Evolved and plastic gene expression in adaptation to a novel niche

Gene expression, resulting from complex regulatory interactions, plays an important role in adaptation and speciation. While gene expression historically has been studied in the context of reproductive isolation in speciation research, a role for evolved differences in gene expression in adaptation to novel niches is increasingly appreciated. How gene expression evolves and enables divergent ecological adaptation, and how changes in gene expression relate to genomic architecture and genetic divergence are pressing questions in understanding the processes of adaptation and ecological speciation. Further, how plasticity in gene expression can both contribute to and be affected by the process of ecological adaptation is a crucial component in understanding gene expression evolution. To address these questions, we investigate the role of evolved and plastic gene expression differences in adaptation leveraging an established host plant shift in the peacock fly Tephritis conura . Using a cross-fostering design where larvae feed on either natal or alternate host plants, we uncover extensive evolved differences in gene expression between the ecotypes, strikingly in genes associated with processing of host plant chemicals. We find limited evidence for plasticity, with some indications of higher plasticity in the ancestral ecotype where the expression of three gene coexpression modules is altered when larvae are cross-fostered to the derived host plant. Interestingly, we find an enrichment of differentially expressed genes within a large, ecotype-specific inversion in the T. conura genome. This finding adds to evidence that inversions are important for enabling diversification in the face of gene flow and underscores that effects on gene expression may be key to understanding the role of inversions.