Regulation of Streptococcus pneumoniae clp genes and their role in competence development and stress survival.

In vitro mariner transposon mutagenesis of Streptococcus pneumoniae chromosomal DNA was used to isolate regulatory mutants affecting expression of the comCDE operon, encoding the peptide quorum-sensing two-component signal transduction system controlling competence development. A transposon insertion leading to increased comC expression was found to lie directly upstream from the S. pneumoniae clpP gene, encoding the proteolytic subunit of the Clp ATP-dependent protease, whose expression in Bacillus subtilis is controlled by the CtsR repressor. In order to examine clp gene regulation in S. pneumoniae, a detailed analysis of the complete genome sequence was performed, indicating that there are five likely CtsR-binding sites located upstream from the clpE, clpP, and clpL genes and the ctsR-clpC and groESL operons. The S. pneumoniae ctsR gene was cloned under the control of an inducible promoter and used to demonstrate regulation of the S. pneumoniae clpP and clpE genes and the clpC and groESL operons by using B. subtilis as a heterologous host. The CtsR protein of S. pneumoniae was purified and shown to bind specifically to the clpP, clpC, clpE, and groESL regulatory regions. S. pneumoniae Delta ctsR, Delta clpP, Delta clpC, and Delta clpE mutants were constructed by gene deletion/replacement. ClpP was shown to act as a negative regulator, preventing competence gene expression under inappropriate conditions. Phenotypic analyses also indicated that ClpP and ClpE are both required for thermotolerance. Contrary to a previous report, we found that ClpC does not play a major role in competence development, autolysis, pneumolysin production, or growth at high temperature of S. pneumoniae.

The CtsR regulator of stress response is active as a dimer and specifically degraded in vivo at 37 degrees C.

CtsR (class three stress gene repressor) negatively regulates the expression of class III heat shock genes (clpP, clpE and the clpC operon) by binding to a directly repeated heptanucleotide operator sequence (A/GGTCAAA NAN A/GGTCAAA). CtsR-dependent genes are expressed at a low level at 37 degrees C and are strongly induced under heat shock conditions. We performed a structure/function analysis of the CtsR protein, which is highly conserved among low G+C Gram-positive bacteria. Random chemical mutagenesis, in vitro cross-linking, in vivo co-expression of wild-type and mutant forms of CtsR and the construction of chimeric proteins with the DNA-binding domain of the lambda CI repressor allowed us to identify three different functional domains within CtsR: a helix-turn-helix DNA-binding domain, a dimerization domain and a putative heat-sensing domain. We provide evidence suggesting that CtsR is active as a dimer. Transcriptional analysis of a clpP'-bgaB fusion and/or Western blotting experiments using antibodies directed against the CtsR protein indicate that ClpP and ClpX are involved in CtsR degradation at 37 degrees C. This in turn leads to a low steady-state level of CtsR within the cell, as CtsR negatively autoregulates its own synthesis. This is the first example of degradation of a repressor of stress response genes by the Clp ATP-dependent protease.

Identification in Listeria monocytogenes of MecA, a homologue of the Bacillus subtilis competence regulatory protein.

We identified in Listeria monocytogenes a gene encoding a protein homologous to MecA, a regulatory protein acting with ClpC and ComK in the competence pathway of Bacillus subtilis. In L. monocytogenes, MecA is involved, along with ClpC and ClpP, in the downregulation of a 64-kDa secreted protein. In B. subtilis, the MecA protein of L. monocytogenes behaves as a regulatory protein, controlling the transcription of comK and comG. Complete or disrupted ComK homologues were also found in L. monocytogenes. However, we failed to detect competence in various strains of L. monocytogenes, including those with intact ComK. Our results suggest that the functions of MecA in the saprophytes L. monocytogenes and B. subtilis have presumably diverged in response to their respective ecological niches.

CtsR controls class III heat shock gene expression in the human pathogen Listeria monocytogenes.

