Expression and maintenance of ComD-ComE, the two-component signal-transduction system that controls competence of Streptococcus pneumoniae.

A secreted competence-stimulating peptide (CSP), encoded by comC, constitutes, together with the two-component system ComD-ComE, the master switch for competence induction in Streptococcus pneumoniae. Interaction between CSP and its membrane-bound histidine-kinase receptor, ComD, is believed to lead to autophosphorylation of ComD, which then transphosphorylates the ComE response regulator to activate transcription of a limited set of genes, including the comCDE operon. This generates a positive feedback loop, amplifying the signal and co-ordinating competence throughout the population. On the other hand, the promoter(s) and proteins important for basal comCDE expression have not been defined. We now report that CSP-induced and basal comCDE transcription both initiate from the same promoter, P(E); that basal expression necessitates the presence of both ComD and a phosphate-accepting form of ComE, but not CSP; and that overexpression of ComE(R120S) triggers ComD-dependent transformation in the absence of CSP. These observations suggest that self-activation of ComD is required for basal comCDE expression. We also establish that transcriptional readthrough occurs across the tRNA(Arg5) terminator and contributes significantly to comCDE expression. Finally, we demonstrate by various means, including single-cell competence analysis with GFP, that readthrough is crucial to avoid the stochastic production of CSP non-responsive cells lacking ComD or ComE.

Inhibition of competence development in Streptococcus pneumoniae by increased basal-level expression of the ComDE two-component regulatory system.

Natural competence for genetic transformation in Streptococcus pneumoniae is controlled by the ComCDE signal-transduction pathway. Together, ComD, a membrane histidine kinase, and ComE, its cognate response regulator, constitute a typical two-component regulatory system involved in sensing the comC-encoded competence-stimulating peptide (CSP). The comCDE operon is strongly upregulated when CSP reaches a critical threshold, probably to coordinate competence induction throughout the population. During a study of the early regulation of the comCDE operon, a mutation which resulted in increased beta-galactosidase production from a comC : : lacZ fusion was isolated. This mutation, which was characterized as a G-->T change in the transcription terminator of the tRNA(Arg) located immediately upstream of comCDE, is suggested to destabilize the terminator and to allow transcriptional readthrough of comCDE. Here, it is shown that, quite unexpectedly, the mutation confers reduced transformability. A series of experiments undertaken with the aim of understanding this surprising phenotype is described. Evidence is presented that increased basal-level expression of comDE impedes both spontaneous and CSP-induced competence in S. pneumoniae. There is a discussion of how an increased concentration of ComD and/or ComE could affect competence development.

Construction and evaluation of a chromosomal expression platform (CEP) for ectopic, maltose-driven gene expression in Streptococcus pneumoniae.

In this paper, the construction and evaluation of a chromosomal expression platform (CEP), which allows controlled gene expression following ectopic integration into the chromosome of Streptococcus pneumoniae, is described. CEP is based on the well-studied maltosaccharide-inducible system. To facilitate integration at CEP, a plasmid, pCEP, capable of replication in Escherichia coli, but not in S. pneumoniae, was assembled. This plasmid contains an expression/selection cassette flanked on each side by more than 2 kb of pneumococcal DNA. The cassette comprises a maltose-inducible promoter, P(M), separated from a kanamycin-resistance gene by NcoI and BamHI cloning sites. Clones harbouring the gene of interest integrated at CEP under the control of P(M) can be obtained through direct transformation of an S. pneumoniae recipient with ligation products between that gene and NcoI/BamHI-digested pCEP DNA, followed by selection for kanamycin-resistant transformants.

Interconnection of competence, stress and CiaR regulons in Streptococcus pneumoniae: competence triggers stationary phase autolysis of ciaR mutant cells.

Of the 13 two-component signal transduction systems (TCS) identified in Streptococcus pneumoniae, two, ComDE and CiaRH, are known to affect competence for natural genetic transformation. ComD and ComE act together with the comC-encoded competence-stimulating peptide (CSP) and with ComAB, the CSP-dedicated exporter, to co-ordinate activation of genes required for differentiation to competence. Several lines of evidence suggest that the CiaRH TCS and competence regulation are interconnected, including the observation that inactivation of the CiaR response regulator derepresses competence. However, the nature of the interconnection remains poorly understood. Interpretation of previous transcriptome analyses of ciaR mutants was complicated by competence derepression in the mutants. To circumvent this problem, we have used microarray analysis to investigate the transition from non-competence to competence in a comC-null wild-type strain and its ciaR derivative after the addition of CSP. This study increased the number of known CSP-induced genes from approximately 47 to 105 and revealed approximately 42 genes with reduced expression in competent cells. Induction of the CiaR regulon, as well as the entire HrcA and part of the CtsR stress response regulons, was observed in wild-type competent cells. Enhanced induction of stress response genes was detected in ciaR competent cells. In line with these observations, CSP was demonstrated to trigger growth arrest and stationary phase autolysis in ciaR cells. Taken together, these data strongly suggest that differentiation to competence imposes a temporary stress on cells, and that the CiaRH TCS is required for the cells to exit normally from the competent state.