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27 October 2005 A Revision of Extant Greater Antillean Bats of the Genus Natalus
ADRIAN TEJEDOR, VALERIA DA C. TAVARES, GILBERTO SILVA-TABOADA
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Abstract

The taxonomy of the genus Natalus in the Greater Antilles has been controversial for decades. Although as many as three taxa of Natalus (sensu stricto) were described for the Greater Antilles, the main source of disagreement was whether Natalus major (thought to be distributed in Cuba, Hispaniola, and Jamaica) is a species distinct from Natalus stramineus. The Cuban form of Natalus, previously known only from incomplete fossils, has been largely excluded from the debate surrounding the taxonomic status of N. major. The discovery of an extant population of the Cuban Natalus prompted a reanalysis of species limits among Natalus in the Greater Antilles. In this paper, we show that the genus Natalus is represented in the Greater Antilles by three distinct extant species, each endemic to a single island. We also summarize information about the natural history of these species and emphasize the importance of taking immediate conservation action for their protection.

INTRODUCTION

The New World family Natalidae comprises a small assemblage of insectivorous, cave-dwelling bats characterized by funnel-shaped ears, very long legs and tail, and the natalid organ, a saclike glandular structure located in the dorsum of the muzzle in males. The family was long considered monogeneric (e.g., Koopman, 1994; Varona, 1974), with the genus Natalus having three subgenera: Natalus, Chilonatalus, and Nyctiellus. A recent morphological analysis led Morgan and Czaplewski (2003) to suggest that the three previously recognized subgenera are best treated as genera. Six species of Natalidae are currently recognized: Natalus major, Natalus stramineus, Natalus tumidirostris, Chilonatalus micropus, Chilonatalus tumidifrons, and Nyctiellus lepidus (Morgan and Czaplewski, 2003).

The family Natalidae occurs widely throughout the lowlands of tropical America, having its highest diversity in the Caribbean island of Cuba (Tejedor et al., 2004). The genera Chilonatalus and Nyctiellus are restricted to the West Indies, and the genus Natalus is distributed throughout the Neotropics, from northwestern Mexico (Baja California and Sonora) and the West Indies (Greater and Lesser Antilles) to southeastern Brazil, Bolivia and Paraguay (Koopman, 1994; López-Gonzales et al., 1998; Taddei and Uieda, 2001). In the Greater Antilles, the genus Natalus occurs on the three largest islands in the region (Cuba, Hispaniola, and Jamaica) and is known from fossil remains from the Bahamas and the Cayman Islands (Morgan, 1989, 1994, 2001). Historically, the taxonomy of Natalus in the Greater Antilles has been controversial. Depending on the author, the taxa of Cuba, Hispaniola, and Jamaica have been recognized as one or two Greater Antillean endemic species, or as insular subspecies of Natalus stramineus Gray, 1838, a widespread continental species with a distribution congruent with that of the genus Natalus (Koopman, 1994).

The genus Natalus was first known in the Greater Antilles through the description of Natalus major Miller, 1902, from Hispaniola, a taxon diagnosed as having a larger skull and a more inflated braincase than the already known form, Natalus stramineus. Years later, Anthony (1919) described Natalus primus, from Cuba, on the basis of two fossil mandibular rami that were much larger and had heavier teeth than mandibles of N. major. By the middle of the 20th century, Koopman and Williams (1951) reported the first record of Natalus from Jamaica (and tentatively referred it to N. major), based on a single partial mandible collected by H. E. Anthony on that island during 1919–1920. Living specimens of the Jamaican Natalus were first reported almost a decade later, with Goodwin's (1959) description of Natalus major jamaicensis. Surprisingly, although Goodwin (1959) diagnosed the Jamaican Natalus on the basis of more than five discrete characters he still considered it to be only subspecifically distinct from the Hispaniolan population. In his paper, Goodwin (1959) also treated the Cuban N. primus as a subspecies of N. major, thereby recognizing a single, endemic species of Natalus for all Greater Antillean islands. Living representatives of Natalus in Cuba were not known until 1991, when a colony was found in a cave in the westernmost tip of the island (Tejedor et al., 2004).

Traditionally, taxonomic decisions involving Greater Antillean Natalus (and all of the Natalidae, in general) have been conservative, and often have lacked appropriate support. Cabrera (1957), for example, suggested, without providing justification, that most populations of Natalus, both insular and continental (with the exception of Natalus tumidirostris Miller, 1900, from northern South America), represented the single species Natalus stramineus. This point of view was formalized in the 1970s in a series of publications (Linares, 1970, 1971; Linares and Lö big-A, 1973) that, based on limited character observation, collectively argued that morphological variation among all populations of Natalus, including West Indian species, was clinal, and that therefore should all be referred to Natalus stramineus (even though the name N. tumidirostris was tentatively retained for Venezuelan populations). Later, Varona (1974) also assigned all Greater Antillean Natalus to N. stramineus, but similarly did not provide justification for his decision. Subsequently, with the exceptions of Hoyt and Baker (1980) and McFarlane (1997), which retained N. major as a valid Greater Antillean species, most authors (e.g., Hall, 1981; Koopman, 1989, 1993, 1994; McFarlane, 1986; Silva-Taboada, 1979) have followed Linares' (1971) and Varona's (1974) arrangement.

Despite the historic prevalence of conservative treatment regarding the systematics of Greater Antillean Natalus, taxonomic discordance has continued until the present. In recent years, several works have argued for the revalidation of full specific status for Natalus major on the basis of the larger size of Greater Antillean Natalus (Tejedor et al., 2004) and of divergent discrete cranial morphology between Greater Antillean and other populations of Natalus (Morgan, 1989, 1994, 2001; Morgan and Czaplewski, 2003). Nonetheless, a recent monograph on the bats of Dominica (Genoways et al., 2001) favored the inclusion of all insular Natalus within Natalus stramineus. This point of view was further supported by Timm and Genoways (2003: 30), who stated that, other than size, there were no “structural” differences between N. major and other insular and continental taxa of Natalus.

Besides the fact that influential taxonomic decisions involving Greater Antillean Natalus have often been based on insufficient evidence, the few truly detailed morphological studies of the genus Natalus in the West Indies (e.g., Goodwin, 1959; Morgan, 1989, 2001) have been limited by specimen sampling and availability (for instance, most of Morgan's morphological arguments for the recognition of N. major as a distinct species apply only to the Jamaican form of Natalus). In particular, the lack of neontological material of the Cuban form of the genus reduced the breadth of any morphological study that aimed at understanding the diversity of Natalus in the Greater Antilles. Recent material of Natalus made available from Cuba (Tejedor et al., 2004) prompted the reanalysis of the taxonomic status of the three Greater Antillean populations of Natalus. As our study shows, we find that the three populations of the subgenus Natalus that inhabit the three largest Greater Antillean Islands are divergent in many morphological traits and therefore merit recognition as three distinct species.

MATERIALS AND METHODS

Museum Specimens

We examined most of the specimens of Greater Antillean Natalus currently available in museum collections in Cuba, the United Kingdom, and the United States. Museums visited and specimens examined are listed in the appendix.

