Diversity and Evolutionary Dynamics of Antiphage Defense Systems in Ralstonia solanacearum Species Complex

Castillo, José A. García del; Secaira-Morocho, Henry; Maldonado, Stephanie; Sarmiento, Katlheen N.

doi:10.3389/fmicb.2020.00961

Cited by 12 publications

(11 citation statements)

References 78 publications

(64 reference statements)

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“…We also observed the presence of methyltransferases in both genomes (ORF145 in vB_KpnM-VAC13 and ORF123 in vB_KpnM-VAC66), that are able to methylate the phage DNA to evade attacks of the bacterial restriction enzymes, involved in the restriction/methylation defense system [29]. These proteins play a role in the phage defense against their hosts, together with other mechanisms [30].…”

Section: Interference With Bacterial Metabolism and Defensementioning

confidence: 81%

Phenotypic and Genomic Comparison of Klebsiella pneumoniae Lytic Phages: vB_KpnM-VAC66 and vB_KpnM-VAC13

Pacios

Fernández-García

Bleriot

et al. 2021

Viruses

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Klebsiella pneumoniae is a human pathogen that worsens the prognosis of many immunocompromised patients. Here, we annotated and compared the genomes of two lytic phages that infect clinical strains of K. pneumoniae (vB_KpnM-VAC13 and vB_KpnM-VAC66) and phenotypically characterized vB_KpnM-VAC66 (time of adsorption of 12 min, burst size of 31.49 ± 0.61 PFU/infected cell, and a host range of 20.8% of the tested strains). Transmission electronic microscopy showed that vB_KpnM-VAC66 belongs to the Myoviridae family. The genomic analysis of the phage vB_KpnM-VAC66 revealed that its genome encoded 289 proteins. When compared to the genome of vB_KpnM-VAC13, they showed a nucleotide similarity of 97.56%, with a 93% of query cover, and the phylogenetic study performed with other Tevenvirinae phages showed a close common ancestor. However, there were 21 coding sequences which differed. Interestingly, the main differences were that vB_KpnM-VAC66 encoded 10 more homing endonucleases than vB_KpnM-VAC13, and that the nucleotidic and amino-acid sequences of the L-shaped tail fiber protein were highly dissimilar, leading to different three-dimensional protein predictions. Both phages differed significantly in their host range. These viruses may be useful in the development of alternative therapies to antibiotics or as a co-therapy increasing its antimicrobial potential, especially when addressing multidrug resistant (MDR) pathogens.

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Section: Interference With Bacterial Metabolism and Defensementioning

confidence: 81%

Phenotypic and Genomic Comparison of Klebsiella pneumoniae Lytic Phages: vB_KpnM-VAC66 and vB_KpnM-VAC13

Pacios

Fernández-García

Bleriot

et al. 2021

Viruses

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“…These may have been geographical barriers as the phylotypes are thought to have arisen from geographical isolation (98) although prophages were found to have widespread, often overlapping, geographical distributions. Alternatively, inter-phylotype prophage transmission may be limited by biological transmission barriers, such as phage defence systems, which are abundant in R. solanacearum (7). Furthermore, it is possible that prophages could encode specific auxiliary genes that lead to phylotype-specific ecological differences, which reduce the likelihood of strains coexistence and horizontal movement of prophages.…”

Section: Discussionmentioning

confidence: 99%

“…Lytic phages can impose strong bottom-up density regulation of bacteria across different ecosystems, driving nutrient turnover by infecting their host bacteria (5,6). They can also drive bacterial diversification through frequency-dependent selection (5), whilst selecting for phage resistance evolution via the acquisition of phage defence systems (7) and cell membrane alterations that disrupt phage infection (8). As phage resistance mechanisms are often associated with fitness trade-offs (9,10), these evolutionary changes can further alter phage-bacteria population dynamics leading to eco-evolutionary feedbacks in microbial communities (for review see (11)).…”

Section: Introductionmentioning

confidence: 99%

Global diversity and distribution of prophages are lineage-specific within the Ralstonia solanacearum plant pathogenic bacterium species complex

