An orphan DNA (cytosine-5-)-methyltransferase in Vibrio cholerae

Banerjee, Sanjib; Chowdhury, Rukhsana

doi:10.1099/mic.0.28624-0

Cited by 24 publications

(35 citation statements)

References 19 publications

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“…Solitary REases and MTases might be components of R-M systems encoded apart in the genome. Several of these have been found (35,36,81). In this case, one would expect a similar number of solitary REases and MTases.…”

Section: Resultsmentioning

confidence: 98%

The interplay of restriction-modification systems with mobile genetic elements and their prokaryotic hosts

Oliveira

Touchon

Rocha

2014

Nucleic Acids Research

260

245

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The roles of restriction-modification (R-M) systems in providing immunity against horizontal gene transfer (HGT) and in stabilizing mobile genetic elements (MGEs) have been much debated. However, few studies have precisely addressed the distribution of these systems in light of HGT, its mechanisms and its vectors. We analyzed the distribution of R-M systems in 2261 prokaryote genomes and found their frequency to be strongly dependent on the presence of MGEs, CRISPR-Cas systems, integrons and natural transformation. Yet R-M systems are rare in plasmids, in prophages and nearly absent from other phages. Their abundance depends on genome size for small genomes where it relates with HGT but saturates at two occurrences per genome. Chromosomal R-M systems might evolve under cycles of purifying and relaxed selection, where sequence conservation depends on the biochemical activity and complexity of the system and total gene loss is frequent. Surprisingly, analysis of 43 pan-genomes suggests that solitary R-M genes rarely arise from the degradation of R-M systems. Solitary genes are transferred by large MGEs, whereas complete systems are more frequently transferred autonomously or in small MGEs. Our results suggest means of testing the roles for R-M systems and their associations with MGEs.

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Section: Resultsmentioning

confidence: 98%

The interplay of restriction-modification systems with mobile genetic elements and their prokaryotic hosts

Oliveira

Touchon

Rocha

2014

Nucleic Acids Research

260

245

View full text Add to dashboard Cite

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“…An alternative argument is that this might be a mechanism to ensure that the VSR system can efficiently detect and correct mutant sites with minimal confusion arising from 'normal' C[C/T]W[G/A]G sites; there might be an interplay of both forces in determining the final oligonucleotide usage in the E. coli genome. However, several other organisms might, in fact, make use of cytosine methylation to generate genotypic diversity during stationary phase; for example, Vibrio cholerae encodes a Dcm (targeting the external cytosine in RCCGGY motif), but not a VSR repair system 50 . Analysis of the genome of V. cholerae shows that a striking 97% of 'methylatable' cytosines are at non-synonymous positions, suggesting a strong preference for having methyl-dependent mutations at nonsynonymous sites (3,964 of 4,074 sites on either strand of both chromosomes).…”

Section: Discussionmentioning

confidence: 99%

Genomics of DNA cytosine methylation in Escherichia coli reveals its role in stationary phase transcription

et al. 2012

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DnA cytosine methylation regulates gene expression in mammals. In bacteria, its role in gene expression and genome architecture is less understood. Here we perform high-throughput sequencing of bisulfite-treated genomic DnA from Escherichia coli K12 to describe, for the first time, the extent of cytosine methylation of bacterial DnA at single-base resolution. Whereas most target sites (C m CWGG) are fully methylated in stationary phase cells, many sites with an extended CC m CWGG motif are only partially methylated in exponentially growing cells. We speculate that these partially methylated sites may be selected, as these are slightly correlated with the risk of spontaneous, non-synonymous conversion of methylated cytosines to thymines. microarray analysis in a cytosine methylation-deficient mutant of E. coli shows increased expression of the stress response sigma factor Rpos and many of its targets in stationary phase. Thus, DnA cytosine methylation is a regulator of stationary phase gene expression in E. coli.

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“…The specificity subunit recognizes a specific DNA motif for methylation (3, 6) and has been shown to function together with a dimer of the MTase (7); there are also solitary DNA MTases that do not have a restriction enzyme counterpart. Examples of the latter are the N 6 -adenine MTase Dam, CcrM (8) and the C-5 cytosine methylase Dcm (9, 10), and VchM (9, 11). While R-M systems are known for their role in the defense against foreign DNA (10), DNA methylation enzymes also seem to play functional roles in the timing of DNA replication, chromosome partitioning, DNA repair, control of transposition, and conjugal transfer of plasmids and gene regulation (12–20, 61, 62).…”

Section: Introductionmentioning

confidence: 99%

Identification of a Pseudomonas aeruginosa PAO1 DNA Methyltransferase, Its Targets, and Physiological Roles

Doberenz

Eckweiler

Reichert

et al. 2017

mBio

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DNA methylation is widespread among prokaryotes, and most DNA methylation reactions are catalyzed by adenine DNA methyltransferases, which are part of restriction-modification (R-M) systems. R-M systems are known for their role in the defense against foreign DNA; however, DNA methyltransferases also play functional roles in gene regulation. In this study, we used single-molecule real-time (SMRT) sequencing to uncover the genome-wide DNA methylation pattern in the opportunistic pathogen Pseudomonas aeruginosa PAO1. We identified a conserved sequence motif targeted by an adenine methyltransferase of a type I R-M system and quantified the presence of N6-methyladenine using liquid chromatography-tandem mass spectrometry (LC-MS/MS). Changes in the PAO1 methylation status were dependent on growth conditions and affected P. aeruginosa pathogenicity in a Galleria mellonella infection model. Furthermore, we found that methylated motifs in promoter regions led to shifts in sense and antisense gene expression, emphasizing the role of enzymatic DNA methylation as an epigenetic control of phenotypic traits in P. aeruginosa. Since the DNA methylation enzymes are not encoded in the core genome, our findings illustrate how the acquisition of accessory genes can shape the global P. aeruginosa transcriptome and thus may facilitate adaptation to new and challenging habitats.

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An orphan DNA (cytosine-5-)-methyltransferase in Vibrio cholerae

Cited by 24 publications

References 19 publications

The interplay of restriction-modification systems with mobile genetic elements and their prokaryotic hosts

The interplay of restriction-modification systems with mobile genetic elements and their prokaryotic hosts

Genomics of DNA cytosine methylation in Escherichia coli reveals its role in stationary phase transcription

Identification of a Pseudomonas aeruginosa PAO1 DNA Methyltransferase, Its Targets, and Physiological Roles

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