Measurements

All observations reported here are based on adults with closed epiphyses. Cranial and external measurements follow Silva-Taboada (1979) and Handley (1988). Cranial measurements and length of tibia were taken to the nearest 0.1 mm with digital or dial calipers. Ear length, and forearm length of dry specimens were taken from specimen tags. Weight was measured in the field or taken from specimen tags.

  • Forearm length: Maximum distance between elbow and wrist, taken dorsally with the wing folded.

  • Length of tibia: Maximum length of the tibia taken with the femur and foot flexed in an angle smaller than 90°.

  • Ear length: Greatest distance from the basal notch of the ear to the tip of the ear.

  • Greatest skull length: Maximum length of the skull taken from the anterior edge of the premaxilla to the posterior edge of the occiput.

  • Zygomatic breadth: Maximum distance between the exterior sides of the zygomatic arches, taken perpendicular to the longitudinal axis of the skull.

  • Postorbital breadth: Distance between the lateral walls of the frontals, taken dorsally at the level of the least postorbital width.

  • Braincase breadth: Maximum distance between the lateral walls of the braincase, taken perpendicular to the longitudinal axis of the skull.

  • Breadth across molars: Maximum distance between the labial margins of the molar tooth rows, taken perpendicular to the longitudinal axis of the skull.

  • Maxillary tooth row length: Maximum distance between anterior edge of maxillary canine and posterior edge of last maxillary molar.

STATISTICAL ANALYSES

Statistical analyses were performed with STATISTICA (1995, version 5). Six two-way ANOVAs and Tukey's Test for unequal sample sizes were used to compare measurements between species for six variables with sample sizes (per species) ≥ 10. Given a previous report of sexual dimorphism in a Greater Antillean Natalus (Tejedor et al., 2004), we used T tests to compare measurements between sexes in our samples. Due to the small size of samples of females from Hispaniola and Jamaica, and given that significant differences between the sexes of Natalus from Cuba showed no interaction with differences between island samples, we pooled both sexes in most statistical analyses. Nonetheless, we performed a separate one-way ANOVA for zygomatic breadth including only males because it was the only character for which differences among males (potentially significant due to relatively large sample sizes) seemed obscured by differences among females. Probabilities were compared to a significance level of α = 0.01 for all the ANOVAs and T tests (in which several tests were performed on the same all-species sample), and to a significance level of α = 0.05 for the Tukey's comparisons. Within-island geographic variation was not tested because there is only one known extant locality for two of the three species treated in this paper (i.e., Natalus jamaicensis and Natalus primus), and the sizes of the available samples of Natalus major with different geographic provenience were generally very small. Finally, we performed a principal components analysis (PCA) of the variables with sample sizes (per species) ≥ 10, and used the first two extracted principal components to generate a plot of specimen scores.

SYSTEMATICS

Our analyses of qualitative and quantitative morphological characters reveal the presence of three separate evolutionary lineages of the genus Natalus in the Greater Antilles, with a degree of morphological divergence characteristic of fully differentiated species. The three species are distinct in cranial morphology, and can be distinguished by size and external characters. Accordingly, we redescribe them here.

Natalus major Miller, 1902 Figures 1–4

  • Natalus major major Goodwin, 1959.

  • Natalus stramineus major Linares, 1971.

  • Holotype:

    USNM 101395, adult male skull and skin in fluid, collected by W. M. Gabb between 1869 and 1871 “near Savaneta [locality 10 in the appendix], Dominican Republic”. The skull is complete and the skin is in good condition.

    Distribution:

    Hispaniola, including the Dominican Republic and Haiti (fig. 5).

    Diagnosis:

    Forearm length relatively small (42.1–44.8 mm); ear tip pointed, with a shallow notch on the outer margin; rostrum relatively short, with the point of flexion between rostrum and braincase dorsal to the anterior edge of orbit; braincase not rising abruptly from the rostrum, with an angle smaller than 55° between dorsal plane of rostrum and frontal plane of forehead; braincase oval-shaped in dorsal profile, its breadth smaller than its length; postorbital constriction relatively wide, its sides markedly diverging anteriorly; maxillary convex dorsal to molars; one pair of small palatal fenestra sometimes present between last molars; basisphenoid pits shallow, and raised above plane of basisphenoid furrows, in ventral view; posterior edge of ascending ramus of mandible straight and vertical, forming an angle close to 90° with basal plane of dentary, and lacking notch below condyloid process (table 1).

    Description:

    Natalus major has a relatively short forearm (42.0–44.8 mm) and a relatively short ear (ear length 15.8–17.9 mm). The braincase breadth and greater skull length means of males of N. major appear to average larger than those of females (fig. 6), but these differences were not statistically significant in our sample.

    The hair is long (7 mm) and lax, both ventrally and dorsally. Dorsal hairs are bicolored, with bases lighter than tips, and ventral hairs are monocolored. There are two morphs of pelage color, one bright yellowish and another grayish, with a few intermediate individuals. In the bright-yellowish morph, dorsal hair bases are buff and the tips are sepia, and ventral hairs are entirely cream buff (fig. 4). In the grayish morph, the dorsal hairs are drab to smoke gray with fuscous tips, and ventral hairs are pale smoke gray. Most individuals have a darker-colored patch on the forehead. There is a fringe of hairs along the free border of the uropatagium. Mustachelike facial hair is sepia to fuscous, connected across dorsum of muzzle by a narrow band of dark hairs. The pelage extends slightly into both faces of the plagiopatagium, dorsally to 6 mm, and ventrally to 10 mm.

    The muzzle is relatively short and dorsoventrally flattened. The nostrils are small, oval, and open ventrolaterally. In ventral view, the tip of the muzzle between the nostrils projects slightly beyond the upper lip. The lower lip is thickened and with a shallow central groove. The ears are rather square-shaped. The inner edge of the ear is straight below the tip and has a shallow notch on the outer edge, giving the tip a pointed appearance. The ears of N. major show five to seven rudimentary folds, though they may be entirely absent in some individuals.

    The skull is relatively broad and robust. The braincase of Natalus major is not markedly inflated, nor very abruptly elevated above the rostrum, forming an angle smaller than 55° with the dorsal plane of the nasals. The postparietal region is relatively wide in dorsal view. A conspicuous ridge separates the postparietal and occipital regions. The sagittal crest is well developed. The postorbital region is wide, with sides markedly diverging anteriorly, in dorsal view. The rostrum is relatively short and broad. The dorsal point of flexion between the rostrum and the braincase is dorsal to the anterior edge of the orbit. There is a moderately deep sulcus between the nasal bones. The premaxillary region does not project anteriorly, so that in lateral view the small diastema between canines and incisors is not particularly noticeable. The maxillary is convex above molars. The rostrum does not tip downward, or does so only slightly. The anterior palatal foramina are very small and near the palatine emargination, and their anterior margin is posterior to the anterior edge of the canines. Two pairs of small palatal fenestra are present at the level of the last molar in some individuals. The bony palate extends more than half the distance between the posterior edge of the last molar and the tip of pterygoids. The pterygoid processes are slightly convergent and markedly hooked in lateral view. In ventral view, the inner edge of each pterygoid is smoothly convex. In ventral view, the basisphenoid pits, between the maxillary articular facets, are shallow and raised above the level of the basisphenoid furrows.

