Abstract
BackgroundDNA methylation is one of the most phylogenetically widespread epigenetic modifications of genomic DNA. In particular, DNA methylation of transcription units (‘gene bodies’) is highly conserved across diverse taxa. However, the functional role of gene body methylation is not yet fully understood. A long-standing hypothesis posits that gene body methylation reduces transcriptional noise associated with spurious transcription of genes. Despite the plausibility of this hypothesis, an explicit test of this hypothesis has not been performed until now.ResultsUsing nucleotide-resolution data on genomic DNA methylation and abundant microarray data, here we investigate the relationship between DNA methylation and transcriptional noise. Transcriptional noise measured from microarrays scales down with expression abundance, confirming findings from single-cell studies. We show that gene body methylation is significantly negatively associated with transcriptional noise when examined in the context of other biological factors.ConclusionsThis finding supports the hypothesis that gene body methylation suppresses transcriptional noise. Heavy methylation of vertebrate genomes may have evolved as a global regulatory mechanism to control for transcriptional noise. In contrast, promoter methylation exhibits positive correlations with the level of transcriptional noise. We hypothesize that methylated promoters tend to undergo more frequent transcriptional bursts than those that avoid DNA methylation.
Highlights
DNA methylation is one of the most phylogenetically widespread epigenetic modifications of genomic DNA
We show that promoter DNA methylation is highly significantly associated with transcriptional noise
Transcriptional noise is negatively correlated with expression abundance and associate with specific functions Levels of gene expression vary between cells even with the same genetic materials and under the same biological conditions [34,35,36]
Summary
DNA methylation is one of the most phylogenetically widespread epigenetic modifications of genomic DNA. DNA methylation of transcription units (‘gene bodies’) is highly conserved across diverse taxa. The functional role of gene body methylation is not yet fully understood. DNA methylation at CpG dinucleotides is a key epigenetic modification in the human genome crucial for regulatory and developmental processes [1,2]. Transcription units, or so-called ‘gene bodies’, are even more heavily methylated than the surrounding intergenic regions [6,7,8,9]. The functional consequences of promoter methylation on chromatin configuration and transcriptional regulation are extensively documented (see, for example, [10,11,12]). The role of gene body methylation remains largely unresolved. Studies have begun to identify molecular consequences of gene
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