Stress proteins play an important role in virulence, yet little is known about the regulation of stress response in pathogens. In the facultative intracellular pathogen Listeria monocytogenes, the Clp ATPases, including ClpC, ClpP and ClpE, are required for stress survival and intracellular growth. The first gene of the clpC operon of L. monocytogenes encodes a homologue of the Bacillus subtilis CtsR repressor of stress response genes. An L. monocytogenes ctsR-deleted mutant displayed enhanced survival under stress conditions (growth in the presence of 2% NaCl or at 42 degrees C), but its level of virulence in the mouse was not affected. The virulence of a wild-type strain constitutively expressing CtsR is significantly attenuated, presumably because of repression of the stress response. Regulation of the L. monocytogenes clpC, clpP and clpE genes was investigated using transcriptional fusions in B. subtilis as a host. The L. monocytogenes ctsR gene was placed under the control of an inducible promoter, and regulation by CtsR and heat shock was demonstrated in vivo in B. subtilis. The purified CtsR protein of L. monocytogenes binds specifically to the clpC, clpP and clpE regulatory regions, and the extent of the CtsR binding sites was defined by DNase I footprinting. Our results demonstrate that this human pathogen possesses a CtsR regulon controlling class III heat shock genes, strikingly similar to that of the saprophyte B. subtilis. This is the first description of a stress response regulatory gene in a pathogen.

The high-pathogenicity island of Yersinia enterocolitica Ye8081 undergoes low-frequency deletion but not precise excision, suggesting recent stabilization in the genome.

Highly pathogenic strains of Yersinia pestis, Y. pseudotuberculosis, and Y. enterocolitica are characterized by the possession of a pathogenicity island designated the high-pathogenicity island (HPI). This 35- to 45-kb island carries an iron uptake system named the yersiniabactin locus. While the HPIs of Y. pestis and Y. pseudotuberculosis are subject to high-frequency spontaneous deletion from the chromosome, we were initially unable to obtain HPI-deleted Y. enterocolitica 1B isolates. In the present study, using a positive selection strategy, we identified three HPI-deleted mutants of Y. enterocolitica strain Ye8081. In these three independent clones, the chromosomal deletion was not limited to the HPI but encompassed a larger DNA fragment of approximately 140 kb. Loss of this fragment, which occurred at a frequency of approximately 5 x 10(-7), resulted in the disappearance of several phenotypic traits, such as growth in a minimal medium, hydrolysis of o-nitrophenyl-beta-D-thiogalactopyranoside, Tween esterase activity, and motility, and in a decreased virulence for mice. However, no precise excision of the Ye8081 HPI was observed. To gain more insight into the molecular basis for this phenomenon, the putative machinery of HPI excision in Y. enterocolitica was analyzed and compared to that in Y. pseudotuberculosis. We show that the probable reasons for failure of precise excision of the HPI of Y. enterocolitica Ye8081 are (i) the interruption of the P4-like integrase gene located close to its right-hand boundary by a premature stop codon and (ii) lack of conservation of 17-bp att-like sequences at both extremities of the HPI. These mutations may represent a process of HPI stabilization in the species Y. enterocolitica.

When the going gets tough: survival strategies and environmental signaling networks in Bacillus subtilis.

Regulatory pathways involving two-component histidine kinase/response regulator proteins of Bacillus subtilis are highly interconnected and form a signal transduction network controlling stationary-phase adaptive responses. These include chemotaxis and motility, degradative enzyme synthesis, antibiotic production, natural competence for DNA uptake, and sporulation. Many of these responses are mutually exclusive, with different control levels involving protein-environment, protein-protein and protein-DNA interactions, allowing the bacteria to adapt rapidly to environmental changes.

ClpE, a novel type of HSP100 ATPase, is part of the CtsR heat shock regulon of Bacillus subtilis.

Clp ATPases, which include the ubiquitous HSP100 family, are classified according to their structural features and sequence similarities. During the course of the Bacillus subtilis genome sequencing project, we identified a gene encoding a new member of the HSP100 family. We designated this protein ClpE, as it is the prototype of a novel subfamily among the Clp ATPases, and have identified homologues in several bacteria, including Listeria monocytogenes, Enterococcus faecalis, Streptococcus pyogenes, Streptococcus pneumoniae, Lactobacillus sakei and Clostridium acetobutylicum. A unique feature of these Hsp100-type Clp ATPases is their amino-terminal zinc finger motif. Unlike the other class III genes of B. subtilis (clpC and clpP ), clpE does not appear to be required for stress tolerance. Transcriptional analysis revealed two sigmaA-type promoters, expression from which was shown to be inducible by heat shock and puromycin treatment. Investigation of the regulatory mechanism controlling clpE expression indicates that this gene is controlled by CtsR and is thus a member of the class III heat shock genes of B. subtilis. CtsR negatively regulates clpE expression by binding to the promoter region, in which five CtsR binding sites were identified through DNase I footprinting and sequence analysis.

