Nunez, J. C. B.; Tangwancharoen, S.; Finnegan, K. M.; Proud, L. A.; Lockwood, B. L.

Despite decades of research in environmental change, we know relatively little about the genetics of environmentally influenced traits across the life cycle of species with complex life histories. Previously, we reported that natural variation in heat tolerance is life-stage specific in Drosophila melanogaster, suggesting that thermal selection predominantly targets the early embryonic life stage. Here, we used advanced introgression and pooled whole-genome resequencing to map the genomic basis of enhanced embryonic heat tolerance in a neotropical line of D. melanogaster. We identified two loci on chromosomes 2R and X that were consistently targeted by 16 generations of thermal selection across six replicate introgressions. We compared alleles in these regions to published datasets of natural variation from North America and Europe using the DEST dataset. This analysis revealed that two SNPs associated with embryonic heat tolerance exhibited both clinal and seasonal patterns, with the seasonal variation significantly correlated with environmental variability in average precipitation and temperature variance across space and time. The two SNPs lie in the putative regulatory regions of the genes SP70 and sog, and individuals with different alleles at these loci exhibited disparate gene expression responses to heat stress. Overall, our results suggest that loci that influence embryonic heat tolerance are under selection in nature. Our study extends previous work in developmental genetics of Drosophila by characterizing the genomics of an ecologically relevant developmental trait in natural populations.