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.
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.
Ralstonia solanacearum species complex (RSSC) is a destructive group of plant pathogenic bacteria and the causative agent of bacterial wilt disease. Experimental studies have attributed RSSC virulence to insertion sequences (IS), transposable genetic elements which can both disrupt and activate host genes. Yet, the global diversity and distribution of RSSC IS are unknown. In this study, IS were bioinformatically identified in a diverse collection of 356 RSSC isolates representing five phylogenetic lineages and their diversity investigated based on genetic distance measures and comparisons with the ISFinder database. IS phylogenetic associations were determined based on their distribution across the RSSC phylogeny. Moreover, IS positions within genomes were characterised and their potential gene disruptions determined based on IS proximity to coding sequences. In total, we found 24732 IS belonging to eleven IS families and 26 IS subgroups with over half of the IS found in the megaplasmid. While IS families were generally widespread across the RSSC phylogeny, IS subgroups showed strong lineage-specific distributions and genetically similar bacterial isolates had similar IS contents. Similar associations with bacterial host genetic background were also observed with IS insertion positions which were highly conserved in closely related bacterial isolates. Finally, IS were found to disrupt genes with predicted functions in virulence, stress tolerance, and metabolism suggesting that they might be adaptive. This study highlights that RSSC insertion sequences track the evolution of their bacterial hosts potentially contributing to both intra- and inter-lineage genetic diversity.
Ralstonia solanacearumis aplant pathogenic gram-negative bacterium capable of infecting several economically important crops such as potato and tomato. It can also persist in environmental reservoirs including soils, rivers and in asymptomatic wild hosts, causing disease outbreaks during pathogen spillover events when crossing agroecological interface. In the UK, R. solanacearum outbreaks originate from Solanum dulcamarawild hosts (woody nightshade) and river networks. To what extent selection in these natural environments drive R. solanacearumsurvival and life history evolution including virulence is unknown. To study this, we focused on a largely clonal R. solanacearum lineage inhabiting river networks across the UK consisting of a collection of 182 isolates spanning 30 years since the first outbreak in 1992. We first characterised strains phenotypically regarding 32 traits including resource catabolism, virulence and abiotic stress tolerance and then used microbial GWAS techniques to identify links between phenotypic traits and the presence of specific accessory genes. We found that isolates can be clustered into three phenotypic groups, which differed clearly regarding their resource specialism and stress tolerance. No effect of isolation location was found. However, isolates became more variable phenotypically along with time. While only few SNPs were found to vary among all isolates, the presence and absence of certain accessory genes, such asS-layer family protein,could be associated with phenotypic variation in terms ofsurvival in stressful environments. Together, our findings suggest that a low number of accessory genes can cause high phenotypic variability within highly clonal bacterial lineage.
Ralstonia solanacearum is a destructive plant pathogenic bacterium which harbours a wide variety of virulence genes allowing it to infect over 200 plant species worldwide. Its virulence is also affected by the presence of integrated bacteriophages, termed prophages. While several such prophages have been identified, the global distribution and diversity of R. solanacearum prophages is unknown. To study this, we first identified prophages present in a diverse collection of 192 assembled R. solanacearum genomes. Prophage diversity was explored by calculating prophage genetic distances and clustering with characterised prophages in a neighbour-joining tree. Prophage clusters were further verified by assessing gene content, GC content, and prophage length. Prophage identities were determined using the NCBI Virus database, and prophage-encoded virulence genes identified by analysing pangenome content. 343 intact prophages were identified, forming ten prophage clusters with distinct gene content, GC content, and length profiles. Five prophage clusters, containing 159 prophages, belonged to the Inoviridae, Myoviridae, and Siphoviridae phage families. The remaining 184 prophages were uncharacterised and may therefore represent novel prophages. Transcriptional regulators with potential virulence effects were identified in three prophage clusters, including one uncharacterised cluster. These prophage clusters were unequally distributed throughout the R. solanacearum population being host genotype specific. This research demonstrates that R. solanacearum contains a high level of uncharacterised prophage diversity and highlights novel prophages that could contribute to pathogen virulence. Given their potential host-genotype-specific virulence effects, R. solanacearumprophages could be co-evolving with their hosts, and may contribute to global variation in R. solanacearum virulence.
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