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

The acquisition of clinically relevant amoxicillin resistance in Streptococcus pneumoniae requires ordered horizontal gene transfer of four loci

Understanding how antimicrobial resistance spreads is critical for optimal application of new treatments. In the naturally competent human pathogen Streptococcus pneumoniae, resistance to β-lactam antibiotics is mediated by recombination events in genes encoding the target proteins, resulting in reduced drug binding affinity. However, for the front-line antibiotic amoxicillin, the exact mechanism of resistance still needs to be elucidated. Through successive rounds of transformation with genomic DNA from a clinically resistant isolate, we followed amoxicillin resistance development. Using whole genome sequencing, we showed that multiple recombination events occurred at different loci during one round of transformation. We found examples of non-contiguous recombination, and demonstrated that this could occur either through multiple D-loop formation from one donor DNA molecule, or by the integration of multiple DNA fragments. We also show that the final minimum inhibitory concentration (MIC) differs depending on recipient genome, explained by differences in the extent of recombination at key loci. Finally, through back transformations of mutant alleles and fluorescently labelled penicillin (bocillin-FL) binding assays, we confirm that pbp1a, pbp2b, pbp2x, and murM are the main resistance determinants for amoxicillin resistance, and that the order of allele uptake is important for successful resistance evolution. We conclude that recombination events are complex, and that this complexity contributes to the highly diverse genotypes of amoxicillin-resistant pneumococcal isolates.

Fluorescently Labeled DNA Interacts with Competence and Recombination Proteins and Is Integrated and Expressed Following Natural Transformation of Bacillus subtilis

During competence, Bacillus subtilis is able to take up DNA from its environment through the process of transformation. We investigated the ability of B. subtilis to take up fluorescently labeled DNA and found that it is able to take up fluorescein-dUTP-, DyLight 550-dUTP-, and DyLight 650-dUTP-labeled DNA. Transformation with labeled DNA containing an antibiotic cassette resulted in uptake of the labeled DNA and also generated antibiotic-resistant colonies. DNA is primarily taken up at the pole, as it can be seen to colocalize with ComFC, which is a component of the competence machinery. The DNA is taken up rapidly and can be seen to localize with (the actively searching form of) RecA. Colocalization with a homologous locus on the chromosome increases over time. Using microfluidics, we observed replacement of the homologous locus and subsequent expression of the integrated labeled and unlabeled DNA, although whether the integrated DNA contains labeled nucleotides needs to be determined conclusively. Integrated DNA in cells with a doubling time of 60 min is expressed on average 6 h 45 min after the addition of DNA and 4 h 45 min after the addition of fresh medium. We also found that the expression of the incoming DNA under these conditions can occur before cell division and, thus, before complete exit from the competence state. Because the competence machinery is conserved among naturally competent bacteria, this method of labeling is also suitable for studying transformation of other naturally competent bacteria.IMPORTANCE We used DNA that was covalently labeled with fluorescent nucleotides to investigate the transformation process of Bacillus subtilis at the molecular level. We show that the labeled DNA colocalizes with components of the competence machinery, the chromosome, and the recombination protein RecA. Using time-lapse microscopy and microfluidics, we visualized, in real-time, the uptake of fluorescently labeled DNA. We found that under these conditions, cell division is not required for the expression of integrated DNA. Because the competence machinery is conserved in naturally competent bacteria, this method can also be used to investigate the transformation process in many other bacterial species.

The cell pole: the site of cross talk between the DNA uptake and genetic recombination machinery

