Comparative genomic analysis of Streptococcus suis reveals significant genomic diversity among different serotypes

ABSTRACT Whole-genome sequencing has been skewed toward bacterial pathogens as a consequence of the prioritization of medical and veterinary diseases. However, it is becoming clear that in order to accurately measure genetic variation within and between pathogenic groups, multiple isolates, as well as commensal species, must be sequenced. This study examined the pangenomic content of Escherichia coli. Six distinct E. coli pathovars can be distinguished using molecular or phenotypic markers, but only two of the six pathovars have been subjected to any genome sequencing previously. Thus, this report provides a seminal description of the genomic contents and unique features of three unsequenced pathovars, enterotoxigenic E. coli, enteropathogenic E. coli, and enteroaggregative E. coli. We also determined the first genome sequence of a human commensal E. coli isolate, E. coli HS, which will undoubtedly provide a new baseline from which workers can examine the evolution of pathogenic E. coli. Comparison of 17 E. coli genomes, 8 of which are new, resulted in identification of ∼2,200 genes conserved in all isolates. We were also able to identify genes that were isolate and pathovar specific. Fewer pathovar-specific genes were identified than anticipated, suggesting that each isolate may have independently developed virulence capabilities. Pangenome calculations indicate that E. coli genomic diversity represents an open pangenome model containing a reservoir of more than 13,000 genes, many of which may be uncharacterized but important virulence factors. This comparative study of the species E. coli, while descriptive, should provide the basis for future functional work on this important group of pathogens.

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Comparative genomic analysis shows that Streptococcus suis meningitis isolate SC070731 contains a unique 105K genomic island

Gene ◽

10.1016/j.gene.2013.11.044 ◽

2014 ◽

Vol 535 (2) ◽

pp. 156-164 ◽

Cited By ~ 24

Author(s):

Zongfu Wu ◽

Weixue Wang ◽

Min Tang ◽

Jing Shao ◽

Chen Dai ◽

...

Keyword(s):

Genomic Island ◽

Genomic Analysis ◽

Streptococcus Suis ◽

Comparative Genomic Analysis ◽

Comparative Genomic

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Comparative genomic analysis of twelve Streptococcus suis (pro)phages

Genomics ◽

10.1016/j.ygeno.2013.04.005 ◽

2013 ◽

Vol 101 (6) ◽

pp. 336-344 ◽

Cited By ~ 25

Author(s):

Fang Tang ◽

Alex Bossers ◽

Frank Harders ◽

Chengping Lu ◽

Hilde Smith

Keyword(s):

Genomic Analysis ◽

Streptococcus Suis ◽

Comparative Genomic Analysis ◽

Comparative Genomic

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Comparative Genomic Analysis of Rhodococcus equi: An Insight into Genomic Diversity and Genome Evolution

International Journal of Genomics ◽

10.1155/2019/8987436 ◽

2019 ◽

Vol 2019 ◽

pp. 1-14

Author(s):

Jianchao Ying ◽

Jun Ye ◽

Teng Xu ◽

Qian Wang ◽

Qiyu Bao ◽

...

Keyword(s):

Core Genome ◽

Genomic Analysis ◽

Rhodococcus Equi ◽

Comparative Genomic Analysis ◽

Genomic Islands ◽

Genomic Diversity ◽

Comparative Genomic ◽

Niche Adaptation ◽

Genomic Studies ◽

Insight Into

Rhodococcus equi, a member of the Rhodococcus genus, is a gram-positive pathogenic bacterium. Rhodococcus possesses an open pan-genome that constitutes the basis of its high genomic diversity and allows for adaptation to specific niche conditions and the changing host environments. Our analysis further showed that the core genome of R. equi contributes to the pathogenicity and niche adaptation of R. equi. Comparative genomic analysis revealed that the genomes of R. equi shared identical collinearity relationship, and heterogeneity was mainly acquired by means of genomic islands and prophages. Moreover, genomic islands in R. equi were always involved in virulence, resistance, or niche adaptation and possibly working with prophages to cause the majority of genome expansion. These findings provide an insight into the genomic diversity, evolution, and structural variation of R. equi and a valuable resource for functional genomic studies.

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Comparative genomic analysis of Mycobacterium intracellulare: implications for clinical taxonomic classification in pulmonary Mycobacterium avium-intracellulare complex disease

BMC Microbiology ◽

10.1186/s12866-021-02163-9 ◽

2021 ◽

Vol 21 (1) ◽

Author(s):

Yoshitaka Tateishi ◽

Yuriko Ozeki ◽

Akihito Nishiyama ◽

Mari Miki ◽

Ryoji Maekura ◽

...

