AI Article Synopsis
- The type VI secretion system (T6SS) in Gram-negative bacteria is a crucial mechanism for delivering toxins and effectors directly to neighboring cells, playing a significant role in bacterial competition and virulence.
- A study involving 1,740 genomes revealed that about 40% of these strains contain multiple T6SS clusters, specifically the i3*, i3
- *, and i4 clusters, with notable clade-specific distributions.
- Phylogenetic analysis suggests that certain T6SS clusters were likely acquired by ancestral species and have undergone gain or loss events throughout evolution, indicating a non-random pattern in the distribution and retention of these clusters among different bacterial clades.
Article Abstract
The type VI secretion system (T6SS) present in many Gram-negative bacteria is a contact-dependent apparatus that can directly deliver secreted effectors or toxins into diverse neighboring cellular targets including both prokaryotic and eukaryotic organisms. Recent reverse genetics studies with T6 core gene loci have indicated the importance of functional T6SS toward overall competitive fitness in various pathogenic spp. To understand the contribution of T6SS toward ecology and evolution of spp., we explored the distribution of the three distinguishable T6SS clusters, i3*, i3***, and i4, in approximately 1,740 genomes, along with their conservation, genetic organization, and their evolutionary patterns in this genus. Screening genomes for core genes of each T6 cluster indicated that 40% of the sequenced strains possess two T6 clusters, with combinations of i3*** and i3* or i3*** and i4. A few strains of , , and were the exception, possessing a unique combination of i3* and i4. The findings also indicated clade-specific distribution of T6SS clusters. Phylogenetic analysis demonstrated that T6SS clusters i3* and i3*** were probably acquired by the ancestor of the genus , followed by gain or loss of individual clusters upon diversification into subsequent clades. T6 i4 cluster has been acquired in recent independent events by group 2 xanthomonads followed by its spread via horizontal dissemination across distinct clades across groups 1 and 2 xanthomonads. We also noted reshuffling of the entire core T6 loci, as well as T6SS spike complex components, and , among different species. Our findings indicate that gain or loss events of specific T6SS clusters across phylogeny have not been random.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9048695 | PMC |
| http://dx.doi.org/10.3389/fmicb.2022.840308 | DOI Listing |
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