Symbiotic microorganisms exert multifaceted impacts on the physiology of their animal hosts. Recent discoveries have shown the gut microbiota influence host brain function and behavior, but the host and microbial molecular factors required to actuate these effects are largely unknown.
To uncover molecular mechanisms that underlie the gut-microbiota-brain axis, we used Drosophila melanogaster and its bacterial microbiota as a model to identify microbiota-dependent gene expression changes in the host brain and head. Specifically, we employed RNA-seq and nanoString nCounter technology to identify Drosophila genes that exhibit altered transcript levels in fly heads upon elimination of the microbiota. The identified genes, some of which exhibited sex-specific differences, have demonstrated or inferred functional roles in the immune response, metabolism, neuronal activity, and stress resistance. Overall, this study reveals microbiota-responsive genes in the fly head, an anatomical structure not previously investigated in this context. Our results serve as a foundation for future investigations of how microbe-driven gene expression changes impact Drosophila biology.