Characterisation of Type II DNA Methyltransferases of

Overview

Journal Microorganisms

Specialty Microbiology

Date 2023 Jun 28

PMID 37375093

Authors

Lars Vogelgsang

Azlan Nisar

Sebastian Alexander Scharf

Anna Rommerskirchen

Dana Belick

Alexander Dilthey

Birgit Henrich

Affiliations

Soon will be listed here.

Abstract

Bacterial virulence, persistence and defence are affected by epigenetic modifications, including DNA methylation. Solitary DNA methyltransferases modulate a variety of cellular processes and influence bacterial virulence; as part of a restriction-modification (RM) system, they act as a primitive immune system in methylating the own DNA, while unmethylated foreign DNA is restricted. We identified a large family of type II DNA methyltransferases in , comprising six solitary methyltransferases and four RM systems. Motif-specific 5mC and 6mA methylations were identified with a tailored Tombo analysis on Nanopore reads. Selected motifs with methylation scores >0.5 fit with the gene presence of DAM1 and DAM2, DCM2, DCM3, and DCM6, but not for DCM1, whose activity was strain-dependent. The activity of DCM1 for CCWGG and of both DAM1 and DAM2 for GATC was proven in methylation-sensitive restriction and finally for recombinant rDCM1 and rDAM2 against a -, -negative background. A hitherto unknown 8/3 gene fusion containing a (TA) repeat region of varying length was characterized within a single strain, suggesting the expression of DCM8/DAM3 phase variants. The combination of genetic, bioinformatics, and enzymatic approaches enabled the detection of a huge family of type II DNA MTases in , whose involvement in virulence and defence can now be characterized in future work.

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