Your search keyword '"bacterial epigenetics"' showing total 25 results

1. Emerging methylation-based approaches in microbiome engineering

Author

Changhee Won and Sung Sun Yim

Subjects

Bacterial epigenetics, Methylome, Restriction-modification (R-M) systems, DNA methyltransferases, Microbiome engineering, Biotechnology, TP248.13-248.65, Fuel, TP315-360

Abstract

Abstract Bacterial epigenetics, particularly through DNA methylation, exerts significant influence over various biological processes such as DNA replication, uptake, and gene regulation in bacteria. In this review, we explore recent advances in characterizing bacterial epigenomes, accompanied by emerging strategies that harness bacterial epigenetics to elucidate and engineer diverse bacterial species with precision and effectiveness. Furthermore, we delve into the potential of epigenetic modifications to steer microbial functions and influence community dynamics, offering promising opportunities for understanding and modulating microbiomes. Additionally, we investigate the extensive diversity of DNA methyltransferases and emphasize their potential utility in the context of the human microbiome. In summary, this review highlights the potential of DNA methylation as a powerful toolkit for engineering microbiomes.

Published

2024

2. Emerging methylation-based approaches in microbiome engineering

Author

Won, Changhee and Yim, Sung Sun

Published

2024

3. The red thread between methylation and mutation in bacterial antibiotic resistance: How third-generation sequencing can help to unravel this relationship.

Author

Papaleo, Stella, Alvaro, Alessandro, Nodari, Riccardo, Panelli, Simona, Bitar, Ibrahim, and Comandatore, Francesco

Subjects

DNA mismatch repair, BACTERIAL mutation, MOBILE genetic elements, DRUG resistance in bacteria, METHYLATION, DNA methylation, GENE expression, BACTERIAL population

Abstract

DNA methylation is an important mechanism involved in bacteria limiting foreign DNA acquisition, maintenance of mobile genetic elements, DNA mismatch repair, and gene expression. Changes in DNA methylation pattern are observed in bacteria under stress conditions, including exposure to antimicrobial compounds. These changes can result in transient and fast-appearing adaptive antibiotic resistance (AdR) phenotypes, e.g., strain overexpressing eux pumps. DNA methylation can be related to DNA mutation rate, because it is involved in DNA mismatch repair systems and because methylated bases are well-known mutational hotspots. The AdR process can be the first important step in the selection of antibiotic-resistant strains, allowing the survival of the bacterial population until more efficient resistant mutants emerge. Epigenetic modifications can be investigated by third-generation sequencing platforms that allow us to simultaneously detect all the methylated bases along with the DNA sequencing. In this scenario, this sequencing technology enables the study of epigenetic modifications in link with antibiotic resistance and will help to investigate the relationship between methylation and mutation in the development of stable mechanisms of resistance. [ABSTRACT FROM AUTHOR]

Published

2022

4. The red thread between methylation and mutation in bacterial antibiotic resistance: How third-generation sequencing can help to unravel this relationship

Author

Stella Papaleo, Alessandro Alvaro, Riccardo Nodari, Simona Panelli, Ibrahim Bitar, and Francesco Comandatore

Subjects

adaptive antibiotic resistance, DNA methylation, mutations, third-generation sequencing, bacterial epigenetics, DNA repair systems, Microbiology, QR1-502

Abstract

DNA methylation is an important mechanism involved in bacteria limiting foreign DNA acquisition, maintenance of mobile genetic elements, DNA mismatch repair, and gene expression. Changes in DNA methylation pattern are observed in bacteria under stress conditions, including exposure to antimicrobial compounds. These changes can result in transient and fast-appearing adaptive antibiotic resistance (AdR) phenotypes, e.g., strain overexpressing efflux pumps. DNA methylation can be related to DNA mutation rate, because it is involved in DNA mismatch repair systems and because methylated bases are well-known mutational hotspots. The AdR process can be the first important step in the selection of antibiotic-resistant strains, allowing the survival of the bacterial population until more efficient resistant mutants emerge. Epigenetic modifications can be investigated by third-generation sequencing platforms that allow us to simultaneously detect all the methylated bases along with the DNA sequencing. In this scenario, this sequencing technology enables the study of epigenetic modifications in link with antibiotic resistance and will help to investigate the relationship between methylation and mutation in the development of stable mechanisms of resistance.

