CtsR, the Gram-positive master regulator of protein quality control, feels the heat

Protein quality networks are required for the maintenance of proper protein homeostasis and essential for viability and growth of all living organisms. Hence, regulation and coordination of these networks are critical for survival during stress as well as for virulence of pathogenic species. In low GC, Gram‐positive bacteria central protein quality networks are under the control of the global repressor CtsR. Here, we provide evidence that CtsR activity during heat stress is mediated by intrinsic heat sensing through a glycine‐rich loop, probably in all Gram‐positive species. Moreover, a function for the recently identified arginine kinase McsB is confirmed, however, not for initial inactivation and dissociation of CtsR from the DNA, but for heat‐dependent auto‐activation of McsB as an adaptor for ClpCP‐mediated degradation of CtsR.     

A tyrosine kinase and its activator control the activity of the CtsR heat shock repressor in B. subtilis

The soil bacterium Bacillus subtilis possesses a fine-tuned and complex heat stress response system. The repressor CtsR, whose activity is regulated by its modulators McsA and McsB, controls the expression of the cellular protein quality control genes clpC, clpE and clpP. Here, we show that the interaction of McsA and McsB with CtsR results in the formation of a ternary complex that not only prevents the binding of CtsR to its target DNA, but also results in a subsequent phosphorylation of McsB, McsA and CtsR. We further demonstrate that McsB is a tyrosine kinase that needs McsA to become activated. ClpC inhibits the kinase activity of McsB, indicating a direct role in initiating CtsR-controlled heat shock response. Interestingly, the kinase domain of McsB is homologous to guanidino phosphotransferase domains originating from eukaryotic arginine and creatine kinases. Mutational analysis of key residues of the guanidino kinase domain demonstrated that McsB utilizes this domain to catalyze the tyrosine phosphorylation. McsB represents therefore a new kind of tyrosine kinase, driven by a guanidino phosphotransferase domain.     

Activity control of the ClpC adaptor McsB in Bacillus subtilis

Controlled protein degradation is an important cellular reaction for the fast and efficient adaptation of bacteria to ever-changing environmental conditions. In the low-GC, Gram-positive model organism Bacillus subtilis, the AAA+ protein ClpC requires specific adaptor proteins not only for substrate recognition but also for chaperone activity. The McsB adaptor is activated particularly during heat stress, allowing the controlled degradation of the CtsR repressor by the ClpCP protease. Here we report how the McsB adaptor becomes activated by autophosphorylation on specific arginine residues during heat stress. In nonstressed cells McsB activity is inhibited by ClpC as well as YwlE.     

McsA and the roles of metal-binding motif in Staphylococcus aureus

McsA is a key modulator of stress response in Staphylococcus aureus that contains four CXXC potential metal-binding motifs at the N-terminal. Staphylococcus aureus ctsR operon encodes ctsR, clpC, and putative mcsA and mcsB genes. The expression of the ctsR operon in S. aureus was shown to be induced in response to various types of heavy metals such as copper and cadmium. McsA was cloned and overexpressed, and purified product was tested for metal-binding activity. The protein bound to Cu(II), Zn(II), Co(II), and Cd(II). No binding with any heavy metal except copper was found when we performed site-directed mutagenesis of Cys residues of three CXXC motifs of McsA. These data suggest that two conserved cysteine ligands provided by one CXXC motif are required to bind copper ions. In addition, using a bacterial two-hybrid system, McsA was found to be able to bind to McsB and CtsR of S. aureus and the CXXC motif was needed for the binding. This indicates that the Cys residues in the CXXC motif are involved in metal binding and protein interaction.     