Natural transformation is a programmed mechanism characterized by binding of free double-stranded (ds) DNA from the environment to the cell pole in rod-shaped bacteria. In Bacillus subtilis some competence proteins, which process the dsDNA and translocate single-stranded (ss) DNA into the cytosol, recruit a set of recombination proteins mainly to one of the cell poles. A subset of single-stranded binding proteins, working as "guardians", protects ssDNA from degradation and limit the RecA recombinase loading. Then, the "mediators" overcome the inhibitory role of guardians, and recruit RecA onto ssDNA. A RecA·ssDNA filament searches for homology on the chromosome and, in a process that is controlled by "modulators", catalyzes strand invasion with the generation of a displacement loop (D-loop). A D-loop resolvase or "resolver" cleaves this intermediate, limited DNA replication restores missing information and a DNA ligase seals the DNA ends. However, if any step fails, the "rescuers" will repair the broken end to rescue chromosomal transformation. If the ssDNA does not share homology with resident DNA, but it contains information for autonomous replication, guardian and mediator proteins catalyze plasmid establishment after inhibition of RecA. DNA replication and ligation reconstitute the molecule (plasmid transformation). In this review, the interacting network that leads to a cross talk between proteins of the uptake and genetic recombination machinery will be placed into prospective.

A high-resolution view of genome-wide pneumococcal transformation

Transformation is an important mechanism of microbial evolution through which bacteria have been observed to rapidly adapt in response to clinical interventions; examples include facilitating vaccine evasion and the development of penicillin resistance in the major respiratory pathogen Streptococcus pneumoniae. To characterise the process in detail, the genomes of 124 S. pneumoniae isolates produced through in vitro transformation were sequenced and recombination events detected. Those recombinations importing the selected marker were independent of unselected events elsewhere in the genome, the positions of which were not significantly affected by local sequence similarity between donor and recipient or mismatch repair processes. However, both types of recombinations were sometimes mosaic, with multiple non-contiguous segments originating from the same molecule of donor DNA. The lengths of the unselected events were exponentially distributed with a mean of 2.3 kb, implying that recombinations are stochastically resolved with a fixed per base probability of 4.4×10(-4) bp(-1). This distribution of recombination sizes, coupled with an observed under representation of large insertions within transferred sequence, suggests transformation has the potential to reduce the size of bacterial genomes, and is unlikely to act as an efficient mechanism for the uptake of accessory genomic loci.

Frequency of mutation to rifampin resistance in Streptococcus pneumoniae clinical strains: hexA and hexB polymorphisms do not account for hypermutation

The frequency of mutation to rifampin resistance of 200 clinical Streptococcus pneumoniae isolates was examined. Two peaks were observed in the distribution, with mode frequencies of 2.5 x 10(-7) (20% of isolates) and 2.5 x 10(-8). The hexA and hexB gene entire sequences were analyzed in 13 isolates. Sequences from both hypermutable and "normomutable" strains were conserved relative to that of the R6 S. pneumoniae control strain. The phenotypic Hex system proficiency, in terms of transforming efficiency, was also maintained irrespective of the variations in mutation frequency values.

Identification of 113 conserved essential genes using a high-throughput gene disruption system in Streptococcus pneumoniae

The recent availability of bacterial genome sequence information permits the identification of conserved genes that are potential targets for novel antibiotic drug discovery. Using a coupled bioinformatic/experimental approach, a list of candidate conserved genes was generated using a Microbial Concordance bioinformatics tool followed by a targeted disruption campaign. Pneumococcal sequence data allowed for the design of precise PCR primers to clone the desired gene target fragments into the pEVP3 'suicide vector'. An insertion-duplication approach was employed that used the pEVP3 constructs and resulted in the introduction of a selectable chloramphenicol resistance marker into the chromosome. In the case of non-essential genes, cells can survive the disruption and form chloramphenicol-resistant colonies. A total of 347 candidate reading frames were subjected to disruption analysis, with 113 presumed to be essential due to lack of recovery of antibiotic-resistant colonies. In addition to essentiality determination, the same high-throughput methodology was used to overexpress gene products and to examine possible polarity effects for all essential genes.

