave, dorsal margin arching upward at midline, covering juxta, barely covering valva bases, mesal area with a trifid strut; juxta a concave, cup-shaped structure, extending ventrally below lower margin of saccus; valva simple, lightly sclerotized, widest at base, then narrowed toward apex; BO absent, saccus strongly emarginate; costa wide; apex simple, bearing long, coarse setae; transtillar arms narrow, straplike, oriented horizontally, then curving abruptly downward at midline, junction V-shaped, simple; aedeagus moderately long, wide, curved downward, base wide, dorsoventrally compressed; apex of aedeagus with a narrow dorsal sclerite and a curved, hook-shaped ventral point; vesica simple, as wide as aedeagus, lacking cornuti.

Female. Unknown.

Etymology

This species name combines carbo, Latin for “coal”, with the Greek pteron, “wing”, in reference to the coal black ground color of the FW and HW in this species, which distinguishes it from all other members of Euchontha.

Distribution

Euchontha carboniptera is endemic to the eastern slopes of the Peruvian Andes, from Tingo María in the Department of Huanuco south to Cuzco (fig. 252). The holotype (AMNH) was collected at a site in the Cosñipata Valley, approximately 90 km east of Cuzco. Euchontha carboniptera and its apparent sister species, E. memor, show roughly sympatric distributions.

Discussion

Earlier (Miller, 1989), I had regarded material of E. carboniptera as being conspecific with E. memor (Warren). At that time only two examples of E. carboniptera were known (USNM), both from Tingo María. Now, with the availability of more recently collected specimens (AMNH, LACM), I have concluded that what I initially thought was a dark phenotype of memor in fact constitutes a separate species. Based on their morphologies, the two taxa are extremely close relatives.

Holotype

Male (pl. 23). Peru: Cuzco: Cosñipata Valley, Quebrada Quita Calzón, 1020 m, S13°01′21″, W71°39′52″, 21 Oct 2005, leg. J.S. Miller, day-collecting, on mud (genitalia slide no. JSM-1561). The holotype is deposited at the AMNH.

Paratypes

None.

Other Specimens Examined

Peru: Huanuco: 1♂, 12 km S of Tingo María Santa Rosa, 825 m, 9.38°S, 75.954°W, 20 Jun 2001, leg. Leuschner (LACM); 1♂, Tingo María, 13 Dec 1949, leg. H.A. Allard (USNM; genitalia slide no. JSM-257); 1♂, Tingo María, 12 Nov 1949, leg. H.A. Allard (USNM).

Dissected

Holotype ♂, 1♂.

Euchontha ciris Druce

Figure 253; plate 23

Euchontha ciris Druce, 1893: 297, pl. 20, fig. 10.

Type Locality

Ecuador, Intaj.

Type

Syntype ♂, leg. Buckley (BMNH).

Monocreaga circis Dognin, 1894: 73.

Type Locality

Ecuador, Santiago-Zamora, Zamora.

Type

Syntype ♂ (USNM).

Monocreaga clareta Dognin, 1894: 239.

Type Locality

Ecuador, Loja, San Francisco.

Type

Holotype ♀, leg. August 1886 (USNM type no. 30965).

Discussion

Euchontha ciris is the only Ciris Group species endemic to Ecuador; all the others occur from northeastern Peru south into Bolivia. Material at the BMNH collected by Buckley over 100 years ago is notorious for improper labeling. Sarayacu, a common locality on Buckley specimens, is a small lowland town in the Upper Amazon Basin of Ecuador, east of Baños. There is almost no possibility that E. ciris occurs there. Instead, specimens labeled “Sarayacu” could have been collected almost anywhere in Ecuador (see Distribution for Pseudoricia). Similarly, the type locality for E. ciris according to the Buckley label is “Intaj”, the modern name for which is Intag (00°20′N, 78°37′W). This town is located at 1200 meters in Imbabura Province, north of Quito in the central valley near the town of Otavalo. No modern specimens of E. ciris have been collected that far north, and nothing provides supporting evidence that the moth actually occurs on the western side of the Andes. On the contrary, all non-Buckley material of E. ciris has been recorded from far southern Ecuador on the eastern slope, near the towns of Loja and Zamora (fig. 5). The specimen figured here (pl. 23) was captured by Elicio Tapia in March 2006, along the Río Bombuscara (pl. 46C), west of Zamora.

Distribution

Ecuador (BMNH, USNM, ZMH).

Dissected

♂, Ecuador, Sarayacu, BMNH (genitalia slide no. JSM-246, appendage slide no. JSM-250); ♂, Ecuador, Intaj, BMNH (genitalia slide no. JSM-247); ♀ type of clareta, USNM (genitalia slide no. JSM-249).

Euchontha commixta Warren

Figure 254; plate 23 [EX]

Euchontha commixta Warren, 1904: 16.

Type Locality

Peru, Junín, Upper Río Toro, La Merced, 3000 m.

Type

Syntype ♂, leg. Simons, Aug–Sep 1900 (BMNH).

Devara chilion Druce, 1907: 303.

Type Locality

[Not known].

Type

Syntype ♂ (BMNH).

Discussion

Euchontha commixta is somewhat more common than other Ciris Group species. However, even it is rare. Although E. commixta appears in six institutional collections, each of those contains only one or a few specimens. Its lack of white FW markings makes this species distinctive; the FW fascia and subapical spot are semihyaline, while the rest of the wing is chocolate brown.

There is no locality label on the syntype male of chilion Druce, a synonym of commixta. The collector was Watkins, who was active in Peru in the early 1900s (G. Lamas, personal commun.).

Distribution

Peru (AMNH, BMNH, CUIC, MPM, MUSM, ZMH); Bolivia (BMNH).

Dissected

♂, Peru, Cuzco, Cosñipata Valley, Quebrada Quita Calzón, S13°01′21″, W71°39′52″, 1020 m, 25 Oct 2005, leg. J.S. Miller, day-collecting, 12:30 p.m., AMNH (genitalia slide no. JSM-1564); ♂, Peru, Tambo Eneñas, CUIC (genitalia slide no. JSM-261, appendage slide no. JSM-262); ♂, Peru, Tambo Eneñas, CUIC (genitalia slide no. JSM-263).

Euchontha memor Warren

Plate 23

Euchontha memor Warren, 1904: 16.

Type Locality

Peru, Junín, Chanchamayo.

Type

Holotype ♂, leg. Hoffmanns, January–August 1901 (BMNH).

Discussion

Euchontha memor appears to be the sister species of E. carboniptera. As is noted in my description of the latter (above), I had earlier recognized two color forms of E. memor (Miller, 1989). Here, that assessment is revised; E. carboniptera, described for the darker phenotype, is new. Like E. carboniptera, females of E. memor are unknown. The two taxa are sympatric almost throughout their ranges.

Distribution

Peru (BMNH, CUIC, USNM).

Dissected

♂, Peru, Hacienda no. 2, Col. Perené, CUIC (genitalia slide no. JSM-254); ♂, Peru, La Merced, Río Chanchamayo, CUIC (appendage slide no. JSM-256, genitalia slide no. JSM-255).

Euchontha moyobamba Miller

Plate 23

Euchontha moyobamba Miller, 1989: 27–30, figs. 73–79.

Type Locality

Peru, San Martín, Moyobamba.

Type

Holotype ♂ (BMNH).

Discussion

Other than a large series at the BMNH (four types, 19 additional specimens), all collected in northern Peru by M. de Mathan in the years 1887 and 1888, E. moyobamba is known from a single AMNH male captured by J.C. Pallister at Quince Mil, Cuzco (26 April 1947). That specimen, which I discovered subsequent to my revision (Miller, 1989), extends the distribution of E. moyobamba to within 150 km of the Bolivian border. The species' range now spans almost the entire length of Peru.

Distribution

Peru (AMNH, BMNH).

Dissected

♂, Peru, San Martín, Moyobamba, leg. M. de Mathan, BMNH (appendage slide no. JSM-265, genitalia slide no. JSM-266); ♂, Peru, San Martín, Moyobamba, leg. M. de Mathan, BMNH (labial palpus slide no. JSM-270, genitalia slide no. JSM-267); ♂, Peru, San Martín, Moyobamba, leg. M. de Mathan, BMNH (genitalia slide no. JSM-269); ♀, Peru, San Martín, Moyobamba, leg. M. de Mathan, BMNH (genitalia slide no. JSM-268).

PSEUDORICIA PROUT, 1918

Figures 255Figure 256Figure 257Figure 258Figure 259Figure 260261; plate 23

Figure 255

Morphology of Pseudoricia ovisigna (♂). A, head, lateral view; B, head, frontal view; C, head posterior view; D, head, lateral view; E, tegula; F, wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f255.gif

Figure 256

Scanning electron micrographs of Pseudoricia ovisigna ♂. A, antenna in lateral view, distal at right; B, sensillum styloconicum (lateral view), from distal margin of flagellomere; C, forewing stridulatory organ, dorsal surface; D, scales from dorsal surface of FW stridulatory organ; E, FW stridulatory organ, ventral surface; F, FW stridulatory organ ventral surface, showing area at bases of M1 and M2.

i0003-0090-321-1-1-f256.gif

Figure 257

Scanning electron micrographs of Pseudoricia ovisigna ♂, FW stridulatory organ (ventral surface). A, scales in stridulatory organ; B, scales in stridulatory organ; C, fold between M1 and M2; D, corrugated wing surface along fold.

i0003-0090-321-1-1-f257.gif

Figure 258

Male genitalia of Pseudoricia flavizoma, sp. nov. (JSM-1304). A, genitalia; B, aedeagus; C, Tg8; D, St8.

i0003-0090-321-1-1-f258.gif

Figure 259

Costa Rica, showing the known distribution of Pseudoricia flavizoma, sp. nov.

i0003-0090-321-1-1-f259.gif

Figure 260

Genitalia of Pseudoricia ovisigna (♂ JSM-400, ♀ JSM-401). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f260.gif

Figure 261

Male genitalia of Pseudoricia sibyllae (JSM-496). A, genitalia; B, St8; C, aedeagus; D, Tg8.

i0003-0090-321-1-1-f261.gif

Pseudoricia Prout, 1918: 406. Type species: Josiodes sibyllae Druce, 1885b (by original designation).

Diagnosis

The three members of Pseudoricia are easily recognizable (pl. 23). These are the only Dioptinae with the following combination of characters: labial palpus thin and held upright, close to front (fig. 255A, D); FW veins Rs2–Rs4 in the pattern 2+[3+4] (fig. 255F); FW DC extremely short—even in female—with male showing a highly developed stridulatory organ (figs. 256C–F, 257); and antenna finely ciliate (fig. 256A, B) in both sexes. The FW ground color is an unusual olive gray, though in P. sibyllae, a mostly yellow moth, this coloration is restricted to the wing's distal third. In all three Pseudoricia species, the HW is yellow with a blackish-brown outer margin. The genitalia of Pseudoricia are highly distinctive, exhibiting a host of apomorphic features, such as the extremely narrow, sclerotized valvae (figs. 258A, 260A, 261A) bearing a fringe of coarse setae.

Redescription

Male. FW length  =  14.0–16.5 mm. Head (figs. 255A–D, 256A, 256B): Labial palpus long, thin curving upward to middle of front, or slightly below antennal base; Lp1 relatively short, straight; Lp2 elongate, almost twice as long as Lp1, distinctly curved; Lp3 short, ovoid; scales of front pointing dorsomedially, meeting at midline between antennal bases to form a small tuft; eye size variable, from moderately large and dorsoventrally compressed, with gena broadly scaleless below (P. sibyllae) to extremely large and bulging (P. flavizoma); antenna with pectinations absent, ventral surface evenly covered with setae.

Thorax (fig. 255E): Epiphysis short, wide at base, abruptly tapered at apex; tegula approximately two-thirds length of mesoscutum, distal portion broad, almost rounded, ventral process blunt, sulcus weak; metathoracic tympanum moderately large, cavity shallow but well defined, membrane fairly large, almost round, facing posteroventrally.

Forewing (figs. 255F, 256C–F, 257; pl. 23): Elongate, apical angle strong (wings broader in P. sibyllae); vein Rs1 arising from radial sector; veins Rs2–Rs4 in the pattern 2+[3+4]; M1 arising from DC widely separate from base of radial sector, UDC relatively long; stridulatory organ highly developed, DC approximately one-fourth length of FW, M1 and M2 swollen at base, a deep ventral fold between them, surface of stridulatory organ corrugated; veins M3 and CuA1 long stalked; ground color dull, greyish olive, either with a light yellow fascia beyond DC (P. ovisigna, P. flavizoma), or basal two-thirds light yellow (P. sibyllae); veins (P. ovisigna, P. flavizoma) lined with light, whitish yellow, especially at base; ventral surface similar to dorsal one, slightly darker dull olive.

Hind wing (figs. 255F; pl. 23): Broad, outer margin gently convex; UDC at end of DC greatly displaced toward base; M3 and CuA1 long stalked.

Abdomen: Moderately long, apex acute (dorsum exhibiting yellow, transverse stripes in P. flavizoma).

Terminalia (figs. 258, 260A–D, 261): Tg8 short and broad, roughly quadrate, with posterolateral angles sometimes expanded, posterior margin concave or convex, sometimes sclerotized and rugose (P. flavizoma, P. ovisigna); St8 triangular, widest posterolaterally, surface spiculate and setose, rugose, especially along posterior margin; anterior margin of St8 with a broadly or narrow, elongate apodeme; posterior margin of St8 with an extremely deep and narrow mesal excavation, either U-shaped or V-shaped, margin crenulate, with longitudinal striations; socii/uncus complex short, wide, bent sharply downward; uncus comprising paired processes, either widely separated (P. flavizoma, P. ovisigna) or apposed (P. sibyllae); socii narrow, sharply upturned from base, apices variable; tegumen taller than vinculum, either wide or narrow; vinculum short and narrow, tilted upward compared to tegumen, forming a transverse lower margin, produced slightly downward at midline; saccus forming a wide triangle, partially enclosing valva bases; BO absent; valva sclerotized, widest in basal one-third, abruptly narrow beyond, distal portion strongly curved dorsomedially; ventral margin of valva with an angulate or broadly rounded structure near base; valva ventral margin bearing a row of coarse, spinelike (P. flavizoma, P. ovisigna), or fine, hairlike (P. sibyllae) setae extending from basal process to valva apex, setae longer and more robust near apex; aedeagus moderately long, thin, curved upward near middle, bearing a small, hingelike process at midpoint below; aedeagus terminating in an upturned point; vesica shorter than one-third aedeagus length, roughly round, with a faint lateral sclerite at base; cornuti absent.

Female (P. ovisigna only). FW length  =  15.0–18.0 mm. Head: Labial palpus somewhat shorter than in male, thin, curved sharply upward to immediately below middle of front; antenna ciliate, each annulation with paired, basal bristles; frenulum with approximately six bristles.

Other features of head, thorax, and abdomen similar to male except: wings significantly larger, broader, more rounded at outer margins; FW with DC short, but lacking a stridulatory organ.

Terminalia (fig. 260E): Tg7 wide, lateral margins poorly defined, anterior margin simple, posterior margin slightly sinuate, lightly setose; A7 pleuron with lightly sclerotized, spiculate bulges below spiracles; St7 much narrower than Tg7, lateral margins poorly defined, anterior margin simple, posterior margin with a shallow, V-shaped mesal excavation; St7 heavily setose from posterolateral angles across posterior margin; Tg8 completely membranous; AA delicate, thin; A8 pleuron membranous; PP slightly more robust that AA, straight, tapered toward apices; PA relatively small, margins smoothly rounded, surface densely spiculate; PVP apparently absent; lower margins of ostium lightly sclerotized, spiculate; DB greatly elongate, narrow, membranous; CB extremely large and round, completely membranous; signum tiny, ovoid, located dorsally, internal surface finely dentate; DS arising on dorsum of DB a short distance anterior to ostium, base of DS expanded.

Distribution

The sole Central American Pseudoricia species, P. flavizoma, occurs exclusively on the Caribbean slope of the Cordillera de Talamanca (fig. 259). Its sister species, P. ovisigna, is known from the Pacific slope of the Ecuadorian Andes, with a single specimen, the type, being recorded from “Bogotá”, a designation notoriously misused by early collectors. The exact provenance of the third included taxon—sibyllae—is unknown. All four existing specimens bear labels stating that they came from “Sarayacu”. This is a lowland locality (fig. 5) in southeastern Ecuador (1°44′S, 77°29′W; 500 m) situated on the Río Bobonaza, a tributary of the Río Pastaza. The moth almost certainly does not live there. Lepidoptera specimens purportedly from Sarayacu, all attributed to C. Buckley who collected in Ecuador during the late 19th century, are well represented in the holdings of the BMNH.

According to Gerardo Lamas (personal commun.), Buckley frequently purchased material from local collectors. A locality of great interest to him was Sarayacu, home of the Jívaro tribe, famous Amazonian headhunters and headshrinkers (examples of their work are on display at the AMNH). However, Buckley had no intention of traveling to Sarayacu himself. When Ecuadorian collectors learned that he would pay more for specimens from there, they placed that locality designation on much of their material, when in fact it had been gathered at a range of other, more accessible (and less dangerous) localities. Wisely, like Buckley, they probably never went to Sarayacu either. This mislabeling has caused great confusion for Lepidoptera taxonomists over the years, and has confounded my own efforts to establish type localities and geographical distributions for several other Ecuadorian Dioptinae, such as Scoturopsis coras and Lyces striata, whose types also bear the “Sarayacu” label.

Biology

In July 1983, an entomological team from the CMNH discovered larvae of P. ovisigna feeding on Rinorea apiculata (Violaceae). The genus Rinorea (pl. 47C), numbering approximately 50 species in the New World (Gentry, 1993), is a common understory shrub throughout the Neotropics. Rinorea appears prominently in the host list for the Dioptinae (table 4), having been recorded for three additional genera—Scotura, Oricia, and Phanoptis. Cladistic analyses suggest that this host association has evolved no fewer than three separate times in the Dioptinae (fig. 356).

Discussion

When Prout (1918) described Pseudoricia, to include a single species—sibyllae Druce (1885b)—he listed a series of diagnostic traits. Several of them refer to wing venation, but of those, only the extremely short FW DC combined with the arrangement of FW veins Rs2–Rs4 are unusual to the genus. Prout accurately noted the strange configuration of both the labial palpus and the antenna. Other features of Pseudoricia on his list, such as “face smooth” and “femora glabrous”, are difficult to interpret. Hering (1925: 509) later noted the arrangement of the FW radials in Pseudoricia, and again stressed, “the [discal] cell is remarkably short”. He concurred with Prout by including only P. sibyllae in the genus.

During the course of this research, I became curious about a second species, ovisigna, which Prout (1918) had described in Scotura based solely on the holotype. A large series of that moth species became available from the CMNH collection, study of which made clear that ovisigna and sibyllae belong together in Pseudoricia. Even more recently, an undescribed species from Central America came to light, Pseudoricia flavizoma (described below). Much remains to be learned about this small but fascinating genus. Undiscovered species undoubtedly exist. Furthermore, available material for P. sibyllae and P. flavizoma is extremely limited; females are unknown. My description of female genital morphology (above) is based solely on P. ovisigna.

KEY TO PSEUDORICIA SPECIES (MALES)

Plate 23

1. Forewing ground color dull greenish gray, with an ovoid, light yellow fascia; eye large, bulging outward, gena extremely narrow; mesal apophysis on anterior margin of male St8 wide (figs. 258D, 260D); aedeagus short, curved downward (figs. 258B, 260C)2

FW yellow in basal three-quarters, without a contrasting fascia, distal fourth dull greenish gray; eye relatively small, not bulging, gena wide; mesal apophysis on anterior margin of male St8 long and narrow (fig. 261B); aedeagus large, straight (fig. 261C); ♂ FW length  =  15.0–15.5 mm (Ecuador)sibyllae (Druce)

2. Abdominal dorsum uniformly gray-brown; lateral portions of patagium yellow-orange, central portion dull greenish gray with a few scattered yellow scales; FW fascia small, its anterior margin touching base of radial sector; uncus comprising a pair of widely separated, thumblike processes (fig. 260A); socii narrow, not laterally compressed; ♂ FW length  =  14.5–16.5 mm (Colombia S to NW Ecuador)ovisigna (Prout)

Abdominal dorsum with a series of alternating yellow-orange and gray-brown transverse bands; patagium entirely yellow-orange; FW fascia large, its anterior margin touching R1; uncus absent (fig. 258A); socii spatulate, laterally compressed; ♂ FW length  =  14.0–15.5 mm (E Costa Rica)flavizoma, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Pseudoricia flavizoma, new species

Figures 258, 259; plate 23

Diagnosis

Pseudoricia flavizoma exhibits all the characteristics of the genus: male antenna ciliate; labial palpus thin, curved upward over the front; and DC less than one-fourth the FW length. The male FW stridulatory organ in P. flavizoma is highly developed; veins M1 and M2 are swollen on the ventral surface, and there is a prominent fold in the fascia between them. Pseudoricia flavizoma is easily distinguished from the other two Pseudoricia species. In addition to its Central American rather than South American distribution, P. flavizoma is unique in showing alternating gray and yellow-orange rings on the abdominal dorsum (pl. 23). The male genitalia differ from those of P. ovisigna (fig. 260A) and P. sibyllae (fig. 261A) in having the socii laterally compressed (fig. 258A).