    The dentary is curved (upturned) and thick. The angular process is thick, rather straight, and with a blunt spatulate end. The base of the angular process is dorsal to the alveolar plane. The coronoid process is at about the same height than the condyle, above the alveolar plane. The ascending ramus of the mandible is markedly upturned, with its anterior border concave and raising from the alveolar plane at an angle greater than 80°. The posterior border of the ascending ramus rises from the base of the angular process at a nearly straight angle with the base of the dentary, giving a rectangular appearance to the ascending ramus. The mental foramen is between the canine and the first premolar.

    The upper incisors of Natalus major are small, with a hooked point in lateral view. The first incisor is situated more posteriorly than the second, so that in lateral view the first incisor is not visible. The base of the upper canines is robust, in occlusal view, with a well-developed cingulum that is about as wide as it is long. The upper premolars are successively larger, in occlusal view, and relatively short and crowded. The upper molar row is relatively slender, its width less than half the width of the palate. The first and second molars are approximately equal in size, with the third slightly smaller.

    The lower incisors are small, tricuspid, and subequal. The lower canine is large and rather curved, with a large cingulum that is slightly longer than it is wide. The canine and premolars are longitudinally short in occlusal view, and the first premolar is shorter than the canine and the other two premolars. The first two molars are larger and wider than the third; the first projects more labially than the other two. The last premolar and first molar are relatively crowded (fig. 3).

    Comparisons:

    Natalus major can be distinguished from most other species of Natalus (with the exception of Natalus jamaicensis) on the basis of body size and external characters. The forearm length of N. major (42.0–45.0 mm) is smaller than that of Natalus primus (46.1–51.2 mm; P < 0.001; fig. 6), and is larger than those of Natalus stramineus (35.0–41.0 mm; Tejedor et. al., 2004) and Natalus tumidirostris (37.2–41.5 mm; Tejedor, unpublished data). Externally, the ear of N. major has a straight anterior margin and a pointed tip, whereas that of N. primus has a relatively rounded tip and those of N. stramineus and N. tumidirostris have slightly to deeply concave anterior margins. The dorsum of the muzzle of N. major shows a thin band of dark, long hairs connecting the labial mustaches, which is absent in N. primus.

    Natalus major is morphometrically distinct from Natalus jamaicensis (figs. 6, 7), but both species overlap in size and are similar in external characters. Nonetheless, N. major can be unambiguously distinguished from N. jamaicensis on the basis of cranial characters (table 1, figs. 2–3). In N. major the maxillary bone is convex dorsal to the molars, and in N. jamaicensis it is markedly concave. In N. major, the sulcus between the nasal bones is moderately deep and long, whereas it is short and shallow in N. jamaicensis. In N. major, the upper molar series is narrower than half of the palate width, whereas in N. jamaicensis it is thicker than half of the palate's width. In N. major, the postorbital constriction is wider than in N. jamaicensis (P < 0.001, fig. 6), with sides markedly diverging anteriorly, in dorsal view, as opposed to sides almost parallel in N. jamaicensis. Also, in N. major, the braincase is much less inflated than in N. jamaicensis, and it is oval-shaped in dorsal profile, instead of almost circular as in N. jamaicensis. Finally, in N. major, the braincase does not rise very abruptly from the rostrum (angle between dorsal plane of rostrum and frontal plane of braincase less than 55°), whereas it rises very abruptly from the rostrum in N. jamaicensis (angle between dorsal plane of rostrum and frontal plane of braincase greater than 60°).

    Cranially, Natalus major can also be distinguished from Natalus primus, by its smaller skull size (greatest skull length 17.0–18.1 mm; P < 0.001), and shallow basisphenoid pits, whereas in the latter the basisphenoid pits are very deep and the skull is larger (greatest skull length 18.1–19.9 mm; P < 0.001; table 2, figs. 2–3). From Natalus tumidirostris, N. major can be distinguished by its convex yet uninflated maxillary bones, which are markedly inflated in the former, so that the molars are not easily seen in dorsal view. Natalus major differs from Natalus stramineus, as it is currently defined, by its larger skull (greatest skull length: 17.0–18.1 mm, 15.0–17.1 mm in N. stramineus) and by a larger and more voluminous braincase, relative to the overall size of the skull.

    Remarks:

    Fossil Natalus collected in the eastern Bahamas (Grand Caicos) were referred to N. major major by Morgan (1989). We tentatively include these fossils within N. major until they can be reexamined.

    Natalus primus Anthony, 1919 Figures 1–3

  • Natalus major primus Goodwin, 1959.

  • Natalus stramineus primus Linares, 1971.

  • Holotype:

    AMNH 41009, a fossil right dentary, collected by H. E. Anthony in 1917, Cueva de Los Indios (locality 29 in the appendix), Daiquirí, Santiago de Cuba, Cuba. The holotype is missing the coronoid process plus the incisors, canine, and first premolar, and is stained dark brown. (A second right dentary, designated by Anthony as a topotype, is in the vial with the holotype. It is complete, but is missing all teeth except the third premolar and the first molar).

    Distribution:

    Cuba, Isle of Pines, and the Bahamas (Abaco, Andros, New Providence). There is only one known extant locality (Cueva La Barca, Cuba; Tejedor et al., 2004) and 14 fossil localities (fig. 5).

    Diagnosis:

    Largest extant species in the genus Natalus (forearm length 46.1–51.2 mm, greatest skull length 18.1–19.9 mm); ear tip rounded, notch on outer margin of ear almost imperceptible; rostrum longer than in any other Greater Antillean Natalus, point of flexion between rostrum and braincase posterior to anterior edge of orbit; braincase not rising abruptly from rostrum, forming an angle smaller than 55° with dorsal plane of rostrum; braincase oval-shaped in dorsal profile, breadth smaller than length; postorbital constriction relatively wide, its sides markedly diverging anteriorly; postorbital sphenoid fenestra present; maxillary convex above molars; two pairs of relatively large fenestra on palate, between molars; basisphenoid pits deeply concave; posterior edge of ascending ramus of mandible forming an angle smaller than 70° with basal plane of dentary, and often with a notch below condyloid process (table 1).

    Description:

    Natalus primus is the largest of the Greater Antillean Natalus in mean forearm length, greatest skull length, and breadth across molars (P < 0.001; table 2, fig. 6). Its mean braincase breadth, however, is relatively small compared to those of N. jamaicensis and N. major (P < 0.001; fig. 6). The ears of N. primus are very large (20.2–21.2 mm). Males of N. primus are significantly, although only slightly, larger than females in body weight, length of tibia, greatest skull length, and zygomatic breadth (P < 0.01; table 2; fig. 6).