Published

2022

5. Comparative Genomics Reveals the Diversity of Restriction-Modification Systems and DNA Methylation Sites in Listeria monocytogenes

Author

Chen, Poyin, Bakker, Henk C den, Korlach, Jonas, Kong, Nguyet, Storey, Dylan B, Paxinos, Ellen E, Ashby, Meredith, Clark, Tyson, Luong, Khai, Wiedmann, Martin, and Weimer, Bart C

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Genetics, Microbiology, Medical Microbiology, Digestive Diseases, Prevention, Foodborne Illness, Vaccine Related, Biodefense, Human Genome, Infectious Diseases, Emerging Infectious Diseases, 2.1 Biological and endogenous factors, Aetiology, 2.2 Factors relating to the physical environment, Infection, DNA Methylation, DNA Restriction-Modification Enzymes, Genome, Bacterial, Genomics, Listeria monocytogenes, Sequence Alignment, Synteny, L. monocytogenes, 100K Pathogen Genome Project, SMRT sequencing, methylation, inversion, infection, bacterial epigenetics, genetic epidemiology, DNA methylation, Listeria, genome analysis, virulence regulation, Medical microbiology

Abstract

Listeria monocytogenes is a bacterial pathogen that is found in a wide variety of anthropogenic and natural environments. Genome sequencing technologies are rapidly becoming a powerful tool in facilitating our understanding of how genotype, classification phenotypes, and virulence phenotypes interact to predict the health risks of individual bacterial isolates. Currently, 57 closed L. monocytogenes genomes are publicly available, representing three of the four phylogenetic lineages, and they suggest that L. monocytogenes has high genomic synteny. This study contributes an additional 15 closed L. monocytogenes genomes that were used to determine the associations between the genome and methylome with host invasion magnitude. In contrast to previous findings, large chromosomal inversions and rearrangements were detected in five isolates at the chromosome terminus and within rRNA genes, including a previously undescribed inversion within rRNA-encoding regions. Each isolate's epigenome contained highly diverse methyltransferase recognition sites, even within the same serotype and methylation pattern. Eleven strains contained a single chromosomally encoded methyltransferase, one strain contained two methylation systems (one system on a plasmid), and three strains exhibited no methylation, despite the occurrence of methyltransferase genes. In three isolates a new, unknown DNA modification was observed in addition to diverse methylation patterns, accompanied by a novel methylation system. Neither chromosome rearrangement nor strain-specific patterns of epigenome modification observed within virulence genes were correlated with serotype designation, clonal complex, or in vitro infectivity. These data suggest that genome diversity is larger than previously considered in L. monocytogenes and that as more genomes are sequenced, additional structure and methylation novelty will be observed in this organism.ImportanceListeria monocytogenes is the causative agent of listeriosis, a disease which manifests as gastroenteritis, meningoencephalitis, and abortion. Among Salmonella, Escherichia coli, Campylobacter, and Listeria-causing the most prevalent foodborne illnesses-infection by L. monocytogenes carries the highest mortality rate. The ability of L. monocytogenes to regulate its response to various harsh environments enables its persistence and transmission. Small-scale comparisons of L. monocytogenes focusing solely on genome contents reveal a highly syntenic genome yet fail to address the observed diversity in phenotypic regulation. This study provides a large-scale comparison of 302 L. monocytogenes isolates, revealing the importance of the epigenome and restriction-modification systems as major determinants of L. monocytogenes phylogenetic grouping and subsequent phenotypic expression. Further examination of virulence genes of select outbreak strains reveals an unprecedented diversity in methylation statuses despite high degrees of genome conservation.

Published

2017

6. Bacterial epigenetics opens door to novel frontier in Infection biology.

Author

Ganguli, Sriradha and Chakraborty, Ranadhir

Abstract

Bacteria, like eukaryotes, use post-replicative DNA methylation to regulate the epigenetic regulation of DNA–protein interactions. In bacteria, DNA methyltransferases (Mtases) are common, and the majority of them are part of restriction-modification systems. Environmental factors influence DNA methylation patterns by altering regulatory protein binding. As an epigenetic cue, bacteria use DNA adenine methylation rather than DNA cytosine methylation. The virulence of various human pathogens is influenced by DNA adenine methylation. Methylome research has contributed to the discovery of a wide range of Mtases and their unique target sequences. The mRNA alteration via methylation and capping contributes to bacterial epigenetics alongside DNA modifications. Research on phase-variable Type I and Type III restriction-modification systems in multiple human-adapted bacterial pathogens have revealed global variations in methylation in regulating the expression of multiple genes. Bacteria can also influence the chromatin structure and transcriptional program of host cells by influencing various epigenetic factors, as per recent findings. Bacterial infection is increasingly being shown to play a role in modulating the epigenetic information of host cells through a variety of mechanisms. Further challenging realm is to uncover the function of chromatin modifications and their regulators in the physiopathology of infectious diseases. This will open new possibilities for future study in the field of bacterial pathogenesis and chromatin-based defense gene regulation. [ABSTRACT FROM AUTHOR]

