The RecA-directed recombination pathway of natural transformation initiates at chromosomal replication forks in the pneumococcus

The characterization of outer membrane vesicles (OMVs) and their role in mediating antibiotic-resistance gene transfer through natural transformation in Riemerella anatipestifer

Riemerella anatipestifer (R. anatipestifer, RA) is the etiological agent of duck serositis, an acute multisystemic disease in ducks that is globally distributed and causes serious economic losses in the duck industry. Despite exhibiting multidrug resistance, the transmission mechanism of its antibiotic resistance genes (ARGs) remains incompletely identified. To contribute to addressing this gap, in this study, outer membrane vesicles (OMVs) from the RA strain CH-1 were isolated and characterized to investigate their involvement in ARG transfer in RA. Sequencing and data analysis revealed that RA CH-1 OMVs had ∼2.04 Mb genomic size, representing 88.3 % of the RA CH-1 genomic length. Proteomic analysis showed that OMVs contained 577 proteins, representing 27.2 % of the bacterial proteins. Subsequent investigations demonstrated that OMVs from antibiotic-resistant strains transferred ARG fragments and plasmids to the sensitive strain RA ATCC11845, relying on the natural transformation system, and the transformants exhibited corresponding resistance. Overall, OMV-mediated horizontal transfer of ARGs serving as a significant mechanism for acquiring multiple resistance genes in R. anatipestifer.

Competence induction of homologous recombination genes protects pneumococcal cells from genotoxic stress

Homologous recombination (HR) is a universally conserved mechanism of DNA strand exchange between homologous sequences, driven in bacteria by the RecA recombinase. HR is key for the maintenance of bacterial genomes via replication fork restart and DNA repair, as well as for their plasticity via the widespread mechanism of natural transformation. Transformation involves the capture and internalization of exogenous DNA in the form of single strands, followed by HR-mediated chromosomal integration. In the human pathogen Streptococcus pneumoniae, transformation occurs during a transient, stress-induced differentiation state called competence. RecA and its partner DNA branch migration translocase RadA are both well conserved and cooperate in HR during transformation and certain genome maintenance pathways. Both recA and radA genes are basally expressed and transcriptionally induced during competence. In this study, we explored the importance of competence induction of recA and radA in transformation and genome maintenance. We confirmed that competence induction of recA, but not radA, was important for transformation. In contrast, we uncovered that the competence induction of both genes was required for optimal tolerance faced with transient exposure to the lethal genotoxic agent methyl methanesulfonate. However, this was not the case for another DNA-damaging agent, norfloxacin. These results show that competence induction of HR effectors is important for the increased tolerance to genotoxic stress provided to competent pneumococci. This reinforces the finding that pneumococcal competence is a stress-sensing mechanism, transiently increasing the expression of some genes not to optimize transformation but to improve survival faced with specific lethal stresses.IMPORTANCEHomologous recombination (HR) is a mechanism of DNA strand exchange important for both the maintenance and plasticity of bacterial genomes. Bacterial HR is driven by the recombinase RecA along with many accessory partner proteins, which define multiple dedicated pathways crucial to genome biology. Thus, a main mechanism of genome plasticity in bacteria is natural genetic transformation, which involves uptake and chromosomal integration of exogenous DNA via HR. In the human pathogen Streptococcus pneumoniae, transformation occurs during a transient, stress-induced physiological state called competence. RecA and the helicase RadA are key for both genome maintenance and transformation, and both are over-produced during competence. Here, we explore the importance of this over-production for transformation and genome maintenance, quantified by tolerance to genotoxic stress. While over-production of RecA was important for both processes, over-production of RadA was required only for genotoxic stress tolerance. This highlights the importance of competence as a stress-responsive mechanism, with induction of HR genes important for genotoxic stress tolerance.

An Extracellular, Ca2+-Activated Nuclease (EcnA) Mediates Transformation in a Naturally Competent Archaeon

Transformation, the uptake of DNA directly from the environment, is a major driver of gene flow in microbial populations. In bacteria, DNA uptake requires a nuclease that processes dsDNA to ssDNA, which is subsequently transferred into the cell and incorporated into the genome. However, the process of DNA uptake in archaea is still unknown. Previously, we cataloged genes essential to natural transformation in Methanococcus maripaludis, but few homologs of bacterial transformation-associated genes were identified. Here, we characterize one gene, MMJJ_16440 (named here as ecnA), to be an extracellular nuclease. We show that EcnA is Ca2+-activated, present on the cell surface, and essential for transformation. While EcnA can degrade several forms of DNA, the highest activity was observed with ssDNA as a substrate. Activity was also observed with circular dsDNA, suggesting that EcnA is an endonuclease. This is the first biochemical characterization of a transformation-associated protein in a member of the archaeal domain and suggests that both archaeal and bacterial transformation initiate in an analogous fashion.

Multitasking functions of bacterial extracellular DNA in biofilms

Bacterial biofilms are intricate ecosystems of microbial communities that adhere to various surfaces and are enveloped by an extracellular matrix composed of polymeric substances. Within the context of bacterial biofilms, extracellular DNA (eDNA) originates from cell lysis or is actively secreted, where it exerts a significant influence on the formation, stability, and resistance of biofilms to environmental stressors. The exploration of eDNA within bacterial biofilms holds paramount importance in research, with far-reaching implications for both human health and the environment. An enhanced understanding of the functions of eDNA in biofilm formation and antibiotic resistance could inspire the development of strategies to combat biofilm-related infections and improve the management of antibiotic resistance. This comprehensive review encapsulates the latest discoveries concerning eDNA, encompassing its origins, functions within bacterial biofilms, and significance in bacterial pathogenesis.