Abstract
Nucleosome occupancy results in complex sequence variation rate heterogeneity by either increasing mutation rate or inhibiting DNA repair in yeast, fish, and human. H2A.Z nucleosome is extensively involved in gene transcription activation and regulation. To test whether H2A.Z nucleosome has the similar impact on sequence variability in the Drosophila genome, we profiled the H2A.Z nucleosome occupancy and sequence variation rate at gene ends and splicing sites. Consistent with previous studies, H2A.Z nucleosome positioning helps to demarcate the borders of exons. Nucleosome occupancy is anticorrelated with sequence divergence rate in the regions flanking transcription start sites and splicing sites. However, there is no rate heterogeneity between the linker DNA and H2A.Z nucleosomal DNA regardless of nucleosome occupancy, fuzziness, positioning in promoter, coding, and intergenic regions, young or old genes. But the rate at intergenic nucleosomes and the flanking linker regions is higher than that at the genic counterparts. Further analyses found that the high sequence divergence rate in the promoter regions that are usually nucleosome depleted regions may be likely resulted from the high mutation rate in the enriched tandem repeats. Interestingly, within nucleosomes spanning splicing sites, sequence variability of nucleosomal DNA significantly increases from the end within exons to the other end protruding into introns. The relaxed functional constraint in introns contributes to the high rate of nucleosomal DNA residing in introns while the strict functional constraint in exons maintains the low rate of nucleosomal DNA residing in exons. Taken together, H2A.Z nucleosome occupancy has no effect on sequence variability of Drosophila genome, which is likely determined by local sequence composition and the concomitant selection pressure.
Highlights
Nucleosome is the fundamental unit of chromatin in eukaryotes, consisting of approximately 147 bp of DNA coiling around a histone octamer [1,2]
We explored the interplay between sequence variation and nucleosome position at transcription start sties (TSSs), transcription terminal sites (TTSs), splicing sites and intergenic regions
Our study examined the interplay between H2A.Z nucleosome positioning and sequence variability in Drosophila genome
Summary
Nucleosome is the fundamental unit of chromatin in eukaryotes, consisting of approximately 147 bp of DNA coiling around a histone octamer [1,2]. Nucleosome positioning has been shown to be involved in gene transcription [3], demarcation of exon borders [4,5], mRNA splicing [6], DNA replication [7], and DNA repair [8]. Nucleosomes exert these functions mainly through regulating the accessibility of DNA. Mutations in genomic regions can change the ability of DNA sequence to bend and alter nucleosome positioning as a result. There is likely a co-evolution of genomic DNA sequence conservation and chromatin structure
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