Description

Male. Forewing length  =  14.0–15.5 mm. Head: Labial palpus long, thin, held against front; Lp1 light creamy yellow; Lp2 creamy yellow on inner and ventral surfaces, brown on lateral surface; Lp3 creamy yellow, tipped with longish scales; front sparsely clothed with light yellow, upwardly pointing scales below, longer orange-yellow scales above, extending to antennal bases; occiput with light yellow scales below, orange-yellow scales above; vertex completely covered with long, brilliant orange-yellow scales, pointing anteriorly; antenna finely ciliate; scape dark brown with a small patch of cream-colored scales below; antennal shaft dark brown above.

Thorax: Proleg cream-colored on inner surface, olive brown on outer one; pleuron of prothorax light yellow anteriorly, olive brown posteriorly; collar, including patagium, with long, rich orange-yellow scales; pleuron of meso- and metathorax mostly creamy yellow, mesepisternum light greenish gray; tegula covered with long, bright orange-yellow scales, lateral margins dark brown; dorsum dark brown, with small areas of long, light yellow-orange scales posteriorly.

Forewing: (Dorsal) Ground color olive gray in outer half (pl. 23), slightly darker at margins; basal half lighter olive gray, light yellow along cubitus and 1A+2A from base; costa brown; region between costa and subcosta yellow in basal third, olive gray beyond; an ovoid, light yellow fascia in basal half immediately beyond DC, fascia extending from subcosta to slightly short of M3+CuA1; scales surrounding fascia darker gray-brown, especially on inner and outer margins; anal margin lined with yellow scales. (Ventral) Outer half uniformly dark olive gray; basal half lemon yellow, veins yellow-orange; outer margin of yellow basal area extended outward between veins CuA1 and CuA2; fascia semihyaline, with scattered long, yellow-orange scales; veins M1 and M2 lined with long, yellow-orange scales as they pass through fascia.

Hind wing: (Dorsal) Ground color yellow-orange (pl. 23); a dark brown band along outer margin, band widest near apex, narrowest as it crosses M3+CuA1; anterior margin light yellow to buff; anal margin yellow-orange, concolorous with central area. (Ventral) Similar to dorsal surface, except yellow of central area and brown of marginal band slightly lighter.

Abdomen: Dorsum with Tg2 yellow-orange; terga of A3–A6 with basal half olive brown, distal half yellow-orange, giving abdomen a ringed appearance; Tg7 olive brown with a central patch of yellow scales; A8 completely olive brown above; pleuron of A1–A8 with a buff to yellow lateral stripe; venter creamy yellow.

Terminalia (fig. 258): Tg8 short, roughly quadrate, with posterolateral angles expanded and earlike, these ears crenulate below; St8 triangular, anterior margin forming a broadly rounded, blunt apodeme, posterior margin angled, with a deep, narrow medial excavation; posterior margin of St8, including mesal notch, crenulate, with longitudinal striations below, ventral surface with transverse striations as well; socii/uncus complex short, wide, angled downward; uncus comprising a pair of short, widely separated horns; socii upturned from base, laterally compressed and bladelike, apices bluntly rounded; tegumen somewhat taller than vinculum; tegumen wide, abruptly narrowed where it meets vinculum; vinculum narrow; saccus transverse, upper margin horizontal, produced slightly at midline below; valva narrow, completely sclerotized, BO absent; valva widest in basal third, abruptly narrow in distal two-thirds, apical third thin and hook shaped, curving dorsomedially; costa with a smooth, shallow hump one-third out; a blunt process on ventral margin of valva near base; ventral margin bearing a row of coarse, spinelike setae extending from basal process to valva apex, setae longer and more robust at apex; aedeagus small, thin, curved upward near middle, bearing a small hingelike process at midpoint below; apex of aedeagus terminating in an upturned process; vesica small, round, wrinkled, with a faint lateral sclerite at base, cornuti absent.

Female. Unknown.

Etymology

This name combines Latin flavus, for “yellow”, and Greek zoma, meaning “girdled” or “belted”, in reference to the unique orange-yellow and gray bands on the moth's abdomen.

Distribution

All five Costa Rican localities so far recorded for P. flavizoma (BMNH, INBio) are from the Caribbean drainage in the southeastern portion of the country (fig. 259). A single specimen from Panama (CAS) does not bear more specific locality data. Pseudoricia flavizoma occurs in wet forest areas at elevations ranging between 200 and 1100 meters.

Discussion

This is the only Central American representative of Pseudoricia. Like the other two species, it is extremely rare. My first knowledge of the taxon was based on two Costa Rican males, which I discovered among unsorted material at the BMNH in 1996. A single male, with label data simply stating “Panama”, later appeared in a loan from the CAS. The largest series is housed at INBio; their holdings contain four males, including the holotype. It will be important to discover the biology of P. flavizoma. At present, nothing is known. Its host plant will almost certainly prove to be a species of Rinorea, the genus on which Pseudoricia ovisigna has been recorded in Ecuador (table 4). Adults of P. flavizoma have been collected at lights, as well as during the day.

Holotype

Male (pl. 23). Costa Rica: Cartago: Turrialba, Tayutic, P.N. Barbilla, Cerro Tigre, Zona de Acampa, 1124 m, Sep 2001, leg. L. Chavarría, T. de Luz, L N 213500 600750, #64718 (INBio). The type is deposited at INBio, Heredia, Costa Rica.

Paratypes

Costa Rica: Cartago: 1♂, R. F. Río Pacuare, Turrialba, P.N. Barbilla, Est. Barbilla, 500 m, Aug 2001, leg. L. Chavarría (INBio). Limón: 1♂, Valle de la Estrella, Reserva Biol. Hitoy Cerere, Sendero Espavel, 560 m, Mar 2001, leg. L. Chavarría, “Red mariposera”, L S 570120 400702, #61765, “Volando de día” (INBio; JSM-1304); 1♂, Est. Hitoy-Cerere, Res. Biol. Hitoy Cerere, Río Cerere, 200 m, Nov 1990, leg. M. Barrelier, L N 184200, 643300 (INBio); 2♂♂, Río Telire, 15 Mar 1933 (BMNH; genitalia slide no. JSM-836).

Other Specimens Examined

1♂, Panama, R.H. Stretch Collection (CAS).

Dissected

2♂♂.

Pseudoricia ovisigna (Prout), new combination

Figures 255Figure 256257, 260; plate 23 [EX]

Scotura ovisigna Prout, 1918: 407.

Type Locality

Colombia, “Bogotá”.

Type

Holotype ♀ (BMNH).

Discussion

Although Prout (1918) described ovisigna in Scotura, where it remained until the present time (Hering, 1925; Bryk, 1930), analysis of adult morphology demonstrates that the species belongs in Pseudoricia as a new combination. Interestingly, Prout (1918) described the genus Pseudoricia in that same paper, but did not recognize ovisigna as a member. It seems likely that he misplaced P. ovisigna because of its contrasting yellow vertex, a characteristic of Scotura (pls. 1, 2). Closer study reveals a host of morphological apomorphies shared by P. ovisigna and P. sibyllae. These are listed in the genus redescription above. My research further suggests that P. ovisigna is more closely related to the newly described Central American species, P. flavizoma, than it is to its country mate, P. sibyllae.

When I began studying the Dioptinae, very little was known about P. ovisigna. The only example I had seen was the female holotype (BMNH), a specimen in poor condition with a handwritten label that simply reads “Bogota”. However, members of a CMNH expedition collected a large series of P. ovisigna in Chical, Ecuador (Carchi Province), on the western slope of the Andes at the Colombian border. Adults were captured at lights, and caterpillars were found feeding on Rinorea apiculata (Violaceae). Aside from the type, this CMNH material, comprising 43 specimens, seems to represent the world's holdings of P. ovisigna.

Distribution

Colombia (BMNH); Ecuador (CMNH).

Dissected

♂, Ecuador, Charchi, Chical, 1250 m, 0°56′N, 78°11′W, 1 Jul 1983, leg. J. Rawlins & R. Davidson, CMNH (wing slide no. JSM-187, genitalia slide no. JSM-400); ♂, Ecuador, Carchi, Chical, 0°56′N, 78°11′W, 1250 m, 1 Jul 1983, leg. J. Rawlins, CMNH (genitalia slide no. JSM-1512); ♀, Ecuador, Carchi, Chical, 1250 m, 0°56′N, 78°11′W, 8 Jul 1983, leg. J. Rawlins, CMNH (wing slide no. JSM-193, genitalia slide no. JSM-401).

Pseudoricia sibyllae (Druce)

Figure 261; plate 23

Josiodes sibyllae Druce, 1885b: 523, pl. 32, fig. 7.

Type Locality

Ecuador, Sarayacu.

Type

Syntype ♀, leg. C. Buckley (BMNH).

Discussion

Druce (1885b) described this species in Josiodes, an arctiid genus now in the Lithosiinae (Watson et al., 1980). Prout (1918) later erected Pseudoricia in the Dioptinae, with sibyllae as its only included species. Pseudoricia sibyllae is known from only four specimens—two males and one female at the BMNH, and one female at the ZMH. Oddly, in both females the abdomen had at some point fallen off. In each, someone re-attached it backward onto the body, the glue being applied to the genitalia-end, making dissection impossible. All of these specimens are from the same series, and all bear the notorious data “Sarayacu, C. Buckley” (see Pseudoricia Distribution, above). Until additional specimens are collected, the only distributional information that can be given for P. sibyllae is that the moth occurs somewhere in Ecuador.

Of the three species, P. sibyllae differs from the other two in having smaller eyes. Its male genitalia (fig. 261) differ significantly from those of P. ovisigna (fig. 260A–D) and P. flavizoma (fig. 258). I suggest that, in this three-member clade, P. ovisigna and P. flavizoma are sister species, with P. sibyllae being sister to those.

Distribution

Ecuador (BMNH, ZMH).

Dissected

♂, Ecuador, Sarayacu, leg. C. Buckley, BMNH (genitalia slide no. JSM-496).

STENOPLASTIS C. AND R. FELDER, 1874

Figures 247, 262Figure 263Figure 264Figure 265Figure 266267; plates 23, 24

Figure 262

Morphology of Stenoplastis (♂♂). A, head of S. decorata, lateral view; B, head of S. decorata, frontal view; C, head of S. decorata, posterior view; D, head of S. flavinigra, lateral view; E, S. flavinigra tegula; F, S. decorata tegula; G, head of S. flavinigra, lateral view; H, S. decorata wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f262.gif

Figure 263

Scanning electron micrographs of Tithraustes and Stenoplastis ♀ abdomens. A, terminal segments of T. seminigrata (ventral view), showing postvaginal plate (PVP), papillae anales and corethrogyne; B, terminal segments of S. decorata in lateral view (anterior at left), showing St7 and corethrogyne; C, corethrogyne of S. decorata; D, deciduous corethrogyne scales of S. decorata; E, apices of S. decorata corethrogyne scales; F, tip of a single corethrogyne scale from E.

i0003-0090-321-1-1-f263.gif

Figure 264

Genitalia of Stenoplastis decorata (holotype ♂ JSM-1024, ♀ JSM-535). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♀ genitalia; E, ♂ St8; F, ♀ St7.

i0003-0090-321-1-1-f264.gif

Figure 265

Genitalia of Stenoplastis dyeri, sp. nov. (paratype ♂ JSM-730, paratype ♀ JSM-1814). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♀ genitalia; E, ♂ Tg8; F, ♀ St7 (illustration by J.S. Miller).

i0003-0090-321-1-1-f265.gif

Figure 266

Genitalia of Stenoplastis flavinigra (♂ JSM-530, ♀ JSM-531). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ St7; F, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f266.gif

Figure 267

Holotype ♂ genitalia of Stenoplastis satyroides (JSM-1397). A, genitalia; B, aedeagus; C, St8; D, Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f267.gif

Stenoplastis C. and R. Felder, 1874: pl. 105, fig. 16. Type species: Stenoplastis satyroides C. and R. Felder, 1874 (by subsequent designation by Kirby, 1892: 342).

Diagnosis

Although morphological evidence for the monophyly of Stenoplastis is strong, the four included species show divergent wing patterns (pls. 23, 24). When wing coloration is ignored, Stenoplastis can be recognized by the following set of characters: labial palpus short, porrect, barely ascending to clypeus (fig. 262A, D, G); Lp2 much shorter than Lp1; eye small, not bulging outward (fig. 262A–D, G), gena wide; postgena wide, covered with forward-pointing scales (fig. 262G); male antenna subserrate, ventral surface of each annulation with two transverse rows of setae; each annulation of female antenna with a distal, transverse row of bristles; FW DC less than one-half wing length (fig. 262H); male with a well-developed FW stridulatory organ, veins M1 and M2 swollen, raised from wing ventral surface; tympanal cavity fairly deep, enclosing an ovoid membrane; posterior margin of male Tg8 with a long, spiculate mesal process; female with a corethrogyne on Tg7 (fig. 263B–F); female St7 extremely broad (figs. 263B, 264F, 265F, 266E), wrapping upward laterally, surface scaleless, spiculate. All Stenoplastis species are relatively small, with FW lengths ranging between 11.0 and 15.0 mm.

Redescription

Male. FW length  =  11.0–13.0 mm. Head (fig. 262A–D, G): Labial palpus extremely short, porrect, barely ascending to clypeus; Lp1 long, curving slightly upward; Lp2 narrow, much shorter than Lp1; Lp3 short, almost quadrate; scales of front short, pointing mesodorsally, meeting at midline above to form a triangular tuft between antennal bases; eye relatively small, postgena wide, covered with short, forward-pointing scales, gena wide, scaleless, surface spiculate; antenna subserrate, ventral surface of each annulation bearing two transverse rows of short cilia.

Thorax (figs. 262E, 262F): Epiphysis short and flat, extending almost to apex of tibia; tegula relatively small and broad, apex blunt, ventral process without a sulcus separating it from dorsal portion; metathoracic tympanum relatively small, tympanal cavity deep, enclosing an ovoid membrane, membrane facing posterolaterally; dorsum of thorax, including tegula, lacking markings.

Forewing (fig. 262H; pls. 23, 24): Broad, outer margin weakly convex; vein Rs1 arising from radial sector below Rs2–Rs4; veins Rs2–Rs4 in the pattern [2+3]+4; M1 arising from distal margin of DC, widely separate from radial sector, UDC well developed; stridulatory organ present, M1 and M2 swollen near bases, raised from wing ventral surface; DC shorter than one-half FW length; veins M3 and CuA1 long stalked; wing pattern variable, with a wide yellow-orange transverse band (S. flavinigra, S. dyeri), with reddish orange basal and transverse maculations (S. decorata), or wings completely dark (S. satyroides); ventral surface with a silvery white triangle at base (S. satyroides, S. decorata), or base light brown to brown (S. flavinigra, S. dyeri).

Hind wing (fig. 262H; pls. 23, 24): Moderately broad; M3 and CuA1 long stalked; dorsal surface blackish brown (S. dyeri, S. satyroides), or with yellow (S. flavinigra) or orange (S. decorata) markings in central area; ventral surface broadly silvery white from base to beyond DC (S. decorata, S. satyroides), broadly orange-yellow (S. flavinigra) or brown (S. dyeri).

Abdomen: Short, truncate distally.

Terminalia (figs. 264A–C, 264E, 265A–C, 265E, 266A–D): Tg8 highly modified, tergum small, abruptly narrowed distally, forming an elongate mesal process on posterior margin, its apex densely spiculate, in S. decorata with a pair of long, hornlike, spiculate processes arising from membrane on either side; anterior margin of Tg8 simple; St8 larger and wider than Tg8, anterior margin broadly convex or forming a pair of broad apodemes (S. dyeri), posterior margin with a deep mesal excavation, margin sometimes setose (S. flavinigra); St8 with greatly expanded posterolateral angles, these densely spiculate; socii/uncus complex narrowly attached to tegumen, hinged; uncus short, broad, sometimes bifid; socii extremely short, thumblike; tegumen moderately wide, sides roughly parallel; tegumen shorter than vinculum; vinculum narrow, meeting below valva bases to form a convex saccus; valva wide, especially at base, evenly sclerotized; BO absent; costa moderately wide, not more heavily sclerotized than valva itself; apex variable, broad; aedeagus short, wide at base, then abruptly narrowed, curving downward in distal third, apex acute or not, without a ventral process; vesica small, lacking cornuti.

Female. FW length  =  11.5–15.0 mm. Head: Labial palpus similar to male, Lp2 much shorter than Lp1; antenna ciliate, threadlike.

Thorax: Similar to male.

Forewing (pl. 23): Broader, longer, and more triangular than male; markings similar, but colors less intense.

Hind wing (pl. 23): Broader, more rounded that male, markings similar, coloration less intense, orange central area of S. decorata more extensive than male; frenulum comprising 4–6 bristles.

Abdomen (fig. 263B–F): Short, wide; a corethrogyne on Tg7, its beige to light brown scales deciduous, densely packed, pointing posteriorly.

Terminalia (figs. 263B; 264D, F; 265D, F; 266E, F): Tg7 (bearing corethrogyne) membranous; St7 extremely wide, wrapping upward laterally, surface scaleless, setose, coarsely spiculate, posterior margin with a wide mesal excavation, posterolateral angles broadly rounded, forming shallow pockets; Tg8 completely membranous, bearing deciduous scales; AA small; pleuron of A8 membranous; PP long and thin, straight; PA ovoid, margin simple, surface spiculate; PVP mostly membranous, surface spiculate, infolded below PA (S. flavinigra, S. dyeri); ostium sometimes sclerotized and fluted below (S. flavinigra); DB extremely short, narrow, lightly sclerotized; CB small, narrow at base, expanding to an elongate oval anteriorly, completely membranous, without a signum or sclerites of any sort; DS arising dorsally near ostium, at junction of DB and CB.

Distribution

Of the four described Stenoplastis species, only two—S. flavinigra and S. decorata—occur with any frequency in collections. These are found on the western slope of the Colombian and Ecuadorian Andes, at elevations between 100 and 2200 meters. Stenoplastis dyeri, sp. nov., lives on Ecuador's eastern slope (fig. 247). The geographical distribution of the fourth taxon, S. satyroides, remains a mystery; in my search of the world's collections, only two male specimens were found. One (ZMH) has no label data except “Colombia”, whereas the provenance of the second (the BMNH type) is given as Bogotá. Stenoplastis has not been recorded south of Ecuador or north of Colombia.

Biology

A single larva of Stenoplastis dyeri was collected by Lee Dyer (October 2006) on an unidentified understory palm at San Rafael Falls, Ecuador (pl. 41A). That larva emerged as the only known female (JSM-1814). Subsequent focused collecting (January 2009) at the same site, as well as at two other locations, the Río Malo (S00°09′09″, W77°38′27″) and the Río Quijos near Baeza (S00°27′52″, W77°54′27″), produced S. dyeri larvae on Geonoma orbignyana (Arecaceae; see table 4). In fact, the caterpillars were fairly common on their palm host in the narrow band of forest lining the banks of the Río Quijos. At no time were adults collected, or even observed. Understory palms are now the confirmed host plants for two major clades of the Dioptinae, Dioptis (45 species) and Clade 17 (fig. 7), which includes Stenoplastis, Isostyla, and Tithraustes (totaling 19 species).

Stenoplastis adults are quite rare. I have collected S. flavinigra in bright sunshine along a dirt road in western Ecuador (1000 m). A group of four individuals were inadvertently flushed from low, weedy vegetation with a sweep net. Three males of S. dyeri were captured within the span of an hour, resting on the flowers of Asteraceae along the banks of the Río Quijos (Napo Province). These flowers were attracting large numbers of diurnal Lepidoptera.

