Fate of DNA in eclipse complex during genetic transformation in Streptococcus pneumoniae

Genomics and Genetics of Streptococcus pneumoniae

Ninety years after the discovery of pneumococcal Transformation, and 74 years after the work of Avery and colleagues that identified DNA as the genetic material, Streptococcus pneumoniae is still one of the most important model organism to understand Bacterial Genetics and Genomics. In this Chapter special emphasis has been given to Genomics and to Mobile Genetic Elements (the Mobilome) which greatly contribute to the dynamic variation of pneumococcal genomes by horizontal gene transfer. Other topics include molecular mechanisms of Genetic Transformation, Restriction/Modification Systems, Mismatch DNA Repair, and techniques for construction of genetically engineered pneumococcal strains.

Transformation inStreptococcus pneumoniae: formation of eclipse complex in acoiAmutant implicates CoiA in genetic recombination

CoiA is a transient protein expressed specifically during competence and required for genetic transformation in Streptococcus pneumoniae, but not for DNA uptake. It is widely conserved among Gram-positive bacteria but its function is unknown. Here we report that although the rate of DNA uptake was not affected in a coiA mutant, the internalized donor DNA did not recombine into the host chromosome to form a physical and genetic heteroduplex. Instead, DNA taken up by a coiA mutant accumulated in the form of a single-stranded (ss) DNA-protein complex indistinguishable from the eclipse complex formed as a recombination intermediate in wild-type competent cells. Internalized donor DNA in a dprA mutant did not accumulate either as ss DNA or as an eclipse complex. Together, these results establish that a coiA mutant exhibits a phenotype different from that of dprA or recA mutants, and that CoiA functions at a later step in promoting recombination during genetic transformation in Streptococcus pneumoniae.

An unstable competence-induced protein, CoiA, promotes processing of donor DNA after uptake during genetic transformation in Streptococcus pneumoniae

Natural genetic transformation in Streptococcus pneumoniae entails transcriptional activation of at least two sets of genes. One set of genes, activated by the competence-specific response regulator ComE, is involved in initiating competence, whereas a second set is activated by the competence-specific alternative sigma factor ComX and functions in DNA uptake and recombination. Here we report an initial characterization of CoiA, a ComX-dependent gene product that is induced during competence and is required for transformation. CoiA is widely conserved among gram-positive bacteria, and in streptococci, the entire coiA locus composed of four genes is conserved. By use of immunoblot assay, we show that, similar to its message, CoiA protein is transient, appearing at 10 min and largely disappearing by 30 min post-competence induction. Using complementation analysis, we establish that coiA is the only gene of this induced locus needed for transformability. We find no indication of CoiA having a role in regulating competence. Finally, using 32P- and 3H-labeled donor DNA, we demonstrate that a coiA mutant can internalize normal amounts of donor DNA compared to the wild-type strain but is unable to process it into viable transformants, suggesting a role for CoiA after DNA uptake, either in DNA processing or recombination.

Transformation of Streptococcus pneumoniae relies on DprA- and RecA-dependent protection of incoming DNA single strands

Seventy-five years after the discovery of transformation with Streptococcus pneumoniae, it is remarkable how little we know of the proteins that interact with incoming single strands in the early processing of transforming DNA. In this work, we used as donor DNA in transformation a radioactively labelled homologous fragment to examine the fate of the single-stranded (ssDNA) products of uptake in cells mutant for DprA or RecA, two proteins essential for transformation. Fifteen minutes after uptake, the labelling of specific chromosomal restriction fragments that demonstrated homologous integration in the wild type was not detected in dprA or recA cells, indicating that in the mutants incoming ssDNA could not be processed into recombinants. Investigation of the fate of donor label 1 min after uptake revealed that incoming ssDNA was immediately degraded in the absence of DprA or RecA. Our results demonstrate that incoming ssDNA requires active protection prior to the RecA-driven search for homology and that both DprA and RecA are needed for this protection.