Published

2021

7. Novel Identification of Bacterial Epigenetic Regulations Would Benefit From a Better Exploitation of Methylomic Data

Author

Amaury Payelleville and Julien Brillard

Subjects

bacterial epigenetics, DNA methylation, methylome, transcriptome, phenotypic heterogeneity, Microbiology, QR1-502

Abstract

DNA methylation can be part of epigenetic mechanisms, leading to cellular subpopulations with heterogeneous phenotypes. While prokaryotic phenotypic heterogeneity is of critical importance for a successful infection by several major pathogens, the exact mechanisms involved in this phenomenon remain unknown in many cases. Powerful sequencing tools have been developed to allow the detection of the DNA methylated bases at the genome level, and they have recently been extensively applied on numerous bacterial species. Some of these tools are increasingly used for metagenomics analysis but only a limited amount of the available methylomic data is currently being exploited. Because newly developed tools now allow the detection of subpopulations differing in their genome methylation patterns, it is time to emphasize future strategies based on a more extensive use of methylomic data. This will ultimately help to discover new epigenetic gene regulations involved in bacterial phenotypic heterogeneity, including during host-pathogen interactions.

Published

2021

8. Novel Identification of Bacterial Epigenetic Regulations Would Benefit From a Better Exploitation of Methylomic Data.

Author

Payelleville, Amaury and Brillard, Julien

Subjects

BACTERIAL genomes, EPIGENETICS, PHENOTYPES, DNA methylation, METAGENOMICS, GENETIC regulation, GENOMES

Abstract

DNA methylation can be part of epigenetic mechanisms, leading to cellular subpopulations with heterogeneous phenotypes. While prokaryotic phenotypic heterogeneity is of critical importance for a successful infection by several major pathogens, the exact mechanisms involved in this phenomenon remain unknown in many cases. Powerful sequencing tools have been developed to allow the detection of the DNA methylated bases at the genome level, and they have recently been extensively applied on numerous bacterial species. Some of these tools are increasingly used for metagenomics analysis but only a limited amount of the available methylomic data is currently being exploited. Because newly developed tools now allow the detection of subpopulations differing in their genome methylation patterns, it is time to emphasize future strategies based on a more extensive use of methylomic data. This will ultimately help to discover new epigenetic gene regulations involved in bacterial phenotypic heterogeneity, including during host-pathogen interactions. [ABSTRACT FROM AUTHOR]

Published

2021

9. Distinct epigenetic signatures of classical and hypervirulent Klebsiella pneumoniae .

Author

Ghosh D, Pal A, Mohapatra S, Raj S, and Vivekanandan P

Subjects

Humans, Virulence genetics, Adenine, Cytosine, Klebsiella pneumoniae, Klebsiella Infections microbiology

Abstract

Emergence and spread of the hypervirulent pathotype of Klebsiella pneumoniae have significantly increased infection rates in community as well as healthcare settings. There is an increasing interest to identify discriminating features between classical K. pneumoniae (cKp) and hypervirulent K. pneumoniae (hvKp) to facilitate our understanding of the rapid emergence and dissemination of the hypervirulent pathotype. Here, we sought to identify unique epigenetic signatures of hvKp pathotype that differ from its classical counterpart using single-base resolution methylome analysis of native DNA sequencing on the Oxford Nanopore Technologies platform. The overall global adenine methylation in GATC motifs (i.e., Dam methylation motif) and cytosine methylation in CCWGG motifs (i.e., Dcm methylation motif) were significantly higher in hvKp isolates compared to that in cKp isolates, irrespective of their position in chromosomes or putative extra-chromosomal genetic elements. Notably, we observed significant enrichment of hypermethylated GATC and CCWGG motifs in the virulome of hvKp compared to hvKp genes not directly associated with virulence. We also observed increased methylation of GATC and CCWGG motifs in the capsule synthesis locus of hvKp isolates compared to cKp isolates. Furthermore, we identified several differentially methylated genes (DMGs) between the two pathotypes; interestingly, these DMGs include metal ion transporters, multidrug efflux pumps, transcriptional regulators of stress response, and genes associated with biofilm formation. Our results highlight hypermethylation of GATC and CCWGG motifs as unique epigenetic signatures of hvKp isolates.IMPORTANCEHypervirulent Klebsiella pneumoniae (hvKp) is a more virulent and rapidly evolving hypermucoviscous pathotype of classical K. pneumoniae (cKp). The hypervirulent pathotype is a major public health concern and is associated with high infection rates in community as well as hospital settings. With the recent emergence of multidrug-resistant hvKp, it has become imperative to investigate non-classical mechanisms such as epigenetics in addition to canonical biochemical and genetic mechanisms that delineate and differentiate the hypervirulent pathotype from its classical counterpart. Here, we identify genome-wide differences in adenine and cytosine methylation marks at well-characterized motifs between the two pathotypes. Overall, significantly higher levels of methylation were observed across chromosomal DNA and extrachromosomal elements in hvKp compared to cKp. Among hvKp isolates, the genes associated with virulence are particularly enriched for methylation marks. Our findings shed light on how epigenetic signatures may help distinguish the pathogenic potential of bacteria., Competing Interests: The authors declare no conflict of interest.