Discussion

Cajetan and Rudolf Felder (1874) created the genus Stenoplastis for a single species, satyroides. Kirby (1892) placed Stenoplastis in the Lithosiidae (now Arctiidae: Lithosiinae). Prout (1918) moved the genus to the Dioptinae, and quickly added 17 species. Hering (1925) added five more. By the time of Bryk (1930), Stenoplastis contained 24 species. The only character state these authors used to unite the group was the presence of “ciliate” male antennae. Finally, Miller (1989) created the genus Pareuchontha, transferring two species from Stenoplastis into it. Prior to the work described here, Stenoplastis thus contained 22 species. It is noteworthy that so-called ciliate male antennae occur in no fewer than 11, mostly unrelated, genera of the Dioptinae.

Morphological study of the BMNH holotype of S. satyroides, combined with comprehensive cladistic analyses, show that membership in Stenoplastis should be greatly restricted. I have retained only three species from Bryk's (1930) list: satyroides C. and R. Felder, flavinigra Dognin, and decorata Dognin. A fourth, S. dyeri, is newly described. According to the classification proposed here (appendix 2), the other 19 species, formerly placed in Stenoplastis, belong in four dioptine genera—Argentala, Momonipta, Polypoetes, and Scoturopsis (see Discussion: Classification; fig. 354). The male genitalia of the S. satyroides holotype (fig. 267) show an apomorphy unique to Stenoplastis, presence of a long, spiculate central process on the posterior margin of Tg8 (figs. 264C, 265E, 266D). Additional synapomorphies of Stenoplastis include: the shape of male St8; the sclerotized valva; the configuration of the socii/uncus complex; the broadly sclerotized juxta; and the wide base of the aedeagus. The monophyly of this genus is not in doubt.

However, from a taxonomic and biogeographic standpoint, Stenoplastis remains obscure. As more specimens accumulate, the number of species will undoubtedly increase. Existing collections contain an undescribed Ecuadorian taxon, known from two specimens—a male (Mindo, Ecuador; FPC) and a female (“Ecuador”; BMNH). Body characters and genitalia (JSM-880, JSM-1459) provide clear indication of its membership in Stenoplastis, even though the wing pattern differs markedly from any known species.

Stenoplastis is the sister group to Isostyla + Tithraustes (Clade 17; fig. 7). These genera are united by having male genitalia with sclerotized valvae, and a socii/uncus complex that is reflexed downward (e.g., figs. 264A, 269A, 277A). Females in this clade are characterized by the presence of a corethrogyne on Tg7 (fig. 263).

KEY TO STENOPLASTIS SPECIES

1. Dorsal surface of FW with conspicuous yellow or orange markings (pl. 23); posterolateral angles of male St8 densely spiculate (figs. 264E, 265C, 266B); valva wide (figs. 264A, 265A, 266A), not curved inward in distal third2

Dorsal surface of FW without markings (pl. 24), completely dark chocolate brown, FW fascia faintly visible beyond DC; posterolateral angles of male St8 not densely spiculate (fig. 267C); valva narrow (fig. 267A), curved inward in distal third (Colombia)satyroides C. and R. Felder

2. Forewing with a wide, yellow-orange transverse band crossing apex of DC from subcosta to tornus, no basal dash; ventral surface of HW yellow or brown; distal process of male Tg8 arrow shaped (figs. 265E, 266D); valva not curling downward (figs. 265A, 266A); mesal excavation on posterior margin of female St7 not extending to St6 (figs. 265F, 266E)3

FW with a narrow, orange transverse band crossing beyond DC, as well as a long, orange basal dash running anterior to anal fold; ventral surface of HW silvery white; distal process of male Tg8 T-shaped (fig. 264C); valva curling broadly downward (fig. 264A); mesal excavation on posterior margin of female St7 extremely deep, extending to St6 (fig. 264F); FW length  =  12.5–14.5 mm (W Colombia)decorata (Dognin)

3. Yellow-orange FW band abruptly wider between CuA1 and CuA2, band terminating well short of tornus; HW with a large yellow central area; posterior margin of male St7 broadly concave (fig. 266B); valva apex tapered (fig. 266A); posterior margin of female St7 with a wide, V-shaped mesal excavation (fig. 266E); FW length  =  11.0–12.0 mm (W Colombia, W Ecuador)flavinigra (Dognin)

Yellow-orange FW band widest near costa, band extending almost to tornus; HW uniformly blackish brown; posterior margin of male St7 with a wide, U-shaped mesal excavation (fig. 265C); valva apex rounded (fig. 265A); posterior margin of female St7 broadly concave (fig. 265F); FW length  =  11.5–13.0 mm (E Ecuador)dyeri, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Stenoplastis decorata (Dognin)

Figures 262A–C, 262F, 262H, 263B–F, 264; plate 23 [EX]

Polypoetes decorata Dognin, 1909: 224.

Type Locality

Colombia, San Antonio, 2000 m.

Type

Syntype ♂, 1908, leg. Fassl (USNM type no. 30955).

Discussion

Our knowledge of Stenoplastis decorata is based on 12 moths collected in western Colombia by A.H. Fassl, as well as a single example captured by G.M. Palmer. All of this material was deposited a century ago in the BMNH, MNHN, and USNM collections. The largest part of the series, eight specimens, is at the USNM.

The positions of the orange FW and HW maculations (pl. 23) make this species distinctive within the Dioptinae. Characters of wing pattern and male genitalia suggest that S. decorata and S. satyroides are sister species. For example, in both taxa the HW ventral surface is broadly silvery white in the basal half (see S. satyroides, pl. 24); the HW ventral surface of S. flavinigra is yellow, whereas that of S. dyeri is dark brown. Furthermore, in S. decorata and S. satyroides the distal process on male Tg8 is truncate at its apex (figs. 264C, 267D), whereas in S. flavinigra and S. dyeri this process is arrow shaped (fig. 265E, 266D).

Distribution

Colombia (BMNH, MNHN, USNM).

Dissected

♂, Colombia, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-534); ♂, Colombia, Alto de las Ances, 2200 m, Oct 1908, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1024, wing slide no. JSM-1025); ♀, Colombia, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-535, wing slide no. JSM-1442).

Stenoplastis dyeri, new species

Figures 247, 265; plate 23

Diagnosis

The wing pattern of S. dyeri is striking; no other Stenoplastis has a FW with a single wide, orange transverse band (pl. 23). Stenoplastis dyeri cannot be confused with S. decorata (pl. 23), where the FW shows an orange basal dash and the HW bears an orange maculation beyond the DC. Furthermore, Lp1, as well as the thoracic and abdominal venter, are cream colored in S. decorata, but these are dark in S. dyeri. Stenoplastis dyeri can be separated from its Ecuadorian congener, S. flavinigra (pl. 23), because the latter shows a large yellow central area of the HW. These two also occur on opposite sides of the Andes.

In the male genitalia, S. dyeri is distinguished by its lobate valva apex (fig. 265A), as well as by the posterolateral margins of St8, which curve outward (fig. 265C). In S. dyeri females, the posterior margin of St7 is broadly concave (fig. 265F), whereas in other Stenoplastis for which females are known (S. flavinigra, S. decorata) there is a deep mesal excavation (figs. 264F, 266E).

Description

Male. Forewing length  =  11.5–12.0 mm. Head: Labial palpus short, porrect, curving upward to immediately above clypeus; Lp1 gray-brown, dorsum bearing scattered cream-colored scales, venter bearing longer, erect scales; Lp2 and Lp3 gray-brown; front gray-brown, scales pointing dorsomedially, forming a small, upright tuft between antennal bases, frontal midline scaleless; occiput covered with short, appressed, anteriorly directed, charcoal-gray scales; eye small, completely surrounded by a scaleless area, gena broadly scaleless; vertex covered with long, forward-pointing gray-brown scales, these with a steely blue cast; antenna subserrate; dorsum of antennal shaft covered with appressed, coppery brown scales.

Thorax: Legs light coppery brown; pleuron light gray-brown, covered with long, hairlike and shorter triangular scales, these dentate at their apices; patagium and tegula covered with coppery brown to dark brown hairlike scales; dorsum dark coppery brown to blackish brown; tympanum moderate in size, membrane facing posterolaterally, area immediately below membrane scaleless.

Forewing: (Dorsal) Ground color dark brown to blackish brown (pl. 23), veins concolorous; a wide, ochreous orange transverse band, extending from Sc anteriorly to near tornus posteriorly; inner margin of transverse band slightly irregular, gently convex, crossing immediately beyond DC along discocellular veins; outer margin of transverse band gently concave, crossing well beyond fork of Rs1+Rs2–Rs4 and fork of M3+CuA1. (Ventral) Similar to dorsal surface, except ground color slightly lighter brown; area of fascia, within transverse band, sparsely scaled.

Hind wing: (Dorsal) Ground color dark brown to blackish brown, slightly lighter in tone than FW, anterior margin lighter gray-brown in basal two-thirds; no maculations present. (Ventral) Uniformly dark brown, slightly lighter in tone than dorsal surface.

Abdomen: Dorsum dark coppery brown to blackish brown; venter gray-brown.

Terminalia (figs. 265A–C, E): Tg8 longer than Tg7, shorter than St8, anterior margin gently sinuate, expanded at lateral angles; lateral margins of Tg8 gently concave and gradually tapered in basal third, then immediately constricted inward at a 90° angle, distal two-thirds forming a narrow, arrow-shaped structure, with arrowhead posteriorly covered with coarse setae; socii/uncus complex small, narrowly attached to arms of tegumen; uncus short, bifid; socii short, wide, curving slightly outward at apices; arms of tegumen thin, slightly wider dorsally, arms strongly arched as they join at midline; arms of vinculum narrow, forming a V-shaped margin below; saccus small, folded upward, but falling well short of valva bases and juxta; valva broad, lightly sclerotized, extremely wide at base, constricted distally to form a lobate apex; BO absent; costa narrow, poorly differentiated; apex bent slightly downward, covered with long setae; juxta roughly ovoid, ventral margin forming a shallow cup; arms of transtilla short, oriented horizontally, abruptly narrowed, joining above aedeagus to form a small, cup-shaped structure; aedeagus moderate in length, curving gently downward, bell shaped at base, gradually tapered distally; vesica small, ovoid, with a small sclerite at base, cornuti apparently absent.

Female. Forewing length  =  13.0 mm. Head, thoracic, and abdominal coloration similar to male; abdominal dorsum gray-brown; venter light gray-brown; corethrogyne comprising densely packed, gray-brown hairlike scales on Tg7 and Tg8.

Terminalia (fig. 265D, F): Tg7 quadrate, almost membranous, bearing corethrogyne scales, length and width equal to Tg6, anterior and posterior margins simple; St7 large and wide, heavily sclerotized, lateral portions forming large, shallow pockets, these with crenulate margins, central region covered with long setae; anterior margin of St7 gently convex, crenulate, posterior margin broadly concave; Tg8 large, balloonlike, completely membranous, bearing corethrogyne scales; AA relatively short and thin, forming irregular sclerotized knobs at apices; A8 pleuron lightly sclerotized, crenulate dorsally, posterior margin emarginate; PA large, lightly sclerotized, roughly triangular, surface densely spiculate; PP long and extremely thin, widened near bases; membrane below PA infolded; DB short, narrow, completely membranous; ostium tiny, sclerotized, dorsoventrally compressed; PVP short and wide; CB small, ovoid, completely membranous; signum absent; DS attached to DB dorsally, near junction with ostium.

Etymology

This species is named in honor of Lee Dyer (University of Nevada, Reno), who initially discovered larvae of S. dyeri (October 2006) feeding on an understory palm. Lee has spearheaded the NSF-funded project entitled Caterpillars and parasitoids of the eastern Andes in Ecuador. His tireless research efforts have contributed greatly to our growing knowledge of the Lepidoptera fauna of Andean Ecuador and lowland Costa Rica.

Distribution

Stenoplastis dyeri is the only described member of the genus confirmed to occur on the eastern side of the Andes (fig. 247). The type locality for S. satyroides is purportedly “Bogotá”, while S. decorata and S. flavinigra, for which we have well-documented localities, are restricted to the western slope. The range of S. dyeri, as currently understood, is relatively small, extending from Baeza (Napo Province) approximately 60 km northeast to San Rafael (Sucumbíos Province). The species has been captured at two elevations—1200 and 1890 meters.

Biology

The host plant of Stenoplastis dyeri has been established as Geonoma orbignyana, in the Arecaceae (table 4). Recent fieldwork (January 2009) has shown that caterpillars of S. dyeri are relatively common on their host, whereas adults are almost never collected. Observations of this sort provide crucial support for caterpillar-based faunal surveys of tropical Lepidoptera. These are essential to thoroughly document the existing biodiversity.

Discussion

On a single afternoon in 1988, I collected three males of S. dyeri on flowers of a shrub growing along the banks of the Río Quijos, which flows below the town of Baeza. Four subsequent visits to precisely the same locality (1993, 2004, 2006, 2009) produced no additional adult specimens.

Wing pattern and genitalia suggest that S. dyeri is the sister species to S. flavinigra. For example, both show an arrow-shaped process on the posterior margin of male Tg8 (figs. 265E, 266D).

Holotype

Male. Ecuador: Napo: Baeza, near Río Quijos, 1890 m, 31 Oct 1988, leg. J.S. Miller, on flowers of Asteraceae. The type is deposited at the AMNH.

Paratypes

Ecuador: Napo: 2♂♂, Baeza, near Río Quijos, 1890 m, 31 Oct 1988, leg. J.S. Miller, on flowers of Asteraceae (AMNH; genitalia slide no. JSM-730). Sucumbíos: 1♀, Cascada de San Rafael, 0°06′13.7″S, 77°35′16.2″W, 1200 m, 21 Oct 2006, leg. L. Dyer, larva on palm (AMNH; genitalia slide no. JSM-1814).

Other Specimens Examined

None.

Dissected

1♂, 1♀.

Stenoplastis flavinigra (Dognin)

Figures 262D, 262E, 262G, 266; plate 23 [EX]

Momonipta flavinigra Dognin, 1910a: 17.

Type Locality

Colombia, Cali.

Type

Syntype ♂ (USNM type no. 30956).

Discussion

Stenoplastis flavinigra is more common than other Stenoplastis species in museum collections, and appears to be more widely distributed, recorded from Chocó in northwestern Colombia south to Pichincha, Ecuador. It occurs at low to midelevations—between 100 and 1000 meters. This is the smallest species of Stenoplastis. Additional USNM syntypes of S. flavinigra were captured in western Colombia at Juntas, Dagua (300 m), in March 1909.

Distribution

Colombia (AMNH, BMNH, USNM, ZMH), Ecuador (AMNH).

Dissected

♂, Ecuador, Pichincha, road nr. Tinalandia to Cooperativa Bolivar, 1030 m, 20 May 1993, leg. J.S. Miller, day-coll., AMNH (genitalia slide no. JSM-1690); ♂, Colombia, El Tigre, Río Tamana, Chocó, 320 ft, Feb 1909, BMNH (genitalia slide no. JSM-530); ♀, W Colombia, Juntas de Río Tamana and Río San Juan, 405 ft, Feb 1909, BMNH (genitalia slide no. JSM-531).

Stenoplastis satyroides C. and R. Felder

Figure 267; plate 24

Stenoplastis satyroides C. and R. Felder, 1874: pl. 105, fig. 16.

Type Locality

Colombia, “Bogotá”.

Type Locality

Holotype ♂, leg. Lindig (BMNH).

Discussion

The description of Stenoplastis satyroides is comprised solely of the color plate (C. and R. Felder, 1874), and only the moth's ventral surface was shown. I had long thought that the satyroides type would never be found, having looked for it several times at the BMNH. However, Martin Honey (July 2003) managed to locate a BMNH specimen that is, with little doubt, the Felder type. According to Honey, the handwriting on the determination label is Felder's. The moth's underside (pl. 24) matches the specimen figured in the original description with precision. There are three labels on this specimen: (1) “Stenoplastis satyroides, [?] i. t.” [ =  in tabula, or figured] in red handwriting; (2) “372 Lin[dig] Bogota” in black handwriting; and (3) “Rothschild Bequest, B.M. 1939-1” in black type.

Careful study of the satyroides type, including its genitalia (fig. 267), was extremely illuminating. This species is not congeneric with the numerous taxa that have historically been included in Stenoplastis ( =  Momonipta) by Prout (1918), Hering (1925), and Bryk (1930). The FW exhibits a well-developed stridulatory organ in which the DC is less than one-half the FW length, veins M1 and M2 are swollen on the wing's ventral surface, and the fascia beyond the DC is sparsely scaled. Furthermore, the moth bears short labial palpi, upturned to immediately above the clypeus; Lp2 is shorter than Lp1, and Lp3 is extremely small. The eyes are relatively small, with a wide, scaleless gena. When Stenoplastis is finally defined according to the apomorphic traits exemplified by S. satyroides, only two species originally placed there—decorata and flavinigra—remain.

Interestingly, the only other confirmed example of S. satyroides I have seen is a male in the ZMH collection, identified long ago by Martin Hering. That specimen, from Colombia (no other data; leg. Kalbreyer), matches the type precisely and is in all probability the moth figured by Hering (1925: fig. 69i, ventral surface shown) in his contribution to Seitz. Amazingly, as obscure as this moth is, Hering had firmly established its identity, even without dissection. This is testament to his remarkable knowledge of the Dioptinae.

Distribution

Colombia (BMNH, ZMH).

Dissected

Holotype ♂ (genitalia slide no. JSM-1397).

The following species have been transferred from Stenoplastis: aborta Dognin to Polypoetes (Rubribasis Group) albicuneata Dognin to Polypoetes (Rufipuncta Group) albiplaga Warren to Momonipta aterrima Dognin to Polypoetes (Rubribasis Group) carderi Druce to incertae sedis coras Druce to Scoturopsis disconnexa Dognin to Polypoetes (Rubribasis Group) empheres Prout to Polypoetes (Persimilis Group) eximia Warren to Polypoetes (Persimilis Group) flavibasis Druce to incertae sedis jipiro Dognin to Polypoetes (Persimilis Group) opaca Hering to Polypoetes (Persimilis Group) pellucida Dognin to Polypoetes (Rubribasis Group) persimilis Dognin to Polypoetes (Persimilis Group) rubribasis Hering to Polypoetes (Rubribasis Group) semisocia Dognin to Polypoetes (Persimilis Group, as a synonym of pallinervis Dognin) subalba Walker to Argentala subcaesia Prout to Argentala subcoerulea Warren to Argentala unifascia Hering to Scoturopsis

TITHRAUSTES DRUCE, 1885

Figures 263A, 268Figure 269Figure 270Figure 271Figure 272Figure 273Figure 274275; plate 24

Figure 268

Morphology of Tithraustes (♂♂). A, head of T. lambertae, lateral view; B, head of T. lambertae, frontal view; C, head of T. lambertae, posterior view; D, T. deiphon labial palpus; E, head of T. lambertae, lateral view; F, T. lambertae tegula; G, T. lambertae wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f268.gif

Figure 269

Genitalia of Tithraustes lambertae, sp. nov. (♂ JSM-1793, ♀ JSM-1794). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♀ genitalia; E, ♂ Tg8 (illustration by J.S. Miller).

i0003-0090-321-1-1-f269.gif

Figure 270

Costa Rica, showing the known distributions of Tithraustes lambertae, sp. nov., and T. snyderi, sp. nov.

i0003-0090-321-1-1-f270.gif

Figure 271

Genitalia of Tithraustes moerens (♂ JSM-516, ♀ JSM-520). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♂ Tg8; E, ♀ genitalia; F, ♀ St7.

i0003-0090-321-1-1-f271.gif

Figure 272

Genitalia of Tithraustes deiphon (♂ JSM-1621, ♀ JSM-1054). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ genitalia; F, ♀ St7.

i0003-0090-321-1-1-f272.gif

Figure 273

Genitalia of Tithraustes esernius (♂ JSM-538, ♀ JSM-539). A, ♂ genitalia; B, ♂ St8; C, aedeagus; D, ♂ Tg8; E, ♀ St7; F, ♀ genitalia.

i0003-0090-321-1-1-f273.gif

Figure 274

Genitalia of Tithraustes haemon (♂ JSM-515, ♀ JSM-522). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f274.gif

Figure 275

Genitalia of Tithraustes snyderi, sp. nov. (holotype ♂ JSM-1632, paratype ♀ JSM-1778). A, ♂ genitalia; B, ♂ Tg8; C, aedeagus; D, ♂ St8; E, ♀ genitalia; F, ♀ St7.

i0003-0090-321-1-1-f275.gif

Tithraustes Druce, 1885a: 158. Type species: Tithraustes haemon Druce, 1885a (by subsequent designation by Kirby, 1892: 413).