CtsR, a novel regulator of stress and heat shock response, controls clp and molecular chaperone gene expression in gram-positive bacteria.

clpP and clpC of Bacillus subtillis encode subunits of the Clp ATP-dependent protease and are required for stress survival, including growth at high temperature. They play essential roles in stationary phase adaptive responses such as the competence and sporulation developmental pathways, and belong to the so-called class III group of heat shock genes, whose mode of regulation is unknown and whose expression is induced by heat shock or general stress conditions. The product of ctsR, the first gene of the clpC operon, has now been shown to act as a repressor of both clpP and clpC, as well as clpE, which encodes a novel member of the Hsp100 Clp ATPase family. The CtsR protein was purified and shown to bind specifically to the promoter regions of all three clp genes. Random mutagenesis, DNasel footprinting and DNA sequence deletions and comparisons were used to define a consensus CtsR recognition sequence as a directly repeated heptad upstream from the three clp genes. This target sequence was also found upstream from clp and other heat shock genes of several Gram-positive bacteria, including Listeria monocytogenes, Streptococcus salivarius, S. pneumoniae, S. pyogenes, S. thermophilus, Enterococcus faecalis, Staphylococcus aureus, Leuconostoc oenos, Lactobacillus sake, Lactococcus lactis and Clostridium acetobutylicum. CtsR homologues were also identified in several of these bacteria, indicating that heat shock regulation by CtsR is highly conserved in Gram-positive bacteria.

Stress induction of the Bacillus subtilis clpP gene encoding a homologue of the proteolytic component of the Clp protease and the involvement of ClpP and ClpX in stress tolerance.

The Bacillus subtilis clpP gene, encoding the proteolytic component of the Clp or Ti protease, was cloned and sequenced. The amount of clpP-specific mRNA increased after heat shock, salt and ethanol stress, as well as after treatment with puromycin. Two transcriptional start sites upstream of the clpP structural gene were identified, preceded by sequences resembling the consensus sequences of promoters recognized by sigmaA and sigmaB transcriptional factors of the B. subtilis RNA polymerase respectively. Transcription initiation occurred predominantly at the putative sigmaA-dependent promoter in exponentially growing cells and was induced under stress conditions. After exposure to stress, initiation of transcription also increased at the sigmaB-dependent promoter, but to a lesser extent, indicating that clpP belongs to a double promoter-controlled subgroup of class III general stress genes in B. subtilis. In a sigB mutant strain, clpP remained heat and stress inducible at the sigmaA-dependent promoter. BgaB-reporter gene fusions, carrying either the sigmaA- or the sigmaB-dependent promoter, showed a higher bgaB induction at the sigmaA-dependent promoter, whereas a significantly lower level of induction was measured at the sigmaB-dependent promoter. The sigmaA-dependent promoter appeared to be crucial for the heat-inducible transcription of clpP. A CIRCE (controlling inverted repeat of chaperone expression) element, the characteristic regulation target of class I heat shock genes such as dnaK and groESL, was not found between the transcriptional and translational start sites. Mutants lacking either the proteolytic component ClpP or the regulatory ATPase component ClpX were phenotypically distinct from the wild type. Both mutants produced chains of elongated cells and exhibited severely impaired growth under stress conditions and starvation. Comparison of two-dimensional protein gels from wild-type cells with those from clpP and clpX mutant cells revealed several changes in the protein pattern. Several proteins, such as GroEL, PpiB, PykA, SucD, YhfP, YqkF, YugJ and YvyD, which were found preferentially in higher amounts in both clpP and clpX mutants, might be potential substrates for the ClpXP protease.

ClpP of Bacillus subtilis is required for competence development, motility, degradative enzyme synthesis, growth at high temperature and sporulation.

