The sweetpotato whitefly, Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae), is one of the most damaging, polyphagous insect pests of agricultural cropping systems around the world. Insecticide control is one of the main tactics used to mitigate damage and crop injury caused by the species. Similarly, plant chemical defenses are primary natural mechanisms that reduce attacks from whiteflies. Like all Sternorrhyncha insects, whiteflies have piercing/sucking mouthparts and feed on phloem sap from vascular plants through a stylet. Therefore, if this insect can overcome the physical barriers of the plant and pierce the vascular bundle, the main remaining barriers to nutrition uptake and utilization are phytochemicals that might exhibit some degree of toxicity toward the insect. Bemisia tabaci has been reported to feed on over 1,000 plant species representing an enormous range of phytochemicals to which whiteflies are potentially exposed. Recently, whiteflies were shown to have acquired a gene from plants to detoxify the plant's phenolic glycosides that are usually toxic. Additionally, host plants have been shown to alter the response of a single whitefly population to insecticides. Herein, we review possible interactions between the highly polyphagous B. tabaci, the potential phytochemicals associated with its extensive plant host range, and the main chemical insecticides used to control this pest. This review aims to provide a conceptual framework for studying possible biological interactions between the insect, host plant, and insecticidal toxins used to control this pest at the mechanistic and population selection levels.

Flowering plants and pollinators are in a mutualistic association, where pollinators collect floral resources and plants receive pollination services. Bees and other pollinators are declining in many parts of the world, and their loss affects the functional composition of fauna, flora, and habitats. Different strategies are being deployed to improve pollinator services, including the management of bees. Sustainable management of a bee species strongly depends on floral resource availability. Therefore, beekeepers need to have adequate knowledge about the surrounding vegetation (especially nectar and pollen sources for the bee species). Diverse methodologies are used around the world to determine floral resources for bees. Field surveys and pollen analysis of honey, corbicular/scopal pollen loads, residual pollens in brood cells, forager's body surface pollen content, and internal organs (gut, intestine, crop, etc.) were used by the researchers. For pollen identification, most researchers carried out microscopy-based methods. However, pollen DNA-based methods were also used by researchers in recent years. Regarding the morphology-based identification, most researchers processed pollen samples according to Erdtman's acetolysis method to increase the visibility of diagnostic characteristics of the pollen grains. The method specified by the International Commission for Bee Botany was used to conduct qualitative and quantitative pollen analysis on honey samples. For quantitative pollen load analysis, researchers used numerous techniques that may have been the most effective. Our discussion about the different techniques utilized to determine floral resources of a bee species will be helpful for researchers in selecting a suitable protocol and may assist in developing superior methodologies.

Graphical Abstract

Wasmannia auropunctata (Roger) is an invasive tramp ant species that has been transported globally since [at least] the early twentieth century. It is often claimed that despite the negative impacts associated with this species and its listing among the world's worst invasive species, very little research attention has been paid to W. auropuntata. Although the need for future research exists, there is currently a considerable body of research from around the world and spanning back to the 1920's on this species. Here we synthesize over 200 peer reviewed research manuscripts, book chapters, conference presentations, and media reports of new distributions spanning 1929–2022 culminating in a comprehensive literature review on W. auropunctata. This review covers all current knowledge on this species and is intended to serve as a quick reference for future research and provide the reference resources for those seeking more in-depth information on specific topics. Topics included in this review include taxonomic identification, current global distribution and pathways, life history, impacts, detection, and control. We discuss where consensus and ambiguity currently lie within the research community, identify contextual considerations for future researchers when interpreting data, and suggest where we believe more research or clarifications are needed.

Gap junctions are integral membrane proteins that play a role in cell-to-cell communication. They are coded by the functional genes called connexins in chordates and innexins in invertebrates. However, recently pannexins were also found in mammalian genomes, which are homologous to insect innexins. Gap junction intercellular communication (GJIC) has different functions ranging from their role in ontogenesis to the transfer of intracellular signal molecules and minimizing the adverse effects of xenobiotics by dilution and steady-state catabolism. Perturbations of these gap junctions are known to promote cancers besides, and many tumor inducers reduce the functioning of these gap junctions. Insect gap junctions play a crucial role in the development of insects and perhaps might be one of the reasons for the success of insects on terrestrial habitats. Majority of the work on innexins was done on Drosophila melanogaster Meigen, 1830 (Diptera: Drosophilidae), and its innexins regulate size of the central nervous system, embryonic gut formation, metamorphosis, and the fertility of germ lines in the reproductive system. There are several insecticides like cyclodienes, organochlorines, phenypyrazoles, synthetic pyrethroids, avermectins, milbemycins, oxadiazines, semicarbazones, metadiamides, isoxazolines which target ion channels in the insects, but there is no evidence that supports the possible toxic effects of insecticides on insect gap junctions. In this review, we discuss the importance of insect gap junctions and how they could be a potential target for chemical pest management.

High-speed microcinematography was used to elucidate the details of prey capture by the larvae of three predatory mosquito species. The obligate predators Toxorhynchites amboinensis and Psorophora ciliata exhibited a high degree of convergence as both utilize three essential elements: 1) abdominally-generated hemostatic pressure to propel the head towards the prey; 2) lateral palatal brushes (LPB) opening and fanning into anterior-directed basket-like arrangements; 3) simultaneously with the LPB-basket formation, the wide opening of sharp-toothed mandibles. Thus, LPBs and mandibles are used for prey capture by both species. The facultative predator Sabethes cyaneus utilizes a vastly different prey-capture mechanism that involves ventro-lateral body arching and scooping of prey with axially pointed siphons into the grasp of open maxillae bearing elongate apical teeth. Prey consumption, which is typically incomplete in this species, then involves the action of teeth on the mandibles which cut into the held prey. Although prey consumption is incomplete, simple experiments show that Sa. cyaneus do gain nutritionally from consuming mosquito larvae and that they do discriminate heterospecific from conspecific larvae and actively approach heterospecific mosquito prey. These findings indicate that independent evolutionary pathways have produced diverse predatory behaviors and morphologies in aquatic environments where the immature stages of mosquitoes co-occur.

Here, I provide data from a longitudinal survey that suggests that male entomology doctoral graduates are more successful at getting scientific positions than female graduates are. I digitally followed over 800 male and female doctorates graduating between 2001 and 2018 over several years to determine occupational outcomes. Males significantly outnumber females in industry positions, and occupy more academic positions and government jobs than females. Males may get a head start in employment by publishing significantly more scientific papers during their graduate programs than do females, setting them up to be more competitive. Once hired into academia, males appear to continue this publication pattern, obtaining significantly higher H-indices than female academic colleagues later in their careers, which may play a role in being promoted more quickly than females. Males are also favored by institutions at which they previously interned: Males working as postdoctoral scientists in USDA labs end up being hired into significantly more permanent jobs at USDA than females who also were postdocs at USDA. Another important result of the research is the finding that the majority of both genders undergo postdoctoral training, but fewer than 25% of entomology postdocs get academic positions, demonstrating the bleak outlook of the academic job market.