Published

2024

10. Comparative Genomics Reveals the Diversity of Restriction-Modification Systems and DNA Methylation Sites in Listeria monocytogenes.

Author

Poyin Chen, den Bakker, Henk C., Korlach, Jonas, Nguyet Kong, Storey, Dylan B., Paxinos, Ellen E., Ashby, Meredith, Clark, Tyson, Khai Luong, Wiedmann, Martin, and Weimera, Bart C.

Subjects

*COMPARATIVE genomics, *DNA modification & restriction, *DNA methylation, *LISTERIA monocytogenes, *VIRULENCE of bacteria

Abstract

Listeria monocytogenes is a bacterial pathogen that is found in a wide variety of anthropogenic and natural environments. Genome sequencing technologies are rapidly becoming a powerful tool in facilitating our understanding of how genotype, classification phenotypes, and virulence phenotypes interact to predict the health risks of individual bacterial isolates. Currently, 57 closed L. monocytogenes genomes are publicly available, representing three of the four phylogenetic lineages, and they suggest that L. monocytogenes has high genomic synteny. This study contributes an additional 15 closed L. monocytogenes genomes that were used to determine the associations between the genome and methylome with host invasion magnitude. In contrast to previous findings, large chromosomal inversions and rearrangements were detected in five isolates at the chromosome terminus and within rRNA genes, including a previously undescribed inversion within rRNA-encoding regions. Each isolate's epigenome contained highly diverse methyltransferase recognition sites, even within the same serotype and methylation pattern. Eleven strains contained a single chromosomally encoded methyltransferase, one strain contained two methylation systems (one system on a plasmid), and three strains exhibited no methylation, despite the occurrence of methyltransferase genes. In three isolates a new, unknown DNA modification was observed in addition to diverse methylation patterns, accompanied by a novel methylation system. Neither chromosome rearrangement nor strain-specific patterns of epigenome modification observed within virulence genes were correlated with serotype designation, clonal complex, or in vitro infectivity. These data suggest that genome diversity is larger than previously considered in L. monocytogenes and that as more genomes are sequenced, additional structure and methylation novelty will be observed in this organism. [ABSTRACT FROM AUTHOR]

Published

2017

11. Global DNA Methylation Level among Ciprofloxacin-Resistant Clinical Isolates of Escherichia coli

Author

Thiyagarajan Yugendran and Belgode Narasimha Harish

Subjects

5-mc methylation, bacterial epigenetics, enterobacteriaceae, fluoroquinolone resistance, Medicine

Abstract

Introduction: Fluoroquinolone resistant clinical isolates belonging to the family Enterobacteriaceae, is a major public health concern in India. Data analysis in JIPMER hospital revealed 10% rise in fluoroquinolone resistance within a span of three years suggestive of the possible involvement of mechanism/s other than QRDR capable of imparting fluoroquinolone resistance. DNA methylation regulates gene expression. Moreover, methylated cytosine is a mutational hotspot. Thus, DNA methylation can alter bacterial gene expression profile as well as facilitate the bacteria in accumulating mutations possibly leading to increased antimicrobial resistance. Therefore, the present study was carried out to identify the potential involvement of DNA methylation in ciprofloxacin resistance. Aim: To elucidate and compare the methylation level of genomic and plasmid DNA among clinical isolates of E. coli sensitive and resistant to ciprofloxacin. Materials and Methods: The study included 40 clinical E. coli isolates of which, 30 were ciprofloxacin-resistant and 10 were sensitive to ciprofloxacin. Genomic DNA (gDNA) and plasmid DNA were extracted and quantified. Methylation levels were elucidated using 5-mC DNA ELISA kit (Zymoresearch, California, USA) as per kit protocol and guidelines. Statistical Analysis: Spearman correlation 2-tailed test was used. A p-value 256 µg/mL respectively. No difference was found in plasmid DNA methylation level but, the gDNA methylation level of the resistant strains significantly differed from that of the sensitive strains. Based on Spearman correlation test gDNA methylation level of bacteria was found to be inversely proportional to its MIC against ciprofloxacin with p= -0.956 (p-value < 0.0001). Conclusion: The influence of DNA methylation over plasmidmediated quinolone resistance needs to be further confirmed by bisulphite DNA sequencing of the plasmid-borne genes. Extensive usage of ciprofloxacin has led to rise in ciprofloxacin resistance possibly induced by DNA methylation. Thus rational usage of ciprofloxacin in a clinical setting is essential to combat the further development of ciprofloxacin resistance. Hypomethylated genes and adenine methylation needs to be identified to fill up gaps in knowledge concerning the involvement of DNA methylation in fluoroquinolone resistance exhibited by E. coli.

