Abstract
Gene-body methylation (gbM) refers to an increased level of methylated cytosines specifically in a CG sequence context within genes. gbM is found in plant genes with intermediate expression level, which evolve slowly, and is often broadly conserved across millions of years of evolution. Intriguingly however, some plants lack gbM, and thus it remains unclear whether gbM has a function. In animals, there is support for a role of gbM in reducing erroneous transcription and transcription noise, but so far most studies in plants have tested for an effect of gbM on expression level, not noise. Here, we therefore tested whether gbM was associated with reduced expression noise in Arabidopsis thaliana, using single-cell transcriptome sequencing data from root quiescent centre cells. We find that gbM genes have lower expression noise levels than unmethylated genes. However, an analysis of covariance revealed that, if other genomic features are taken into account, this association disappears. Nonetheless, gbM genes were more consistently expressed across single-cell samples, supporting previous inference that gbM genes are constitutively expressed. Finally, we observed that fewer RNAseq reads map to introns of gbM genes than to introns of unmethylated genes, which indicates that gbM might be involved in reducing erroneous transcription by reducing intron retention.
Highlights
Comparing Gene-body methylation (gbM) to unmethylated genes revealed that gbM genes had significantly lower expression noise than unmethylated genes, using both noise measures (F* and F, Table 1)
We found gbM genes to be significantly longer than unmethylated genes (Table 1) and to have intermediate expression levels
Significantly fewer gbM genes were retained from the α and βγ wholegenome duplication (WGD) or tandem duplicated and gbM genes had on average a significantly higher co-expression module size and expression breadth, than unmethylated genes (Table 1)
Summary
Matzke et al 2015; Fultz et al 2015) and is usually associated with an enrichment of mCHH as well as mCG and mCHG (Matzke et al 2015; Bewick et al 2016 and Bewick and Schmitz 2017; Hirsch and Springer 2017). Despite the fact that mCG is the most common form of cytosine methylation in the genomes of angiosperms (Niederhuth et al 2016; Bewick and Schmitz 2017), the functional consequence of mCG enrichment in genes is not well understood
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