Greenrod

Stoycheva

Elphinstone

et al. 2021

Preprint

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Ralstonia solanacearum is a destructive plant pathogenic bacterium and the causative agent of bacterial wilt disease, infecting over 200 plant species worldwide. In addition to chromosomal genes, its virulence is mediated by mobile genetic elements including integrated DNA of bacteriophages, i.e. prophages, which may carry fitness-associated auxiliary genes or modulate host gene expression. Although experimental studies have characterised several prophages that shape R. solanacearum virulence, the global diversity, distribution, and wider functional gene content of R. solanacearum prophages is unknown. In this study, prophages were identified in a diverse collection of 192 R. solanacearum draft genome assemblies originating from six continents. Prophages were identified bioinformatically and their diversity investigated using genetic distance measures, gene content, GC, and total length. Prophage distribution was characterised using metadata on R. solanacearum geographic origin and lineage classification (phylotypes), and their functional gene content was assessed by identifying putative prophage-encoded auxiliary genes. In total, 343 intact prophages were identified, forming ten genetically distinct clusters. These included five prophage clusters belonging to the Inoviridae, Myoviridae, and Siphoviridae phage families, and five uncharacterised clusters, possibly representing novel, previously undescribed phages. The prophages had broad geographical distribution being present across multiple continents. However, they were generally host phylogenetic lineage-specific, and overall, prophage diversity was proportional to the genetic diversity of their hosts. The prophages contained a myriad of auxiliary genes involved in metabolism and virulence of both phage and bacteria. Our results show that while R. solanacearum prophages are highly diverse globally, they make lineage-specific contributions to the R. solanacearum accessory genome, which could result from shared coevolutionary history.

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“…Lytic phages can impose strong bottom-up density regulation of bacteria across different ecosystems, driving nutrient turnover by infecting their host bacteria [ 5 , 6 ]. They can also drive bacterial diversification through frequency-dependent selection [ 5 ], whilst selecting for phage resistance evolution via the acquisition of phage defence systems [ 7 ] and cell membrane alterations that disrupt phage infection [ 8 ]. In contrast, temperate prophages tend to have a more modest effect on bacterial population dynamics as they often replicate during bacterial cell division and become lytic only when induced by environmental stresses such as UV irradiation or antibiotic treatment [ 9 , 10 ].…”

Section: Introductionmentioning

confidence: 99%

Global diversity and distribution of prophages are lineage-specific within the Ralstonia solanacearum species complex

et al. 2022

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Background Ralstonia solanacearum species complex (RSSC) strains are destructive plant pathogenic bacteria and the causative agents of bacterial wilt disease, infecting over 200 plant species worldwide. In addition to chromosomal genes, their virulence is mediated by mobile genetic elements including integrated DNA of bacteriophages, i.e., prophages, which may carry fitness-associated auxiliary genes or modulate host gene expression. Although experimental studies have characterised several prophages that shape RSSC virulence, the global diversity, distribution, and wider functional gene content of RSSC prophages are unknown. In this study, prophages were identified in a diverse collection of 192 RSSC draft genome assemblies originating from six continents. Results Prophages were identified bioinformatically and their diversity investigated using genetic distance measures, gene content, GC, and total length. Prophage distributions were characterised using metadata on RSSC strain geographic origin and lineage classification (phylotypes), and their functional gene content was assessed by identifying putative prophage-encoded auxiliary genes. In total, 313 intact prophages were identified, forming ten genetically distinct clusters. These included six prophage clusters with similarity to the Inoviridae, Myoviridae, and Siphoviridae phage families, and four uncharacterised clusters, possibly representing novel, previously undescribed phages. The prophages had broad geographical distributions, being present across multiple continents. However, they were generally host phylogenetic lineage-specific, and overall, prophage diversity was proportional to the genetic diversity of their hosts. The prophages contained many auxiliary genes involved in metabolism and virulence of both phage and bacteria. Conclusions Our results show that while RSSC prophages are highly diverse globally, they make lineage-specific contributions to the RSSC accessory genome, which could have resulted from shared coevolutionary history.

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Diversity and Evolutionary Dynamics of Antiphage Defense Systems in Ralstonia solanacearum Species Complex

Cited by 12 publications

References 78 publications

Phenotypic and Genomic Comparison of Klebsiella pneumoniae Lytic Phages: vB_KpnM-VAC66 and vB_KpnM-VAC13

Phenotypic and Genomic Comparison of Klebsiella pneumoniae Lytic Phages: vB_KpnM-VAC66 and vB_KpnM-VAC13

Global diversity and distribution of prophages are lineage-specific within the Ralstonia solanacearum plant pathogenic bacterium species complex

Global diversity and distribution of prophages are lineage-specific within the Ralstonia solanacearum species complex

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