Effect of the Streptococcus pneumoniae MmsA protein on the RecA protein-promoted three-strand exchange reaction. Implications for the mechanism of transformational recombination

Streptococcus pneumoniae is a naturally transformable bacterium that is able to incorporate DNA from its environment into its own chromosome. This process, known as transformational recombination, is dependent in part on the mmsA gene, which encodes a protein having a sequence that is 40% identical to that of the Escherichia coli RecG protein, a junction-specific DNA helicase believed to be involved in the branch migration of recombinational intermediates. We have developed an expression system for the MmsA protein and have purified the MmsA protein to more than 99% homogeneity. The MmsA protein has DNA-dependent ATP hydrolysis and DNA junction-helicase activities that are similar to those of the E. coli RecG protein. The effect of the MmsA protein on the S. pneumoniae RecA protein-promoted three-strand exchange reaction was also investigated. In the standard direction (circular single-stranded (ss) DNA + linear double-stranded (ds) DNA --> linear ssDNA + nicked circular dsDNA), the MmsA protein appears to promote the branch migration of partially exchanged intermediates in a direction opposite of the RecA protein, resulting in a nearly complete inhibition of the overall strand exchange reaction. In the reverse direction (linear ssDNA + nicked circular dsDNA --> circular ssDNA + linear dsDNA), however, the MmsA protein appears to facilitate the conversion of partially exchanged intermediates into fully exchanged products, leading to a pronounced stimulation of the overall reaction. These results are discussed in terms of the molecular mechanism of transformational recombination.

A hypermutator phenotype attenuates the virulence of Listeria monocytogenes in a mouse model

The integrity of the genetic material of bacteria is guaranteed by a set of distinct repair mechanisms. The participation of these repair systems in bacterial pathogenicity has been addressed only recently. Here, we study for the first time the participation in virulence of the MutSL mismatch repair system of Listeria monocytogenes. The mutS and mutL genes, which are contiguous in the L. monocytogenes chromosome, were identified after in silico analysis. The deduced MutS shares 62% identity with MutS of Bacillus subtilis and 50% identity with HexA, its homologue in Streptococcus pneumoniae; MutL shares 59% identity with MutL of B. subtilis and 47% identity with HexB of S. pneumoniae. Functional analysis of the mutSL locus was studied by constructing a double knock-out mutant. We showed that the deletion DeltamutSL induces: (i) a 100- to 1000-fold increase in the spontaneous mutation rate; and (ii) a 10- to 15-fold increase in the frequency of transduction, thus demonstrating the role of mutSL of L. monocytogenes in both mismatch repair and homologous recombination. We found that the deletion DeltamutSL moderately affected bacterial virulence, with a 1-log increase in the lethal dose 50% (LD50) in the mouse. Strikingly, repeated passages of the mutant strain in mice reduced virulence further. Competition assays between wild-type and mutant strains showed that the deletion DeltamutSL reduced the capacity of L. monocytogenes to survive and multiply in mice. These results thus demonstrate that, for the intracellular pathogen L. monocytogenes, a hypermutator phenotype is more deleterious than profitable to its virulence.

Homologous recombination at the border: insertion-deletions and the trapping of foreign DNA in Streptococcus pneumoniae

Integration of foreign DNA was observed in the Gram-positive human pathogen Streptococcus pneumoniae (pneumococcus) after transformation with DNA from a recombinant Escherichia coli bacteriophage lamda carrying a pneumococcal insert. Segments of lamda DNA replaced chromosomal sequences adjacent to the region homologous with the pneumococcal insert, whence the name insertion-deletion. Here we report that a pneumococcal insert was absolutely required for insertion-deletion formation, but could be as short as 153 bp; that the sizes of foreign DNA insertions (289-2,474 bp) and concomitant chromosomal deletions (45-1,485 bp) were not obviously correlated; that novel joints clustered preferentially within segments of high GC content; and that the crossovers in 29 independent novel joints were located 1 bp from the border or within short (3-10 nt long) stretches of identity (microhomology) between resident and foreign DNA. The data are consistent with a model in which the insert serving as a homologous recombination anchor favors interaction and subsequent illegitimate recombination events at microhomologies between foreign and resident sequences. The potential of homology- directed illegitimate recombination for genome evolution was illustrated by the trapping of functional heterologous genes.

Sexual isolation in bacteria

Bacteria exchange genes rarely but are promiscuous in the choice of their genetic partners. Inter-specific recombination has the advantage of increasing genetic diversity and promoting dissemination of novel adaptations, but suffers from the negative effect of importing potentially harmful alleles from incompatible genomes. Bacterial species experience a degree of 'sexual isolation' from genetically divergent organisms - recombination occurs more frequently within a species than between species. In this review, I outline the sources and mechanisms of sexual isolation within the context of selective pressures acting on different types of recombination events.

