The ability to disperse is vital for all organisms, but especially for those whose habitats deteriorate, necessitating relocation to better feeding or breeding sites. Phoresy is assisted dispersal in which one organism uses another as its vehicle. In this review, phoresy will be largely restricted to cases wherein the rider is not parasitic on the vehicular stage used for dispersal, and in which insects are riders or rides. Phoresy occurs in organisms with limited mobility, and in secondarily brachypterous or completely wingless insects. Intraspecific phoresy also occurs. Generally, immature stages resistant to environmental assaults, such as dauers in nematodes, triungulins in beetles, or deutonymphs in mites, undertake phoresy. A size differential between rider and rider enables several conspecifics to board the same vehicle, likely ensuring mating opportunities at the destination. Riders may have special attachment devices or adhesive secretions to ensure safety during travel. Life cycles of riders and vehicles are often synchronized, and when phoresy is mutualistic, vehicles may also employ chemical tactics to achieve this synchrony. Chemical cues help to identify the appropriate vehicle, for disembarkation, or to lure the vehicle towards riders. Most riders prefer female vehicles, possibly to ensure access to rich nesting sites. Density-dependent selection may operate to limit the number of riders on a vehicle and phoresy may also facilitate sexual selection among riders. Whether vehicles can avoid phoresy is barely understood. This review attempts to place phoresy within a broad evolutionary context and points out the paucity of knowledge in certain research areas.

Wasps of the genus Bembix (Fabricius) have enjoyed over 300 years as subjects of interest to entomologists and ethologists due to their large size and repertoire of dramatic nesting behaviors. This research history began with these wasps as the focus of brief behavioral accounts, which developed over time to yield detailed studies of the habits of individual species, as well as comparative studies of behavior. This work has revealed that Bembix is behaviorally diverse, with most aspects of their nesting habits showing variation both within and between species. Ultimately, this research history has made Bembix one of the best-known groups of solitary aculeate wasps. At the same time, much work remains to be done on Bembix. While the genus' behavioral diversity is well-recognized, it has not nearly been fully characterized, with the majority of Bembix species remaining unstudied in the field. Furthermore, no phylogeny has ever been published for the genus, and its evolutionary and biogeographic history remains essentially unknown. Thus, this review presents an overview of historical and biological information on Bembix with the aim of stimulating further work on this behaviorally diverse genus.

Insect infestations can result in a damaged or destroyed product, costing producers and retailers millions of dollars annually. Postharvest insects move through space searching for mates, food, and shelter. Movement of product, sanitation activities, and insecticide applications also drive their spatial distribution patterns. Determining spatial distributions and population density of insects provides important information to develop targeted and cost-effective management programs. Monitoring data collected using traps to capture insect pests have provided information under a range of conditions: in bins of grain, grain elevator silos and their immediate environment, milling and processing facilities, commercial warehouses, and retail stores. In evaluating available data, we identified key influences that may be leveraged to increase the impacts of future monitoring schemes. Species-specific locations of infestation were common among stored product insect pests and seasonal variation was highly influential in population growth patterns. Competition among different species also drives spatial and temporal distributions and overlap among species is rare. Vertical distribution of insects was common in bins, elevators, and silos. More insects were often found in the receiving and storage areas of mills and processing facilities and insects often migrated into facilities from surrounding natural reservoirs. Previously stored grain and spillage can also harbor insect populations, which also reinforces the need for sanitation in and around stored grain products. Continued monitoring research will provide information to develop predictive tools which will use behavioral patterns to further our understanding of these insect pests within these unique facilities and circumstances.