The nucleotide sequence of the Bacillus subtilis clpP gene was determined. The predicted protein shows very high similarity to members of the ClpP family of proteolytic subunits (68% amino acid sequence identity with that of Escherichia coli). We show that ClpP plays an essential role in stationary phase adaptive responses. Indeed, a delta clpP mutant was constructed and shown to display a pleiotropic phenotype, including a deficiency in both sporulation initiation and competence for DNA uptake. The delta clpP mutant has a highly filamentous morphology and appears to be non-motile, as judged by swarm plate assays. Expression of clpP is strongly induced under heat shock conditions, and ClpP is shown to be essential for growth of B. subtilis at high temperature. The role of ClpP in the sporulation and competence regulatory pathways was investigated. ClpP is required for expression of the spollA and spollG operons, encoding the sigmaF and sigmaE sporulation-specific sigma factors. ClpP is also necessary for the expression of the comK gene, encoding a positive transcriptional regulator of competence genes. ComK-dependent transcription of sacB, encoding the exocellular degradative enzyme levansucrase, was found to be abolished in the delta clpP mutant. MecA has been characterized previously as a negative regulator of comK expression, whose overproduction inhibits both sporulation and competence development. Expression of a mecA'-'lacZ translational fusion is shown to be increased in the delta clpP mutant. We suggest that ClpP is involved in controlling MecA levels in the cell through proteolysis. Increased levels of MecA in the absence of ClpP are at least partly responsible for the observed pleiotropic phenotype of the delta clpP mutant.

Alternate promoters direct stress-induced transcription of the Bacillus subtilis clpC operon.

clpC of Bacillus subtilis is part of an operon containing six genes. Northern blot analysis suggested that all genes are co-transcribed and encode stress-inducible proteins. Two promoters (PA and PB) were mapped upstream of the first gene. PA resembles promoters recognized by the vegetative RNA polymerase E sigma A. The other promoter (PB) was shown to be dependent on sigma B, the general stress sigma factor in B. subtilis, suggesting that clpC, a potential chaperone, is expressed in a sigma B-dependent manner. This is the first evidence that sigma B in B. subtilis is involved in controlling the expression of a gene whose counterpart, clpB, is subject to regulation by sigma 32 in Escherichia coli, indicating a new function of sigma B-dependent general stress proteins. PB deviated from the consensus sequence of sigma B promoters and was only slightly induced by starvation conditions. Nevertheless, strong induction by heat, ethanol, and salt stress occurred at the sigma B-dependent promoter, whereas the vegetative promoter was only weakly induced under these conditions. However, in a sigB mutant, the sigma A-like promoter became inducible by heat and ethanol stress, completely compensating for sigB deficiency. Only the downstream sigma A-like promoter was induced by certain stress conditions such as hydrogen peroxide or puromycin. These results suggest that novel stress-induction mechanisms are acting at a vegetative promoter. Involvement of additional elements in this mode of induction are discussed.

Differential activation of virulence gene expression by PrfA, the Listeria monocytogenes virulence regulator.

PrfA is a pleiotropic activator of virulence gene expression in the pathogenic bacterium Listeria monocytogenes. Several lines of evidence have suggested that a hierarchy of virulence gene activation by PrfA exists. This hypothesis was investigated by assessing the ability of PrfA to activate the expression of virulence gene fusions to lacZ in Bacillus subtilis. Expression of PrfA in this heterologous host was sufficient for activation of transcription at the hly, plcA, mpl, and actA promoters. Activation was most efficient at the divergently transcribed hly and plcA promoters. The putative PrfA binding site shared by these promoters is perfectly symmetrical and appears to represent the optimum sequence for target gene activation by PrfA. The activation of actA and mpl expression was considerably weaker and occurred more slowly than that observed at the hly and plcA promoters, suggesting that greater quantities of PrfA are required for productive interaction at these promoters. Interestingly, expression of an inlA-lacZ transcriptional fusion was very poorly activated by PrfA in B. subtilis, suggesting that other Listeria factors, in addition to PrfA, are required for PrfA-mediated activation at this promoter. Further support for the involvement of such factors was obtained by constructing and analyzing a prfA deletion mutant of L. monocytogenes. We observed that, in contrast to that of the other genes of the PrfA regulon, expression of inlA is only partially dependent on PrfA.