Do bacteria have sex?

Do bacteria have genes for genetic exchange? The idea that the bacterial processes that cause genetic exchange exist because of natural selection for this process is shared by almost all microbiologists and population geneticists. However, this assumption has been perpetuated by generations of biology, microbiology and genetics textbooks without ever being critically examined.

Purification and characterization of the single-stranded DNA binding protein from Streptococcus pneumoniae

The Escherichia coli single-stranded DNA binding (SSB) protein is a non-sequence-specific DNA binding protein that functions as an accessory factor for the RecA protein-promoted three-strand exchange reaction. An open reading frame encoding a protein similar in size and sequence to the E. coli SSB protein has been identified in the Streptococcus pneumoniae genome. The open reading frame has been cloned, an overexpression system has been developed, and the protein has been purified to greater than 99% homogeneity. The purified protein binds to ssDNA in a manner similar to that of the E. coli SSB protein. The protein also stimulates the S. pneumoniae RecA protein and E. coli RecA protein-promoted strand exchange reactions to an extent similar to that observed with the E. coli SSB protein. These results indicate that the protein is the S. pneumoniae analog of the E. coli SSB protein. The availability of highly-purified S. pneumoniae SSB protein will facilitate the study of the molecular mechanisms of RecA protein-mediated transformational recombination in S. pneumoniae.

Purification and characterization of the RecA protein from Streptococcus pneumoniae

Streptococcus pneumoniae is a naturally transformable bacterium that is able to take up single-stranded DNA from its environment and incorporate the exogenous DNA into its genome. This process, known as transformational recombination, is dependent upon the presence of the recA gene, which encodes an ATP-dependent DNA recombinase whose sequence is 60% identical to that of the RecA protein from Escherichia coli. We have developed an overexpression system for the S. pneumoniae RecA protein and have purified the protein to greater than 99% homogeneity. The S. pneumoniae RecA protein has ssDNA-dependent NTP hydrolysis and NTP-dependent DNA strand exchange activities that are generally similar to those of the E. coli RecA protein. In addition to its role as a DNA recombinase, the E. coli RecA protein also acts as a coprotease, which facilitates the cleavage and inactivation of the E. coli LexA repressor during the SOS response to DNA damage. Interestingly, the S. pneumoniae RecA protein is also able to promote the cleavage of the E. coli LexA protein, even though a protein analogous to the LexA protein does not appear to be present in S. pneumoniae.

An improved vector system for insertional gene inactivation inspired by the tmRNA-tagging system of S. pneumoniae

Insertional mutagenesis is a technique often used to inactivate genes in Streptococcus pneumoniae. Using conventional vectors, a 5' segment of the targeted gene remains under the control of the gene's authentic promoter following gene disruption. Thus, the expression of a functional peptide and the misinterpretation of results in consequence cannot be excluded. To circumvent this problem, we have developed a plasmid for insertional mutagenesis based on the tmRNA-tagging system of S. pneumoniae which ensures that any protein expressed after gene disruption is degraded. Insertional mutagenesis using this vector results in the targeted gene being tagged with a tmRNA-derived sequence coding for a proteolysis tag. Here we show that the translation product of a gene tagged by this method is not detectable by Western blotting, suggesting that the protein was degraded. This modified vector allows total inactivation of genes with a reliability that cannot be achieved by conventional vectors for insertional mutagenesis. This approach can be applied to other bacterial species.