The Mexican lepidopteran fauna is particularly diverse, but many moth groups remain poorly documented. The tribe Arctiini is a species-rich group that has been used as a reliable indicator of environmental change. However, little is known about the fauna of the tribe Arctiini in Mexico, and there is no exhaustive review of its diversity and distribution patterns. Our aims were: 1) to account for the species diversity and distribution patterns of the tribe Arctiini; 2) to build spatial distributions and discuss possible changes in the distribution areas of the tribe Arctiini using conservative (RCP 2.6) and liberal (RCP 8.5) future climate scenarios; and 3) to discuss the conservation implications for key taxa that due to their life history characteristics and restricted distribution, might require particular conservation actions. We compiled a total of 16,385 records and 548 species in seven subtribes. Diversity profiles revealed higher cumulative species richness and diversity for the subtribes Phaegopterina, Ctenuchina, and Euchromiina, and we identified a pattern of decreasing species diversity with elevation. In addition, we estimated that 35% and 84% of modeled species in future conservative and liberal climatic scenarios, respectively, would result in significant losses of climatic suitability and shifts in spatial distribution. The endemic species, Virbia semirosea, Poliopastea jalapensis, and Pygoctenucha azteca would likely reduce their distribution by approximately 50% in both climatic scenarios. Maintaining a network of highly threatened habitats (e.g., cloud forests, tropical rain forests) will be essential to preserve persisting species populations and to increase likely (re)colonization events.

Due to the increase in global transport in recent decades, species that flourish in human-altered environments are widening their geographical distribution. Consequently, endemic species are either declining or going to extinction. Here, we report the first occurrence of the Afrotropical fly Zaprionus tuberculatus Malloch in the Americas. This species has been recognized as invasive by the Invasive Species Compendium, and we argue that it will probably impact drosophilid communities. Our study was conducted on the natural and urban environments of the Brazilian Savanna, a biodiversity hotspot where drosophilid communities have been monitored since 1999. Z. tuberculatus was first collected in January 2020, at low abundances, in urban parks located in Brasília. In December 2020, we recorded it in a preserved area approximately 200 km away from the urban parks. From January to March 2021, we found the species in seven urban parks in Brasília and three natural reserves (conservation units) located around the city. The species' relative abundance increased from 0.9% in 2020 (n = 11,244 drosophilids) to 17% in 2021 (n = 6,002 drosophilids). This is a rare opportunity to monitor a recent invasion event in a well-studied area. Based on the impact of Z. indianus Gupta, which invaded the Brazilian Savanna in 1999 and remained the dominant species during the rainy seasons, we fear that this new arrival will reduce the diversity of drosophilids in the Neotropics.

Auchenorrhyncha (Hemiptera) includes several families of sap-feeding insects that tend to feed on a wide-range of host plants. Some species within Auchenorrhyncha are major agricultural pests that transmit plant pathogens or cause direct feeding damage. Nearly all pest Auchenorrhyncha are highly polyphagous, have mobile nymphs, and colonize crops from noncrop habitats. We examined whether methods for gut content analysis developed for more specialized Hemiptera identify dietary history of polyphagous Auchenorrhyncha. We used high-throughput sequencing of the plant genes trnF and ITS to examine the dietary history of Circulifer tenellus (Baker) (Cicadellidae), Colladonus geminatus (Van Duzee) (Cicadellidae), Colladonus montanus reductus (Van Duzee) (Cicadellidae), and Lycorma delicatula (White) (Fulgoridae). C. tenellus is a vector of the vegetable pathogens Candidatus Phytoplasma trifolii and beat curly top virus. Both Colladonus species are vectors of Ca. Phytoplasma pruni, the pathogen associated with X-disease of stone fruits. Lycorma delicatula is an invasive pest of grape and ornamentals in the eastern United States. Results showed spring hosts for C. tenellus included Brassicaceae, especially Sisymbrium sp. (tumble mustard), and spring hosts for both Colladonus species included Taraxacum sp. (dandelion). Gut content analysis also detected a decrease in host-breadth by L. delicatula from early to late instars. Results demonstrate that directed sequencing of plant DNA identified the dietary history of leafhopper and planthopper pests. Expanded use of gut content analysis will help identify the noncrop sources of phytoplasma-infected C. tenellus and Colladonus, and to examine seasonal changes in host shifts by L. delicatula.

