Functional characterization of the competence protein DprA/Smf in Escherichia coli

In several bacterial species that show natural transformation, dprA has been described as a competence gene. The DprA protein has been suggested to be involved in the protection of incoming DNA. However, members of the dprA gene family (also called smf) can be detected in virtually all bacterial species, which suggests that their gene products have a more general function. We examined the function of the DprA/Smf homologue of Escherichia coli. Escherichia coli dprA/smf is able to partially restore transformation in a Haemophilus influenzae dprA mutant, which shows that dprA/smf genes from competent and noncompetent species are interchangeable with respect to their involvement in natural transformation. From this, we conclude that natural transformation is probably an additional function of these genes. Subsequently, the dprA/smf gene was deleted in various recombination mutants of E. coli, and the resultant phenotype was tested. All the resultant E. coli dprA/smf mutants did not differ from their parent strains with respect to transformation, Hfr-conjugation, recombination and DNA repair. Therefore, a role of DprA/Smf in DNA recombination could not be established and the basic function of dprA/smf remains unclear.     

Conservation of key elements of natural competence in Lactococcus lactis ssp

Natural competence is active in very diverse species of the bacterial kingdom and probably participates in horizontal gene transfer. Recently, the genome sequence of various species, including Lactococcus lactis, revealed the presence of homologues of competence genes in bacteria, which were not previously identified as naturally transformable. We investigated the conservation among lactococcal strains of key components of the natural competence process in streptococci: (i) comX which encodes a sigma factor, allowing the expression of the late competence genes involved in DNA uptake, (ii) its recognition site, the cin-box and (iii) dprA which encodes a protein shown to determine the fate of incoming DNA. The comX and dprA genes and the cin-box appeared conserved among strains, although some L. lactis ssp. lactis strains presented an inactivated dprA gene. We established that ComX controls the expression of the late competence genes in L. lactis. In conclusion, our work strongly suggests that ComX has the same role in streptococci and L. lactis, i.e. the regulation of late competence genes. It also allowed the identification of a set of L. lactis strains and the construction of a comX overexpression system, which should facilitate the investigation of the natural competence activity in lactococci.