Published

2016

12. The red thread between methylation and mutation in bacterial antibiotic resistance: How third-generation sequencing can help to unravel this relationship

Author

Stella, Papaleo, Alessandro, Alvaro, Riccardo, Nodari, Simona, Panelli, Ibrahim, Bitar, and Francesco, Comandatore

Subjects

Settore MED/38 - Pediatria Generale e Specialistica, bacterial epigenetics, DNA methylation, Settore VET/06 - Parassitologia e Malattie Parassitarie degli Animali, DNA repair systems, adaptive antibiotic resistance, mutations, third-generation sequencing, Settore BIO/19 - Microbiologia Generale

Abstract

DNA methylation is an important mechanism involved in bacteria limiting foreign DNA acquisition, maintenance of mobile genetic elements, DNA mismatch repair, and gene expression. Changes in DNA methylation pattern are observed in bacteria under stress conditions, including exposure to antimicrobial compounds. These changes can result in transient and fast-appearing adaptive antibiotic resistance (AdR) phenotypes, e.g., strain overexpressing efflux pumps. DNA methylation can be related to DNA mutation rate, because it is involved in DNA mismatch repair systems and because methylated bases are well-known mutational hotspots. The AdR process can be the first important step in the selection of antibiotic-resistant strains, allowing the survival of the bacterial population until more efficient resistant mutants emerge. Epigenetic modifications can be investigated by third-generation sequencing platforms that allow us to simultaneously detect all the methylated bases along with the DNA sequencing. In this scenario, this sequencing technology enables the study of epigenetic modifications in link with antibiotic resistance and will help to investigate the relationship between methylation and mutation in the development of stable mechanisms of resistance.

Published

2022

13. DNA methyltransferases and epigenetic regulation in bacteria.

Author

Adhikari, Satish and Curtis, Patrick D.

Subjects

*DNA methylation, *DNA methyltransferases, *EPIGENETICS, *DNA repair, *DNA replication

Abstract

Epigenetics is a change in gene expression that is heritable without a change in DNA sequence itself. This phenomenon is well studied in eukaryotes, particularly in humans for its role in cellular differentiation, X chromosome inactivation and diseases like cancer. However, comparatively little is known about epigenetic regulation in bacteria. Bacterial epigenetics is mainly present in the form of DNA methylation where DNA methyltransferases add methyl groups to nucleotides. This review focuses on two methyltransferases well characterized for their roles in gene regulation: Dam and CcrM. Dam methyltransferase in Escherichia coli is important for expression of certain genes such as the pap operon, as well as other cellular processes like DNA replication initiation and DNA repair. In Caulobacter crescentus and other Alphaproteobacteria, the methyltransferase CcrM is cell cycle regulated and is involved in the cell-cycle-dependent regulation of several genes. The diversity of regulatory targets as well as regulatory mechanisms suggests that gene regulation by methylation could be a widespread and potent method of regulation in bacteria. [ABSTRACT FROM AUTHOR]

Published

2016

14. Epigenetic Modulating Chemicals Significantly Affect the Virulence and Genetic Characteristics of the Bacterial Plant Pathogen Xanthomonas campestris pv. campestris

Author

Baránek, Miroslav, Kováčová, Viera, Gazdík, Filip, Špetík, Milan, Eichmeier, Aleš, Puławska, Joanna, and Baránková, Kateřina

Subjects

DNA methylation, Virulence, dual RNA-seq, Brassica rapa, QH426-470, Xanthomonas campestris, Polymorphism, Single Nucleotide, Article, Epigenesis, Genetic, bacterial epigenetics, Bacterial Proteins, Purines, Genetics, Sirtuins, sense organs, Enzyme Inhibitors