    The hair is long and lax. Dorsal and ventral hairs are 8 mm long. The dorsal hairs are bicolored, with bases lighter than tips, and the ventral hair is monocolored. There are two pelage-color morphs, one bright yellowish and another grayish, with some individuals showing intermediate coloration. In the bright-yellowish phase the bases of the dorsal hairs are buff and the tips are sepia, and the ventral hair is entirely cream buff. In the grayish phase the dorsal hairs are drab to smoke gray with fuscous tips and the ventral hairs are pale smoke gray. There is a fringe of hairs along the free border of uropatagium. Natalus primus has mustachelike facial hair tufts that are sepia to fuscous in color, and are not connected across the dorsum of the muzzle by a band of dark hairs. The pelage extends slightly into both faces of the plagiopatagium, dorsally to 6 mm, and ventrally to 10 mm.

    The muzzle is long and dorsoventrally flattened. The small, oval nostrils open ventrolaterally. The tip of the muzzle, between nostrils, projects slightly beyond upper lip, a feature that is most noticeable in ventral view. The lower lip is thickened and has a shallow central groove. The ears are rather square-shaped, with a straight anterior margin and lacking a notch on the posterior margin, giving the tip a relatively round appearance. The ears of Natalus primus show rudimentary folds, varying in number from five to seven.

    The braincase of Natalus primus is moderately inflated, and does not rise abruptly from the rostrum, forming an angle smaller than 55° with the dorsal plane of the nasals. The sagittal crest is pronounced and its interparietal region is slightly higher than its supraoccipital region. The postparietal region is relatively narrow in dorsal view and the ridge formed between this region and the occipital is relatively low. The postorbital constriction is relatively wide, with sides markedly diverging anteriorly. The rostrum is very long and moderately broad. The sulcus between the nasals is long and deep. The premaxillary region projects anteriorly, so that in lateral view the diastema between canines and incisors is conspicuous. The maxillary is convex dorsal to the molars. The rostrum tips slightly downward. The infraorbital foramen opens laterally, close to the alveolar margin. The anterior palatal foramina are very small and near the palatine emargination, at the level of the anterior edge of the canines. There are two relatively large palatal fenestra at the level of the last two molars. The bony palate extends for less than half the distance between posterior edge of last molars and tip of pterygoids. The pterygoid processes are convergent posteriorly, and vary from broadly triangular to acutely pointed in lateral view. The inner edge of each pterygoid has a prominent right-angled point visible in ventral view. The basisphenoid pits are deep, forming a large, double concavity that is conspicuously deeper than the basisphenoid furrows between the auditory bullae.

    The dentary bone is thin and not markedly curved. A rudimentary mandibular angle is sometimes present. The angular process is long and thin, rather straight, and with a hooked end. The base of the angular process is at the level of the alveolar plane. The coronoid process is at about the same height or slightly higher than the condyle above the alveolar plane. The ascending ramus is not markedly upturned. The anterior border of the ascending ramus is slightly concave, rising from the alveolar plane in an angle of about 80°. The posterior border of the ascending ramus rises from the base of the angular process in an angle smaller than 70°. Usually the posterior edge of the ascending ramus is not straight, having a shallow notch immediately above the base of the angular process. The mental foramen is between the canine and the first premolar.

    The superior incisors are relatively long and slightly hooked in lateral view. The first incisor is situated more anteriorly than the second, so that in lateral view the first incisor is easily visible. In occlusal view, the base of the canine is slender, its width comprising about two thirds of its length. The cingulum of the canine is well developed. The premolars are successively larger, in occlusal view, and relatively long and not crowded. The molar row is relatively slender, its width less than half the width of the palate. The first and second molars are approximately equal in size, with the third slightly smaller.

    The inferior incisors are small, tricuspid, and subequal. The canine is relatively small and straight. In occlusal view, the canine and premolars are longitudinally elongate, with the first premolar longer than the canine and about as long as the other two premolars. The molars are approximately equal in size and shape, with the first more projected labially than the other two. The last premolar and the first molar are not markedly crowded (fig. 3).

    Comparisons:

    Natalus primus is the largest of all extant Natalus, and overlaps in range of forearm length only with Natalus jamaicensis (mean forearm length, however, is significantly different between the two species; P < 0.001; table 2). Natalus primus, therefore, can be distinguished by size alone from most other species of the genus.

    Externally N. primus can be identified by its rather rounded ear tip that lacks a notch or emargination along the posterior margin of the ear, whereas in all other species of Natalus the ear tip is markedly pointed and the lateral ear margin has a notch below the ear tip. Similarly, N. primus lacks the band of dark hairs that in all other species of Natalus connects the labial mustachelike hair tufts characteristic of the genus.

    Cranially, Natalus primus is unlike any other species of Natalus in that its basisphenoid pits are very deep and steep-sided, whereas in the remaining species of the genus the basisphenoid pits are shallow. Also, in N. primus, the rostrum appears proportionately longer, relative to skull length, than in all other species of Natalus. This greater length of the rostrum in N. primus is concomitant with (1) the elongation of the premaxillary region, resulting in an anterior projection of the incisors, and (2) the position of the dorsal point of flexion of the skull, which, in lateral view, lies posterior to the anterior edge of the orbit. In all other species of Natalus, the premaxilla is not markedly elongated, so that the incisors are at or near the level of the canines, and the dorsal point of flexion of the skull, in lateral view, lies dorsal to the anterior edge of the orbit. In N. primus, the posterior edge of the ascending ramus of the mandible is not perpendicular to the basal plane of the dentary, and usually shows a distinctive notch, absent in all other species of Natalus, that is dorsal to the angular process.

    Remarks:

    Fossil Natalus collected in the western Bahamas were referred to N. major primus by Morgan (1989), but were reported by him to be noticeably larger than those of Cuba. Although it is possible that the Bahamian fossils represent a species distinct from N. primus, we refrain from excluding them from the Cuban taxon until specimens from both island groups are compared in greater detail.

    Natalus jamaicensis (Goodwin), 1959 Figures 2–4

  • Natalus major jamaicensis Goodwin, 1959.

  • Natalus stramineus jamaicensis Linares, 1971.

  • Holotype:

    AMNH 182000, skull and skin in fluid, collected by C. B. Lewis in St. Clair Cave (locality 1 in the appendix), St. Catherine Parish, Jamaica on 5 March 1954. The skull is complete, and the skin is in good condition.

    Distribution:

    Jamaica, known to be extant at the type locality only (fig. 5).

    Diagnosis:

    A relatively large representative of Greater Antillean Natalus with a long forearm (44.1–44.8 mm) relative to its skull length (17.4–18.1 mm); ear tip pointed, with a shallow notch on the outer margin of ear; point of flexion between rostrum and braincase dorsal to anterior edge of orbit; braincase rising abruptly from rostrum, with an angle greater than 60° between dorsal plane of rostrum and frontal plane of forehead; braincase rounded in dorsal profile, with breadth almost as great as length; postorbital constriction narrow, its sides almost parallel; maxillary distinctly concave above molars; one pair of small palatal fenestrae near the posterior edge of palate; basisphenoid pits shallow and almost imperceptible; posterior edge of ascending ramus of mandible straight and vertical, forming an angle close to 90° with basal plane of dentary, and lacking notch below condyloid process (tables 2, 3).