Control of recombination rate during transformation of Streptococcus pneumoniae: an overview

Despite the fact that natural transformation was described long ago in Streptococcus pneumoniae, only a limited number of recombination genes have been identified. Two of them have recently been characterized at the molecular level, recA which encodes a protein essential for homologous recombination and mmsA which encodes the homologue of the Escherichia coli RecG protein. After a survey of the available information regarding the function of RecA, RecG, and other proteins such as the mismatch repair proteins HexA and HexB that can affect the outcome of recombinants, the different levels at which horizontal genetic exchange can be controlled are discussed. It is shown that the specific induction of the recA gene which occurs in competent cells is required for full recombination proficiency. Results regarding the ability of the Hex generalized mismatch repair system to prevent recombination between partially divergent sequences during transformation are also summarized. A structural analysis of homeologous recombinants which suggests that formation of mosaic recombinants can occur independently of mismatch repair in a single-step transformation is also reported. Finally, arguments in favor of an evolutionary origin of transformation as a means of genome evolution are discussed and the different types of recombination events observed which could potentially contribute to S. pneumoniae genome evolution are listed.

The rec locus, a competence-induced operon in Streptococcus pneumoniae

To study competence and the process of transformation (TFN) in pneumococci, we developed a method for isolating TFN- mutants using insertional inactivation coupled with fusions to the gene for alkaline phosphatase (phoA). One TFN- mutant transformed 2 log units less efficiently than the parent strain. Reconstitution of the mutated region revealed a locus, rec, that contains two polycistronic genes, exp10 and the previously identified recA (B. Martin, J. M. Ruellan, J. F. Angulo, R. Devoret, and J. P. Claverys, Nucleic Acids Res. 20:6412, 1992). Exp10 is likely to be a membrane-associated protein, as it has a prokaryotic signal sequence and an Exp10-PhoA fusion localized with cell membranes. On the basis of sequence similarity, pneumococcal RecA is a member of bacterial RecA proteins responsible for homologous recombination of DNA. DNA-RNA hybridization analysis showed that this locus is transcribed as a polycistronic message, with increased transcription occurring during competence. With an Exp10-PhoA chimera used as a reporter, there was a 10-fold increase in the expression of the rec locus during competence while there was only minimal expression under growth conditions that repressed competence. The TFN- mutant containing the exp10-phoA fusion produced activator, a small extracellular polypeptide that induces competence, and the expression of rec was induced in response to activator. Therefore, the rec locus is directly required for genetic transformation and is regulated by the cell signaling mechanism that induces competence.

Genetic transformation in Streptococcus pneumoniae: molecular cloning and characterization of recP, a gene required for genetic recombination

A 225-base-pair fragment of a recombination gene was identified by insertion-duplication mutagenesis and used as a radioactive probe to clone the corresponding rec locus from Streptococcus pneumoniae in Escherichia coli plasmid vectors. Attempts to clone large pieces of this locus were unsuccessful, but small pieces of DNA from this region were cloned in the E. coli transcriptional terminator vectors pKK232-8 and pJDC9. The extent of the rec region, 2.1 to 2.2 kilobases, was defined by determining the competence phenotype of insertion mutations constructed in vitro. A deletion of the rec locus showed it to be necessary for chromosomal integration but not for plasmid establishment. A plasmid carrying the entire locus encoded a 72-kilodalton polypeptide in a cell-free E. coli transcription-translation system.

Localization of competence-induced proteins in Streptococcus pneumoniae

Intracellular locations of 11 proteins associated with the development of competence in Streptococcus pneumoniae were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of subcellular fractions prepared from protoplasts. Controls showed that the competence-induced proteins were stable during the formation of protoplasts at 25 degrees C even though some had a half-life of only 8 min at 37 degrees C. Five competence-induced proteins p38, p27, p19.5, p16, and p14.5, were found in the cytoplasm. Two, p52 and p41, were associated with the membrane, and one, p10, was extracellular. Three others, p50, p36, and p29, were recovered in both cytoplasmic and membrane fractions. No competence-induced protein was detected in the periplasmic fraction except under conditions where leakage of all components was occurring, a phenomenon that was seen in many preparations. Similar fractionation of competent cells soon after uptake of [3H]DNA showed the "eclipse complex" of single-stranded DNA and p19.5 was associated approximately one-third with membranes and two-thirds with cytoplasmic fractions, with almost none in the periplasm. This result suggests strongly that at the time the donor DNA entered the cytosol it was in single-stranded form and it had not yet paired with the recipient DNA.