Abstract

Epigenetics is the study of heritable alterations in phenotypes that are not caused by changes in DNA sequence. In the present study, we characterized the genetic and phenotypic alterations of the bacterial plant pathogen Xanthomonas&nbsp, campestris pv. campestris (Xcc) under different treatments with several epigenetic modulating chemicals. The use of DNA demethylating chemicals unambiguously caused a durable decrease in Xcc bacterial virulence, even after its reisolation from infected plants. The first-time use of chemicals to modify the activity of sirtuins also showed some noticeable results in terms of increasing bacterial virulence, but this effect was not typically stable. Changes in treated strains were also confirmed by using methylation sensitive amplification (MSAP), but with respect to registered SNPs induction, it was necessary to consider their contribution to the observed polymorphism. The molecular basis of the altered virulence was deciphered by using dualRNA-seq analysis of treated Xcc strains infecting Brassica&nbsp, rapa plants. The results of the present study should promote more intensive research in the generally understudied field of bacterial epigenetics, where artificially induced modification by epigenetic modulating chemicals can significantly increase the diversity of bacterial properties and potentially contribute to the further development of the fields, such as bacterial ecology and adaptation.

Published

2021

15. Investigation of Burkholderia cepacia Complex Methylomes via Single-Molecule, Real-Time Sequencing and Mutant Analysis.

Author

Mannweiler, Olga, Pinto-Carbó, Marta, Lardi, Martina, Agnoli, Kirsty, and Eberl, Leo

Abstract

Bacterial genomes can be methylated at particular motifs by methyltransferases (MTs). This DNA modification allows restriction endonucleases (REs) to discriminate between self and foreign DNA. While the accepted primary function of such restriction modification (RM) systems is to degrade incoming foreign DNA, other roles of RM systems and lone RE or MT components have been found in genome protection, stability, and the regulation of various phenotypes. The Burkholderia cepacia complex (Bcc) is a group of closely related opportunistic pathogens with biotechnological potential. Here, we constructed and analyzed mutants lacking various RM components in the clinical Bcc isolate Burkholderia cenocepacia H111 and used single-molecule, real-time (SMRT) sequencing of single mutants to assign the B. cenocepacia H111 MTs to their cognate motifs. DNA methylation is shown to affect biofilm formation, cell shape, motility, siderophore production, and membrane vesicle production. Moreover, DNA methylation had a large effect on the maintenance of the Bcc virulence megaplasmid pC3. Our data also suggest that the gp51 MT-encoding gene, which is essential in H111 and is located within a prophage, is required for maintaining the bacteriophage in a lysogenic state, thereby ensuring a constant, low level of phage production within the bacterial population. [ABSTRACT FROM AUTHOR]

Published

2021

16. Comparative Genomics Reveals the Diversity of Restriction-Modification Systems and DNA Methylation Sites in Listeria monocytogenes

Author

Tyson A. Clark, Khai Luong, Henk C. den Bakker, Meredith Ashby, Martin Wiedmann, Dylan Storey, Jonas Korlach, Bart C. Weimer, Poyin Chen, Nguyet Kong, Ellen E. Paxinos, and Drake, Harold L

Subjects

0301 basic medicine, SMRT sequencing, medicine.disease_cause, Applied Microbiology and Biotechnology, Genome, 2.2 Factors relating to the physical environment, 2.1 Biological and endogenous factors, Aetiology, genome analysis, Genetics, DNA methylation, Ecology, Bacterial, Genomics, Foodborne Illness, bacterial epigenetics, Infectious Diseases, Biotechnology, L. monocytogenes, genetic epidemiology, Listeria, 030106 microbiology, Biology, Microbiology, Synteny, DNA sequencing, Vaccine Related, 03 medical and health sciences, inversion, Listeria monocytogenes, Biodefense, medicine, DNA Restriction-Modification Enzymes, Evolutionary and Genomic Microbiology, Gene, Comparative genomics, 100K Pathogen Genome Project, Prevention, Human Genome, Epigenome, DNA Methylation, infection, 030104 developmental biology, Emerging Infectious Diseases, methylation, virulence regulation, Digestive Diseases, Sequence Alignment, Genome, Bacterial, Food Science

