Dark-rearing uncovers novel gene expression patterns in an obligate cave-dwelling fish.

Extreme environments often result in the evolution of dramatic adaptive features. The Mexican tetra, Astyanax mexicanus, includes 30 different populations of cave-dwelling forms that live in perpetual darkness. As a consequence, many populations have evolved eye loss, reduced pigmentation, and amplification of nonvisual sensory systems. Closely-related surface-dwelling morphs demonstrate typical vision, pigmentation, and sensation. Transcriptomic assessments in this system have revealed important developmental changes associated with the cave morph, however, they have not accounted for photic rearing conditions. Prior studies reared individuals under a 12:12 hr light/dark (LD) cycle. Here, we reared cavefish under constant darkness (DD) for 5+ years. From these experimental individuals, we performed mRNA sequencing and compared gene expression of surface fish reared under LD conditions to cavefish reared under DD conditions to identify photic-dependent gene expression differences. Gene Ontology enrichment analyses revealed a number of previously underappreciated cave-associated changes impacting blood physiology and olfaction. We further evaluated the position of differentially expressed genes relative to QTL positions from prior studies and found several candidate genes associated with these ecologically relevant lighting conditions. In sum, this work highlights photic conditions as a key environmental factor impacting gene expression patterns in blind cave-dwelling fish.

Genetic Basis of Body Color and Spotting Pattern in Redheaded Pine Sawfly Larvae (Neodiprion lecontei).

Pigmentation has emerged as a premier model for understanding the genetic basis of phenotypic evolution, and a growing catalog of color loci is starting to reveal biases in the mutations, genes, and genetic architectures underlying color variation in the wild. However, existing studies have sampled a limited subset of taxa, color traits, and developmental stages. To expand the existing sample of color loci, we performed QTL mapping analyses on two types of larval pigmentation traits that vary among populations of the redheaded pine sawfly (Neodiprion lecontei): carotenoid-based yellow body color and melanin-based spotting pattern. For both traits, our QTL models explained a substantial proportion of phenotypic variation and suggested a genetic architecture that is neither monogenic nor highly polygenic. Additionally, we used our linkage map to anchor the current N. lecontei genome assembly. With these data, we identified promising candidate genes underlying (1) a loss of yellow pigmentation in populations in the mid-Atlantic/northeastern United States [C locus-associated membrane protein homologous to a mammalian HDL receptor-2 gene (Cameo2) and lipid transfer particle apolipoproteins II and I gene (apoLTP-II/I)], and (2) a pronounced reduction in black spotting in Great Lakes populations [members of the yellow gene family, tyrosine hydroxylase gene (pale), and dopamine N-acetyltransferase gene (Dat)]. Several of these genes also contribute to color variation in other wild and domesticated taxa. Overall, our findings are consistent with the hypothesis that predictable genes of large effect contribute to color evolution in nature.