Nematode histone H2A variant evolution reveals diverse histories of retention and loss and evidence for conserved core-like variants

Abstract

ABSTRACTHistone variants are paralogs that replace canonical histones in nucleosomes, often imparting novel functions. Despite their importance, how histone variants arise and evolve is poorly understood. Reconstruction of histone protein evolution is challenging due to high amino acid conservation and large differences in evolutionary rates across gene lineages and sites. Here we combined amino acid sequences and intron position data from 108 nematode genomes to trace the evolutionary histories of the three H2A variants found in Caenorhabditis elegans: the ancient H2A.ZHTZ-1, the sperm-specific HTAS-1, and HIS-35, which differs from canonical H2A by a single glycine-to-alanine C-terminal change. We find disparate evolutionary histories. Although the H2A.ZHTZ-1 protein is highly conserved, its gene exhibits recurrent intron gain and loss. This pattern suggests that it is intron presence, rather than specific intron sequences or positions, that may be important to H2A.Z functionality. In contrast, for HTAS-1 and HIS-35, we find variant-specific intron positions that are conserved across species. HIS-35 arose in the ancestor of Caenorhabditis and its sister group, including the genus Diploscapter, while the sperm-specific variant HTAS-1 arose more recently in the ancestor of a subset of Caenorhabditis species. HIS-35 exhibits gene retention in some descendent lineages but also recurrent gene loss in others, suggesting that histone variant use or functionality is highly flexible in this case. We also find that the single amino acid differentiating HIS-35 from core H2A is ancestral and common across canonical Caenorhabditis H2A sequences and identify one nematode species that bear identical HIS-35 and canonical H2A proteins, findings that are not predicted from the hypothesis that HIS-35 has a distinct function. Instead, we speculate that HIS-35 enables H2A expression across the cell cycle or in distinct tissues; genes encoding such partially-redundant functions may be advantageous yet relatively replaceable over evolutionary times, consistent with the patchwork pattern of retention and loss of both genes. Our study shows the evolutionary trajectory for histone H2A variants with distinct functions and the utility of intron positions for reconstructing the evolutionary history of gene families, particularly those undergoing idiosyncratic sequence evolution.