Influence of DNA conformation and role of comA and recA on natural transformation in Ralstonia solanacearum.

Naturally competent bacteria such as the plant pathogen Ralstonia solanacearum are characterized by their ability to take up free DNA from their surroundings. In this study, we investigated the efficiency of various DNA types including chromosomal linear DNA and circular or linearized integrative and (or) replicative plasmids to naturally transform R. solanacearum. To study the respective regulatory role of DNA transport and maintenance in the definite acquisition of new DNA by bacteria, the natural transformation frequencies were compared with those obtained when the bacterial strain was transformed by electroporation. An additional round of electrotransformation and natural transformation was carried out with the same set of donor DNAs and with R. solanacearum disrupted mutants that were potentially affected in competence (comA gene) and recombination (recA gene) functions. Our results confirmed the critical role of the comA gene for natural transformation and that of recA for recombination and, more surprisingly, for the maintenance of an autonomous plasmid in the host cell. Finally, our results showed that homologous recombination of chromosomal linear DNA fragments taken up by natural transformation was the most efficient way for R. solanacearum to acquire new DNA, in agreement with previous data showing competence development and natural transformation between R. solanacearum cells in plant tissues.

Natural transformation-based foreign DNA acquisition in a Ralstonia solanacearum mutS mutant.

Mutator strains with defective methyl-mismatch repair (MMR) systems have been shown to play an important role in adaptation of bacterial populations to changing and stressful environments. In this report, we describe the impact of mutS::aacC3-IV inactivation on foreign DNA acquisition by natural transformation in the phytopathogenic bacterium Ralstonia solanacearum. A mutS mutant of R. solanacearum exhibited 33- to 60-fold greater spontaneous mutation frequencies, in accordance with a mutator phenotype. Transformation experiments indicated that intra- and interspecific DNA transfers increased up to 89-fold. To assess horizontal gene transfer (HGT) from genetically modified plants to R. solanacearum, fitness of the mutator was first evaluated in soil and plant environments. Competitiveness was not modified after 61 days in soil and 8 days in tomato, and the progress of plant decay symptoms was similar to that of the wild-type strain. Despite its survival in soil and in planta, and the powerful capacities of HGT, R. solanacearum was not genetically transformed by transgenic plant DNA in a wide range of in vitro and in planta tests.