Diagnosis

The genus Tithraustes contains light-bodied species, many with delicate, semihyaline wings (pl. 24). The FW invariably exhibits a white fascia immediately beyond the DC, semihyaline basal dashes, and 2–3 small submarginal spots. The HW can be broadly white in the central area, or show a conspicuous white spot beyond the DC. Other characteristics of Tithraustes include thin, sickle-shaped labial palpi with an elongate Lp3, and large bulging eyes (fig. 268A–E). Males have a thin abdomen, wider at the apex, as well as bipectinate antennae with long, thin rami. In conjunction with the traits listed above, females can be recognized by the corethrogyne (fig. 263A), tightly packed with deciduous scales at the terminus of the abdomen.

The genus with which Tithraustes can most easily be confused is its sister group, Isostyla (pls. 24, 25). Isostyla species exhibit many of the same features as Tithraustes, and they fly in the same habitats. However, among other things, a wing-venation difference is diagnostic: in Tithraustes, FW veins Rs2–Rs4 branch in the pattern [2+3]+4 (fig. 268G), whereas the wings of Isostyla (fig. 276G) show a less common configuration, 2+[3+4]. Additional characters for separation are discussed with reference to Isostyla (below).

Redescription

Male. FW length  =  10.5–20.0 mm. Head (fig. 268A–E): Labial palpus long, thin, often held away from face, curving strongly upward to middle of front or above, not reaching antennal bases; Lp1 relatively long, almost straight, sometimes with a few elongate scales below; Lp2 extremely long and thin, over one and a half times the length of Lp1, curving gently upward, a few longer scales along ventral surface; Lp3 narrow, greatly elongate, nearly one-half the length of Lp2, tightly scaled, apex acute; scales of front short, closely spaced, pointing dorsomedially, forming a small, triangular tuft between antennal bases; eye usually large, bulging outward, no scaleless band below, rarely (T. albinigra, T. snyderi) somewhat small with a wide gena; postgena narrow to moderately wide; antenna bipectinate, rami long and thin, each with a robust dorsal bristle approximately one-third from apex.

Thorax (fig. 268F): Epiphysis long, almost four-fifths length of tibia, extending slightly beyond tibia apex; tegula extremely short, wide, almost ovoid, much less than one-half length of mesoscutum, distal portion broad, ventral angle blunt, transverse sulcus absent; metathoracic tympanum small, tympanal cavity shallow, scaleless, tympanal membrane small, ovoid, facing posteroventrally.

Forewing (fig. 268G; pl. 24): Broad, outer margin convex, rounded at tornus; vein Rs1 long stalked with radial sector; veins Rs2–Rs4 in the pattern [2+3]+4, stalk of 3+4 often short; M1 arising from DC near anterolateral angle of DC, widely separate from base of Rs1–Rs4, UDC well developed; stridulatory organ present, veins M1 and M2 arising close together from DC, their bases swollen, a short fold between bases of M1 and M2 on ventral surface; DC one-half or slightly greater than one-half FW length; veins M3 and CuA1 long stalked; ground color gray-brown to blackish brown; with a white fascia beyond DC; with 1 or 2 small, white subapical spots, as well as a small, white submarginal spot near tornus.

Hind wing (fig. 268G; pl. 24): Somewhat elongate; M3 and CuA1 long stalked; ground color gray-brown to blackish brown; a large white fascia beyond DC.

Abdomen: Elongate, narrow at base, wider distally.

Terminalia (figs. 269A–C, E; 271A–D; 272A–D; 273A–D; 274A–D; 275A–D): Tg8 much longer than St8, narrower than Tg7, constricted near midpoint, lateral margins with straplike longitudinal struts to which tendons are attached, anterior margin with short lateral apodemes, posterior margin bearing various sclerotized processes; St8 short and wide, lateral margins expanded, convex; anterior margin of St8 simple, sometimes slightly concave at midline, posterior margin with a variously shaped mesal notch, its edge heavily sclerotized; socii/uncus complex small, narrowly attached to tegumen, hinged downward; uncus short, curving downward, apex digitate (Moerens Group) or bifid (Haemon Group); socii short, thumblike, curving slightly upward; tegumen wide, concave, much taller than vinculum; vinculum short, narrow, joined to tegumen to form large, elbowlike structures along anterior margin of ring; saccus apparently absent; region above ventral margin of genitalia with a cup-shaped, mesal structure in membrane; valva short to moderately long, completely sclerotized, variable in shape, strongly attached to ring, concave on inner surface; BO absent or present as a few fine wrinkles; costa either narrow, or apparently absent; apex variable in shape, often lobelike (Haemon Group) or scoop shaped (Moerens Group); arms of transtilla extremely thin, straplike, oriented horizontally, meeting at midline to form a small, anteriorly directed sclerite; aedeagus relatively short, simple, and tube shaped, slightly wider at base; apex of aedeagus simple or with a small, ventral tooth (e.g., T. haemon); vesica small, opening dorsally, bearing a brush of thin, spinelike cornuti near base.

Female. FW length  =  12.0–20.0 mm. Head: Labial palpus shorter than in male, Lp3 not as elongate; antenna without pectinations, each annulation with four robust bristles arising near base.

Thorax: Similar to male.

Forewing: Longer and broader than male, ground color lighter, markings larger and more diffuse, wings less densely scaled.

Hind wing: Longer and broader than male, ground color lighter, wings more hyaline than in males; frenulum comprising approximately 4–6 bristles.

Abdomen (fig. 263A): Shorter than male; St7 sclerotized, conspicuously devoid of scales, with a mesal notch on posterior margin; Tg7 and Tg8 membranous, greatly expanded, bearing a corethrogyne comprising an extremely large patch of densely packed, deciduous scales; corethrogyne varying in color, either blue gray, light gray-brown, or yellowish brown.

Terminalia (figs. 269D; 271E, F; 272E, F; 273E, F; 274E; 275E, F): Tg7 large, membranous; St7 short and wide, sclerotized, lateral margins gently convex; anterior margin of St7 simple, posterior margin with a large, V-shaped or U-shaped mesal excavation; Tg8 membranous, deciduous scales shorter than ones on Tg7; AA relatively short, curved downward, swollen, especially near bases; A8 pleuron membranous; PP long, bent sharply downward, greatly swollen at bases; PA large, often roughly triangular, posterior margin convex; PVP extremely large and wide, variable in shape, posterior margin sclerotized, emarginate; DB sclerotized, short and narrow (e.g., T. moerens), or relatively long and wide (e.g., T. haemon); CB moderately large, membranous, an elongate oval or round; signum a narrow, transverse sclerite, located on dorsal midline near base of CB, its internal surface finely spiculate; DS arising dorsally near ostium, at junction of DB and CB.

Distribution

Tithraustes has a Central American-Chocoan distribution. Described species occur from Honduras south to Ecuador. No members have been recorded north of Honduras, none occur in the Oriente of Colombia or Ecuador, and none live in Peru. Other dioptine genera showing this general distribution include Isostyla and Pseudoricia, close relatives of Tithraustes (Clade 16; fig. 7). Tithraustes reaches its highest diversity in Costa Rica and Panama, where eight of the nine described species occur. A single taxon, T. moerens, lives in western Colombia and Ecuador. Most Tithraustes have been collected below 700 meters. This is perhaps related to the distribution of their larval host plants, understory palms.

Biology

Immature stages are known for five Tithraustes species. The caterpillars of all are associated with understory palms (table 4). So far, the host list for Tithraustes includes six palm genera—Asterogyne (pl. 48B), Calyptrogyne (pl. 48C), Chamaedorea, Geonoma, Prestoea, and Welfia. Some Tithraustes species are oligophagous (recorded from more than one palm). For example, T. lambertae has been reared on six palm species in five genera. Tithraustes seminigrata has also been found consistently on Heliconia (Heliconiaceae), which thus represents a second monocot association. Outside the Dioptinae, at least one other notodontid group feeds on palms; the genus Dunama Schaus, has been recorded on Chamaedorea (Todd, 1976; see also Janzen and Hallwachs, 2008; Dyer et al., 2009).

Tithraustes caterpillars share a characteristic appearance. The head capsule is yellowish brown and bears a black spot on its vertex, as well as black lateral spots on each side of the head (pl. 39A, D, E). This pattern is mirrored on A8, which apparently serves as a “false head”. The thorax and abdomen of Tithraustes larvae exhibit alternating longitudinal black, white, and grayish stripes. The chrysalis (pl. 39B, F), which is attached to the leaf surface in an exposed manner, is yellowish brown with a contrasting series of black spots, lines and dashes. Larval coloration differences have not been explored as a means for separating Tithraustes species, but such traits show potential in other groups. For example, head capsule patterns can be used to separate species of Lymantria (Nagaraja et al., 1969) and Josia (Miller and Otero, 1994).

Discussion

The dioptine classifications of Prout (1918) and Hering (1925), both based on relatively meager character information, have proved to be remarkably insightful when subjected to detailed scrutiny using cladistic methods more than 80 years later. However, as was true of most early taxonomists, those authors recognized groups, often termed “dumping ground” genera in modern vernacular, where they placed species showing no obvious affinities elsewhere. Tithraustes was one of those.

Bryk (1930), who summarized the works of Prout and Hering to produce the only available catalog for the Dioptinae, listed 42 species in Tithraustes. In my classification (appendix 2), only eight of those remain. As with all dumping-ground genera, the problem invariably stemmed from a lack of derived traits to define the group. These authors seemed to refer any member of the Dioptinae in which males have a FW stridulatory organ and bipectinate antennae to Tithraustes. Such a strategy was doomed to failure. According to the classification proposed here (appendix 2), the male FW stridulatory organ occurs in 18 genera of the Dioptinae, and bipectinate antennae occur throughout the subfamily.

A sister-group relationship between Tithraustes and Isostyla is strongly supported (BS  =  6, fig. 2; appendix 4). Synapomorphies include the long, thin, sickle-shaped labial palpi (figs. 268A, D, E; fig. 276A, D, F) with an elongate Lp3. More obscure synapomorphies include a tall, narrow metameron on the thorax, and almost ovoid tegulae (fig. 268F, 276E). Male and female genitalia provide additional supporting evidence of a sister-group relationship between these genera. Larvae of Tithraustes and Isostyla are superficially identical, and both utilize understory palms as host plants. Means for distinguishing the adults are detailed in the Key to the Genera of Dioptini, as well as in the diagnoses for each genus. Together, Tithraustes + Isostyla form a clade with Stenoplastis (Clade 17; fig. 7). Among other features, this group is defined by presence of a corethrogyne on the female abdomen.

Tithraustes species are difficult to identify. By far the most effective way is by study of their genitalia, which provide definitive means for separation. Wing patterns are difficult to interpret (pl. 24), but they can be helpful in certain cases. In the keys below I have used all the characters I could find. Characters from male genitalia demonstrate the existence of two subclades within Tithraustes, which I designate the Moerens and Haemon groups.

The species keys obviously do not apply to undescribed taxa. I have discovered at least six unnamed Tithraustes species based on study of existing material in collections. As holds true for many other dioptine genera, there is little doubt that Tithraustes will double in size when comprehensive revisionary work is eventually undertaken.

KEY TO TITHRAUSTES SPECIES GROUPS (MALES)

1. Uncus digitate, simple at apex (e.g., fig. 269A); valva elongate, heavily sclerotized, constricted near midpoint to form a large, concave structure distally (Costa Rica S to Ecuador)Moerens Group

Uncus narrow or short, bifid at apex (e.g., fig. 273A); valva moderate in length, lightly sclerotized, constricted distally to form a small, lobate apical structure (El Salvador S to Panama)Haemon Group

1. MOERENS GROUP

There are only three species in the Moerens Group. One of those, T. quinquepunctata, is easy to identify by its wing pattern. The other two—T. moerens from Ecuador and T. lambertae from Costa Rica—are similar to each other in appearance. They can be separated by having two (T. lambertae) as opposed to three (T. moerens) white submarginal FW spots, and by comparison of their male and female genitalia. Males of these two can be distinguished without dissection; the shape of Tg8 differs (figs. 269E, 271D), a trait that can be observed by brushing scales from the apex of the abdomen.

KEY TO MOERENS GROUP SPECIES

Plate 24

1. Forewing with a white basal dash along anal fold; HW mostly white with a wide, chocolate-brown band along outer margin (Panama)quinquepunctata Warren

FW without a white basal dash along anal fold; HW mostly gray, semihyaline in basal half, with an ovoid white fascia beyond distal margin of DC2

2. Forewing with three small, white submarginal spots; posterior margin of male Tg8 with a middorsal keel (fig. 271D); valva apex forming a small, rounded, spatulate structure small (fig. 271A); base of female DB small and narrow (fig. 271E), cylindrical, lightly sclerotized (W Ecuador)moerens Warren

FW with two small, white submarginal spots; posterior margin of male Tg8 with paired lobes at lateral angles (fig. 269E); valva apex forming a large, oblong, spatulate structure (fig. 269A); base of DB wide, flattened (fig. 269D), heavily sclerotized (Costa Rica)lambertae, sp. nov.

SPECIES INCLUDED AND MATERIAL EXAMINED

Tithraustes lambertae, new species

Figures 268A–C, 268E–G, 269, 270; plates 24, 39A, 39B, 39E

Diagnosis

Among Costa Rican Tithraustes species, the wing size and pattern of T. lambertae most closely resemble T. haemon (pl. 24). In both, the male FW has a roughly ovoid white fascia beyond the discal cell, as well as two small submarginal spots—one on M2 and the other slightly anterior to CuA2. The HW shows a single, large white fascia beyond the DC. Females of T. lambertae and T. haemon exhibit an additional submarginal spot on the FW, straddling M1. The wing patterns of other Central American Tithraustes differ from these, and would not likely be confused. One way to separate T. lambertae from T. haemon is that the FW ground color of lambertae is dark gray and the HW is dark charcoal gray, whereas in T. haemon the FW is gray-brown and the HW is dark gray-brown. Other features of body coloration do not differ. The male and female genitalia of these two taxa are dramatically different, indicating membership in different taxa groups (appendix 2).

Description

Male. Forewing length  =  16.0–17.5 mm. Head (fig. 268A–C, E): Labial palpus curving upward almost to antennal base, all segments narrow narrow and elongate; Lp1 gray to dark gray, a few scattered white scales laterally and ventrally, scales below forming a ridge; Lp2 dark gray, with a white patch on inner surface in distal two-thirds; Lp3 entirely dark gray; scales of front pointing dorsomedially, not quite reaching antennal bases, midline scaleless; lateral and ventral margins of front white, central area dark gray; occiput white, with long scales ventrally; eye extremely large, bulging, completely surrounded by scales; vertex gray-brown, with a thin white line along midline, and white immediately behind each antennal base conjoined with white, posterolateral patches; antenna bipectinate, rami long; scape dark gray; dorsum of antennal shaft silvery gray.

Thorax (fig. 268F): Legs, including coxae and spurs, white on inner surfaces, dark gray on outer ones; pleuron covered with long white scales, a few gray scales interspersed; patagium dark gray, a thin white stripe along midline; tegula covered with short, erect, orange to dark orange scales, fringed at apex with gray hairlike scales; dorsum gray to blue-gray, a poorly defined midsagittal line of short, white scales; tympanum shallow, partially enclosed; tympanal membrane small, almost round, facing lateroventrally, metepimeron scaleless below membrane.

Forewing (fig. 268G; pl. 24): (Dorsal) Ground color gray to dark gray, some tinges of gray-brown; basal third semihyaline, with veins gray as they pass through; apex of DC dark gray; a moderately sized, white fascia immediately beyond DC, extending from base of Rs1–Rs4 anteriorly to a point halfway between M2 and fork of M3+CuA1 posteriorly, fascia wider at posterior margin; two small, white submarginal spots, a round one straddling M2, and a second, more diffuse one, located immediately anterior to CuA2. (Ventral) Similar to dorsal surface, but ground color darker, generally charcoal gray; three white fascias standing out in sharp contrast.

Hind wing (fig. 268G; pl. 24): (Dorsal) Ground color gray, generally darker than FW; central area of wing from base semihyaline, veins gray as they pass through; a wide, dark charcoal-gray band along outer margin, band widest near apex; a large, ovoid, white fascia immediately beyond DC; anterior margin of fascia touching base of Rs+M1, posterior margin falling short of M3+CuA1; discocellular veins, immediately proximal to fascia, dark charcoal gray. (Ventral) Similar to dorsal surface, but ground color slightly darker; a short, diffuse, white dash along anal fold in outer third, falling short of margin.

Abdomen: Dark, metallic gray above; venter white; a pair of white lateral stripes along pleuron.

Terminalia (fig. 269A–C, E): Tg8 elongate, relatively narrow, arching upward at midline, constricted near middle; a pair of ventral apodemes present at halfway point along lateral margins of Tg8, sclerotized struts running from these to near lateral angles; wide, sclerotized processes at posterolateral angles of Tg8, these excavated near middle; posterior margin of Tg8 with a hump shaped mesal process, crenulate below; St8 wide, shorter than Tg8; posterior margin of St8 sclerotized, forming two flat, hornlike processes on either side of a U-shaped mesal excavation; anterior margin of St8 sinuate near midline, anterolateral angles excavated; socii/uncus complex small, thinly joined to dorsum of ring, hinged downward; uncus digitate, curved downward; socii digitate, curved gradually upward; tegumen narrow, concave, much taller than vinculum, an elbowlike anteroventral expansion; vinculum short, thin; saccus small, V-shaped below; juxta narrow, tall, forming a cup-shaped structure; manica with paired, sclerotized dorsoventral bands above aedeagus opening; valva sclerotized, wide, an indentation in ventral margin two-thirds out from base; BO absent, region sclerotized, with coarse setae on valva inner surface; apex broadly spatulate, with sparsely scattered setae on inner surface; transtillar arms extremely thin, arched upward from base, produced anteriorly near midline; aedeagus moderately long and wide, expanded at base, no process at apex; vesica relatively small, with a swirl of thin, progressively longer, spinelike cornuti laterally on right side.

Female. Forewing length  =  16.5–18.0 mm. Body coloring similar to male; labial palpus shorter than male, curving upward to immediately above clypeus; antenna ciliate, with two pairs of long bristles arising from proximal part of each annulation.

Forewing: Similar to male, but with an additional, faint, white submarginal spot straddling M1.

Hind wing: Similar to male.

Abdomen: Coloring similar to male; a corethrogyne on A7 and A8, comprising a dense mat of short, buff-colored scales laterally, and a large patch of short, blue-gray scales in central region of A8.

Terminalia (269D): Tg7 large, wide, membranous, bearing a corethrogyne; St7 small, trapezoidal, widest at anterior margin, posterior margin slightly concave near midline, anterior margin simple; Tg8 membranous, expanded dorsally, bearing scales of corethrogyne; AA hollow, moderately long, wide at base, narrowing and upturned near apex; pleuron of A8 with a sclerotized band along anterior margin; PVP extremely large, smoothly sclerotized, slightly concave; posterior margin of PVP with wide processes at lateral angles, gently concave at midline; ostium ovoid; DB sclerotized, relatively short, dorsoventrally compressed, narrowing distally; DS arising from DB near ostium; CB roughly ovoid, narrower near base; a narrow, transverse signum, its surface finely dentate, present in CB on right side; membrane between PVP and PA expanded, shagreened; PA large, outer margin almost straight, emarginate near base, sclerotized; PP hollow, wide at base, gradually narrowing, drooping slightly downward distally.

Etymology

This species is named in honor of Anne Lambert of Chester, Nova Scotia, Canada, in recognition of her enthusiasm for protecting the Area de Conservación Guanacaste rainforest, where Tithraustes lambertae lives. Anne's contributions have included both forest purchase and providing salaries for the parataxonomists who rear wild-caught caterpillars.

Distribution

Whereas T. haemon has been recorded only on the Pacific side of the Central Cordillera in southern Costa Rica, T. lambertae occurs in wet forests on the Caribbean slope (fig. 270). It has been recorded from the eastern slopes of Volcán Orosí near the Nicaraguan border (pl. 47A), south as far as the Río Sixaola on the Panamanian border. The species has been captured at altitudes as high as 700 meters, and as low as sea level. Tithraustes lambertae is known from Barra del Colorado and Cerro Tortuguero (P. N. Tortuguero), on the Caribbean coast in northeastern Costa Rica. A considerable amount of T. lambertae material has been collected in and around the La Selva Field Station, near Puerto Viejo (see fig. 4).

The type locality for Tithraustes lambertae is the Rincón Rainforest portion of the Area de Conservación Guanacaste, a locale approximately 4 km S of Birmania, a town SE of Santa Cecilia near the Nicaraguan border.

