Abstract
Brain plasticity is widespread in nature, as it enables adaptive responses to sensory demands associated with novel stimuli, environmental changes and social conditions. Social Hymenoptera are particularly well-suited to study neuroplasticity, because the division of labor amongst females and the different life histories of males and females are associated with specific sensory needs. Here, we take advantage of the social waspPolistes dominulato explore if brain plasticity is influenced by caste and sex, and the exploitation by the strepsipteran parasiteXenos vesparum.Within sexes, male wasps had proportionally larger optic lobes, while females had larger antennal lobes, which is consistent with the sensory needs of sex-specific life histories. Within castes, reproductive females had larger mushroom body calyces, as predicted by their sensory needs for extensive within-colony interactions and winter aggregations, than workers who frequently forage for nest material and prey. Parasites had different effects on female and male hosts. Contrary to our predictions, female workers were castrated and behaviorally manipulated by female or male parasites, but only showed moderate differences in brain tissue allocation compared to non-parasitized workers. Parasitized males maintained their reproductive apparatus and sexual behavior. However, they had smaller brains and larger sensory brain regions than non-parasitized males. Our findings confirm that caste and sex mediate brain plasticity inP. dominula, and that parasitic manipulation drives differential allocation of brain regions depending on host sex.
Highlights
Brain plasticity enables adaptive responses to different sensory demands such as novel stimuli, changing environments and social conditions (Taborsky and Oliveira, 2012; O’Donnell et al, 2013; Anderson and Finlay, 2014; Kamhi et al, 2017; Jernigan et al, 2021)
Reproductive females had larger calyces compared to worker females, reflecting sensory needs associated with division of labor
We provide novel evidence for the effect of the Xenos vesparum parasite in neural investment by female and male hosts
Summary
Brain plasticity enables adaptive responses to different sensory demands such as novel stimuli, changing environments and social conditions (Taborsky and Oliveira, 2012; O’Donnell et al, 2013; Anderson and Finlay, 2014; Kamhi et al, 2017; Jernigan et al, 2021). Visual input travels from the eyes and is received and processed by the optic lobes, while olfactory input is received by the antennal lobes (Strausfeld, 1989; Anton and Homberg, 1999; Gronenberg and Hölldobler, 1999). From these lower-order sensory neuropils, projection neurons convey the computed information to the mushroom bodies (Akalal et al, 2006). In these higherorder brain centers, the chemical and visual information is further processed and integrated with internal information by intrinsic neurons and projected to premotor areas. The central complex is implicated in spatial navigation (Pfeiffer and Homberg, 2014; Honkanen et al, 2019; Le Moël et al, 2019)
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