Interspecies recombination between enterococci: genetic and phenotypic diversity of vancomycin-resistant transconjugants

Handwerger and colleagues demonstrated that a particular clinical isolate of Enterococcus faecium, designated GUC, and here redesignated as GUCR, can conjugatively transfer vancomycin resistance. The vancomycin resistance is encoded by a chromosomally born linked set of genes in the donor, designated the vanA cluster, to the chromosome of an E. faecalis recipient, JH2-2. Here it is reported that an earlier isolate of E. faecium from the same patient who later harbored the vancomycin-resistant E. faecium GUCR lacks the vanA gene cluster but is otherwise similar (by SmaI chromosomal fingerprint and metabolic fingerprinting) to the vancomycin-resistant GUCR. Therefore, "GUCS" is a strong suspect as the base strain for the clinical acquisition of the vanA cluster present in GUCR. Thirteen laboratory-generated vanA transconjugants derived from conjugation between GUCR and JH2-2 were subjected to further analysis, allowing a comparison between transfer in the laboratory and transfer that occurred in the clinical setting. Surprisingly, each JH2-2 transconjugant had a unique constellation of abilities to oxidize various members of a panel of potential carbon sources. This pattern was stable for each transconjugant, and it was not changed by growing the strains with or without vancomycin. Transconjugants had pulsed-field gel electrophoretic (PFGE) patterns largely consistent with that of JH2-2, the recipient in conjugation experiments. However, PFGE analysis showed that a large but variable amount of DNA, between 145 kb and 277 kb, was transferred into different transconjugants. The mechanism appears to be conjugative transposition in which new DNA is added to the pre-existing genome rather than substituting for a segment in the recipient. Mapping and hybridization studies of several transconjugants showed that each received similar, but not exactly the same, DNA fragment of at least 30 kb from the donor. Sequencing of 16S ribosomal genes was used to confirm that the recipient and donor strains used in transconjugation experiments were different species. Sequence analysis was also used to consider the possibility that rRNA operons might be mobilized in conjugation, but no evidence for the transfer of rDNA operons was found. An apparent insertion sequence in E. faecium almost identical to IS 1485 and 57% sequence identity to IS 199 of Streptococcus mutans was found in the region of DNA transferred. The results imply new consequences of conjugative transfer and interspecies recombination.

Barriers to genetic exchange between bacterial species: Streptococcus pneumoniae transformation

Interspecies genetic exchange is an important evolutionary mechanism in bacteria. It allows rapid acquisition of novel functions by transmission of adaptive genes between related species. However, the frequency of homologous recombination between bacterial species decreases sharply with the extent of DNA sequence divergence between the donor and the recipient. In Bacillus and Escherichia, this sexual isolation has been shown to be an exponential function of sequence divergence. Here we demonstrate that sexual isolation in transformation between Streptococcus pneumoniae recipient strains and donor DNA from related strains and species follows the described exponential relationship. We show that the Hex mismatch repair system poses a significant barrier to recombination over the entire range of sequence divergence (0.6 to 27%) investigated. Although mismatch repair becomes partially saturated, it is responsible for 34% of the observed sexual isolation. This is greater than the role of mismatch repair in Bacillus but less than that in Escherichia. The remaining non-Hex-mediated barrier to recombination can be provided by a variety of mechanisms. We discuss the possible additional mechanisms of sexual isolation, in view of earlier findings from Bacillus, Escherichia, and Streptococcus.

Adaptation to the environment: Streptococcus pneumoniae, a paradigm for recombination-mediated genetic plasticity?

Genetic plasticity plays a central role in the biology of the human pathogen Streptococcus pneumoniae. This is illustrated by the existence of at least 90 different capsular types (the polysaccharide capsule has an essential antiphagocytic function) as well as by the rapid emergence of penicillin-resistant (PenR) pneumococcal isolates. Natural genetic transformation is believed to be essential for this genetic plasticity; capsular types can be switched by intraspecies transformation, whereas interspecies transformation is responsible for the appearance, in the PenR isolates, of mosaic pbp genes, which encode proteins with reduced affinity for penicillin. Data on the regulation of competence for transformation in S. pneumoniae, on the control of intra- and interspecies genetic exchange and on the shuffling and capture of exogenous sequences during transformation are reviewed. Possible links between transformation and changes in environmental conditions are discussed, and the adaptive 'strategy' deduced for S. pneumoniae is compared with that of Escherichia coli.