Biology

Larvae of T. lambertae have been reared by Janzen and Hallwachs (2008) on six species of palm (table 4). This is the broadest host-plant range yet known for Tithraustes. The immature stages (pl. 39A, B, E) show color patterns characteristic of the genus. As is typical of Tithraustes, the moths fly in the dark understory of moist rainforests, where their palm hosts occur (pl. 48B–D).

Discussion

The taxonomy of Central American Tithraustes is extremely difficult. For most species, the only reliable means of identification is through study of genital morphology, but even then ambiguities abound. Nevertheless, it can definitively be said that T. lambertae is distinct from all other previously described Central American Tithraustes. A careful, specimen-by-specimen revision of Tithraustes, which would ideally include numerous dissections as well as DNA analyses, seems the only solution for refining species boundaries. Such research will undoubtedly reveal numerous undescribed taxa, currently misidentified in collections. In the meantime, to the Costa Rican species related to T. moerens, I apply the name Tithraustes lambertae.

Based on genital similarities, T. lambertae is the sister species to T. moerens, the latter known exclusively from Colombia and Ecuador. The wings of these two are similar in color and pattern (pl. 24). Their genitalia differ most obviously in the configurations of male Tg8 and the female PVP (figs. 269, 271).

Dissections (JSM-697, 698) demonstrate the existence of an undescribed species, closely related to T. moerens and T. lambertae, collected at Nusagandí, a site in San Blas, Panama, located on the Caribbean slope. Cal Snyder and Annette Aiello reared that taxon (June 1993) on the palm genus Calyptrogyne. Although the wing pattern of this Panamanian species is indistinguishable from T. lambertae, comparison of genitalia reveals significant structural differences. For example, differences can be seen in the shape of male Tg8 and St8, the configuration of the male valva apices, and in the shape of the female postvaginal plate. I leave description of that Panamanian taxon for future work.

Holotype

Male (pl. 24). Costa Rica: Alajuela: Area de Conservación Guanacaste, Rincón Rainforest, Quebrada Guarumo, 10.90445°N, 85.28412°W, 400 m, 31 Jul 2002, leg. Freyci Vargas, ACG voucher no. 02-SRNP-7844 ( http://janzen.sas.upenn.edu). The type is deposited at INBio, Heredia, Costa Rica.

Paratypes

Costa Rica: Alajuela: 1♂, Area de Conservación Guanacaste, Rincón Rainforest, Quebrada Guarumo, 10.90445°N, 85.28412°W, 400 m, 31 Jul 2002, leg. Freyci Vargas, ACG voucher no. 02-SRNP-7845 (INBio); 1♂, Rincón Rainforest, Sendero Bejuco, 10.9061°N, 85.28281°W, 400 m, 17 Aug 2002, leg. Freyci Vargas, ACG voucher no. 02-SRNP-7918 (AMNH; genitalia slide no. JSM-1314); 1♀, Rincón Rainforest, Sendero Penya, 10.89928, -85.27486, 420 m, 29 Aug 2002, leg. Freyci Vargas, ACG voucher no. 02-SRNP-7915 (AMNH; genitalia slide no. JSM-1315); 2♂♂, 1♀, Rincón Rainforest, Sendero Bejuco, 10.9061°N, 85.28281°W, 400 m, 30 Jul 2002, leg. José Perez, ACG voucher Nos. 02-SRNP-7833, 7834, 7835 (INBio).

Other Specimens Examined

Costa Rica: Guanacaste: 1♂, 1♀, P. N. Guanacaste, Est. Pitilla, 9 km S Sta. Cecilia, 700 m, L N 330200_380200, Jan 1994, leg. C. Moraga, #2563 (INBio; male genitalia slide no. JSM-1783, wing slide no. JSM-1784); 1♂, P. N. Guanacaste, Est. Pitilla, 9 km S Sta. Cecilia, 700 m, L N 330200_380200, 27 Jan 2007, leg. J.F. Corrales (AMNH); 1♂, 1♀, 8 km S Santa Cecila, Pitilla mtn., 10°58.895′N, 85°25.55′W, 18 Jun 2005, leg. A. Sourakov (FNHM). Heredia: 2♂♂, vicinity of Selva Verde property, Sarapiquí, Chilamate, 200 ft, 4 Aug 1991, leg. G.E. Martinez (AMNH; genitalia slide no. JSM-517); 3♀♀, Finca La Selva, nr. Puerto Viejo, 500 ft, 4–26 Jun 1975, leg. D.R. Perry, ex Malaise trap 1.1 m off ground in Tree #1, Coumarouna oleifera (LACM); Est. Magsasay, P. N. Braulio Carrillo, 200 m, L_N_264600, 531100, 1♂, Jun 1990, leg. D. Acevedo (INBio), 1♂, Dec 1990, leg. A. Fernandez (INBio), 1♂, Jan 1991, leg. M. Barrelier (INBio); 1♂, La Selva, Apr 1989, leg. P. DeVries (AMNH). Limón: 5♂♂, 6♀♀, Hacienda Tapezco, 29 air km W Tortuguero, 40 m, 10°30′N, 83°47′W, 14 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller and C. Lewis, LACM/Earthwatch Trees of Tapezco Expedition (LACM; male genitalia slide no. JSM-523, female genitalia slide no. JSM-514); 4♂♂, 2♀♀, Hdas. La Suerte/Tapezco, 29 air km W Tortuguero, 40 m, 10°30′N, 83°47′W, 13–31 Aug 1979, leg. J.P. Donahue, C.C. Hair, N.K. Moore & M.A. Hopkins, LACM/Earthwatch Tapezco's Rainforest Expedition (LACM); 1♂, 1♀, Sardinas, Barra del Colorado, 15 m, 6–12 Nov 1994, leg. F.V. Araya, L N 291500_565900, #3293 (INBio); 1♂, Río Sardinas, R. N. F. S., Barra del Colorado, L_N_291500, 564700, 10 m, 24 June 1993, leg. J.F. Corrales (INBio); 1♀, Tortuga Lodge, N of Tortuguero, 20 ft, 10–11 Feb 1991, leg. Julian P. Donahue (LACM); 1♂, 1♀, Cerro Tortuguero, P. N. Tortuguero, 100 m, Apr 1989, leg. R. Aguilar & J. Solano, 285000, 588000 (INBio); 1♂, Guápiles, 850 ft, Collection Wm. Schaus (USNM); 1♂, Carrillo, Apr, Dognin Collection (USNM); 1♂, 1♀, Río Sixaola, Collection Wm. Schaus (USNM).

Dissected

6♂♂, 3♀♀.

Tithraustes moerens Warren

Figure 271; plate 24 [EX]

Tithraustes moerens Warren, 1900: 130.

Type Locality

Ecuador, Cachabí.

Type

Syntype ♂/♀, leg. Rosenberg, low country, 7 Jan 1897 (BMNH).

Tithraustes condensata Warren, 1900: 130.

Type Locality

Ecuador, Paramba.

Type

Syntype ♂, leg. Rosenberg, dry season, May 1897 (BMNH).

Discussion

Tithraustes moerens is relatively common, flying in the forest understory along forest trails and streambeds in the Andean foothills of western Ecuador. Its northern limit reaches southern Colombia, and I have collected it as far south as Cañar Province, Ecuador. However, its range undoubtedly extends further south, at least to Azuay. The species probably does not occur in Peru. In accordance with findings for Central American Tithraustes species (table 4), larvae of T. moerens were discovered feeding on an unidentified understory palm near La Troncal (J.S. Miller and E. Tapia, March 2006).

Although Tithraustes moerens resembles T. haemon in size and wing pattern (pl. 24), the two belong in different species groups. Genital morphology suggests that T. moerens (fig. 271) belongs in the Moerens Group, along with T. lambertae from Costa Rica (fig. 269), and T. quinquepunctata from Panama. Within this subclade, genitalia provide conclusive differences for separation.

Warren (1900: 130) named condensata as an aberration of moerens in which the wings are “much more suffused with smoky, all the white blotches being reduced in size”. The two have been considered synonyms by all previous authors (Bryk, 1930). The male genitalia of the condensata (JSM-829) and moerens (JSM-828) types are identical, thus providing confirmation for this synonymy.

Distribution

Ecuador (AMNH, BMNH, USNM); Colombia (BMNH, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-828); ♂ type of condensata Warren, BMNH (genitalia slide no. JSM-829); ♂, Ecuador, Pichincha, Las Palmeras, 18 km NE Alluriquín, old Quito-Santo Domingo Road, 4700 ft, 23 Oct 1988, leg. J.S. Miller, day coll., AMNH (genitalia slide no. JSM-518); ♂, Ecuador, Chimbo, 1 Sept 1892, leg. M. de Mathan, BMNH (genitalia slide no. JSM-516); ♂, Ecuador, Cachabí, low c., Jan 1897, leg. Rosenberg, BMNH (genitalia slide no. JSM-519); ♀, Ecuador, Paramba, Jan–May 1897, BMNH (genitalia slide no. JSM-520); ♀, Ecuador, Pichincha, Tinalandia, 700 m, 19 May 1993, leg. J.S. Miller, L.D. Otero, E. Tapia, day coll., AMNH (genitalia slide no. JSM-751).

Tithraustes quinquepunctata Warren

Plate 24

Tithraustes quinquepunctata Warren, 1901: 444.

Type Locality

Panama, Chiriquí.

Type

Holotype ♂ (BMNH).

Discussion

Tithraustes quinquepunctata is known exclusively from the male holotype (pl. 24). The contrasting white and chocolate-brown wing pattern of this species is distinctive among Tithraustes, most of which show drabber wings (pl. 24). The occurrence of five white FW spots, to which the species name alludes—more accurately characterized as four white spots and a basal dash—occurs nowhere else in the genus. Tithraustes quinquepunctata is also the largest member of the genus (FW length  =  20.0 mm). The genitalia of the type, particularly the digitate uncus and the shape of the valva, demonstrate membership in the Moerens Group.

Distribution

Panama (BMNH).

Dissected

Holotype ♂ (genitalia slide no. JSM-827).

2. HAEMON GROUP

The Haemon Group comprises seven species, all from Central America. Distinguishing these by their wing patterns can be difficult, since differences are often subtle. However, the taxa can reliably be identified based on male and female genital structure.

KEY TO HAEMON GROUP SPECIES

Plate 24

1. Eye large and bulging outward, gena narrow or absent3

Eye small, not bulging outward, gena wide2

2. Basal third of FW white, with base of radius and a small streak along anal margin blackish brown; FW with two small, white subapical spots; uncus relatively long and narrow, curving strongly downwardalbinigra Warren

Basal third of FW semihyaline, sparsely covered with dark brown scales; FW with three small, semihyaline subapical spots; uncus short and wide, curving gently downward (fig. 275A)snyderi, sp. nov.

3. Wing ground color dark brown to blackish brown; FW and HW equal in tone; FW length small (11.0–16.0 mm)4

Wing ground color chocolate brown to gray-brown; brown areas of FW lighter in tone than in HW; FW length variable (13.0–23.0 mm)5

4. Hind wing DC sparsely covered with pedicellate brown scales, an ovoid white fascia beyond DC; FW with a small white spot on M2, without a spot on M1; posterior margin of male Tg8 with a U-shaped mesal excavation, posterolateral angles of Tg8 truncate, scoop shaped; posterior margin of female St7 with a wide, U-shaped mesal excavation (Panama N to El Salvador)noctiluces (Butler)

Hind wing DC completely white, almost hyaline, confluent with white fascia beyond DC; FW with small white spots on M1 and M2; posterior margin of male Tg8 gently concave, posterolateral angles acute; posterior margin of female St7 slightly concave (Panama)seminigrata Warren

5. Hind wing white from base, outer margin with a dark brown band; HW marginal band widest near apex, narrowest between fork of M3 and CuA1; FW light brown to chocolate brown; posterior margin of male Tg8 with a wide, U-shaped mesal excavation (figs. 272D, 273D); DB of female narrow (figs. 272E, 273F), membranous6

Basal half of HW semihyaline, sparsely covered with gray-brown scales, HW with an ovoid white fascia beyond DC; FW gray to light gray-brown; posterior margin of male Tg8 convex, bearing a rugose, hoof-shaped mesal sclerite (fig. 274B); DB of female wide (fig. 274E), sclerotizedhaemon Druce

6. Forewing fascia completely white, somewhat quadrate; male Tg8 with a lobelike process at each posterolateral angle (fig. 272D); valva somewhat acute distally, bearing a small process below apex (fig. 272A); female PVP with a deep lateral excavation on each side (fig. 272E); FW length  =  16.5–18.0 mmdeiphon Druce

FW fascia with veins M1 and M2 lined with brown scales as they pass through, fascia ovoid; male Tg8 scalloped at each posterolateral angle (fig. 273D); valva broadly lobate at apex (fig. 273A), without a process below apex; female PVP without deep lateral excavations (fig. 273F); FW length  =  12.0–15.0 mmesernius (Druce)

SPECIES INCLUDED AND MATERIAL EXAMINED

Tithraustes albinigra Warren

Plate 24

Tithraustes albinigra Warren, 1905: 316.

Type Locality

Panama, Chiriquí.

Type

Holotype ♂ (BMNH).

Discussion

Tithraustes albinigra is uncommon. I have been able to locate approximately a dozen specimens: two at the BMNH (including the holotype); three at the USNM; two from the SMNS; and six examples at INBio. Of this material, the only female I have seen is at INBio. The arrangement of four white spots against a dark brown ground color in the FW distal two-thirds, combined with presence of a white FW basal third and a large white HW central area, makes T. albinigra distinctive. Tithraustes albinigra (FW length  =  12.5–13.5 mm) is also one of the smallest members of the genus, along with T. esernius and T. snyderi. It shares with T. snyderi the presence of small eyes; in other Tithraustes the eyes are large and bulging (fig. 268A–C, E).

It appears that T. albinigra is endemic to cloud forest habitats in northern Panama and southern Costa Rica at sites along the Pacific slopes of the Cordillera de Talamanca. A specimen with identical wing pattern, but collected at Braulio Carrillo on the Caribbean side, here tentatively identified as T. albinigra (pl. 24), shows male genitalia indicating an undescribed cryptic species.

Distribution

Panama (BMNH); Costa Rica (BMNH, INBio, USNM, SMNS).

Dissected

Holotype ♂ (genitalia slide no. JSM-831); ♂, Costa Rica, San José, Llano Bonito, Chirripo, N 09°27′16″, W 83°32′4″, 2500 m, 24 Jun 2006, leg. Kenji Nishida, day flyer, INBio (genitalia slide no. JSM-1790); ♂, Costa Rica, Heredia, vicinity of NP Braulio Carrillo, rainforest E Finca Gurdian, N 10°12.5′, W 84°07.0′, 1690 m, 29 May 2003, leg. Gunnar Brehm, blacklight 30W, 18.30–19.30 h, FG b (8), SMNS (genitalia slide no. JSM-1630).

Tithraustes deiphon Druce

Figures 268D, 272; plate 24

Tithraustes deiphon Druce, 1885a: 159, pl. 14, fig. 25.

Type Locality

Panama, Volcán de Chiriquí, 3000–4000 ft.

Type

Syntype ♂, leg. Champion (BMNH).

Discussion

In most collections, specimens identified as Tithraustes deiphon, particularly from Costa Rica, represent a complex of cryptic species. For example, dissections for AMNH Costa Rican material that I had initially identified as deiphon instead revealed three species—deiphon itself as well as two undescribed taxa, one from Guanacaste (JSM-777) and the other from Alajuela and Cartago Provinces (JSM-778, 779). As has been discovered throughout these studies, material from southwestern Costa Rica (e.g., Las Alturas Field Station) is conspecific with examples from the important historical collections of Champion (BMNH), captured in Chiriquí, Panama. I reiterate that it is impossible to identify Tithraustes specimens with a deiphon-like wing pattern (pl. 24) without comparing genital morphology across a range of examples.

Distribution

Panama (AMNH, BMNH, CAS, NMW, USNM, ZMH); Costa Rica (AMNH, BMNH, INBio, LACM, VOB).

Dissected

Syntype ♂ (genitalia slide no. JSM-826); ♂, Panama, El Volcán, Chiriquí, R.P., 25 Feb 1936, leg. F.E. Lutz, AMNH (genitalia slide no. JSM-1631); ♂, Costa Rica, Puntarenas, Las Alturas Field Station, 35 km NE San Vito, 4700 ft, 19 Mar 1991, leg. J.S. Miller, day-coll., AMNH (genitalia slide no. JSM-776); ♀, Panama, Chiriquí, May 1907, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1054).

Tithraustes esernius (Druce)

Figure 273; plate 24

Polypoetes esernius Druce, 1885a: 160.

Type Locality

Costa Rica, Irazu, 6000–7000 ft.

Type

Syntype ♂, leg. H. Rogers (BMNH).

Discussion

Tithraustes esernius is a small species, similar in size to T. albinigra and T. snyderi (pl. 24). It can be distinguished from both by the presence of a single white subapical FW spot, rather than two. In T. esernius, this lone spot straddles M2, whereas in the other two species there is a spot on M2 and a second, more anterior one, touching M1 and the base of Rs2–Rs4. Another useful difference involves eye size; the eyes of T. esernius are large and bulging, whereas in T. albinigra and T. snyderi the eyes are relatively small.

However, identifying T. esernius is complicated by the existence of at least one undescribed species. This taxon cannot be separated from T. esernius by wing pattern, but its male genitalia possess a radically different configuration of the valva apex. The undescribed species, well represented in the INBio collection, appears to be much more widespread than T. esernius itself. The latter appears to be restricted to the southern part of Costa Rica. The undescribed taxon, on the other hand, co-occurs with T. esernius at Turrialba (JSM-777), but has also been recorded from Alajuela (JSM-778) and Guanacaste Provinces (JSM-779).

Distribution

Costa Rica (AMNH, BMNH, INBio, SMNS, USNM).

Dissected

Syntype ♂ (genitalia slide no. JSM-832); ♂, Costa Rica, Irazu, 6–7000 ft, leg. H. Rogers, BMNH (genitalia slide no. JSM-538); ♂, Costa Rica, Volcán Turrialba, 6000 ft, 28 Jun 1908, Collection Wm. Schaus, USNM (JSM-1774); ♀, Costa Rica, Río Sucio, leg. H. Rogers, Godman-Salvin Coll., BMNH (genitalia slide no. JSM-539).

Tithraustes haemon Druce

Figure 274; plate 24 [EX]

Tithraustes haemon Druce, 1885a: 158, pl. 14, fig. 20.

Type Locality

Panama, Bugaba, 800–1500 ft.

Type

Syntype ♂, leg. Champion (BMNH).

Discussion

Tithraustes haemon is the type species for the genus. Dissections show that specimens from southwestern Costa Rica (La Amistad, Las Alturas, and the Osa Peninsula) are conspecific with the Panamanian type. However, the geographical range of T. haemon is currently confused by the presence of T. lambertae, a newly described Costa Rican species belonging in the Moerens Group. Although the genital morphology of these taxa differs dramatically (compare figs. 269, 274), their wing patterns are indistinguishable and they are invariably confused in collections. Tithraustes haemon is apparently restricted to the Pacific slope of the Cordillera de Talamanca, ranging from southern Costa Rica south into Panama. Confirmed examples of Tithraustes lambertae are known exclusively from the Caribbean slope of Costa Rica (fig. 270), from Río Sixaola north to Volcán Orosí, near the Nicaraguan border.

Distribution

Panama (BMNH, NMW, USNM, ZMH); Costa Rica (AMNH, BMNH, CAS, INBio, LACM, UCB, USNM, SMNS).

Dissected

Syntype ♂ (genitalia slide no. JSM-830); ♂, Costa Rica, Puntarenas, Osa Peninsula, 1.8 mi. W Rincon, 21 Mar 1971, leg. Charles L. Hogue, LACM (genitalia slide no. JSM-515); ♂, Costa Rica, Puntarenas, Parque Inter. La Amistad, Sector Pacifico, Cerro Biolley, 572100N, 332100S, 1600–1700 m, 7 Aug 2004, reared ex Geonoma edulis, RDR-00170, leg. Roberto Delgado, INBio (genitalia slide no. JSM-1779); ♂, Costa Rica, Puntarenas, 35 km NE San Vito, nr. Las Alturas Field Station, 1540 m, 14 Jul 1992, leg. A. Sourakov, at light, AMNH (genitalia slide no. JSM-521); ♀, Costa Rica, Puntarenas, 35 km NE San Vito, nr. Las Alturas Field Station, 1540 m, 14 Jul 1992, leg. A. Sourakov, at light, AMNH (genitalia slide no. JSM-522).

Tithraustes noctiluces (Butler)

Plate 24

Dioptis noctiluces Butler, 1872: 88.

