Capture of a Functionally Active Methyl-CpG Binding Domain by an Arthropod Retrotransposon Family

Overview

Journal Genome Res

Specialty Genetics

Date 2019 Jun 27

PMID 31239280

Citations 12

Authors

Alex de Mendoza

Jahnvi Pflueger

Ryan Lister

Affiliations

Soon will be listed here.

Abstract

The repressive capacity of cytosine DNA methylation is mediated by recruitment of silencing complexes by methyl-CpG binding domain (MBD) proteins. Despite MBD proteins being associated with silencing, we discovered that a family of arthropod retrotransposons have incorporated a host-derived MBD. We functionally show how retrotransposon-encoded MBDs preferentially bind to CpG-dense methylated regions, which correspond to transposable element regions of the host genome, in the myriapod Consistently, young MBD-encoding retrotransposons (CopiaMBD) accumulate in regions with higher CpG densities than other LTR-retrotransposons also present in the genome. This would suggest that retrotransposons use MBDs to integrate into heterochromatic regions in , avoiding potentially harmful insertions into host genes. In contrast, CopiaMBD insertions in the spider genome disproportionately accumulate in methylated gene bodies compared with other spider LTR-retrotransposons. Given that transposons are not actively targeted by DNA methylation in the spider genome, this distribution bias would also support a role for MBDs in the integration process. Together, these data show that retrotransposons can co-opt host-derived epigenome readers, potentially harnessing the host epigenome landscape to advantageously tune the retrotransposition process.

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