A new tyrosine phosphorylation mechanism involved in signal transduction in Bacillus subtilis

A new kind of prokaryotic protein tyrosine kinase was recently discovered, utilizing a guanidino-phosphotransferase domain for its kinase activity. Guanidino kinase domains originate from eukaryotic phosphagen kinases, a family of phosphoryl transfer enzymes with no homology to the serine/threonine and tyrosine kinase superfamily. Nevertheless, this kinase, McsB, exhibits the main structural and functional properties of prokaryotic tyrosine kinases. Tyrosine phosphorylation in bacteria is predominantly described to be involved in the regulation of exopolysaccharide synthesis and is therefore required for biofilm formation and virulence. McsB on the other hand modulates together with its activator protein, McsA, the activity of the repressor of the class III heat shock genes in B. subtilis. The analogy of the kinase mechanism of McsB to tyrosine kinases implicates that tyrosine kinases may harbor various and independently evolved domains for ATP-binding/hydrolysis and the transfer of the gamma-phosphate of ATP onto tyrosine residues.     

clpC operon regulates cell architecture and sporulation in Bacillus anthracis

The clpC operon is known to regulate several processes such as genetic competence, protein degradation and stress survival in bacteria. Here, we describe the role of clpC operon in Bacillus anthracis. We generated knockout strains of the clpC operon genes to investigate the impact of CtsR, McsA, McsB and ClpC deletion on essential processes of B. anthracis. We observed that growth, cell division, sporulation and germination were severely affected in mcsB and clpC deleted strains, while none of deletions affected toxin secretion. Growth defect in these strains was pronounced at elevated temperature. The growth pattern gets restored on complementation of mcsB and clpC in respective mutants. Electron microscopic examination revealed that mcsB and clpC deletion also causes defect in septum formation leading to cell elongation. These vegetative cell deformities were accompanied by inability of mutant strains to generate morphologically intact spores. Higher levels of polyhydroxybutyrate granules accumulation were also observed in these deletion strains, indicating a defect in sporulation process. Our results demonstrate, for the first time, the vital role played by McsB and ClpC in physiology of B. anthracis and open up further interest on this operon, which might be of importance to success of B. anthracis as pathogen.     

ClpE from Lactococcus lactis promotes repression of CtsR-dependent gene expression

The heat shock response in bacterial cells is characterized by rapid induction of heat shock protein expression, followed by an adaptation period during which heat shock protein synthesis decreases to a new steady-state level. In this study we found that after a shift to a high temperature the Clp ATPase (ClpE) in Lactococcus lactis is required for such a decrease in expression of a gene negatively regulated by the heat shock regulator (CtsR). Northern blot analysis showed that while a shift to a high temperature in wild-type cells resulted in a temporal increase followed by a decrease in expression of clpP encoding the proteolytic component of the Clp protease complex, this decrease was delayed in the absence of ClpE. Site-directed mutagenesis of the zinc-binding motif conserved in ClpE ATPases interfered with the ability to repress CtsR-dependent expression. Quantification of ClpE by Western blot analysis revealed that at a high temperature ClpE is subjected to ClpP-dependent processing and that disruption of the zinc finger domain renders ClpE more susceptible. Interestingly, this domain resembles the N-terminal region of McsA, which was recently reported to interact with the CtsR homologue in Bacillus subtilis. Thus, our data point to a regulatory role of ClpE in turning off clpP gene expression following temporal heat shock induction, and we propose that this effect is mediated through CtsR.     

Comparative genomics reveal novel heat shock regulatory mechanisms in Staphylococcus aureus and other Gram-positive bacteria

Multiple regulatory mechanisms for coping with stress co-exist in low G+C Gram-positive bacteria. Among these, the HrcA and CtsR repressors control distinct regulons in the model organism, Bacillus subtilis. We recently identified an orthologue of the CtsR regulator of stress response in the major pathogen, Staphylococcus aureus. Sequence analysis of the S. aureus genome revealed the presence of potential CtsR operator sites not only upstream from genes encoding subunits of the Clp ATP-dependent protease, as in B. subtilis, but also, unexpectedly, within the promoter regions of the dnaK and groESL operons known to be specifically controlled by HrcA. The tandem arrangement of the CtsR and HrcA operators suggests a novel mode of dual heat shock regulation by these two repressors. The S. aureus ctsR and hrcA genes were cloned under the control of the PxylA xylose-inducible promoter and used to demonstrate dual regulation of the dnaK and groESL operons by both CtsR and HrcA, using B. subtilis as a heterologous host. Direct binding by both repressors was shown in vitro by gel mobility shift and DNase I footprinting experiments using purified S. aureus CtsR and HrcA proteins. DeltactsR, DeltahrcA and DeltactsRDeltahrcA mutants of S. aureus were constructed, indicating that the two repressors are not redundant but, instead, act together synergistically to maintain low basal levels of expression of the dnaK and groESL operons in the absence of stress. This novel regulatory mode appears to be specific to Staphylococci.     

