Genomics analysis of hexanoic acid exposure in Drosophila species.
Zachary A DrumStephen M LannoSara M GregorySerena J ShimshakMukshud AhamedWilliam BarrBethlehem BekeleAlison BiesterColleen CastroLauren ConnollyNicole DelGaudioWilliam HumphreyHelen KarimiSophie KarolczakTay-Shaun LawrenceAndrew McCrackenNoah Miller-MedzonLeah MurphyCameron ParkSojeong ParkChloe QiuKevin SerraGigi SnyderAlexa StraussSpencer TangChristina VyzasJoseph D CoolonPublished in: G3 (Bethesda, Md.) (2021)
Drosophila sechellia is a dietary specialist endemic to the Seychelles islands that has evolved to consume the fruit of Morinda citrifolia. When ripe, the fruit of M. citrifolia contains octanoic acid and hexanoic acid, two medium-chain fatty acid volatiles that deter and are toxic to generalist insects. Drosophila sechellia has evolved resistance to these volatiles allowing it to feed almost exclusively on this host plant. The genetic basis of octanoic acid resistance has been the focus of multiple recent studies, but the mechanisms that govern hexanoic acid resistance in D. sechellia remain unknown. To understand how D. sechellia has evolved to specialize on M. citrifolia fruit and avoid the toxic effects of hexanoic acid, we exposed adult D. sechellia, D. melanogaster and D. simulans to hexanoic acid and performed RNA sequencing comparing their transcriptional responses to identify D. sechellia specific responses. Our analysis identified many more genes responding transcriptionally to hexanoic acid in the susceptible generalist species than in the specialist D. sechellia. Interrogation of the sets of differentially expressed genes showed that generalists regulated the expression of many genes involved in metabolism and detoxification whereas the specialist primarily downregulated genes involved in the innate immunity. Using these data, we have identified interesting candidate genes that may be critically important in aspects of adaptation to their food source that contains high concentrations of HA. Understanding how gene expression evolves during dietary specialization is crucial for our understanding of how ecological communities are built and how evolution shapes trophic interactions.