Project description:Plasmid Transfer

Project description:Enterococcus plasmid transfer study using human gut models

Project description:Horizontal gene transfer via plasmid conjugation is a major driving force in microbial evolution. Transfer of conjugative plasmids is a complex process that needs to be synchronized with the physiological state of the bacterial host. While several host transcription factors are known to control the plasmid-borne transfer control genes, RNA-based regulatory circuits for host-plasmid communication remain unknown. Here, we describe a post-transcriptional mechanism whereby the Hfq-dependent small RNA, RprA, inhibits transfer of pSLT, the virulence plasmid of Salmonella enterica. RprA employs two different seed pairing domains to recognize and activate the mRNAs of both the sigma-factor S and RicI, a cytoplasmic membrane protein. The latter is a hitherto unknown conjugation inhibitor whose transcription requires S. Together, RprA and S constitute a feed-forward loop with AND-gate logic which tightly controls RicI synthesis for selective suppression of plasmid conjugation under membrane stress. This study reports the first sRNA-controlled feed-forward loop based on double target activation and an unexpected function for a core-genome encoded small RNA in controlling extrachromosomal DNA transfer.

Project description:Escherichia coli Genomes from in situ plasmid transfer study

Project description:The type VI secretion system (T6SS) is a highly sophisticated nanomachine widely used by bacteria to achieve competitive advantage and to potentiate horizontal gene transfer. Plasmid conjugation plays crucial roles in bacterial evolution by driving adaptation to environmental stimuli and pathogenicity. The lethal effect mediated by T6SS is detrimental to horizontal gene transfer by conjugation, while bacteria have evolved T6SS repression mechanisms regulated by plasmid to accomplish conjugative transfer. Two TetR family regulators encoded by large conjugative plasmid (LCP) in Acinetobacter baumannii have been proved similar in T6SS restriction, which seems redundant in function. Here, the global regulation roles and multiple DNA binding sites of two plasmid-sourced TetRs were identified. The two TetRs showed distinct preferences in similar roles of T6SS inhibition and binding with DNA probes. Crystal structures of TetRs were solved for illuminating the regulatory mechanism and possible reasons for difference in functions. In addition, plasmid-sourced TetRs also significantly downregulated biofilm formation and bacterial colonization, as well as influenced bacterial virulence in cultured cells and murine pneumonia infection models. Taken together, this work comprehensively elucidates the roles and regulatory mechanisms of TetRs and clarifies their similarity and difference in function, providing insights into plasmid encoded chromosome regulation pathways.

Project description:Plasmid fitness is directed by two orthogonal processes—vertical transfer through cell division and horizontal transfer through conjugation. When considered individually, improvements in either mode of transfer can promote how well a plasmid spreads and persists. Together, however, the metabolic cost of conjugation could create a tradeoff that constrains plasmid evolution. Here we present evidence for the presence, consequences, and molecular basis of a conjugation-growth tradeoff across 40 plasmids derived from clinical E. coli pathogens. We discover that most plasmids operate below a conjugation efficiency threshold for major growth effects, indicating strong natural selection for vertical transfer. Below this threshold, E. coli demonstrates a remarkable growth tolerance to over four orders of magnitude change in conjugation efficiency. This tolerance fades as nutrients become scarce and horizontal transfer attracts a greater share of host resources. Our results provide insight into evolutionary constraints directing plasmid fitness and strategies to combat the spread of antibiotic resistance.

Project description:To search potential point mutation in J2530 strain which could suppress uvrD252 effect on conjugative plasmid transfer

Project description:The type VI secretion system (T6SS) is a highly sophisticated nanomachine widely used by bacteria to achieve competitive advantage and to potentiate horizontal gene transfer. Plasmid conjugation plays crucial roles in bacterial evolution by driving adaptation to environmental stimuli and pathogenicity. The lethal effect mediated by T6SS is detrimental to horizontal gene transfer by conjugation, while bacteria have evolved T6SS repression mechanisms regulated by plasmid to accomplish conjugative transfer. Two TetR family regulators encoded by large conjugative plasmid (LCP) in Acinetobacter baumannii have been proved similar in T6SS restriction, which seems redundant in function. Here, the global regulation roles and multiple DNA binding sites of two plasmid-sourced TetRs were identified. The two TetRs showed distinct preferences in similar roles of T6SS inhibition and binding with DNA probes. Crystal structures of TetRs were solved for illuminating the regulatory mechanism and possible reasons for difference in functions. In addition, plasmid-sourced TetRs also significantly downregulated biofilm formation and bacterial colonization, as well as influenced bacterial virulence in cultured cells and murine pneumonia infection models. Taken together, this work comprehensively elucidates the roles and regulatory mechanisms of TetRs and clarifies their similarity and difference in function, providing insights into plasmid encoded chromosome regulation pathways.

Project description:Rhizobia are gram-negative bacteria able to establish a symbiotic interaction with leguminous plants. Due to their nitrogen fixing capacity, the study of these microorganisms has acquired great relevance for the agriculture. Rhizobia usually harbor many plasmids in their genome which can be transferred to other organisms by conjugation. Two main mechanisms of regulation of rhizobial plasmid transfer have been described: Quorum sensing (QS) and rctA/rctB system. Nevertheless, new genes and molecules that modulate conjugative transfer have been recently described, demonstrating that new actors can tightly regulate the process. In this work, by means of bioinformatics tools and molecular biology approaches, two hypothetical genes are identified as playing key roles in conjugative transfer. These genes are located between conjugative genes of plasmid pLPU83a from Rhizobium favelukesii LPU83, a plasmid that showed a conjugative transfer behavior depending on the genomic background. One of the two mentioned genes, rcgA, is essential for conjugation, while the other, rcgR, acts as an inhibitor of the process. In addition to introducing this new regulatory mechanism, we show evidence of the functions of these genes in different genomic backgrounds, and confirmed that homologous proteins from non-closely related organisms play the same function. These findings set up a cornerstone for a new molecular circuit of conjugative transfer of plasmids.

Project description:Plasmid conjugation is a key facilitator of horizontal gene transfer. Since plasmids often carry antibiotic resistance genes, they are crucial drivers of the world-wide rise of antibiotic resistance among pathogens. In natural, engineered and clinical environments, bacteria often grow in protective biofilms. Therefore, a better understanding of plasmid transfer in biofilms is needed. Our aim was to investigate plasmid transfer in a biofilm adapted wrinkly colony mutant of Xanthomonas retroflexus (XRw) with enhanced matrix production and reduced motility. We found that XRw biofilms had an increased uptake of the broad host-range IncP-1ϵ plasmid pKJK5 compared to the wild type. Proteomics revealed fewer flagellum associated proteins in XRw, suggesting that flagella were responsible for reducing plasmid uptake. This was confirmed by the higher plasmid uptake of non-flagellated ∆fliM mutants of X. retroflexus wild type and wrinkly mutant. Moreover, testing several flagella mutants of Pseudomonas putida suggested that the flagella effect was more general. We identified seven mechanisms with the potential to explain the flagella effect and simulated them in an individual-based model. Two mechanisms could thus be eliminated (increased distances between cells and increased lag times due to flagella). Another mechanism identified as viable in the modelling was eliminated by further experiments. Four additional proposed mechanisms have a reduced probability of plasmid transfer in common. Our findings highlight the important yet complex effects of flagella during bacterial conjugation in biofilms.