The brain atlas of a subsocial bee reflects that of eusocial Hymenoptera

The evolutionary transition from solitary life to group‐living in a society with cooperative brood care, reproductive division of labor and morphological castes is associated with increased cognitive demands for task‐specialization. Associated with these demands, the brains of eusocial Hymenoptera d...

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Bibliographic Details
Published in:Genes, brain and behavior brain and behavior, 2024-12, Vol.23 (6), p.e70007-n/a
Main Authors: Pyenson, Benjamin C., Huisken, Jesse L., Gupta, Nandini, Rehan, Sandra M.
Format: Article
Language:English
Subjects:
Animals
Bees - genetics
Biological Evolution
Brain
Brain - metabolism
Brain architecture
brain evolution
Brood care
Castes
cell type evolution
Ceratina calcarata
Diapause
Division of labor
Gene expression
Glial cells
Hymenoptera
Insects
Neuroglia - metabolism
Neuronal-glial interactions
Neurons - metabolism
neurotransmitters
Original
single cell
Social Behavior
sociality
Transcriptome
Transcriptomics
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Summary:The evolutionary transition from solitary life to group‐living in a society with cooperative brood care, reproductive division of labor and morphological castes is associated with increased cognitive demands for task‐specialization. Associated with these demands, the brains of eusocial Hymenoptera divide transcriptomic signatures associated with foraging and reproduction to different populations of cells and also show diverse astrocyte and Kenyon cell types compared with solitary non‐hymenopteran insects. The neural architecture of subsocial bees, which represent evolutionary antecedent states to eusocial Hymenoptera, could then show how widely this eusocial brain is conserved across aculeate Hymenoptera. Using single‐nucleus transcriptomics, we have created an atlas of neuron and glial cell types from the brain of a subsocial insect, the small carpenter bee (Ceratina calcarata). The proportion of C. calcarata neurons related to the metabolism of classes of neurotransmitters is similar to that of other insects, whereas astrocyte and Kenyon cell types show highly similar gene expression patterns to those of eusocial Hymenoptera. In the winter, the transcriptomic signature across the brain reflected diapause. When the bee was active in the summer, however, genes upregulated in neurons reflected foraging, while the gene expression signature of glia associated with reproductive functions. Like eusocial Hymenoptera, we conclude that neural components for foraging and reproduction in C. calcarata are compartmentalized to different parts of its brain. Cellular examination of the brains of other solitary and subsocial insects can show the extent of neurobiological conservation across levels of social complexity. Single‐cell gene expression was used to develop the first brain atlas for a small carpenter bee describing neurons and glia cell types for this species. Astrocytes and Kenyon cell types are conserved across Hymenoptera in comparison to Diptera. Gene expression related to foraging and reproduction are separated to different brain cell populations.
ISSN:1601-1848
1601-183X
1601-183X
DOI:10.1111/gbb.70007