Keyword(s):

Complex Disease ◽

Genomic Analysis ◽

Comparative Genomic Analysis ◽

Genomic Diversity ◽

Comparative Genomic ◽

Mycobacterium Intracellulare ◽

Clinical Strains ◽

Genetic Components ◽

Genomic Regions ◽

Insight Into

Abstract Background Mycobacterium intracellulare is a representative etiological agent of emerging pulmonary M. avium-intracellulare complex disease in the industrialized countries worldwide. The recent genome sequencing of clinical strains isolated from pulmonary M. avium-intracellulare complex disease has provided insight into the genomic characteristics of pathogenic mycobacteria, especially for M. avium; however, the genomic characteristics of M. intracellulare remain to be elucidated. Results In this study, we performed comparative genomic analysis of 55 M. intracellulare and related strains such as M. paraintracellulare (MP), M. indicus pranii (MIP) and M. yonogonense. Based on the average nucleotide identity, the clinical M. intracellulare strains were phylogenetically grouped in two clusters: (1) the typical M. intracellulare (TMI) group, including ATCC13950 and virulent M.i.27 and M.i.198 that we previously reported, and (2) the MP-MIP group. The alignment of the genomic regions was mostly preserved between groups. Plasmids were identified between groups and subgroups, including a plasmid common among some strains of the M.i.27 subgroup. Several genomic regions including those encoding factors involved in lipid metabolism (e.g., fadE3, fadE33), transporters (e.g., mce3), and type VII secretion system (genes of ESX-2 system) were shown to be hypermutated in the clinical strains. M. intracellulare was shown to be pan-genomic at the species and subspecies levels. The mce genes were specific to particular subspecies, suggesting that these genes may be helpful in discriminating virulence phenotypes between subspecies. Conclusions Our data suggest that genomic diversity among M. intracellulare, M. paraintracellulare, M. indicus pranii and M. yonogonense remains at the subspecies or genovar levels and does not reach the species level. Genetic components such as mce genes revealed by the comparative genomic analysis could be the novel focus for further insight into the mechanism of human pathogenesis for M. intracellulare and related strains.

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Genomic Analysis of Prophages Recovered from Listeria monocytogenes Lysogens Found in Seafood and Seafood-Related Environment

Microorganisms ◽

10.3390/microorganisms9071354 ◽

2021 ◽

Vol 9 (7) ◽

pp. 1354

Author(s):

Hue Thi Kim Vu ◽

Matthew J. Stasiewicz ◽

Soottawat Benjakul ◽

Kitiya Vongkamjan

Keyword(s):

Mitomycin C ◽

Genomic Analysis ◽

Comparative Genomic Analysis ◽

Genomic Diversity ◽

Comparative Genomic ◽

Sequence Comparisons ◽

Related Sequence ◽

Geographical Regions ◽

Insertion Sites ◽

The Impact

A prophage is a phage-related sequence that is integrated into a bacterial chromosome. Prophages play an important role in bacterial evolution, survival, and persistence. To understand the impact of Listeria prophages on their host genome organizations, this work sequenced two L. monocytogenes strains (134LM and 036LM), previously identified as lysogens by mitomycin C induction. Draft genomes were generated with assembly sizes of 2,953,877 bp and 3,000,399 bp. One intact prophage (39,532 bp) was inserted into the comK gene of the 134LM genome. Two intact prophages (48,684 bp and 39,488 bp) were inserted in tRNA-Lys and elongation-factor genes of the 036LM genome. The findings confirmed the presence of three corresponding induced phages previously obtained by mitomycin C induction. Comparative genomic analysis of three prophages obtained in the newly sequenced lysogens with 61 prophages found in L. monocytogenes genomes, available in public databases, identified six major clusters using whole genome-based phylogenetic analysis. The results of the comparative genomic analysis of the prophage sequences provides knowledge about the diversity of Listeria prophages and their distribution among Listeria genomes in diverse environments, including different sources or geographical regions. In addition, the prophage sequences and their insertion sites contribute to the genomic diversity of L. monocytogenes genomes. These data of prophage sequences, prophage insertion sites, and prophage sequence comparisons, together with ANIb confirmation, could be useful for L. monocytogenes classification by prophages. One potential development could be refinement of prophage typing tools for monitoring or surveillance of L. monocytogenes contamination and transmission.

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Extensive genomic diversity among Mycobacterium marinum strains revealed by whole genome sequencing

10.1101/249532 ◽

2018 ◽

Author(s):

Sarbashis Das ◽

B. M. Fredrik Pettersson ◽

Phani Rama Krishna Behra ◽

Amrita Mallick ◽

Martin Cheramie ◽

...

Keyword(s):

Genomic Analysis ◽

Skin Lesions ◽

Comparative Genomic Analysis ◽

Mycobacterium Marinum ◽

Genomic Diversity ◽

Ecological Niches ◽

Comparative Genomic ◽

Genome Sequences ◽

Separate Species ◽

Mutational Hotspots

AbstractMycobacterium marinum is the causative agent for the tuberculosis-like disease mycobacteriosis in fish and skin lesions in humans. Ubiquitous in its geographical distribution, M. marinum is known to occupy diverse fish as hosts. However, information about its genomic diversity is limited. Here, we provide the genome sequences for 15 M. marinum strains isolated from infected humans and fish. Comparative genomic analysis of these and four available genomes of the M. marinum strains M, E11, MB2 and Europe reveal high genomic diversity among the strains, leading to the conclusion that M. marinum should be divided into two different clusters, the “M”- and the “Aronson”-type. We suggest that these two clusters should be considered, if not two separate species, at least two M. marinum subspecies. Our data also show that the M. marinum pan-genome for both groups is open and expanding and we provide data showing high number of mutational hotspots in M. marinum relative to other mycobacteria such as Mycobacterium tuberculosis. This high genomic diversity might be related to that M. marinum occupy different ecological niches.

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