Type Locality

“Costa Rica”.

Type

Syntype ♀, ex E.W. Janson Collection (BMNH).

Dioptis salvini C. and R. Felder, 1874: pl. 105, fig. 5.

Type Locality

“Panama”.

Type Locality

Holotype ♂ (BMNH).

Discussion

Tithraustes noctiluces is the smallest species in the genus (♂ FW length  =  10.5–13.0 mm) and one of the most common in museum collections. The female holotype of noctiluces is in extremely poor condition; its wings are almost devoid of scales and the abdomen is missing. Therefore, its genitalia cannot be compared with other material. After searching through the BMNH collections, I discovered Felder's type of salvini. That specimen, a male, is also badly rubbed and was dissected over 60 years ago by Baron de Worms (his genitalia dissection no. 436/50). The de Worms dissection, originally in alcohol, is dehydrated and I made no attempt to reconstitute it. However, careful study of superficial characters in these types suggests that salvini and noctiluces are synonyms, the position taken by all previous workers on the Dioptinae.

As Nässig and Speidel (2007) eloquently documented, there has been historical debate over the correct date of publication for taxonomic names described in the Reise der österreichischen Freggate Novara. This is revealed in the salvini/noctiluces controversy. The date in the bottom left corner of the plate figuring salvini (C. and R. Felder, 1874) says “Mai, 1868”. If that is used, then salvini is the senior name over noctiluces (Butler, 1872). Both Prout (1918) and Hering (1925) considered salvini to take precedence. Bryk (1930), on the other hand, applied 1874 as the date of publication, and thus recognized noctiluces as the correct name. The analysis of Nässig and Speidel (2007), followed throughout the current work, firmly established 1874 as the appropriate date to use in this case, so Bryk's listing holds.

Tithraustes noctiluces is extremely similar to T. seminigrata (pl. 24). Both are small moths and their wing patterns are almost identical. However, their genitalia differ (see Discussion below for T. seminigrata).

Tithraustes noctiluces has been reared on palms in four different genera, but it is unique in being the first Tithraustes species known to utilize a host plant outside the Arecaceae (table 4); caterpillars were discovered at Estación Pitilla (pl. 48) feeding on Heliconia latispatha in the Heliconiaceae. The species is at least consistent in retaining an affinity for monocots.

Distribution

Panama (AMNH, BMNH, OUMNH, USNM); Cost Rica (AMNH, BMNH, FNHM, INBio, LACM, MPM, NMW, UCB, USNM, VOB); El Salvador (USNM).

Dissected

♂, Panama, Chiriquí, May 1907, W. Schaus Collection, USNM (genitalia slide no. JSM-1079); ♂, Costa Rica, Heredia, Sarapiquí, Chilamate, 6 km E Selva Verde Lodge, 200 ft, 5 Aug 1991, leg. G.E. Martínez, AMNH (genitalia slide no. JSM-700); ♂, Costa Rica, Juan Viñas, 18 Mar 1902, leg. M. Cary, Holland Collection, CMNH (genitalia slide no. JSM-762); ♂, Costa Rica, Carrillo, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1077); ♂, Costa Rica, Limón, Hacienda Tapezco, 29 air km W Tortuguero, N 10°30′, W 83°47′, 40 m, 13 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller & C. Lewis, LACM/Earthwatch Trees of Tapezco Expedition, LACM (genitalia slide no. JSM-512); ♀, Costa Rica, Limón, Hacienda Tapezco, 29 air km W Tortuguero, N 10°30′, W 83°47′, 40 m, 13 Mar 1978, leg. J.P. Donahue, D. Panny, D. Moeller & C. Lewis, LACM/Earthwatch Trees of Tapezco Expedition, LACM (genitalia slide no. JSM-513); ♀, Costa Rica, San José, 16 km N San Isidro del General, N 09°25′, W 83°43′, 1700 m, 12 Jan 1984, leg. J. Rawlins & S. Thompson, CMNH (genitalia slide no. JSM-763); ♀, Costa Rica, Carrillo, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1078).

Tithraustes seminigrata Warren

Figure 263A; plate 24

Tithraustes seminigrata Warren, 1901: 444.

Type Locality

Panama, Chiriquí.

Type

Holotype ♀ (BMNH).

Discussion

Tithraustes seminigrata is extremely similar to T. noctiluces; the maculations on the wings are almost identical (pl. 24). However, after dissecting the female holotype of T. seminigrata and comparing that with dissections of Costa Rican material identified as T. noctiluces, I confirm that the two are distinct species; the PVP is larger in T. noctiluces. Males of the two differ in the shape of Tg8 and in the shape of the valva apex. In addition, study of large series for both taxa shows that, although there is size overlap, T. seminigrata is generally larger. Tithraustes noctiluces is broadly distributed from Panama north to El Salvador, but as far as I am aware, T. seminigrata occurs exclusively in Panama.

Tithraustes seminigrata was reared on an unidentified species of palm in the genus Calyptrogyne (table 4). Preserved immature stages were deposited in the AMNH and STRI collections.

Distribution

Panama (AMNH, BMNH, CUIC, FNHM, NMW, USNM).

Dissected

Holotype ♀ (genitalia slide no. JSM-825); ♂, Panama, Chiriquí, Fortuna, 1150 m, 17 Jun 1982, leg. G.B. Small, USNM (genitalia slide no. JSM-699); ♂, Panama, Chiriquí, La Fortuna, 08°43′10″N, 82°16′02″W, 1100 m, 14 Jun 1994, leg. C. Snyder, ex egg on Calyptrogyne, reared Aiello Lot 94-46 #5, AMNH (genitalia slide no. JSM-757); ♀, Panama, Chiriquí, La Fortuna, 08°43′10″N, 82°16′02″W, 1100 m, 14 Jun 1994, leg. C. Snyder, ex egg on Calyptrogyne, reared Aiello Lot 94-46 #4, AMNH (genitalia slide no. JSM-758).

Tithraustes snyderi, new species

Figures 270, 275; plate 24

Diagnosis

Tithraustes snyderi resembles T. esernius and T. albinigra in its small size (pl. 24). The wing patterns of these three show similarities as well, although T. albinigra stands apart in having the FW basal third white, rather than being semihyaline. The greatest potential for confusion lies in separating T. snyderi and T. esernius. Features for distinguishing these include: the presence of relatively small eyes in T. snyderi as opposed to large, bulging eyes in T. esernius; three small semihyaline spots near the FW apex in T. snyderi compared to either one or two tiny white spots in T. esernius; Lp3 of male labial palpus slightly elongate (T. snyderi) vs. Lp3 greatly elongate (T. esernius). Male genitalia provide obvious features for separating all three taxa.

Description

Male. Forewing length  =  12.5–13.0 mm. Head: Labial palpus long and thin, curving strongly upward, apex reaching to above middle of front; Lp1 moderately long, gently curved, Lp2 long and thin, widest at base, then gradually tapering toward apex, Lp3 moderately long, roughly bullet-shaped; Lp1 white with a loose fringe of long scales ventrally, dorsum light gray; Lp2 gray-brown with a loose fringe of white scales ventrally; Lp3 completely gray-brown; frontal scales long, pointing dorsomedially, forming a triangular tuft between antennal bases; front gray-brown, margin above clypeus and lateral margins thinly bordered with white; occiput gray-brown with a white posterior band, this widest below palpus, terminating near antennal base; eye small, not bulging outward, surrounded by a scaleless band, gena broadly scaleless; vertex covered with long, anteriorly directed, glossy gray-brown scales, a patch of immaculate white scales immediately behind each antennal base; antenna bipectinate, rami long and thin; scape gray-brown, slightly lighter brown on ventral surface; dorsum of antennal shaft covered with appressed, glossy gray-brown scales.

Thorax: Legs white on inner surfaces, gray-brown on outer ones; pleuron covered with long white scales; patagia covered with erect, glossy gray-brown scales; tegula covered with semierect, yellow to yellow-orange scales, distal portion fringed with long, hairlike, dark brown scales; dorsum gray-brown with a diffuse, white midsagittal line; tympanum small and shallow; tympanal membrane extremely small, ovoid, facing lateroventrally, a small scaleless area in metepimeron below membrane.

Forewing: (Dorsal) Ground color chocolate brown to dark brown (pl. 24); basal third semihyaline with veins dark brown as they pass through; a fairly large, roughly quadrate, semihyaline fascia located immediately beyond DC, extending from base of Rs1 to fork of M3+CuA1, scales within fascia dark brown, elongate; subapical area exhibiting three semihyaline spots, anterior one extremely small, located at base of Rs2+Rs3 and Rs4, this conjoined with second spot straddling M1, third spot ovoid, straddling M2, veins in each spot dark brown as they pass through; a fourth small, semihyaline, ovoid, submarginal spot straddling CuA2; wing veins slightly darker than ground color. (Ventral) Similar to dorsal surface, except fascia, subapical, and submarginal spots sparsely covered with white scales rather than dark brown ones.

Hind wing: (Dorsal) An oblique white central area extending from anterior margin to well beyond fork of M3+CuA1 (pl. 24), cubitus and fork of M3+CuA1 sometimes sparsely lined with charcoal-gray scales; outer margin with a dark, charcoal-gray band, this band much wider at apex; anal margin broadly covered with a mixture of light gray and dark charcoal-gray scales. (Ventral) Similar to dorsal surface, except cubitus and M3+CuA1 not lined with dark scales, anal margin whiter.

Abdomen: Dorsum evenly covered with glossy, dark charcoal-gray scales; venter immaculate white.

Terminalia (fig. 275A–D): Tg8 greatly elongate, narrow, widest anteriorly, with a pair of longitudinal struts along lateral margins; anterior margin bearing a pair of short, rounded apodemes; lateral margins broadly excavated, each with an abrupt notch at anterior third, then gradually widening distally; posterior margin bearing a deep, U-shaped mesal excavation, its posterolateral angles forming a pair of small processes; St8 shorter and much wider than Tg8, anterior margin simple, lateral margins convex, expanded outward, posterior margin simple, slightly concave; socii/uncus complex small, thinly joined to dorsum of ring, hinged downward; uncus bifid, short and slightly downturned; socii thumblike, short and upturned; tegumen moderately wide, concave, much taller than vinculum, forming a broad, elbowlike anteroventral expansion at junction with vinculum; vinculum short, extremely thin; saccus small, broadly U-shaped below; juxta forming a tall, cup-shaped structure between valva bases; valva lightly sclerotized, moderately wide, margins roughly parallel, inner surface setose, coarsely rugose; BO extremely small, comprising four to six short, coarse pleats along ventral margin; valva abruptly indented near apex; apex sclerotized, aurate, set off from rest of valva, bearing a few long distal setae; costa thin, slightly wider near apex; transtillar arms wide at base then strongly tapered, meeting to form a small, anteriorly directed sclerite above aedeagus; aedeagus moderately long and wide, dorsoventrally compressed, widest at base, with a small ventral process at apex; vesica small and round, much shorter than aedeagus, opening dorsally, bearing a small dorsal comb of fine, spinelike cornuti.

Female. Forewing length  =  15.0 mm. Head, thorax, and wings similar to male, except: labial palpus shorter; wings longer, outer margin more convex (pl. 24); ground color lighter brown and markings more diffuse; antenna ciliate, each annulation bearing two pairs of stout lateral bristles.

Abdomen: Dorsum glossy gray-brown; venter white; segments A7 and A8 much wider than rest of abdomen, Tg7 and Tg8 bearing a corethrogyne composed of erect, elongate, light gray-brown to dark gray-brown deciduous scales.

Terminalia (fig. 275E, F): Tg7 large and wide, membranous, bearing a corethrogyne; St7 short, extremely wide, anterior margin irregular, posterior margin broadly excavated; Tg8 membranous, bearing scales of corethrogyne; AA large, recurved upward, wide at base, narrowed at midpoint, then expanded at apices; PVP extremely large and robust, broadly convex, with a wide, deep, U-shaped mesal excavation below PA, dorsolateral angles rounded; ostium small, opening at base of PVP; DB membranous, extremely short; DS arising from DB near ostium; CB relatively small, elongate, membranous, narrow at base, then gradually wider anteriorly; a tiny, obsolete, transverse signum located dorsally on CB distally; PA moderate in size, slightly wider dorsally; PP large and robust, widest at base then elbowed upward, distal third bent slightly downward, apices wider, truncate.

Etymology

This species name recognizes Cal Snyder, formerly of the AMNH, whose fieldwork in French Guiana, Costa Rica, Panama, Ecuador, and Peru has resulted in numerous important findings for the Dioptinae. Cal was the first to discover the life history of Tithraustes. He subsequently found the immature stages of five additional understory palm-feeders (table 4) at locations throughout Costa Rica and Panama. He also uncovered the life history of Ephialtias draconis, a josiine unusual in being associated with Turnera rather than Passiflora (table 6). Cal's efforts have greatly advanced the research described throughout this paper.

Distribution

Tithraustes snyderi lives in cloud-forest habitat within La Amistad, a huge international park extending from southcentral Costa Rica into Chiriquí Province, Panama. Although specimens of T. snyderi have so far been collected only in Costa Rica, the species undoubtedly occurs in Panama as well. The moth is known exclusively from the Pacific slopes of the Cordillera de Talamanca (fig. 270), at elevations between 1600 and 2000 meters.

Biology

This is the first Tithraustes species for which the life history became known, establishing understory palms as important host plants for the Dioptinae. In June 1992, Cal Snyder found caterpillars of T. snyderi feeding on Chamaedorea costaricana during his field studies at Las Alturas Field Station (Costa Rica). Tithraustes snyderi was subsequently reared on two additional palm species—one in Chamaedorea and one in Geonoma (table 4).

Discussion

Although T. snyderi most closely resembles T. esernius, its genitalia contradict wing-pattern similarities, instead indicating a sister-species relationship with T. albinigra (pl. 24). In T. snyderi and T. albinigra males, Tg8 and the valva apex show the same configuration. However, these three species are quite rare—T. snyderi itself is known from only four specimens—and all deserve further taxonomic study. In particular, more recently reared material of T. snyderi (INBio 2004, 2006) shows male genital morphology slightly different from the AMNH holotype. For example, the posterior margin of male Tg8 differs in the two, and the valva is a somewhat different shape. Their wing patterns are indistinguishable, except that the INBio material is generally darker in color. In lieu of these subtle differences, I have incorporated the INBio specimens into the description for snyderi, but refrain from including them as paratypes. They were captured in close proximity to the T. snyderi type locality.

Holotype

Male. Costa Rica: Puntarenas: 35 km NE San Vito, Las Alturas Field Station, 1750 m, 6 Jun 1992, leg. C. Snyder, pupal lot 27B (genitalia slide no. JSM-1632). The type is deposited at the AMNH.

Paratypes

None.

Other Specimens Examined

Costa Rica: Puntarenas: 1♀, Parque Inter. La Amistad, Sector Pacifico, Casa Coca, 574500N, 335000S, 1900–2000 m, 1 Aug 2004, reared ex Chamaedorea costaricana, RDR-00159, leg. Roberto Delgado (INBio); 1♂, Sendero al Cerro Biolley, 572100N, 332100S, 1600–1700 m, 8 Sep 2004, reared ex Geonoma edulis, RDR-00169, leg. Roberto Delgado (INBio); 1♂, Pacifico, Sendero al Cerro Biolley, 572100N, 332100S, 1600–1700 m, 15 Sep 2006, reared ex Chamaedorea crucensis, RDR-00446, leg. Roberto Delgado (INBio).

Dissected

2♂♂, 1♀.

The following species have been transferred from Tithraustes: albilinea Schaus to Euchlaenidia Hampson (Arctiidae: Pericopinae) albitumida Dognin to Nebulosa (Albitumida Group) aliena Dognin to Nebulosa (Nervosa Group) augustimacula Dognin to Polypoetes (Haruspex Group) bialbifera Warren to Nebulosa (Plataea Group) butes Druce to Dioptis (Butes Group) caliginosa Dognin to incertae sedis chloris Druce to Dioptis (Chloris Group) cistrina Druce to Nebulosa (Albitumida Group) cistrinoides Dognin to Nebulosa (Nervosa Group) cletor Druce to Nebulosa (Plataea Group) coniades Druce to Dolophrosyne creon Druce to Nebulosa (Nervosa Group) crypsispila Warren to Nebulosa (Halesius Group) demades Druce to Chrysoglossa erymas Druce to Nebulosa (Nervosa Group) eteocles Druce to Dioptis (Butes Group) fulvipalpis Dognin to Nebulosa (Fulvipalpis Group) halesius Warren to Nebulosa (Halesius Group) inaequiplaga Dognin to Nebulosa (Fulvipalpis Group) latialbata Prout to Nebulosa (Nervosa Group) longipennis Schaus to Dioptis (Butes Group) maxima Druce to Chrysoglossa mexicana Hering to Chrysoglossa mirma Druce to Nebulosa (Nervosa Group) nasor Druce to Nebulosa (Albitumida Group) nervosa Edwards to Nebulosa (Nervosa Group) nigrifascia Hering to Chrysoglossa phaethon Schaus to Chrysoglossa pyrifera Dognin to incertae sedis sirenia Hering to Nebulosa (Albitumida Group) subalbata Dognin to Dioptis (Chloris Group) submaxima Hering to Chrysoglossa suffumosa Dognin to Polypoetes (Haruspex Group) thanatos Hering to Nebulosa (Nervosa Group)

ISOSTYLA PROUT, 1918

Figures 276Figure 277Figure 278279; plates 24, 25

Figure 276

Morphology of Isostyla. A, head of I. ithomeina ♂, lateral view; B, head of I. ithomeina ♂, frontal view; C, head of I. ithomeina ♂, posterior view; D, I. zetila ♂ labial palpus; E, I. zetila ♂ tegula; F, head of I. ithomeina ♂, lateral view; G, I. zetila ♀ wings (illustration by J.S. Miller).

i0003-0090-321-1-1-f276.gif

Figure 277

Genitalia of Isostyla ithomeina (♂ JSM-640, ♀ JSM-641). A, ♂ genitalia; B, aedeagus; C, ♂ Tg8; D, ♂ St8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f277.gif

Figure 278

Genitalia of Isostyla. A, ♂ of I. purefacta (JSM-673); B, ♂ Tg8 of I. purefacta; C, aedeagus of I. purefacta; D, ♀ of I. purefacta (JSM-674); E, ♂ St8 of I. purefacta; F, ♀ of I. picata (JSM-1225).

i0003-0090-321-1-1-f278.gif

Figure 279

Genitalia of Isostyla zetila (♂ JSM-424, ♀ JSM-425). A, ♂ genitalia; B, aedeagus; C, ♂ St8; D, ♂ Tg8; E, ♀ genitalia (illustration by A. Trabka).

i0003-0090-321-1-1-f279.gif

Isostyla Prout, 1918: 415. Type species: Dioptis erycinoides C. and R. Felder, 1874 (by original designation).

Diagnosis

As in Tithraustes, its sister genus, Isostyla contains light-bodied moths with broad, delicate, semihyaline wings (pls. 24, 25). The FW and HW ground colors vary from iridescent blue-gray (e.g., I. picata) to almost entirely white (e.g., I. purefacta). All species exhibit a large, white or hyaline FW fascia beyond the DC. The eyes are invariably large and bulging (fig. 276A–C, F), and the labial palpi are long and thin, usually with an elongate Lp3. Males in Isostyla also share with Tithraustes the presence of elongate antennal pectinations. Females exhibit a corethrogyne on the abdominal apex, presence of which helps to support a clade comprising Stenoplastis, Tithraustes, and Isostyla (Clade 17; fig. 7).

The general appearance of Isostyla, including their habit of flying in the forest understory, makes them difficult to distinguish from Tithraustes in the field. One distinguishing feature, initially used by Prout (1918) to define Isostyla, is absolutely reliable: In all Isostyla species, FW veins Rs2–Rs4 branch in the pattern 2+[3+4] (fig. 276G), whereas Tithraustes shows the arrangement more typical for Dioptinae—[2+3]+4 (fig. 268G). This difference can be observed either with a hand lens, or under low magnification using a stereomicroscope.

Abundant genitalia characters distinguish the two genera, but these usually require dissection. One male trait can be seen without dissection: Tg8 in Isostyla bears elongate, sclerotized posterolateral processes, forming a prominent fork (figs. 277C, 278B, 279D). This structure can be observed by gently removing the scales on A8 with a fine paintbrush. In Tithraustes the posterior margin of Tg8 forms sclerotized processes of various types (e.g., figs. 269E, 271D), but never a fork.

