Abstract
In plants, mammals and insects, some genes are methylated in the CG dinucleotide context, a phenomenon called gene body methylation (gbM). It has been controversial whether this phenomenon has any functional role. Here, we took advantage of the availability of 876 leaf methylomes in Arabidopsis thaliana to characterize the population frequency of methylation at the gene level and to estimate the site-frequency spectrum of allelic states. Using a population genetics model specifically designed for epigenetic data, we found that genes with ancestral gbM are under significant selection to remain methylated. Conversely, ancestrally unmethylated genes were under selection to remain unmethylated. Repeating the analyses at the level of individual cytosines confirmed these results. Estimated selection coefficients were small, on the order of 4 Nes = 1.4, which is similar to the magnitude of selection acting on codon usage. We also estimated that A. thaliana is losing gbM threefold more rapidly than gaining it, which could be due to a recent reduction in the efficacy of selection after a switch to selfing. Finally, we investigated the potential function of gbM through its link with gene expression. Across genes with polymorphic methylation states, the expression of gene body methylated alleles was consistently and significantly higher than unmethylated alleles. Although it is difficult to disentangle genetic from epigenetic effects, our work suggests that gbM has a small but measurable effect on fitness, perhaps due to its association to a phenotype-like gene expression.
Highlights
Cytosine DNA methylation is a type of epigenetic mark in which a methyl group is added to the 5th carbon of cytosines
We found that the global rate of CHH methylation was significantly higher in accessions sequenced by Gregor Mendel Institute (GMI) (2.3%) compared to the Salk Institute (0.28%, Supplementary Figure S4), regardless of the geographic origin of accessions (Supplementary Figure S5)
If 4.Ne.s > 1.0 and if 1.0 is not included in the credible interval, significant selection is inferred to act on methylation state
Summary
Cytosine DNA methylation is a type of epigenetic mark in which a methyl group is added to the 5th carbon of cytosines In plants, it can occur in three sequence contexts—CG, CHG, and CHH (where H stands for A, T, or C)—but levels and patterns of DNA methylation vary among genomic regions. Methylation in all three contexts has a well-established repressive function on transposable elements (TEs) and regulatory elements (Luo et al 2018; Schmitz et al 2019) Both CHG and CHH methylation within genes are associated with reduced expression levels in angiosperms, together with CG methylation in the promoter region (Niederhuth et al 2016). It is not yet clear if gbM has a function, because the study of mutants deprived of gbM has failed to reveal a clear effect on phenotype (Teixeira and Colot 2009; Bewick and Schmitz 2017; Zilberman 2017)
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