Abstract

Listeria monocytogenes is a bacterial pathogen that is found in a wide variety of anthropogenic and natural environments. Genome sequencing technologies are rapidly becoming a powerful tool in facilitating our understanding of how genotype, classification phenotypes, and virulence phenotypes interact to predict the health risks of individual bacterial isolates. Currently, 57 closed L. monocytogenes genomes are publicly available, representing three of the four phylogenetic lineages, and they suggest that L. monocytogenes has high genomic synteny. This study contributes an additional 15 closed L. monocytogenes genomes that were used to determine the associations between the genome and methylome with host invasion magnitude. In contrast to previous findings, large chromosomal inversions and rearrangements were detected in five isolates at the chromosome terminus and within rRNA genes, including a previously undescribed inversion within rRNA-encoding regions. Each isolate's epigenome contained highly diverse methyltransferase recognition sites, even within the same serotype and methylation pattern. Eleven strains contained a single chromosomally encoded methyltransferase, one strain contained two methylation systems (one system on a plasmid), and three strains exhibited no methylation, despite the occurrence of methyltransferase genes. In three isolates a new, unknown DNA modification was observed in addition to diverse methylation patterns, accompanied by a novel methylation system. Neither chromosome rearrangement nor strain-specific patterns of epigenome modification observed within virulence genes were correlated with serotype designation, clonal complex, or in vitro infectivity. These data suggest that genome diversity is larger than previously considered in L. monocytogenes and that as more genomes are sequenced, additional structure and methylation novelty will be observed in this organism. IMPORTANCE Listeria monocytogenes is the causative agent of listeriosis, a disease which manifests as gastroenteritis, meningoencephalitis, and abortion. Among Salmonella , Escherichia coli , Campylobacter , and Listeria —causing the most prevalent foodborne illnesses—infection by L. monocytogenes carries the highest mortality rate. The ability of L. monocytogenes to regulate its response to various harsh environments enables its persistence and transmission. Small-scale comparisons of L. monocytogenes focusing solely on genome contents reveal a highly syntenic genome yet fail to address the observed diversity in phenotypic regulation. This study provides a large-scale comparison of 302 L. monocytogenes isolates, revealing the importance of the epigenome and restriction-modification systems as major determinants of L. monocytogenes phylogenetic grouping and subsequent phenotypic expression. Further examination of virulence genes of select outbreak strains reveals an unprecedented diversity in methylation statuses despite high degrees of genome conservation.

Published

2017

17. Antibiotic Resistance and Epigenetics: More to It than Meets the Eye.

Author

Ghosh D, Veeraraghavan B, Elangovan R, and Vivekanandan P

Subjects

Bacteria genetics, Bacterial Infections microbiology, Humans, Anti-Bacterial Agents pharmacology, Bacteria drug effects, Bacterial Infections drug therapy, Drug Resistance, Microbial genetics, Epigenesis, Genetic

Abstract

The discovery of antibiotics in the last century is considered one of the most important achievements in the history of medicine. Antibiotic usage has significantly reduced morbidity and mortality associated with bacterial infections. However, inappropriate use of antibiotics has led to emergence of antibiotic resistance at an alarming rate. Antibiotic resistance is regarded as a major health care challenge of this century. Despite extensive research, well-documented biochemical mechanisms and genetic changes fail to fully explain mechanisms underlying antibiotic resistance. Several recent reports suggest a key role for epigenetics in the development of antibiotic resistance in bacteria. The intrinsic heterogeneity as well as transient nature of epigenetic inheritance provides a plausible backdrop for high-paced emergence of drug resistance in bacteria. The methylation of adenines and cytosines can influence mutation rates in bacterial genomes, thus modulating antibiotic susceptibility. In this review, we discuss a plethora of recently discovered epigenetic mechanisms and their emerging roles in antibiotic resistance. We also highlight specific epigenetic mechanisms that merit further investigation for their role in antibiotic resistance., (Copyright © 2020 American Society for Microbiology.)

Published

2020

18. Recent Advances in the Genomic Profiling of Bacterial Epigenetic Modifications.

Author

Liu L, Zhang Y, Jiang D, Du S, Deng Z, Wang L, and Chen S

Subjects

Bacteria genetics, Epigenesis, Genetic genetics, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, DNA methods, Bacteria metabolism, Genome, Bacterial genetics

Abstract

Bacterial epigenetic modifications play key roles in cellular processes such as stress responses, DNA replication, segregation, antimicrobial resistance, etc. In recent years, emerging new sequencing technologies, including single-molecule real-time (SMRT) sequencing, and nanopore sequencing, have enabled the directed reading of epigenetic modifications without pre-treatment of DNA or DNA amplification. The applications of SMRT and nanopore sequencing open the door for the identification of more diverse epigenetic modifications of DNA bases and backbones and potentially facilitate the understanding of the novel functions of these epigenetic markers in cell physiology. With ongoing improvements in throughput and accuracy, new-generation sequencing has become a contender as an alternative to second-generation sequencing technologies. Here, the authors review recent advances in bacterial epigenetic analysis using SMRT sequencing and nanopore sequencing to provide insights regarding the detection and analysis of DNA epigenetic modifications in bacterial genomes., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