    Description:

    Natalus jamaicensis has a long forearm (44.0–47.0 mm; P < 0.001, compared to Natalus major and Natalus primus) but a relatively small skull (greatest skull length smaller than that of N. primus, P < 0.001; table 2; fig. 6). Its ears are large (20.2–21.2 mm). No significant secondary sexual dimorphism in size was found in our sample of N. jamaicensis.

    The hair of Natalus jamaicensis is long, lax, dense, and slightly woolly. The dorsal hairs are longer (9–11 mm) than the ventral hairs (6–7 mm). The dorsal hairs are bicolored, with bases lighter than tips, and the ventral hair is also slightly bicolored, with bases darker than tips. The dorsal hair bases are buff and the tips are light sepia to tawny olive. The ventral hair bases are buff and the tips are pale pinkish-buff. Dorsally, there is a faint lighter-colored band across the shoulders. The pelage extends slightly into the plagiopatagium, dorsally to 6 mm, and ventrally to 10 mm. The uropatagium is sparsely furred in microscopic view. There is a sparse fringe of hairs along the free edge of the uropatagium.

    The muzzle is long and dorsoventrally flattened. The small, oval nostrils open ventrolaterally. In ventral view, the tip of the muzzle, between the nostrils, projects slightly beyond the upper lip. The lower lip is thickened and has a shallow central groove. The ears are rather square-shaped with a straight anterior edge and a shallow notch on the distal third of the posterior margin, below the tip, giving it a pointed appearance. The ears of N. jamaicensis show rudimentary folds varying in number from five to seven.

    The skull is relatively narrow and delicate. The braincase is greatly inflated and abruptly elevated above the rostrum in an angle greater than 60°. The postparietal region is relatively wide in dorsal view, and is separated from the occipital region by a conspicuous ridge. The sagittal crest is greatly developed and, in the interparietal region, it is noticeably higher than in the supraoccipital region. The postorbital region is very narrow with nearly parallel sides. The rostrum is markedly flattened dorsoventrally, so that the orbits appear relatively narrow in lateral view. The sulcus between the nasal bones is short and shallow, being restricted to the posterior end of the rostrum. The premaxillary region does not project anteriorly, so that in lateral view the diastema between canines and incisors is not particularly noticeable. The maxillary bone is concave above the molars. The rostrum tips downward. The anterior palatal foramina are very small, and near the palatine emargination, their anterior edges lie posterior to the anterior edge of the canines. The bony palate extends more than half the distance between the posterior edge of last molars and the tip of pteryogids. The pterygoid processes are not markedly convergent, and are conspicuously hooked in lateral view. In ventral view the inner edge of each pterygoid is smooth and convex. The basisphenoid pits are very shallow, in contrast with the basisphenoid furrows, which are relatively deep.

    The dentary bone is markedly curved (upturned) and thick. The angular process is relatively short, rather straight, and with a blunt spatulate end. The coronoid process is at about the same height as the condyle above the alveolar plane. The ascending ramus is markedly upturned, being relatively tall and square-shaped, with its anterior border concave at the base and rather straight for most of its length, rising from the alveolar plane in an angle close to 90°. The posterior border of the ascending ramus rises from the base of the angular process in a nearly straight angle with the base of the dentary. The mental foramen is between the canine and the first premolar.

    The upper incisors are small and with slightly hooked tips. The inner incisors are transversally aligned with the outer ones, so that the inner incisors are not visible in lateral view. The base of the canine is robust in occlusal view, with a well-developed cingulum that is slightly longer than it is wide. In occlusal view, the premolars are successively larger, and are relatively short and crowded. The molar row is relatively thick, its width about half the width of the palate. The first and second molar are approximately equal in size, with the third slightly smaller.

    The lower incisors are small, tricuspid, and subequal. The canine is curved, relatively short, and with a well-developed cingulum. In occlusal view, the canine and the premolars are relatively short longitudinally, with the first premolar slightly shorter than the canine and the other two premolars. The first two molars are larger and wider than the third, the first more projected labially than the other two. The last premolar and the first molar are relatively crowded (fig. 3).

    Comparisons:

    The large body size (forearm length 44.0–47.0 mm) of Natalus jamaicensis readily separates this species from Natalus stramineus (35.0–41.0 mm; Tejedor et. al., 2004) and Natalus tumidirostris (37.2–41.5 mm; Tejedor, unpublished data). From Natalus primus and Natalus major, N. jamaicensis is best distinguished by discrete external and/or cranial characters because, although clearly distinct in morphometry from the former two species (as shown by our principal component analysis [PCA] results; fig. 7), N. jamaicensis overlaps in size with the other two Greater Antillean species.

    Natalus jamaicensis differs externally from Natalus primus by its pointed ear tips (rounded in N. primus), and from Natalus stramineus and Natalus tumidirostris by its straight anterior ear margin (slightly to deeply concave in the latter two species). From Natalus major and all remaining species of the genus, N. jamaicensis is best distinguished on the basis of cranial characters. Most conspicuously, N. jamaicensis shows several cranial modifications concomitant with its high degree of cranial flexion. First, in N. jamaicensis the frontal plane of the braincase rises very steeply from the rostrum, in an angle greater than 60°, a condition that is unique among species of the genus Natalus. Second, the braincase of N. jamaicensis is markedly inflated and almost as wide as it is long, hence it has an almost circular profile in dorsal view. In all other species of Natalus the braincase is longer than wider and thus appears oval-shaped. Third, the postorbital constriction of the skull of N. jamaicensis is proportionally narrower than in all other species of Natalus (mean postorbital breadth is significantly smaller than in N. major and N. primus; P < 0.001; fig. 6), with sides almost parallel in dorsal view, whereas in all other species of Natalus the sides of the postorbital constriction markedly diverge anteriorly. Also, the rostrum of N. jamaicensis is flattened dorsally to a greater degree than in other species of Natalus, and shows a marked reduction of the sulcus between nasal bones, a rather dorsal location of the infraorbital foramen, and a concave shape of the maxillary in the area dorsal to the molars. The concave maxillary bone is sufficient to diagnose N. jamaicensis because all other species of Natalus have markedly convex to markedly inflated maxillary bones.

    Remarks:

    Fossil mandibles of Natalus from Grand Cayman were described by Morgan (1994) as being smaller than any other Greater Antillean Natalus, and as having a relatively large last premolar. Morgan referred to these fossils as Natalus cf. N. major and remarked that they may represent and undescribed form. Given the geographical proximity of the Cayman Islands to Jamaica and Cuba, it is probable that either of the populations of these two larger islands may be the closest relative of the Grand Cayman Natalus. Future examination of these fossils should shed light on this question.

    NATURAL HISTORY

    The natural history of Grater Antillean bats of the genus Natalus is poorly known. Even though the differences in morphology between Greater Antillean Natalus may be related to ecological differences, as it has been found to be the case among closely related bat species (e.g., Pipistrellus, Barlow et al., 1997), the information available on their habits is scant. Therefore, we treat the three species together here. Below, we summarize the few accounts that exist on the habits of N. primus and N. jamaicensis, and include Tejedor's unpublished observations of N. major. Most of the available information concerns roosting habits.