Redescription

Male. FW length  =  11.5–17.0 mm. Head (fig. 276A–D, F): Labial palpus long, thin, curving strongly upward to middle of front or above, not reaching antennal base; Lp1 relatively long, almost straight; Lp2 long and thin, over one and a half times the length of Lp1, curving upward, a few longer scales along ventral surface near apex; Lp3 narrow, elongate, tightly scaled, tapered to an acute apex; scales of front short, closely spaced, pointing dorsomedially, arching toward midline between antennal bases, not forming a dorsal tuft; eye extremely large and rounded, curving down below ventral margin of head, gena absent; postgena narrow; antenna bipectinate, rami long and thin, each with a robust dorsal bristle approximately one-third from apex.

Thorax (fig. 276E): Epiphysis long, almost four-fifths length of tibia, extending slightly beyond tibia apex; tegula extremely short, wide, almost ovoid, much less than one-half length of mesoscutum, distal portion broad, ventral angle blunt, transverse sulcus absent; metathoracic tympanum moderate in size, cavity emarginate, usually shallow, rarely (I. ithomeina) deep; tympanal membrane moderately large, ovoid, facing posteroventrally.

Forewing (pls. 24, 25): Broad, outer margin convex, tornus rounded; vein Rs1 long stalked with radial sector; veins Rs2–Rs4 in the pattern 2+[3+4]; M1 arising from DC near anterolateral angle of DC, widely separate from radial sector, UDC well developed; stridulatory organ present, veins M1 and M2 arising close together from DC, their bases swollen, a short fold between bases of M1 and M2 on ventral surface; DC slightly more than one-half FW length; veins M3 and CuA1 long stalked; ground color dark slate gray to gray-brown, usually with an iridescent blue luster; a large white or hyaline fascia present beyond DC; almost always additional small white spots near tornus and apex.

Hind wing (pls. 24, 25): Broadly rounded; M3 and CuA1 long stalked; central area semihyaline, either dark (e.g., I. zetila) or white (e.g., I. purefacta), veins usually lined with dark scales; hyaline central area often with small patches of white scales between veins near outer margin; a narrow, dark brown to blackish brown band along wing outer margin.

Abdomen: Elongate, narrow at base, wider distally.

Terminalia (figs. 277A–D, 278A–C, 278E, 279A–D): Tg8 relatively short, narrower than Tg7, anterior margin simple, lateral margins slightly tapered posteriorly; posterior margin of Tg8 with a wide, deep, horseshoe-shaped mesal excavation, its edge heavily sclerotized, posterolateral angles of excavation extended to form a pair of long, narrow horns, their apices curving laterally; St8 short, wide, anterior margin gently convex, posterior margin with a V- or W-shaped mesal excavation; socii/uncus complex with a wide, transverse attachment to tegumen, base of complex quadrate; uncus apparently absent; socii elongate, curving slightly downward distally, apices acute; tegumen wide, concave, much taller than vinculum; vinculum short, narrow, joined to tegumen to form large, elbowlike structures along anterior margin of ring; saccus apparently absent; juxta forming an elongate cup shaped structure; valva relatively long, wide, almost completely sclerotized; BO absent; apex of valva heavily sclerotized, scoop shaped, otherwise variable in shape; arms of transtilla extremely thin, straplike, oriented horizontally, meeting at midline to form a wide diffuse sclerite; aedeagus short and wide, cylindrical, wider at base; apex of aedeagus simple; vesica small, opening dorsally, cornuti absent.

Female (fig. 276G; pls. 24, 25). FW length  =  15.0–19.5 mm. Head: Labial palpus shorter than male, Lp3 not as elongate; antenna without pectinations, each annulation with 4 robust bristles arising near base.

Thorax: Similar to male.

Forewing: Longer and broader than male, ground color lighter, markings larger and more diffuse, wings less densely scaled.

Hind wing: Longer and broader than male, ground color lighter, wings more hyaline than in males; frenulum comprising approximately 4–6 bristles.

Abdomen: Shorter than male; Tg7 and Tg8 membranous, greatly expanded, bearing a corethrogyne comprising an extremely large patch of densely packed, yellowish brown, deciduous scales.

Terminalia (fig. 277E, 278D, 278F, 279E): Tg7 large, membranous; St7 wide, sclerotized, lateral margins convex, anterior margin simple, posterior margin with a mesal excavation, lateral angles of excavation sometimes forming triangular, sclerotized processes; Tg8 membranous; AA delicate, straight, angled upward, often extremely small; PA large, triangular, with a sclerotized flange near upper margin; PP straight and thin; PVP apparently absent, this region membranous; DB long and thin, membranous; CB large and membranous, roughly ovoid, somewhat laterally compressed, narrowing at base; signum a small, lightly sclerotized oval, located on dorsal midline near base of CB, its internal surface finely spiculate; DS arising anteriorly on DB, near ostium.

Distribution

Isostyla is similar to Tithraustes in generally showing a Central American–Chocoan distribution. The genus has been collected as far north as Guatemala (I. zetila), and as far south as Loja, in southern Ecuador (I. purefacta). Isostyla species are restricted to lowland and midelevation forests, most commonly between sea level and 1000 meters. The highest recorded altitude is 1500 m for a specimen of I. purefacta (AMNH), from western Ecuador. One difference between Isostyla and Tithraustes is that the former is better represented in South America, with three of the five described species occurring there. In Tithraustes, only a single species (T. moerens) has been recorded from South America, while the remaining nine live in Central America.

Biology

Host plants and immature stages have been discovered for I. ithomeina and I. zetila (table 4). So far, they have been recorded on two palm genera—Asterogyne and Calyptrogyne (see pl. 48B, C). The host list of Tithraustes is broader (table 4). The larvae and pupae of Isostyla are extremely similar in appearance to those of Tithraustes.

Discussion

When Prout (1918) erected Isostyla, he proposed that its closest relatives were Monocreaga and Dioptis. Perhaps his judgment was based on the presence of hyaline wings in these genera. Instead, my cladograms suggest that Isostyla belongs in a close-knit clade with Tithraustes and Stenoplastis (figs. 3, 7).

At its inception, Isostyla contained only three species, but totaled eight names. Before Prout brought them together, most of these taxa had been described in Dioptis. Two came from Tithraustes. Similarly, Bryk (1930) listed three valid Isostyla species, and these encompassed 10 names. In my attempt to stabilize the situation, I recognize five valid species with 11 species group names. However, the taxonomy of Isostyla deserves further study.

Several factors make it difficult to provide an effective species key for Isostyla. First, some taxa, such as I. ithomeina, seem to be highly variable with respect to wing pattern. Second, I was unable to locate males of I. picata for study. The key below therefore does not employ male genital characters. Some species show sexual dimorphism for wing pattern, making it difficult to associate males and females. Isostyla zetila is the only taxon within the genus showing consistent and distinctive wing-pattern traits, rendering it relatively easy to identify.

The key provided below is functional in the sense that it can be used to identify material whose wing pattern corresponds closely with type material for each taxon; it will not perform well when applied to examples with divergent phenotypes. The possibility remains that numerous undescribed, cryptic species exist, but resolution of that issue is beyond the scope of this work. When Isostyla is fully revised, its size will undoubtedly double. Similarly, once species boundaries are understood, geographical distributions will differ from the crude ones provided here.

KEY TO ISOSTYLA SPECIES

1. Hind wing veins lined with dark brown to blackish brown (pls. 24, 25), areas between veins semihyaline or white2

HW almost completely white (pl. 24), veins white, outer margin thinly lined with blackish brown (Ecuador)purefacta Prout

2. Forewing hyaline, at least in basal half; fascia white or hyaline; FW with additional small white spots near tornus and often near apex3

FW barely hyaline, basal half suffused with dark blue gray (pl. 24); FW fascia large, white, extending from R1 anteriorly to near tornus posteriorly; no small white FW spots near tornus or apex (Guatemala S to Costa Rica)zetila (Boisduval)

3. Forewing tornus exhibiting two small white spots near outer margin, anterior spot between fork of M3 and CuA1, posterior one between CuA1 and CuA24

FW tornus with a single white spot near outer margin (pl. 25), located between CuA1 and CuA2, area between fork of M3 and CuA1 mostly hyaline; FW fascia white, or hyaline with dark veins (W Colombia, W Ecuador)picata (Warren)

4. Forewing fascia white, wide, roughly ovoid (pl. 24), veins white as they pass through it (Central America)ithomeina (Butler)

FW fascia hyaline, narrowing anteriorly, roughly trapezoidal (pl. 25), veins dark as they pass through it (central Colombia)biquadrata Prout

Isostyla biquadrata Prout, revised status

Plate 25

Isostyla biquadrata Prout, 1918: 415.

Type Locality

Colombia, Cundinamarca, Cananche.

Type

Syntype ♂, leg. M. de Mathan, Jul 1903 (BMNH).

Discussion

Prout (1918) described biquadrata as a subspecies of I. intersecta Warren ( = picata Warren), differing from the nominate form in showing a shorter and narrower FW fascia. Subsequent authors (Hering, 1925; Bryk, 1930) followed that arrangement. After comparing genital morphology of examples representing these phenotypes, I conclude that they are distinct, and thus raise biquadrata to species status. According to my hypothesis, intersecta and picata are synonyms, with the latter being the applicable name.

Isostyla picata occurs in western Ecuador and southwestern Colombia, whereas I. biquadrata is known from central Colombia, in Cundinamarca province. Prout's diagnostic character, presence of a small FW fascia, narrowing anteriorly (pl. 25), with the base of Rs1–Rs4, M1 and M2 dark as they pass through the fascia, appears to function in separating I. biquadrata from other Isostyla species.

Distribution

Colombia (BMNH, OUMNH, USNM).

Dissected

♂, Colombia, Villavicencio, Jul 1918, leg. Apollinaire, Dognin Collection, USNM (genitalia slide no. JSM-1222); ♂, Colombia, Muzo, 400–800 m, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1224); ♀, Colombia, Muzo, 400–800 m, leg. Fassl, Dognin Collection, USNM (genitalia slide no. JSM-1223); ♀, Colombia, Cundinamarca, Cananche, Nouvelle Grenade, 1 Sep 1900, leg. M. de Mathan, BMNH (genitalia slide no. JSM-1633).

Isostyla ithomeina (Butler)

Figures 276A–C, 276F, 277; plate 24

Dioptis ithomeina Butler, 1872: 87.

Type Locality

“Costa Rica”.

Type Locality

Syntype ♂, ex E.W. Janson Collection (BMNH).

Dioptis erycinoides C. and R. Felder, 1874: pl. 105, fig. 4.

Type Locality

“Panama”.

Type

Syntype ♂ (BMNH).

Discussion

Perhaps the most effective way to recognize I. ithomeina is by the presence of a large, quadrate white FW fascia situated well beyond the DC, accompanied by two small white spots near the FW tornus. The upper fork of M3+CuA1 is dark, separating the large white fascia from the small white spots. Some females of the Ecuadorian I. picata (pl. 25) are similar in appearance to females of I. ithomeina. However, there the upper fork of M3+CuA1 is white and the lower fork is dark, thus creating a larger FW fascia accompanied by a single white spot near the tornus.

Confirmed examples of I. ithomeina occur from Panama north to Honduras. However, the AMNH collection contains specimens from western Colombia (Nariño) exhibiting the wing-pattern characteristics of I. ithomeina. I did not dissect the Colombian material.

After searching through the supplementary material at the BMNH (March 2005), I discovered a male that is in all probability the type of erycinoides C. and R. Felder (1874); labels on that specimen establish it without question as the moth shown in the Felder publication (pl. 105, fig. 4). The erycinoides type is in poor condition; the head and right FW are missing. Importantly, comparison of BMNH types confirms that erycinoides and ithomeina are conspecific. The former should properly be retained as a junior synonym of ithomeina, following Bryk (1930). On the other hand, two Ecuadorian taxa regarded as subspecies of ithomeina by previous authors (see Bryk, 1930)—picata Warren and purefacta Prout—I here elevate to species status based on comparison of their morphology with that of I. ithomeina.

Isostyla ithomeina has been reared in Costa Rica on the palm genus Asterogyne (table 4).

Distribution

Panama (AMNH, BMNH, CMNH, NMW, USNM, ZMH); Costa Rica (AMNH, BMNH, CMNH, INBio, USNM); Honduras (AMNH).

Dissected

♂, Costa Rica, Esperanza, 22/5, leg. Schaus, Dognin Collection, USNM (genitalia slide no. JSM-1219); ♂, Costa Rica, Carillo, Apr, Schaus Collection, CMNH (genitalia slide no. JSM-640); ♂, Costa Rica, Carillo, 9 Mar, leg. W. Schaus, BMNH (genitalia slide no. JSM-1221); ♂, Costa Rica, reared by Jorge Corrales, 95-JFCM-33, AMNH (genitalia slide no. JSM-1634); ♀, Costa Rica, Zent District, Feb 1907, Wm. Schaus Collection, USNM (genitalia slide no. JSM-1220); ♀, Panama, Canal Zone, Fort Kobbe, 10 Sep 1958, leg. W.D. Thomas, CMNH (genitalia slide no. JSM-641).

Isostyla picata (Warren), revised status

Figure 278F; plate 25

Tithraustes picata Warren, 1900: 130.

Type Locality

Ecuador, Cachabí.

Type

Syntype ♂, leg. Rosenberg, low country, Jan 1897 (BMNH).

Isostyla ampliplaga Hering, 1930: 517, pl. 7, fig. 7. New synonymy.

Type Locality

Colombia (western), btwn. Tumaco and Pasto.

Type

Holotype ♀, leg. W. Niepelt G. (ZMH).

Tithraustes intersecta Warren, 1900: 130. New synonymy.

Type Locality

Ecuador, Cachabí.

Type

Holotype ♀, leg. Rosenberg, low country, Jan 1897 (BMNH).

Discussion

Warren (1900) described picata from a series of moths at the BMNH, collected at Cachabí in western Ecuador. In that paper he also described the “aberration” intersecta based on a single female from the same Cachabí series. According to Warren, that female differs in having the large FW fascia hyaline, rather than white, with the veins dark as they pass through it. Subsequent authors (Prout, 1918; Hering, 1925; Bryk, 1930) diverged from that opinion, treating picata as a synonym of T. ithomeina Butler, but giving intersecta species status, the latter with its own subspecies—biquadrata Prout.

I struggled with the taxonomy of these names, and after much deliberation have come to the following conclusions: (1) Isostyla picata with a white FW fascia, and so-called I. intersecta with a hyaline fascia (pl. 25), are color forms of the same species. The two phenotypes are consistently collected at the same localities in western Ecuador (AMNH, BMNH, SMNS), usually on the same date. Furthermore, after considerable study, including comparison of genital morphology, I was unable to find a single character for separation other than fascia color. This pattern character seems to vary throughout both Tithraustes and Isostyla, making it an unreliable indicator of species differences. Since intersecta was described as an aberration, that name is unavailable, so picata is the appropriate name to apply. (2) Isostyla picata (fig. 278F; pl. 25) is distinct from I. ithomeina (fig. 277E; pl. 24). (3) biquadrata Prout deserves species status (see above). That taxon shows traits distinguishing it from all other Isostyla species, especially in the configuration of female St7 and the shape of the female anterior and posterior apophyses.

The distributions of these taxa aid in their identification: I. picata occurs along the western foothills of the Andes, from southern Colombia to southern Ecuador; I. biquadrata is restricted to central Colombia; and I. ithomeina is Central American. It is important to again note however, that species boundaries within Isostyla are far from understood. Further resolution of this difficult group will require revisionary research, including collection of additional material. Males of I. picata are unknown.

Based on my examination of the ZMH holotype of ampliplaga Hering, that taxon is conspecific with picata. I here place Hering's name in synonymy. The type locality for ampliplaga is in extreme southwestern Colombia, near the Ecuadorian border. It is therefore not surprising that ampliplaga is conspecific with picata, whose type locality is in western Ecuador.

Distribution

Ecuador (AMNH, BMNH, FNHM, LACM, SMNS, USNM, ZMC); Colombia (AMNH, BMNH, USNM, ZMH).

Dissected

♀, Ecuador, Pichincha, Tinalandia, 700 m, 20 May 1993, leg. J.S. Miller, day coll. in forest understory, AMNH (genitalia slide no. JSM-1226); ♀, Ecuador, Pichincha, Tinalandia, 700 m, 19 May 1993, leg. L.D. Otero, day coll., AMNH (genitalia slide no. JSM-1225).

Isostyla purefacta Prout, revised status

Figure 278A–E; plate 24 [EX]

Isostyla purefacta Prout, 1918: 415.

Type Locality

Ecuador, Zamora, 3–4000 ft.

Type

Holotype ♂, leg. O.T. Baron (BMNH).

Discussion

Prout described purefacta as a subspecies of erycinoides C. and R. Felder ( = ithomeina Butler). In addition to numerous wing-pattern traits, genitalia diffferences confirm that purefacta is a species distinct from I. ithomeina, so I formalize that hypothesis here. The two species show strong differences in the shape of the male valva apices (figs. 277A, 278A), as well as in the shape of the horns on male Tg8 (figs. 277C, 278B).

According to my interpretation, I. ithomeina is restricted to Central America whereas I. purefacta refers to material with almost completely white wings, so far known exclusively from Ecuador. As a note of caution, the holotype of I. purefacta was collected at Zamora (fig. 5), east of Loja in southern Ecuador on the eastern slope of the Andes. All other material of so-called purefacta has been collected much further north on the Pacific slope. Ultimately, the male genitalia of these northern specimens should be compared with the type to assure that only a single taxon is involved. In the meantime, I apply the name purefacta to Isostyla material in which the FW and HW are transparent white with thin, dark brown markings around the margin (pl. 24).

Isostyla purefacta is a relatively common diurnal moth, flying in the forest understory and along trails at midelevations (700–1600 m) on the western slope of the Ecuadorian Andes. Over the course of two days in May 1993, I captured more than 30 individuals (a large number for most Dioptinae) at a single site—Otonga Reserve, near San Francisco de Las Pampas.

Distribution

Ecuador (AMNH, BMNH, FNHM, LACM, OUMNH, SMNS, ZMC).

Dissected

♂, Ecuador, Pichincha, Tinalandia, 700 m, 19 May 1993, leg. J.S. Miller, day-collecting, AMNH (genitalia slide no. JSM-673); ♀, Ecuador, Cotopaxi, trail from San Francisco de Las Pampas to La Otonga Reserve, 1610 m, 18 May 1993, leg. L.D. Otero, AMNH (genitalia slide no. JSM-674).

Isostyla zetila (Boisduval)

Figures 276D, 276E, 276G, 279; plate 24 [EX]

Epilaus zetila Boisduval, 1870: 78.

Type Locality

“Guatemala”.

Type

Not seen.

Hyrmina nubila Schaus, 1912: 537.

Type Locality

Costa Rica, Guapiles.

Type

Syntype ♂ (USNM type no. 17618).

Dioptis symoides Strand, 1914: 115. New synonymy.

Type Locality

“Costa Rica”.

Type

Holotype ♀ (not seen).

Discussion

Of all Isostyla species (pls. 24, 25), I. zetila is the easiest to recognize. The wings are dark with charcoal-gray veins, these showing a dull iridescent blue luster. Areas between the veins are densely covered with dark gray, pedicellate scales. The main distinguishing character of I. zetila is the presence of a single, conspicuous white FW marking—a large, ovoid fascia located in the distal third (pl. 24). Other Isostyla species with fasciae of similar size and contrast (e.g., I. ithomeina and I. picata) exhibit additional small white spots near the FW tornus, and usually one or more white spots near the FW apex. Isostyla zetila is strictly Central American, known from Costa Rica north to Guatemala.

Strand (1914) described Dioptis symoides as very similar to Laurona ( = Hyalurga) syma Walker, a species of Pericopinae (Arctiidae). According to him, the major wing-pattern difference is that D. symoides has a wider white FW band (“width  =  3.5 mm”). The description also states that in symoides the palpi are black below, while the coxae and femora are white. It is clear from Hering's (1925: 521) diagnosis for symoides that he had never seen verified material. He noted that the species is “probably near [Dioptis] candelaria”, a conclusion also reached by Forbes (1931).

Having been unable to locate the type of D. symoides, and in the interest of resolving the identity of the taxon, I conclude the following: Hyalurga syma (as shown in Seitz, 1925: fig. 65e) is an almost perfect mimic of Isostyla zetila. Furthermore, specimens of I. zetila match Strand's description of symoides in every respect. I therefore suggest that symoides is a synonym of zetila, and here formalize that hypothesis. My theory is supported by the fact that, after comprehensive study of thousands of specimens of Costa Rican Dioptinae in collections around the world, only three species of Dioptis are known to occur in that country: D. candelaria, a large, distinctive moth (pl. 18), as well as D. longipennis and D. butes (pl. 17), two taxa placed in Tithraustes by previous authors. None of these Dioptis species remotely resemble Laurona syma.