McsA and B mediate the delocalization of competence proteins from the cell poles of Bacillus subtilis

During the development of transformability (competence), Bacillus subtilis synthesizes a set of proteins that mediate both the uptake of DNA at the cell poles and the recombination of this DNA with the resident chromosome. Most, if not all, of these Com proteins localize to the poles of the cell, where they associate with one another, and are then seen to delocalize as transformability declines. In this study, we use fluorescence microscopy to analyse the localization and delocalization processes. We show that localization most likely occurs by a diffusion-capture mechanism, not requiring metabolic energy, whereas delocalization is prevented in the presence of sodium azide. The kinetics of localization suggest that this process requires the synthesis of a critical protein or set of proteins, which are needed to anchor the Com protein complex to the poles. We further show that the protein kinase proteins McsA and McsB are needed for delocalization, as are ClpP and either of the AAA⁺ ( A TPases a ssociated with a variety of cellular a ctivities) proteins ClpC or ClpE. Of these proteins, at least McsB, ClpC and ClpP localize to the cell poles of competent cells. Our evidence strongly suggests that delocalization depends on the degradation of the postulated anchor protein(s) by the McsA-McsB-(ClpC or ClpE)-ClpP protease in an ATP-dependent process that involves the autophosphorylation of McsB. The extent of cell–pole association at any given time reflects the relative rates of localization and delocalization. The kinetics of this dynamic process differs for individual Com proteins, with the DNA-binding proteins SsbB and DprA exhibiting less net localization.     

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 subtilis 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, DNaseI 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.     

The CtsR regulator of Listeria monocytogenes contains a variant glycine repeat region that affects piezotolerance,stress resistance,motility and virulence

A spontaneous high hydrostatic pressure (HHP)-tolerant mutant of Listeria monocytogenes ScottA, named AK01, was isolated previously. This mutant was immotile and showed increased resistance to heat, acid and H2O2 compared with the wild type (wt) (Karatzas, K.A.G. and Bennik, M.H.J. 2002 Appl Environ Microbiol 68: 3183-3189). In this study, we conclusively linked the increased HHP and stress tolerance of strain AK01 to a single codon deletion in ctsR (class three stress gene repressor) in a region encoding a highly conserved glycine repeat. CtsR negatively regulates the expression of the clp genes, including clpP, clpE and the clpC operon (encompassing ctsR itself), which belong to the class III heat shock genes. Allelic replacement of the ctsR gene in the wt background with the mutant ctsR gene, designated ctsRDeltaGly, rendered mutants with phenotypes and protein expression profiles identical to those of strain AK01. The expression levels of CtsR, ClpC and ClpP proteins were significantly higher in ctsRDeltaGly mutants than in the wt strain, indicative of the CtsRDeltaGly protein being inactive. Further evidence that the CtsRDeltaGly protein lacks its repressor function came from the finding that the Clp proteins in the mutant were not further induced upon heat shock, and that HHP tolerance of a ctsR deletion strain was as high as that of a ctsRDeltaGly mutant. The high HHP tolerance possibly results from the increased expression of the clp genes in the absence of (active) CtsR repressor. Importantly, the strains expressing CtsRDeltaGly show significantly attenuated virulence compared with the wt strain; however, no indication of disregulation of PrfA in the mutant strains was found. Our data highlight an important regulatory role of the glycine-rich region of CtsR in stress resistance and virulence.