Repeated extragenic sequences in prokaryotic genomes: a proposal for the origin and dynamics of the RUP element in Streptococcus pneumoniae

A survey of all Streptococcus pneumoniae GenBank/EMBL DNA sequence entries and of the public domain sequence (representing more than 90% of the genome) of an S. pneumoniae type 4 strain allowed identification of 108 copies of a 107-bp-long highly repeated intergenic element called RUP (for repeat unit of pneumococcus). Several features of the element, revealed in this study, led to the proposal that RUP is an insertion sequence (IS)-derivative that could still be mobile. Among these features are: (1) a highly significant homology between the terminal inverted repeats (IRs) of RUPs and of IS630-Spn1, a new putative IS of S. pneumoniae; and (2) insertion at a TA dinucleotide, a characteristic target of several members of the IS630 family. Trans-mobilization of RUP is therefore proposed to be mediated by the transposase of IS630-Spn1. To account for the observation that RUPs are distributed among four subtypes which exhibit different degrees of sequence homogeneity, a scenario is invoked based on successive stages of RUP mobility and non-mobility, depending on whether an active transposase is present or absent. In the latter situation, an active transposase could be reintroduced into the species through natural transformation. Examination of sequences flanking RUP revealed a preferential association with ISs. It also provided evidence that RUPs promote sequence rearrangements, thereby contributing to genome flexibility. The possibility that RUP preferentially targets transforming DNA of foreign origin and subsequently favours disruption/rearrangement of exogenous sequences is discussed.

Horizontal gene transfers in the environment: natural transformation as a putative process for gene transfers between transgenic plants and microorganisms

Horizontal gene transfers among bacteria, such as natural transformation or conjugation, may have played an important role in bacterial evolution. They are thought to have been involved in promoting genome plasticity which permitted bacteria to adapt very efficiently to any change in their environment and to colonize a wide range of ecosystems. Evidence that some genes were transferred from eukaryotes, and in particular, from plants to bacteria, was obtained from nucleotide and protein sequence analyses. However, numerous factors, including some which are endogenous to the bacterial cells, tend to limit the extent of transfer, particularly among phylogenetically distant organisms. The goal of this paper is to give an overview of the potentials and limits of natural interkingdom gene transfers, with particular focus on prokaryote-originating sequences which fit the nuclear genome of transgenic plants.

Construction and analysis of a library for random insertional mutagenesis in Streptococcus pneumoniae: use for recovery of mutants defective in genetic transformation and for identification of essential genes

To explore the use of insertion-duplication mutagenesis (IDM) as a random gene disruption mutagenesis tool for genomic analysis of Streptococcus pneumoniae, a large mutagenic library of chimeric plasmids with 300-bp inserts was constructed. The library was large enough to produce 60,000 independent plasmid clones in Escherichia coli. Sequencing of a random sample of 84 of these clones showed that 85% of the plasmids had inserts which were scattered widely over the genome; 80% of these plasmids had 240- to 360-bp inserts, and 60% of the inserts targeted internal regions of apparent open reading frames. Thus, the library was both complex and highly mutagenic. To evaluate the randomness of mutagenesis during recombination and to test the usefulness of the library for obtaining specific classes of nonessential genes, this library was used to seek competence-related genes by constructing a large pneumococcal transformant library derived from 20,000 mutagenic plasmids. After we screened the mutants exhaustively for transformation defects, 114 competence-related insertion mutations were identified. These competence mutations hit most previously known genes required for transformation as well as a new gene with high similarity to the Bacillus subtilis competence gene comFA. Mapping of the mutation sites at these competence loci showed that the mutagenesis was highly random, with no apparent hot spots. The recovery of a high proportion of competence genes and the absence of hot spots for mutational hits together show that such a transformant library is useful for finding various types of nonessential genes throughout the genome. Since a promoterless lacZ reporter vector was used for the construction of the mutagenic plasmid library, it also serves as a random transcriptional fusion library. Finally, use of a valuable feature of IDM, directed gene targeting, also showed that essential genes, which can be targets for new drug designs, could be identified by simple sequencing and transformation reactions. We estimate that the IDM library used in this study could readily achieve about 90% genome coverage.

