Abstract
DNA methylation is a repressive epigenetic modification that covers vertebrate genomes. Regions known as CpG islands (CGIs), which are refractory to DNA methylation, are often associated with gene promoters and play central roles in gene regulation. Yet how CGIs in their normal genomic context evade the DNA methylation machinery and whether these mechanisms are evolutionarily conserved remains enigmatic. To address these fundamental questions we exploited a transchromosomic animal model and genomic approaches to understand how the hypomethylated state is formed in vivo and to discover whether mechanisms governing CGI formation are evolutionarily conserved. Strikingly, insertion of a human chromosome into mouse revealed that promoter-associated CGIs are refractory to DNA methylation regardless of host species, demonstrating that DNA sequence plays a central role in specifying the hypomethylated state through evolutionarily conserved mechanisms. In contrast, elements distal to gene promoters exhibited more variable methylation between host species, uncovering a widespread dependence on nucleotide frequency and occupancy of DNA-binding transcription factors in shaping the DNA methylation landscape away from gene promoters. This was exemplified by young CpG rich lineage-restricted repeat sequences that evaded DNA methylation in the absence of co-evolved mechanisms targeting methylation to these sequences, and species specific DNA binding events that protected against DNA methylation in CpG poor regions. Finally, transplantation of mouse chromosomal fragments into the evolutionarily distant zebrafish uncovered the existence of a mechanistically conserved and DNA-encoded logic which shapes CGI formation across vertebrate species.
Highlights
DNA methylation on CpG dinucleotides in vertebrate genomes is associated with transcriptional repression [1,2] and is epigenetically inherited during cell division to propagate repressive chromatin states [3,4,5]
We recently demonstrated that many features of the CpG islands (CGIs) system are shared across vertebrate species [8].This led us to hypothesize that the mechanisms that specify DNA methylation state at CGIs may be evolutionarily conserved and rely on the underlying DNA sequence
To ensure that the presence of the human chromosome did not affect the function of the DNA methylation system in the Tc1 mouse, we compared hypomethylated regions of DNA (HMRs) on the mouse chromosomes in the Tc1 mouse to HMRs formed in the same tissues in wild-type mice of the same genetic background
Summary
DNA methylation on CpG dinucleotides in vertebrate genomes is associated with transcriptional repression [1,2] and is epigenetically inherited during cell division to propagate repressive chromatin states [3,4,5]. In addition to promoter-associated CGIs, an additional class of hypomethylated elements has been identified away from gene promoters that appear to function as distal gene regulatory elements, often encompassing enhancers [8,13,15,16,20]. These regions tend to be hypomethylated in a subset of tissues, suggesting that the mechanisms underpinning their methylation state may differ from that of classical promoter-associated CGIs
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