The other name associated with I. zetila, nubila Schaus, is more straightforward. Having examined the types of that taxon (JSM-1229), I follow previous authors in retaining it as a synonym.

Distribution

Guatemala (BMNH); Nicaragua (OUMNH); Costa Rica (AMNH, BMNH, CAS, CMNH, FNHM, INBio, LACM, MNHN, NMW, UCB, USNM, SMNS, ZMH).

Dissected

♂, Costa Rica, Heredia, vicinity of Selva Verde property, Sarapiquí, Chilamate, 200 ft, 4 Aug 1991, leg. G.E. Martinez, AMNH (genitalia slide no. JSM-424); ♂, Costa Rica, Heredia, vicinity of Selva Verde property, Sarapiquí, Chilamate, 200 ft, 4 Aug 1991, leg. G.E. Martinez, AMNH (genitalia slide no. JSM-1227); ♂ syntype of nubila Schaus, USNM (genitalia slide no. JSM-1229); ♂, Costa Rica, Guapiles, 850 ft, May 1907, Wm. Schaus Collection, USNM (wing slide no. JSM-1230; genitalia slide no. JSM-1232); ♀, Costa Rica, Heredia, Finca La Selva, 3 km SW Puerto Viejo, 75 m, 17 Oct 1973, leg. Opler, AMNH (genitalia slide no. JSM-425); ♀, Costa Rica, Heredia, Finca la Selva, Sarapiquí, 100 m, lowland wet forest, 27 Nov 1973, leg. P.R. Ehrlich, AMNH (genitalia slide no. JSM-1228); ♀, Costa Rica, Guapiles, 850 ft, May 1907, Wm. Schaus Collection, USNM (wing slide no. JSM-1231).

ANTICOREURA PROUT, 1918

Plate 25

Anticoreura Prout, 1918: 427. Type species: Coreura salmoni Druce, 1885b (by original designation).

Diagnosis

Anticoreura contains a single species, salmoni Druce. It would be impossible to confuse this moth with any other species in the Dioptinae. The dull, brownish-black FW (pl. 25), with its salmon-colored transverse band beyond the DC, extending from the subcosta to the tornus, is unique. The HW is iridescent blue with a dark gray fringe. The color figure of A. salmoni in Druce (1885b) is extremely accurate; even the wing venation is correctly depicted. The only other dioptine with a pinkish transverse FW band is Phanoptis miltorrhabda Prout (pl. 8), another incredibly rare taxon known from Peru and Bolivia. In that moth, there are three small, semihyaline subapical FW spots not found in A. salmoni, and the HW is uniformly blackish brown, not iridescent blue.

I did not dissect the female BMNH type of A. salmoni, the sole specimen upon which this genus and species are based. It is therefore impossible to provide a complete genus redescription here. However, after study of that type (March 2005) it is useful to list the following characteristics of Anticoreura: tympanum large, but not of the kettledrum type (as in Josiini); eye small, completely surrounded by a scaleless band; labial palpus short, Lp2 much shorter than Lp1; female antenna bipectinate, with fairly long, thick rami; FW long (length  =  24.0 mm); DC longer than one-half FW length; veins M1 and M2 arising close together from distal margin of DC; radial sector in the arrangement Rs1+[[Rs2+Rs3]+Rs4], typical of Dioptinae; M3 separate from CuA1 in FW; HW vein M3 stalked with CuA1; St7 scaleless, strongly sclerotized, with lateral pockets.

Distribution

The type locality for A. salmoni, Frontino (6°46′49″N, 76°07′50″W), is located northwest of Medellín, Colombia, approximately 150 km from the Panamanian border. That site, home to several other extremely interesting Dioptinae, is situated on the western slope of the Andes at an elevation of 1300 meters.

Biology

Nothing is known concerning the immatures or host plant of Anticoreura.

Discussion

Druce (1885b) described salmoni in the genus Coreura, currently placed in the Ctenuchinae (Arctiidae). Prout (1918) subsequently erected Anticoreura in the Dioptidae (Dioptinae), with salmoni as its only included species. The order in which Prout (1918) listed dioptine genera in his treatise was based on his perceived assessment of relationships. He placed Anticoreura close to Getta, therefore implying membership in the Josiini. Subsequent authors (Hering, 1925; Bryk, 1930) followed that proposal. Prout characterized Anticoreura by the following set of traits: front, pleural regions, and femora “rough-scaled”; palpus short; female antenna pectinate; and abdomen “robust”. The wing venation of Anticoreura is somewhat unusual in that M3 and CuA1 are separate in the FW, but stalked in the HW. However, this configuration occurs in other genera of the Dioptinae, such as Xenorma (fig. 53F).

The precise phylogenetic position of Anticoreura salmoni will remain a mystery until additional material is obtained, and the moth is studied in more detail. However, it is safe to conclude that the species was improperly associated with the Josiini (Prout, 1918; Hering, 1925; Bryk, 1930). I have therefore placed it in the tribe Dioptini. The pectinate female antennae and small eye imply membership in a clade that includes Brachyglene, Nebulosa, and others. Collecting in northwestern Colombia (and perhaps southwestern Panama) may provide additional material of A. salmoni.

SPECIES INCLUDED AND MATERIAL EXAMINED

Anticoreura salmoni (Druce)

Plate 25

Coreura salmoni Druce, 1885b: 521, pl. 32, fig. 6.

Type Locality

Colombia, Antioquia, Frontino.

Type

Holotype ♀ (BMNH).

Discussion

This spectacular taxon is known from a single specimen, the female type (pl. 25). Although Druce (1885b) described salmoni in the genus Coreura (Arctiidae: Ctenuchinae), the species with which A. salmoni shares the closest wing-pattern resemblance is Hypocrita ambigua Hering (Arctiidae: Pericopinae). Specimens at the AMNH, identified as H. ambigua (pl. 25), have been collected in western Ecuador, so the dioptine and pericopine are roughly sympatric, indicating a potential mimetic relationship. There is also a strong possibility that A. salmoni is mimetic with two butterfly taxa—Heliconius erato venus and H. melpomene vulcanus (A.V.Z. Brower, personal commun.). Both butterflies show an iridescent blue ground color and a salmon-colored FW band, and both occur in the Chocó region of Colombia.

Distribution

Colombia (BMNH).

Dissected

None.

DIOPTINI INCERTAE SEDIS

The following species of Dioptinae are of uncertain generic placement. I designate them incertae sedis, pending further study.

“Brachyglene” thirmida Hering

Plate 25

Brachyglene thirmida Hering, 1925: 524.

Type Locality

Bolivia, Río Songo, Yungas, 1200 m.

Type

Holotype ♀ (ZMH).

Discussion

The female holotype, the only known specimen of Brachyglene thirmida, was borrowed and dissected. However, the generic placement of B. thirmida is problematic. While wing venation and body characters imply broad membership in a clade with Brachyglene and relatives, the wing pattern is highly divergent compared to other species in that clade. In lieu of finding male specimens, I have decided to treat thirmida as incertae sedis. Hering (1925) obviously chose the species name to emphasize the remarkable similarity of this moth to members of Scea (pls. 33–35). Morphological traits demonstrate that wing-pattern resemblance in this case is a result of convergent evolution, perhaps attributable to Müllerian mimicry.

The type of B. thirmida was compared with the USNM male type of another mystery moth—Thirmida venusta (pl. 25), from Ecuador. The two are undoubtedly distinct species, but may be sister taxa. Shared features include: a slightly arcuate posterior margin of the HW; an orange area along the anterior margin of the HW; a purple luster in the dark blackish HW; small, barely porrect labial palpi; a moderately sized but well-defined, horizontally oriented metathoracic tympanum. Differences include a short FW DC in the B. thirmida female (long in the T. venusta male).

The female genitalia of B. thirmida resemble those of some basal species in Polypoetes (fig. 3). Further study is obviously required. Both thirmida and venusta belong in a remarkable mimicry ring that includes other, unrelated Dioptinae (Josiini), as well as several species of Arctiidae.

Distribution

Bolivia (ZMH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1218).

“Euchontha” castrona Warren

Figure 280A–D;

Figure 280

Genitalia of species incertae sedis. A, ♂ of “Euchontha” castrona (JSM-275); B, ♂ Tg8 of castrona; C, aedeagus of castrona; D, ♂ St8 of castrona; E, ♀ of “Xenomigia” disciplaga (holotype JSM-1465); F, ♀ Tg7 (left) and St7 (right) of disciplaga.

i0003-0090-321-1-1-f280.gif
plate 25

Euchontha castrona Warren, 1906: 411.

Type Locality

Brazil, Theresopolis.

Type

Holotype ♂, BMNH.

Discussion

Although this species was described in Euchontha, it does not belong there (Miller, 1989). Among a host of other traits, the unusual tympanum and quadripectinate antennae of Euchontha do not occur in E. castrona. In 1989, no genus assignment was suggested and now, 20 years later, the taxon's affinity remains obscure.

Males of E. castrona exhibit the following traits: labial palpus moderately long; antenna bipectinate; FW lacking a stridulatory organ; veins M3 and CuA1 stalked in FW and HW; wings densely scaled, veins lined with dark scales on dorsal and ventral surfaces. The male genitalia (fig. 280A–D) provide few clues. The unusual rugose appendix on the dorsum of the aedeagus, as well as the aedeagus shape, suggest a possible affiliation with the Andean genus Xenomigia (e.g., figs. 238C, 240B). However, among other differences, Xenomigia males show a FW stridulatory organ (fig. 235G, H), absent in castrona. The bipectinate antennae of castrona also conflict with the quadripectinate ones found Xenomigia. It is hoped that, when females of castrona are discovered, they will provide clues regarding the placement of this taxon.

Distribution

Brazil (BMNH, USNM, ZMH).

Dissected

♂, Brazil, Petropolis, BMNH (genitalia slide no. JSM-275; appendage slide no. JSM-279).

“Polypoetes” cuatropuntada Dognin

Polypoetes cuatropuntada Dognin, 1893: 426.

Type Locality

Ecuador, Environs de Loja.

Type

Holotype ♂, leg. 1887 (USNM type no. 30928).

Discussion

Known to me exclusively from the holotype, this moth does not belong in Polypoetes, where it has always been placed (Prout, 1918; Hering, 1925; Bryk, 1930). It does not seem to belong near Brachyglene or Nebulosa either. In cuatropuntada, the FW stridulatory organ is not present, the labial palpus is short and ascending, the antenna is bipectinate and the eye is relatively small. The male genitalia are somewhat nondescript. This species needs further study. Additional material is critically needed.

Based on genital similarities, this taxon belongs in a clade with an undescribed species from Los Libres, Ecuador (leg. G. Onore, JSM-1551).

Distribution

Ecuador (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-927).

“Scoturopsis” seitzi Hering

Plate 25

Scoturopsis seitzi Hering, 1925: 508.

Type Locality

“Bolivia”.

Type

Holotype ♂; not seen (“in the Coll. A. Seitz”; Hering, 1925: 508).

Discussion

If the BMNH specimen labeled “Scoturopsis seitzi” is correctly identified (pl. 25), then this species is not a member of the Dioptinae. The BMNH example matches the moth figured in Hering (1925; fig. 68k), and fits the original description. It seems to be a quadrifid noctuoid, perhaps a lymantriid or arctiid. Examination of the S. seitzi type, supposedly in the A. Seitz collection, will be required to resolve this situation. That type is not at the ZMH, and correspondence with other German collections has not revealed its location.

Distribution

Bolivia (BMNH, ZMH).

Dissected

None.

“Stenoplastis” carderi (Druce)

Plate 25

Devara carderi Druce, 1899: 298.

Type Locality

Interior of Colombia.

Type

Holotype ♂, leg. J. Carder (BMNH).

Discussion

I know this species from the holotype, and from an additional BMNH male (JSM-1418). Characteristics of carderi include: labial palpus short, with a ventral fringe of bristlelike scales; eye small; antenna densely ciliate; five FW radials present, Rs2–Rs4 in the pattern [2+3]+4; male stridulatory organ absent, DC greater than one-half FW length; FW and HW veins M3 and CuA1 long stalked; tympanum open, membrane large, facing ventrolaterally. The male genitalia are nondescript, and provide no obvious features to aid in placing carderi in an existing genus.

Distribution

Colombia (BMNH).

Dissected

♂, Colombia, Bogotá, “89–154”, BMNH (genitalia slide no. JSM-1418).

“Stenoplastis” flavibasis Hering

Stenoplastis flavibasis Hering, 1925: 518: fig. 69i.

Type Locality

Peru, Pozuzo.

Type

Holotype ♂; not seen (in A. Seitz Collection).

Discussion

My interpretation of the original description and figure (Hering, 1925; fig. 69i) suggests that S. flavibasis is related to S. subcoerulea. However, study of the S. flavibasis holotype will ultimately be required. According to Hering (1925: 518), the type of flavibasis is in the Adalbert Seitz Collection, but after inquiries to German museums, I have not been able to locate it.

Distribution

Peru (ZMH).

Dissected

None.

“Thirmida” venusta Dognin

Figure 281;

Figure 281

Holotype ♂ genitalia of “Thirmida” venusta, incertae sedis (JSM-1066). A, genitalia; B, St8; C, aedeagus; D, Tg8, dorsal view.

i0003-0090-321-1-1-f281.gif
plate 25

Thirmida venusta Dognin, 1900: 213.

Type Locality

“Ecuador”.

Type

Holotype ♂, C. de Labonnefon Collection (USNM type no. 30947).

Discussion

This species does not belong in Thirmida (Josiini), where it has been placed (Prout, 1918; Hering, 1925; Bryk, 1930); venusta was obviously described there on the basis of its wing pattern. I know the species exclusively from the male holotype. Judging from its genitalia (fig. 281), venusta could potentially belong in Brachyglene or Nebulosa. The genitalia exhibit the following characters: valva short, truncate at apex, transtilla greatly swollen; Tg8 long, swollen near posterior margin, bearing two short anterior apodemes; St8 short, broad. Importantly, B. venusta does not possess a FW stridulatory organ, and FW veins M3 and CuA1 are approximate, not stalked. Wing venation thus excludes it from either Brachyglene (fig. 145F) or Nebulosa (fig. 162A, C–F).

Distribution

Ecuador (USNM).

Dissected

Holotype ♂ (genitalia slide no. JSM-1066).

“Tithraustes” caliginosa (Dognin)

Plate 25

Polypoetes caliginosa Dognin, 1902: 476.

Type Locality

Ecuador, Loja.

Type

Holotype ♂, leg. 1892 (USNM type no. 30937); abdomen missing.

Discussion

Dognin described caliginosa in Polypoetes, and Prout (1918) later transferred it in Tithraustes. The species belongs in neither, but I am unable to assign it to an existing genus. This is the apparent sister species to pyrifera Dognin, from Quindiu, Colombia (pl. 25), another species of uncertain placement. The two taxa exhibit extremely similar wing patterns. Unfortunately, the abdomen of the caliginosa type, the only specimen known, is missing, so genitalia comparison is not possible. Both caliginosa and pyrifera exhibit the following set of characteristics: labial palpus short, yellow, slightly upturned; eye relatively small; male antenna bipectinate; metathoracic tympanum moderate in size, facing posteroventrally; wing venation typical of Dioptinae, except FW veins M3 and CuA1 not stalked; FW DC long, no stridulatory organ present.

Distribution

Ecuador (USNM).

Dissected

None.

“Tithraustes” pyrifera Dognin

Figure 282; plate 25

Figure 282

Genitalia of “Tithraustes” pyrifera, incertae sedis (holotype ♂ JSM-748, ♀ JSM-749). A, ♂ genitalia; B, ♂ St8; C, ♂ Tg8; D, ♀ genitalia.

i0003-0090-321-1-1-f282.gif

Tithraustes pyrifera Dognin, 1911b: 5.

Type Locality

Colombia, Río Toche, Quindiu, 2400 m.

Type

Syntype ♂, leg. Fassl (USNM type no. 30933); abdomen missing.

Discussion

This taxon is the apparent sister species of caliginosa Dognin, the latter from Loja, Ecuador. Neither belongs in Tithraustes, where they had previously been placed, but I am unable to find an existing genus in which to put them. Forewing veins M3 and CuA1 are separate, and there is no FW stridulatory organ. The FW exhibits five radials, with Rs2, Rs3 and Rs4 arising together to form a trident. The palpus is short, and the male antenna is bipectinate. In the male genitalia of pyrifera (fig. 282A–C), the valva is sclerotized, the transtillar arms are wide, and there is a large, flat uncus. Morphology of the female (fig. 282D) is not informative.

Distribution

Colombia (USNM).

Dissected

♂, Colombia, Quindiu, leg. Fassl, USNM (genitalia slide no. JSM-748); ♀, Colombia, Quindiu, leg. Fassl, USNM (genitalia slide no. JSM-749).

“Xenomigia” disciplaga Hering

Figure 280E, F; plate 25

Xenomigia disciplaga Hering, 1926b: 129.

Type Locality

“Columb.” (Starke?).

Type

Holotype ♀ (ZMH).

Discussion

This taxon, known only from the female type (pl. 25), is impossible to place in an existing dioptine genus. Hering (1926b) apparently described the moth in Xenomigia claiming that veins M3 and CuA1 are separate in the FW. However, this trait occurs not only in Xenomigia, but in several additional dioptine genera. Furthermore, upon close inspection, veins M3 and CuA1 are short stalked in disciplaga, whereas these veins are truly separate in Xenomigia. While now acknowledging that disciplaga is incorrectly placed, I am unable to resolve where it belongs.

The species exhibits the following characteristics: labial palpus short, curving upward to immediately above clypeus; [HT antennae absent]; metathoracic tympanum moderate in size, oriented ventrolaterally, depression moderately deep; FW DC long; vein M1 arising from base of radial sector; FW veins M3 and CuA1 separate; HW veins M3 and CuA1 short stalked. The small, white FW fascia of disciplaga is unusual in its position across CuA2 and the anal fold. As far as I am aware, no other species in the Dioptinae exhibits a pattern like this.

The female genitalia of disciplaga are unusual. There are elongate horns on the lateral margins of Tg7 (fig. 280F), as well as horns on either side of the elongate postvaginal plate (fig. 280E). A third set of small horns occurs on the dorsolateral angles of Tg8. The CB is membranous, without a signum. Additional material, including males, is sorely needed.

Distribution

Colombia (ZMH).

Dissected

Holotype ♀ (genitalia slide no. JSM-1465).

The following species, listed as Dioptinae in Bryk (1930), have been removed from the subfamily:

“Brachyglene” superbior (Strand)

Ephialtias superbior Strand, 1912: 147.

Type Locality

Ecuador, Macas.

Type

Holotype, leg. Niepelt (not seen).

Discussion

Prout (1918) placed Ephialtias superbior Strand (1912) as “incertae sedis” (p. 429). Later, Prout (1920), in his “supplementary notes on Dioptidae”, wrote that the species “is an Amatid [now family Arctiidae]  = Ctenucha cyaniris Hampson.” Bryk (1930) did not notice Prout's correction, and somehow placed superbior in the genus Brachyglene. It should be retained in the Arctiidae.

I have not seen a specimen of superbior, nor have I been able to locate the type. The original description, in German, frequently compares the appearance of superbior to that of Thirmida superba Druce (now Scea superba). At the time Strand was writing, superba was considered to belong in Ephialtias (Josiini), so Strand must have assumed he was describing a congener.

Distribution

Ecuador.

Dissected

None.

Euchlaenidia albilinea (Schaus), new combination

[transferred from Tithraustes Druce to Euchlaenidia Hampson (Arctiidae: Pericopinae)]

Plate 25

Polypoetes albilinea Schaus, 1912: 431.

Type Locality

Costa Rica, Turrialba.

Type

Holotype ♀ (USNM type no. 17613).

Discussion

Schaus (1912) described this taxon in Polypoetes, but Prout (1918: 410) subsequently transferred it to Tithraustes, where it has remained ever since. Examination of the female holotype of albilinea (pl. 25) confirms that the species is an arctiid in the subfamily Pericopinae. My studies further suggest that it belongs in the genus Euchlaenidia Hampson (1901: 186).

Distribution

Costa Rica (USNM).

Dissected

None.

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James S Miller "Generic Revision of the Dioptinae (Lepidoptera: Noctuoidea: Notodontidae) Part 1: Dioptini," Bulletin of the American Museum of Natural History 2009(321), 1-674, (30 June 2009). https://doi.org/10.1206/321.1
Published: 30 June 2009
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