MecB of Bacillus subtilis, a member of the ClpC ATPase family, is a pleiotropic regulator controlling competence gene expression and growth at high temperature.

The Bacillus subtilis DegS-DegU histidine kinase-response regulator pair controls the expression of genes encoding degradative enzymes such as levansucrase (sacB) and of genes involved in genetic competence. The mecA and mecB mutations were previously isolated as allowing competence gene expression in complex media. We have shown that the mec mutations also lead to overexpression of sacB, bypassing the DegS-DegU requirement. This expression was shown to be entirely dependent upon ComK, a positive regulator of competence gene expression. The mecB gene was cloned and its nucleotide sequence was determined. The predicted MecB protein show very high similarity over its entire length with members of the ClpC family of ATPases (60% identity). MecB is essential for growth of B. subtilis at high temperature. MecB also acts as a negative regulator of ComK synthesis, thus preventing late competence gene expression. We suggest that under these conditions MecB may interact with MecA to sequester or otherwise inactivate ComK. In response to an unknown signal, active ComK would accumulate through a positive feedback loop, leading to expression of competence genes allowing DNA uptake.

The phosphorylation state of the DegU response regulator acts as a molecular switch allowing either degradative enzyme synthesis or expression of genetic competence in Bacillus subtilis.

Two classes of mutations were identified in the degS and degU regulatory genes of Bacillus subtilis, leading either to deficiency of degradative enzyme synthesis (degS or degU mutations) or to a pleiotropic phenotype which includes overproduction of degradative enzymes and the loss of genetic competence (degS(Hy) or degU(Hy) mutations). We have shown previously that the DegS protein kinase and the DegU response regulator form a signal transduction system in B. subtilis. We now demonstrate that the DegS protein kinase also acts as a DegU phosphatase. We present evidence that the DegU response regulator has two active conformations: a phosphorylated form which is necessary for degradative enzyme synthesis and a nonphosphorylated form required for expression of genetic competence. The degU146-encoded response regulator, allowing expression of genetic competence, has been purified and seems to be modified within the putative phosphorylation site (D56----N) since it is no longer phosphorylated by DegS. Both the degU146 mutation as well as the degS220 mutation, which essentially abolishes DegS protein kinase activity, lead to deficiency of degradative enzyme synthesis, indicating the requirement of phosphorylated DegU for the expression of this phenotype. We also purified the degU32(Hy)-encoded protein and showed that this response regulator is phosphorylated by the DegS protein kinase in vitro. In addition, the phosphorylated form of the degU32(Hy)-encoded protein presented a strongly increased stability as compared with the wild type DegU protein, thus leading to hyperproduction of degradative enzymes in vivo.

Positive regulation in the gram-positive bacterium: Bacillus subtilis.

Temporally and environmentally regulated gene expression in prokaryotes occurs primarily at the level of transcription initiation. Two main modes of regulation have been described, including either the binding of a repressor that blocks transcription or the interaction of a positive regulator with the transcription complex, leading to transcription initiation. Several classes can be distinguished among positive regulators according to their mechanisms of action. This review describes the different types of positive regulators identified in Bacillus subtilis, a gram-positive bacterium. These include accessory regulatory polypeptides, classical positive regulators that bind to target sites located just upstream from the promoter, ambiactive regulators that can act both positively and negatively, antiterminators, two-component signal transduction systems, and positive regulators associated with specific secondary sigma factors.

Sequence and properties of comQ, a new competence regulatory gene of Bacillus subtilis.

The sequence and properties of the comQ gene are described. comQ was predicted to encode a 34,209-Da protein, and the product of comQ was shown to be required for the development of genetic competence. The apparent transcriptional initiation and termination sites of comQ were mapped, and the location of a likely E sigma A promoter was inferred. The expression of comQ was maximal early in growth and declined as the cells approached the stationary phase. This expression was not dependent on any of the competence regulatory genes tested (comA, comP, sin, abrB, degU, and spo0A). Disruption of comQ in the chromosome prevented the development of competence as well as the transcription of comG, a late competence operon. This disruption also decreased the expression of srfA, a regulatory operon needed for the expression of competence. These and other results suggest a role for ComQ early in the hierarchy of competence regulatory genes, probably as a component of a signal transduction system.

