Roving methyltransferases generate a mosaic epigenetic landscape and influence evolution in Bacteroides fragilis group

Tisza, Michael J.; Smith, Derek D. N.; Clark, Andrew E.; Youn, Jung-Ho; Khil, Pavel P.; Dekker, John P.

Roving methyltransferases generate a mosaic epigenetic landscape and influence evolution in Bacteroides fragilis group

Michael J. Tisza, Derek D. N. Smith, Andrew E. Clark, Jung-Ho Youn, Pavel P. Khil and John P. Dekker ()
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Michael J. Tisza: LCIM, NIAID, NIH
Derek D. N. Smith: LCIM, NIAID, NIH
Andrew E. Clark: NIH
Jung-Ho Youn: NIH
Pavel P. Khil: LCIM, NIAID, NIH
John P. Dekker: LCIM, NIAID, NIH

Nature Communications, 2023, vol. 14, issue 1, 1-15

Abstract: Abstract Three types of DNA methyl modifications have been detected in bacterial genomes, and mechanistic studies have demonstrated roles for DNA methylation in physiological functions ranging from phage defense to transcriptional control of virulence and host-pathogen interactions. Despite the ubiquity of methyltransferases and the immense variety of possible methylation patterns, epigenomic diversity remains unexplored for most bacterial species. Members of the Bacteroides fragilis group (BFG) reside in the human gastrointestinal tract as key players in symbiotic communities but also can establish anaerobic infections that are increasingly multi-drug resistant. In this work, we utilize long-read sequencing technologies to perform pangenomic (n = 383) and panepigenomic (n = 268) analysis of clinical BFG isolates cultured from infections seen at the NIH Clinical Center over four decades. Our analysis reveals that single BFG species harbor hundreds of DNA methylation motifs, with most individual motif combinations occurring uniquely in single isolates, implying immense unsampled methylation diversity within BFG epigenomes. Mining of BFG genomes identified more than 6000 methyltransferase genes, approximately 1000 of which were associated with intact prophages. Network analysis revealed substantial gene flow among disparate phage genomes, implying a role for genetic exchange between BFG phages as one of the ultimate sources driving BFG epigenome diversity.

Date: 2023
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DOI: 10.1038/s41467-023-39892-6

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