    Natalus primus and Natalus jamaicensis are known extant from a single cave each. Natalus major has been found almost exclusively in caves, the exception being one report of nine individuals (2 females and 7 males) found roosting inside a large hollow tree in semiarid lowlands in the northern Dominican Republic (Timm and Genoways, 2003). All caves where Greater Antillean Natalus have been found are “hot caves”, caves housing large bat communities, and with poor ventilation and nearly constant high temperatures (26–40°C) and humidity (> 90%; Silva-Taboada, 1977, 1979; Rodríguez-Durán, 1998). Natalus primus and N. major, however, are rarely found in the hottest parts of hot caves, preferring better-ventilated corridors and chambers that adjoin the areas of maximum temperature (Tejedor et al., 2004; Tejedor, personal obs.). Caves where Natalus have been found often contain open bodies of water (Tejedor et al., 2004). Greater Antillean Natalus are moderately to highly gregarious with cave colonies estimated at fewer than 100 individuals (N. jamaicensis, Goodwin, 1970; N. major, Tejedor, personal obs.), to a few thousand (N. primus, Tejedor et al., 2004). All three species of Greater Antillean Natalus usually roost in close association with many other bat species that often occupy cave chambers with climatic conditions similar to those selected by Natalus: Pteronotus parnellii, Mormoops blainvillii, Brachyphylla nana, Erophylla sezekorni, Monophyllus redmani, Chilonatalus micropus, and more rarely Artibeus jamaicensis (Goodwin, 1970; Tejedor et al., 2004). Individuals of Natalus usually hang on the lower part of walls (mostly at about 1 m high) or from very low ceilings and solution cavities. In contrast, other species generally roost higher up, so that mixed groups rarely occur. As in other species of Natalidae, individuals of Greater Antillean Natalus hang from one or both feet, usually without ventral contact with the substrate, and roost regularly spaced out, keeping a distance greater than the width of one or two bats between individuals (Goodwin, 1970; Hoyt and Baker, 1980; Tejedor et al., 2004). Individuals may be alert or quiet, sometimes taking flight at the slightest sign of disturbance or allowing the extreme close proximity of the observer for a few seconds. When retreating from disturbance, the bats invariably fly extremely close to the cave walls and to the floor (at about 1 m high), sometimes in tight flocks (Goodwin, 1970; Tejedor et al., 2004). Copulation in Natalus primus has been observed to take place in April, and pregnant females of this species have been captured in May (Tejedor et al., 2004).

    Natalus major, the only Greater Antillean Natalus known to occur in more than one locality, does not seem to have any association with a particular kind of habitat. This species is found throughout Hispaniola both in dry areas (e.g., Pepillo Salcedo, locality 8 in the Gazetteer) and moist areas (e.g., La Entrada, locality 7 in the Gazetteer), spanning an annual precipitation gradient of 700– 2000 mm (Bolay, 1997). Natalus primus and Natalus major fly very slowly and are highly maneuverable. They probably forage in rather cluttered vegetation and over relatively small home ranges (Tejedor et al., 2004). Natalus primus have been found to feed mostly on moths, crickets, and beetles, and less frequently on other insect orders: Hymenoptera (Formicidae), Neuroptera, Diptera, Homoptera, and Hemiptera. As is apparently common among natalids, Greater Antillean Natalus dehydrate very rapidly when taken outside the caves where they roost (Hoyt and Baker, 1980; Tejedor et al., 2004). This propensity for dehydration, together with a slow flight, probably restricts the ability of species of Natalus for long-distance dispersal and colonization, a condition that would limit gene flow across the water gaps that separate the Greater Antilles, thus promoting the independent evolution of the genus on different islands.

    CONSERVATION

    The taxonomic changes we propose increase the recognized diversity and endemism of the West Indian bat fauna. Each of the three largest islands within the Greater Antilles hosts an endemic extant species of Natalus. By recognizing three species within what was previously treated as a single species, the range of each is reduced to a single island, which has profound implications for their conservation status. One of these species, Natalus major, is known from extant colonies from at least eight localities, and thus seems of less concern. The remaining two species, Natalus jamaicensis and Natalus primus, however, are each apparently confined to a single locality (St. Clair Cave in Jamaica and Cueva La Barca in Cuba, respectively) and thus seem highly vulnerable to extinction. Treated as Natalus stramineus, none of the three species of Greater Antillean Natalus is listed in the 2003 IUCN Red List of Threatened Species (IUCN, 2003a) or in the IUCN/SSN Chiroptera specialist action plan (IUCN/SSC Chiroptera Specialist Group, 2001). The reduced population estimates given for N. jamaicensis (Goodwin, 1970), taken together with its restricted range, puts this species in the critically endangered IUCN category (IUCN 2003b). In the case of N. primus, populations estimates are greater (Tejedor et al., 2004), but this species is known to have become extirpated throughout most of Cuba apparently beginning in the late Pleistocene and into the Holocene (Silva-Taboada, 1974, Tejedor et al., 2004), suggesting a population decline that may have continued until the present. These conditions also put N. primus in the critically endangered IUCN category (IUCN, 2003b).

    Because of their specialized roosting requirements, species of Natalidae seem more dependent on caves for survival than on other ecological factors (Emmons, 1997; Tejedor et al., 2004; Timm and Genoways, 2003). Given their limited potential of dispersal (Silva-Taboada, 1979; Tejedor et al., 2004), the destruction of roost sites by erosion throughout geologic history may be responsible for the high number of extirpated populations of natalids in the West Indies (Morgan, 2001; Tejedor et al., 2004). Current anthropogenic disturbance of roost sites, found to be highly threatening to cave-bat species worldwide (Kunz and Pierson, 1994), may also imperil species of Natalus.

    Of the three species of Natalus in the Greater Antilles, Natalus jamaicensis, considered the rarest of Jamaican bats (Goodwin, 1970; McFarlane, 1986), seems to be in the most dire situation. Its only known roost site, St. Clair Cave, has resident populations of feral domestic cats that feed on the bats (species not specified) and rats of the cave (McFarlane, 1997). Domestic cats are known to be highly effective predators of bats (e.g., Myotis, Barbour and Davis, 1969; Mystacina, Daniel,1985; Phyllonycteris, Tejedor and Tavares, personal obs.), and if they feed on the Natalus of St. Clair their effect on its population could be considerable. Moreover, given the habit of Natalus species of roosting low on wall surfaces, they may be more vulnerable to cave cats than other bats. Unfortunately, with the exception of Windsor Great Cave in the Jamaican Cockpit Country, no other cave in Jamaica, including St. Clair Cave, receives any form of official protection (Dávalos and Eriksson, 2003).

    Natalus primus may also face grave threats in the near future, when Cueva La Barca (thus far protected by its remoteness in Guanahacabibes Peninsula) becomes more accessible as Cuba opens its remote areas to tourism (Díaz-Brisquets and Pérez-López, 2000). The protection of Cueva La Barca is important not only because it harbors the only known colony of N. primus, but also because its cave life is the most diverse in Cuba (Armas et al., 1989). The impact of its rich bat fauna on the ecology of the Guanahacabibes deciduous forest, the largest of its kind in Cuba (Dinerstein et al., 1995), must be considerable, thus potentially placing a whole ecosystem at risk if the cave is overdeveloped.