DegS-DegU and ComP-ComA modulator-effector pairs control expression of the Bacillus subtilis pleiotropic regulatory gene degQ.

Production of a class of both secreted and intracellular degradative enzymes in Bacillus subtilis is regulated at the transcriptional level by a signal transduction pathway which includes the DegS-DegU two-component system and at least two additional regulatory genes, degQ and degR, encoding polypeptides of 46 and 60 amino acids, respectively. Expression of degQ was shown to be controlled by DegS-DegU. This expression is decreased in the presence of glucose and increased under any of the following conditions: growth with poor carbon sources, amino acid deprivation, phosphate starvation, and growth in the presence of decoyinine, a specific inhibitor of GMP synthetase. In addition, expression of degQ is shown to be positively regulated by the ComP-ComA two-component system. Separate targets for regulation of degQ gene expression by DegS-DegU and ComP-ComA were located by deletion analysis between positions -393 and -186 and between positions -78 and -40, respectively. Regulation of degQ expression by amino acid deprivation was shown to be dependent upon ComA. Regulation by phosphate starvation, catabolite repression, and decoyinine was independent of the two-component systems and shown to involve sequences downstream from position -78. The ComP-ComA and DegS-DegU two-component systems seem to be closely related, sharing several target genes in common, such as late competence genes, as well as the degQ regulatory gene. Sequence analysis of the degQ region revealed the beginning of an open reading frame directly downstream from degQ. Disruption of this gene, designated comQ, suggests that it also controls expression of degQ and is required for development of genetic competence.

Mutational analysis of the Bacillus subtilis DegU regulator and its phosphorylation by the DegS protein kinase.

The DegS-DegU protein kinase-response regulator pair controls the expression of genes encoding degradative enzymes as well as other cellular functions in Bacillus subtilis. Both proteins were purified. The DegS protein was autophosphorylated and shown to transfer its phosphate to the DegU protein. Phosphoryl transfer to the wild-type DegU protein present in crude extracts was shown by adding 32P-labeled DegS to the reaction mixture. Under similar conditions, the modified proteins encoded by the degU24 and degU31 alleles presented a stronger phosphorylation signal compared with that of the wild-type DegU protein. This may suggest an increased phosphorylation of these modified proteins, responsible for the hyperproduction of degradative enzymes observed in the degU24 and degU31 mutants. However, the degU32 allele, which also leads to hyperproduction of degradative enzymes, encodes a modified DegU response regulator which seems not to be phosphorylatable. The expression of the hyperproduction phenotype of the degU32 mutant is still dependent on the presence of a functional DegS protein. DegS may therefore induce a conformational change of the degU32-encoded response regulator enabling this protein to stimulate degradative enzyme synthesis. Two alleles, degU122 and degU146, both leading to deficiency of degradative enzyme synthesis, seem to encode phosphorylatable and nonphosphorylatable DegU proteins, respectively.

Signal transduction pathway controlling synthesis of a class of degradative enzymes in Bacillus subtilis: expression of the regulatory genes and analysis of mutations in degS and degU.

The rates of synthesis of a class of both secreted and intracellular degradative enzymes in Bacillus subtilis are controlled by a signal transduction pathway defined by at least four regulatory genes: degS, degU, degQ (formerly sacQ), and degR (formerly prtR). The DegS-DegU proteins show amino acid similarities with two-component procaryotic modulator-effector pairs such as NtrB-NtrC, CheA-CheY, and EnvZ-OmpR. By analogy with these systems, it is possible that DegS is a protein kinase which could catalyze the transfer of a phosphoryl moiety to DegU, which acts as a positive regulator. DegR and DegQ correspond to polypeptides of 60 and 46 amino acids, respectively, which also activate the synthesis of degradative enzymes. We show that the degS and degU genes are organized in an operon. The putative sigma A promoter of the operon was mapped upstream from degS. Mutations in degS and degU were characterized at the molecular level, and their effects on transformability and cell motility were studied. The expression of degQ was shown to be subject both to catabolite repression and DegS-DegU-mediated control, allowing an increase in the rate of synthesis of degQ under conditions of nitrogen starvation. These results are consistent with the hypothesis that this control system responds to an environmental signal such as limitations of nitrogen, carbon, or phosphate sources.