Species of Liriomyza Mik (Diptera: Agromyzidae) occur worldwide and are economically important leafminers. However, populations of some pest species, although very similar morphologically, show highly divergent mtDNA sequences, suggesting that nominal species are in fact complexes of cryptic species. This study focuses on two globally invasive pests, L. huidobrensis (Blanchard) and L. sativae Blanchard, already known to be highly destructive in Brazilian crops, although only a few studies on morphological and genetic divergences of them have been made. A total of 63 sequences of the mitochondrial cytochrome oxidase I (COI) and cytochrome oxidase II (COII) from Brazilian populations of L. huidobrensis and L. sativae collected from six crops (gypsophila, chrysanthemum, melon, watermelon, tomato, and onion) in Northeastern Brazil were generated to investigate their genetic structure together with available sequences from the Americas, Europe, Asia, Africa, and Australia. Genetic structure was not found to be correlated to neither host plant nor geographical locality. Liriomyza huidobrensis showed an overall low intraspecific global genetic divergence in both genes. On the other hand, high intraspecific divergences for L. sativae and its phylogenetic position confirm a divergent clade currently found only in Brazil and suggest it may be a global complex of cryptic species. Considering the possibility of cryptic species (in the latter case), we provided detailed redescriptions of these Brazilian populations for future studies and local management of these global pests. Finally, our results also revealed a new synonym herein proposed, L. strigosa Spencer as a junior synonym of L. huidobrensis.

Mitochondrial genomes (mitogenomes) advance our understanding of molecular evolution and phylogenetic relationships. In this study, the mitogenome of Mamestra configurata was assembled, annotated, and analyzed. The total length of its genome was 15,322 bp; the A+T content accounted for 81.2%. Both the AT and GC skew values (–0.003 and –0.182) in the mitogenome of M. configurata were negative. Compared with their ancestral insects (trnI-trnQ-trnM), the gene sequence showed a typical trnm rearrangement (trnM-trnI-trnQ). Except for cox1, all the protein-coding genes were initiated with ATN. All tRNAs except trnS1 were of the four-leaf grass type. According to phylogenetic analysis, we found that M. configurata and Protegira songi clustered together in one clade with high node support values. Based on Bayesian inference and maximum likelihood methods, the phylogenetic results revealed that M. configurata was closely related to Protegira songi, the Erebidae was sister to (Nolidae + [Euteliidae + Noctuidae]), Doidae and Notodontidae is sister to the other families of Noctuoidea, respectively. Our results may provide a useful reference for the intensive study of the phylogeny of Noctuidae.

The ventral surfaces of tarsi in spiders in the infraorder Mygalomorphae group play a key role in locomotion and burrow and nest construction. In our research, we analyzed the diversity of setae and patterns of sculpturing on tarsi in three species with different life strategies: a burrowing spider Brachypelma smithi (F. O. Pickard-Cambridge, 1897), a ground-dwelling spider, Pterinochilus murinus Pocock, 1897, and a arboreal spider, Poecilotheria regalis Pocock, 1899. We showed the presence of three types of setae on the ventral side of tarsi: plumose setae, short-haired spiniform setae, and spirally striated setae. Plumose setae were differentiated within a tarsus and their apical sections among the studied species, while the microtriched ensiform and spirally striated setae did not differ. All setae were characterized by a similar structure. Little differentiation was observed in the number and location of setae on the tarsi of the studied species. Spirally striated setae were absent in the burrowing spiders. In contrast, the shape and size of the sculpturing pattern varied among the studied species. The greatest differentiation was found in the burrowing and ground-dwelling spiders, while the smallest differentiation was found in the arboreal spider. We discuss our findings in relation to preferred habitats, the biology of the spiders, and adaptation of sculpturing and setae on spider feet to surface type. The morphology and diversity of setae and sculpturing patterns on the ventral side of tarsi in P. murinus was reported for the first time.