Regulatory Divergence as a Mechanism for X-Autosome Incompatibilities in Caenorhabditis Nematodes.

The world's astounding biodiversity results from speciation, the process of formation of distinct species. Hybrids between species often have reduced fitness due to negative epistatic interactions between divergent genetic factors, as each lineage accumulated substitutions independently in their evolutionary history. Such negative genetic interactions can manifest as gene misexpression due to divergence in gene regulatory controls from mutations in cis-regulatory elements and trans-acting factors. Gene misexpression due to differences in regulatory controls can ultimately contribute to incompatibility within hybrids through developmental defects such as sterility and inviability. We sought to quantify the contributions of regulatory divergence to postzygotic reproductive isolation using sterile interspecies hybrids of two Caenorhabditis nematodes: Caenorhabditis briggsae and Caenorhabditis nigoni. We analyzed previous transcriptome profiles for two introgression lines with distinct homozygous X-linked fragments from C. briggsae in a C. nigoni genomic background that confers male sterility, owing to defects in spermatogenesis (Li R, et al. 2016. Specific down-regulation of spermatogenesis genes targeted by 22G RNAs in hybrid sterile males associated with an X-chromosome introgression. Genome Res. 26:1219-1232). Our analysis identified hundreds of genes that show distinct classes of nonadditive expression inheritance and regulatory divergence. We find that these nonoverlapping introgressions affect many of the same genes in the same way and demonstrate that the preponderance of transgressive gene expression is due to regulatory divergence involving compensatory and joint effects of cis- and trans-acting factors. The similar transcriptomic responses to nonoverlapping genetic perturbations of the X-chromosome implicate multiway incompatibilities as an important feature contributing to hybrid male sterility in this system.

Transgenerational inheritance of learned preferences for novel host plant odors in Bicyclus anynana butterflies.

Many phytophagous insects have strong preferences for their host plants, which they recognize via odors, making it unclear how novel host preferences develop in the course of insect diversification. Insects may learn to prefer new host plants via exposure to their odors and pass this learned preference to their offspring. We tested this hypothesis by examining larval odor preferences before and after feeding them with leaves coated with control and novel odors and by examining odor preferences again in their offspring. Larvae of the parental generation developed a preference for two of these odors over their development. These odor preferences were also transmitted to the next generation. Offspring of butterflies fed on these new odors chose these odors more often than offspring of butterflies fed on control leaves. In addition, offspring of butterflies fed on banana odors had a significant naïve preference for the banana odors in contrast to the naïve preference for control leaves shown by individuals of the parental generation. Thus, butterflies can learn to prefer novel host plant odors via exposure to them during larval development and transmit these learned preferences to their offspring. This ability potentially facilitates shifts in host plant use over the course of insect diversification.