    The fact that Natalus major is known from more localities than the other two Greater Antillean Natalus does not mean that this species is adequately protected. Practices highly disturbing to cave biota, such as intensive guano extraction and cave modification for tourist use (Silva-Taboada, 1979; Trajano, 2000), are widespread in the Dominican Republic (K. Christenson, personal commun.; Tejedor, personal obs.). Unless these activities become controlled and directed to areas of least importance for the survival of cave-bat colonies, their long-term practice can deteriorate the future conservation status of N. major.

    The reduced geographic range and low population numbers of Natalus species in the Greater Antilles makes these bats highly vulnerable to extinction. Programs of population status assessment and monitoring are urgently needed to ensure that these unique West Indian endemic species do not become extinct as a consequence of human activity.

    Acknowledgments

    For welcoming A. Tejedor into their homes and offering their direct participation during fieldwork in the Dominican Republic, we are indebted to Eunice Rodríguez, to Miqueas, Margarita, Japo, and Ray (from La Entrada de Cabrera), and to Paulino (from San Miguel, Cotuí). For kindly allowing us access to specimens of Natalus in the museum collections under their care, we thank Paula Jenkins and Richard Harbord (BMNH); Renato Gregorin (DZSJRP); Bruce D. Patterson and Minh-Tho Schulenberg (FMNH); Thorvald Holmes (KU); Robert Fisher, Linda Gordon and Helen Kafka (USNM).

    Norberto Giannini kindly helped with statistical analyses. Keith Christenson offered information on collecting localities in the Dominican Republic and provided unpublished observations. Fieldwork permits for the Dominican Republic, issued to Liliana Dávalos, were obtained with the help of Renato Rímoli and Gloria Santana Zorrilla. Critical readings by Robert P. Anderson, Liliana M. Dávalos, Gary S. Morgan, and Nancy B. Simmons resulted in the significant improvement of earlier versions of the manuscript. This study was supported by the American Museum of Natural History (Department of Mammalogy, Office of Grants and Fellowships, and a Theodore Roosevelt Research Grant), an Ernst Mayr Research Travel Grant (Museum of Comparative Zoology, Harvard University), the Sue Rosenberg-Zalk Travel and Research Fund (City University of New York), an Exploration Grant (Explorer's Club) to Liliana Dávalos, and by Theodore H. Fleming.

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    Appendices

    APPENDIX

    Gazetteer and Specimens Examined

    The gazetteer below provides locality information for all specimens of Greater Antillean Natalus examined by us or reported in literature known to us. Collection localities are listed by country: italic type identifies secondary political units (states, provinces, etc.) and boldface identifies locality names as cited in the text. Latitude and longitude, obtained from original published references or the United States Office of Geography (USOG 1963) and the United States Defense Mapping Agency (USDMA 1972, 1973) are given in parentheses, followed by supplementary information (when available) including museum catalog number, sex of specimen, and the earliest published reference to each specimen. Specimens measured are in boldface. Locality numbers refer to figure 5.

    The following institutional abbreviations are used: AMNH, American Museum of Natural History, New York, New York, USA; BMNH, The Natural History Museum, London, the United Kingdom; DZSJRP, Department of Zoology, Universidade Estadual Paulista, São José do Rio Preto, Brazil; FLMNH, Florida Museum of Natural History, Gainesville, Florida, USA; FMNH, Field Museum, Chicago, Illinois, USA; IES, Instituto de Ecología y Sistemática, Havana, Cuba; JI, Jamaica Institute, Kingston, Jamaica; ISEZ, Institute of Systematic and Experimental Zoology, Krakow, Poland; KU, University of Kansas Natural History Museum, Lawrence, Kansas, USA; MBML, Museu de Biologia Mello-Leitão, Santa Teresa, Espirito Santo, Brazil; MCZ, Museum of Comparative Zoology, Cambridge, Massachusetts, USA; MNHN, Museo Nacional de Historia Natural, Havana, Cuba; ROM, Royal Ontario Museum, Toronto, Ontario, Canada; USNM, National Museum of Natural History (Smithsonian), Washington, DC, USA.

    Gazetteer

    Natalus jamaicensis

    JAMAICA

    St. Catherine Parish

    • 1. St. Clair Cave, Linstead (18°07′N, 77°01′W). AMNH 181999, 182000 (holotype), 214131, 246123, 246126–246128, 271575, 271576 (8 males, 1 female); FLMNH 13688–13692 (3 males, 2 females); FMNH 93784 (female); BMNH 65.4000a, 65.4000b; JI No. 3, JI No. 4, Goodwin (1959); ROM 37029, 37065–37076 (4 females).

    St. Elizabeth Parish

    Natalus major

    DOMINICAN REPUBLIC

    Barahona

    • 3. Los Patos (17°58′N, 71°10′W). AMNH 97590 (male).

    • 4. Maniel Viejo (17°58′N, 71°19′W, 278 m). AMNH 97589 (female).

    Elias Piña

    • 5. Cerro de San Francisco, Bánica (19°04′N, 71°42′W). FLMNH (fossil), Morgan (2001).

    Independencia

    • 6. Puerto Escondido (18°19′N, 71°34′W), 9.9 km S, North slope Sierra de Bahoruco. USNM 542274 (female, mummy).

    María Trinidad Sánchez

    • 7. Cueva de Murciélagos, Entrada (19°33′N, 69°54′W), Cabrera. AMNH 238148, 238149 (2 females); (AMNH, 4 males, 1 female) AT 44, 45, 49, 51, 52 (field numbers).

    Montecristi

    • 8. Pepillo Salcedo (19°42′N, 71°45′W), 5 km SE. KU 150713–20, KU 152361 (7 males, 2 females), Timm and Genoways (2003).

    Sánchez Ramírez

    • 9. Cueva Grande de Julián, Don Miguel, 4 km E Platanal (19°07′N, 70°05′W). (AMNH, field numbers) AT 70 (female), AT 77 (male).

    Santiago

    • 10. Savaneta (possibly Sabaneta [19°40′N, 70°22′W] “near the north coast”; see Timm and Genoways 2003). USNM 101395a (male, holotype), 101395b (female, paratype), Miller (1902).

    • unknown locality FLMNH 5517 (male); USNM 49362, 96496, Goodwin (1959).

    HAITI

    Departement du L'Ouest

    • 11. Port-au-Prince (18°34′N, 72°17′W). BM (1 specimen, unspecified), Sanborn (1941).

    Departement du Sud

    TURKS AND CAICOS

    Grand Caicos

    Natalus cf. N. major

    CAYMAN ISLANDS

    Grand Cayman

    • 14. Bodden Cave, Bodden Town (19°16′N, 81°15′W). FLMNH (fossil), Morgan (1994).

    Natalus primus

    THE BAHAMAS

    Abaco

    Andros

    • 16. Coleby Bay Cave, Morgans Bluff (25°10′N, 78°02′W). FLMNH 79324 (fossil), Morgan (1989).

    • 17. King Cave, Morgans Bluff (25°10′N, 78°02′W). FLMNH 79110 (fossil), Morgan (1989).