19. Global DNA Methylation Level among Ciprofloxacin-Resistant Clinical Isolates of Escherichia coli.

Author

Yugendran T and Harish BN

Abstract

Introduction: Fluoroquinolone resistant clinical isolates belonging to the family Enterobacteriaceae is a major public health concern in India. Data analysis in JIPMER hospital revealed 10% rise in fluoroquinolone resistance within a span of three years suggestive of the possible involvement of mechanism/s other than QRDR capable of imparting fluoroquinolone resistance. DNA methylation regulates gene expression. Moreover, methylated cytosine is a mutational hotspot. Thus, DNA methylation can alter bacterial gene expression profile as well as facilitate the bacteria in accumulating mutations possibly leading to increased antimicrobial resistance. Therefore, the present study was carried out to identify the potential involvement of DNA methylation in ciprofloxacin resistance., Aim: To elucidate and compare the methylation level of genomic and plasmid DNA among clinical isolates of E. coli sensitive and resistant to ciprofloxacin., Materials and Methods: The study included 40 clinical E. coli isolates of which, 30 were ciprofloxacin-resistant and 10 were sensitive to ciprofloxacin. Genomic DNA (gDNA) and plasmid DNA were extracted and quantified. Methylation levels were elucidated using 5-mC DNA ELISA kit (Zymoresearch, California, USA) as per kit protocol and guidelines., Statistical Analysis: Spearman correlation 2-tailed test. A p-value <0.05 was considered significant., Results: The MIC values of sensitive and resistant strains against ciprofloxacin ranged from 0.125 μg/mL - 0.75 μg/mL and 8 μg/mL - >256 μg/mL respectively. No difference was found in plasmid DNA methylation level but, the gDNA methylation level of the resistant strains significantly differed from that of the sensitive strains. Based on Spearman correlation test gDNA methylation level of bacteria was found to be inversely proportional to its MIC against ciprofloxacin with p= -0.956 (p-value < 0.0001)., Conclusion: The influence of DNA methylation over plasmid-mediated quinolone resistance needs to be further confirmed by bisulphite DNA sequencing of the plasmid-borne genes. Extensive usage of ciprofloxacin has led to rise in ciprofloxacin resistance possibly induced by DNA methylation. Thus rational usage of ciprofloxacin in a clinical setting is essential to combat the further development of ciprofloxacin resistance. Hypomethylated genes and adenine methylation needs to identified to fill up gaps in knowledge concerning the involvement of DNA methylation in fluoroquinolone resistance exhibited by E. coli.

Published

2016

20. EPIGENETIC REGULATION IN BREVUNDIMONAS SUBVIBRIOIDES AND COMPARISON WITH THE CAULOBACTER CRESCENTUS MODEL

Author

Patrick Curtis, Colin Jackson, Erik Hom, Adhikari, Satish, Patrick Curtis, Colin Jackson, Erik Hom, and Adhikari, Satish

21. EPIGENETIC REGULATION IN BREVUNDIMONAS SUBVIBRIOIDES AND COMPARISON WITH THE CAULOBACTER CRESCENTUS MODEL

Author

Patrick Curtis, Colin Jackson, Erik Hom, Adhikari, Satish, Patrick Curtis, Colin Jackson, Erik Hom, and Adhikari, Satish

22. EPIGENETIC REGULATION IN BREVUNDIMONAS SUBVIBRIOIDES AND COMPARISON WITH THE CAULOBACTER CRESCENTUS MODEL

Author

Patrick Curtis, Colin Jackson, Erik Hom, Adhikari, Satish, Patrick Curtis, Colin Jackson, Erik Hom, and Adhikari, Satish

23. EPIGENETIC REGULATION IN BREVUNDIMONAS SUBVIBRIOIDES AND COMPARISON WITH THE CAULOBACTER CRESCENTUS MODEL

Author

Patrick Curtis, Colin Jackson, Erik Hom, Adhikari, Satish, Patrick Curtis, Colin Jackson, Erik Hom, and Adhikari, Satish

24. EPIGENETIC REGULATION IN BREVUNDIMONAS SUBVIBRIOIDES AND COMPARISON WITH THE CAULOBACTER CRESCENTUS MODEL

Author

Patrick Curtis, Colin Jackson, Erik Hom, Adhikari, Satish, Patrick Curtis, Colin Jackson, Erik Hom, and Adhikari, Satish

25. EPIGENETIC REGULATION IN BREVUNDIMONAS SUBVIBRIOIDES AND COMPARISON WITH THE CAULOBACTER CRESCENTUS MODEL

Author

Patrick Curtis, Colin Jackson, Erik Hom, Adhikari, Satish, Patrick Curtis, Colin Jackson, Erik Hom, and Adhikari, Satish