Insertion-duplication mutagenesis in Streptococcus pneumoniae: targeting fragment length is a critical parameter in use as a random insertion tool

To examine whether insertion-duplication mutagenesis with chimeric DNA as a transformation donor could be valuable as a gene knockout tool for genomic analysis in Streptococcus pneumoniae, we studied the transformation efficiency and targeting specificity of the process by using a nonreplicative vector with homologous targeting inserts of various sizes. Insertional recombination was very specific in targeting homologous sites. While the recombination rate did not depend on which site or region was targeted, it did depend strongly on the size of the targeting insert in the donor plasmid, in proportion to the fifth power of its length for inserts of 100 to 500 bp. The dependence of insertion-duplication events on the length of the targeting homology was quite different from that for linear allele replacement and places certain limits on the design of mutagenesis experiments. The number of independent pneumococcal targeting fragments of uniform size required to knock out any desired fraction of the genes in a model genome with a defined probability was calculated from these data by using a combinatorial theory with simplifying assumptions. The results show that efficient and thorough mutagenesis of a large part of the pneumococcal genome should be practical when using insertion-duplication mutagenesis.

Development of competence in Streptococcus pneumonaie: pheromone autoinduction and control of quorum sensing by the oligopeptide permease

Competence for genetic transformation in the human pathogen Streptococcus pneumoniae is a transient physiological property. A competence-stimulating peptide, CSP, was recently identified as the processed product of the comC gene. As conflicting results have been reported regarding CSP autoinduction, we monitored the CSP-induced expression of comCDE in derivatives of strain R6 using comC::lacZ fusions. Autoinduction was demonstrated in this genetic background. The kinetics of CSP-induced transcription of comCDE and of a late competence-induced (cin) operon were compared. While the comCDE mRNA level was highest 5 min after CSP addition then decreased, maximal cin expression required 10 min exposure to CSP. Transformation frequencies paralleled cin expression. After 20 min exposure to CSP, both mRNAs disappeared almost completely, providing evidence for an intrinsic mechanism for shutting off CSP signal transduction. Investigation of spontaneous competence development in mixed cultures indicated that transformation of wild-type cells was delayed in the presence of CSP non-producers, consistent with a direct role of CSP in quorum sensing. The effect of varying inoculum size on the timing of competence development was investigated. While competence developed in wild-type cultures at a similar critical density, about OD550 = 0.15, a mutant lacking the three oligopeptide-binding lipoproteins transformed at a 50-fold reduced cell density. The latter effect was mimicked in a strain harbouring a duplication of comC. Altogether, these results suggest that CSP does not accumulate passively in pneumoccal cultures, but that comCDE basal expression can be modulated.

Competence-specific induction of recA is required for full recombination proficiency during transformation in Streptococcus pneumoniae

Transcriptional activation of the recA gene of Streptococcus pneumoniae was previously shown to occur at competence. A 5.7 kb recA-specific transcript that contained at least two additional genes, cinA and dinF, was identified. We now report the complete characterization of the recA operon and investigation of the role of the competence-specific induction of recA. The 5.7 kb competence-specific recA transcript is shown to include lytA, which encodes the pneumococcal autolysin, a protein previously shown to contribute to virulence of S. pneumoniae. Uncoupling (denoted Ind-) of recA and/or the downstream genes was achieved through the placement of transcription terminators within the operon, either upstream or downstream of recA. Prevention of the competence-specific induction of recA severely affected spontaneous transformation. Transformation efficiencies of recA+ (Ind-) and of wild-type cells were compared under various conditions and with different donor DNA. Chromosomal transformation was reduced 17-(chromosomal donor) to 45-fold (recombinant plasmid donor), depending on the donor DNA, and plasmid establishment was reduced 129-fold. Measurement of uptake of radioactively labelled donor DNA in transformed cells in parallel with scoring for transformants (chromosomal donor) revealed normal uptake, but a 21-fold reduction in recombination in a recA+ (Ind-) strain, indicating that the transformation defect was primarily in recombination. Strikingly enough, a much larger (460-fold) reduction in recombination was observed for the shortest homologous donor fragment used (878 nucleotides long). Possible interpretations of the observation that basal RecA appears unable to promote efficient recombination whatever the number and the length of donor fragments taken up are proposed. The role of recA induction is discussed in view of the potential contribution of transformation to genome plasticity in this pathogen.