    New Providence

    • 18. Banana Hole (25°01′N, 77°33′W). FLMNH 79986–79990 (fossils), Morgan (1989).

    • 19. Hunts Cave (25°02′N, 77°22′W). FLMNH 27694, 79751–79759, 79761–79766, 79843– 79848 (fossils), Morgan (1989).

    CUBA

    Camagüey

    • 20. Cueva de los Portales de Pinto, Jaronú (21°48′N, 77°57′W), Esmeralda. MCZ (fossil), Koopman and Ruibal (1955).

    • 21. Cueva del Círculo, Cairije (21°36′N, 77°40′W), Tomás Betancourt. IES (fossil), Silva-Taboada (1979).

    Cienfuegos

    • 22. Cueva de la Macha [= Cueva de los Machos, Cueva de Vilches], Cantera de San Antón, Soledad (22°07′N, 80°19′W). AMNH (fossil), Goodwin (1959).

    Isla de la Juventud

    • 23. Cueva del Abuelo, Sierra de Caballos (21°52′N, 82°46′W). IES (fossil), Silva-Taboada (1979).

    Matanzas

    • 24. Cueva de la Eloísa, Bellamar (23°01′N, 81°33′W), Guanábana. IES (fossil), Silva-Taboada (1979).

    Pinar del Rio

    1. 25. Cueva La Barca, 20 km E of Cabo de San Antonio (21°50′N, 84°56′W), Guanahacabibes Peninsula, Manuel Lazo. MNHN 1–26 G. Silva-Taboada field numbers (male), 27–51 G. Silva-Taboada field numbers (female), Tejedor et al. (2004). FLMNH 26810 (female).

    Sancti Spiritus

    Santiago de Cuba

    • 28. Cueva de la Cantera, Siboney (19°57′N, 75°42′W), Damayajabo. IES (fossil), Silva-Taboada (1979).

    • 29. Cueva de Los Indios, Daiquirí (19°55′N, 75°39′W), AMNH 41009 (fossil, holotype), Anthony (1919).

    Other Specimens Examined

    Natalus stramineusAntigua and Barbuda, Antigua (2): BMNH 18.4.1.1, 18.4.1.4. Belize (5) FLMNH 9844, 9845, 9847; FMNH 121072, 121073. Bolivia (1): DZSJRP 14507. Brazil (16): DZSJRP 12118, 12124, 12125, 12251, 12261, 12265, 16748, 16750, 16751; MBML 1801 (holotype of Natalus espiritosantensis); USNM 242828, 242829, 245517, 536442, 555711, 242830 (holotype of Natalus stramineus natalensis), 549504. British Virgin Islands, Anguilla (3): AMNH 72368, 72369; USNM 544834. Dominica (10): USNM 62850, 361906–361908, 362100–362104. Costa Rica (1): USNM 566451. Guatemala (2): FMNH 64809, 64810. Mexico (20): AMNH 147903– 147911, 171570–171580; KU 23815 (holotype of Natalus stramineus saturatus); USNM 96496 (holotype of Natalus mexicanus) Panama (8): USNM 319065–319072. Unknown locality (1): BMNH 70.2324 (holotype of Natalus stramineus)

    Natalus tumidirostrisColombia (2): AMNH 183854, 183855. Netherlands Antilles, Curaçao (1): USNM 102106 (holotype Natalus tumidirostris). Trinidad and Tobago (12): AMNH 176587–176589, 176590 (holotype Natalus tumidirostris haymani), 176591–176598. Venezuela (6): BMNH (1) 5.11/12.25 (holotype Phodotes tumidirostris continentis); USNM 405774–405778.

     Fig. 1. 

    Lateral view of the skull of three species of Greater Antillean bats of the genus Natalus: A, N. primus (Cuba; MNHN 51, field number); B, N. major (Hispaniola; AMNH AT 51, field number); C, N. jamaicensis (Jamaica; AMNH 246127)

    i0003-0082-3493-1-1-f01.gif

     Fig. 2. 

    Dorsal and ventral views of the skull of three species of Greater Antillean Natalus. A, Natalus primus (MNHN 51, field number); B, Natalus major (AMNH AT 51, field number); C, Natalus jamaicensis (AMNH 246127)

    i0003-0082-3493-1-1-f02.gif

     Fig. 3. 

    Dorsal view of the right mandibular ramus of three species of Greater Antillean Natalus. A, Natalus primus, B, Natalus major, C, Natalus jamaicensis

    i0003-0082-3493-1-1-f03.gif

     Fig. 4. 

    Photograph of an adult male Natalus major (showing a bright yellowish pelage) captured in Cueva Grande de Julián, Sánchez Ramírez province, Dominican Republic, in January 2002. Photograph by A. Tejedor

    i0003-0082-3493-1-1-f04.jpg

     Fig. 5. 

    The Greater Antilles (excluding Puerto Rico) and adjacent archipelagoes, showing collection localities for bats of the genus Natalus. Symbols: (▪) Natalus major, extant; (□) Natalus major, fossil; (•) Natalus primus, extant; (○) Natalus primus, fossil; (▴) Natalus jamaicensis, extant; (▵) Natalus jamaicensis, fossil; (×) Natalus cf. Natalus major. Numbers correspond to localities in the Gazetteer. Stippled areas show land above 600 m

    i0003-0082-3493-1-1-f05.gif

     Fig. 6. 

    Plot of observed arithmetic mean (dots), one standard deviation on each side of the mean (vertical rectangles), and one standard error on each side of the mean (vertical line) for one external and five cranial dimensions of Greater Antillean Natalus. Males and females are plotted separately. Np: Natalus primus; Nm: Natalus major; Nj: Natalus jamaicensis. * = statistically significant difference (P ≤ 0.01) detected by an ANOVA within the whole sample (if following a measurement) or among male-only samples (if following the word “males”). See text for results of pair-wise Tukey's comparisons

    i0003-0082-3493-1-1-f06.gif

     Fig. 7. 

    Plot of specimen scores on the first two axis of the principal component analysis (PCA) based on forearm length and five variables of cranial dimensions of Greater Antillean Natalus. Breadth across molars had the greatest loading on axis PCI, increasing from the negative to the positive end of the axis. Zygomatic breadth had the greatest loading on axis PCII, increasing from the negative to the positive end of the axis. (○) Natalus major, (▴) Natalus jamaicensis, (▪) Natalus primus

    i0003-0082-3493-1-1-f07.gif

    TABLE 1

    Diagnostic Characters of Greater Antillean Species of the Genus Natalus

    i0003-0082-3493-1-1-t01.gif

    TABLE 2

    Summary of Measurementsa of Greater Antillean Natalus

    i0003-0082-3493-1-1-t02.gif
    ADRIAN TEJEDOR, VALERIA DA C. TAVARES, and GILBERTO SILVA-TABOADA "A Revision of Extant Greater Antillean Bats of the Genus Natalus," American Museum Novitates 2005(3493), 1-22, (27 October 2005). https://doi.org/10.1206/0003-0082(2005)493[0001:AROEGA]2.0.CO;2
    Published: 27 October 2005
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