The Porphyromonas gingivalis clpB gene is involved in cellular invasion in vitro and virulence in vivo

ClpB, a component of stress response in microorganisms, serves as a chaperone, preventing protein aggregation and assisting in the refolding of denatured proteins. A clpB mutant of Porphyromonas gingivalis W83 demonstrated increased sensitivity to heat stress, but not to hydrogen peroxide and extreme pHs. In KB cells, human coronary artery endothelial (HCAE) cells and gingival epithelial cells, the clpB mutant exhibited significantly decreased invasion suggesting that the ClpB protein is involved in cellular invasion. Transmission electron microscopic analysis showed that the clpB mutant was more susceptible to intracellular killing than the wild-type strain in HCAE cells. The global genetic profile of the clpB mutant showed that 136 genes belonging to several different cellular function groups were differentially regulated, suggesting that ClpB is ultimately involved in the expression of multiple P. gingivalis genes. A competition assay in which a mixture of wild-type W83 and the clpB mutant were injected into mice demonstrated that the clpB mutant did not survive as well as the wild type. Additionally, mice treated with the clpB mutant alone survived significantly better than those treated with the wild-type strain. Collectively, these data suggest that ClpB, either directly or indirectly, plays an important role in P. gingivalis virulence.     

The heat shock protein ClpB mediates the development of thermotolerance in the cyanobacterium Synechococcus sp. strain PCC 7942.

The heat shock protein CIpB (HSP100) is a member of the diverse group of Clp polypeptides that function as molecular chaperones and/or regulators of energy-dependent proteolysis. A single-copy gene coding for a ClpB homolog was cloned and sequenced from the unicellular cyanobacterium Synechococcus sp. strain PCC 7942. The predicted polypeptide sequence was most similar to sequences of cytosolic ClpB from bacteria and higher plants (i.e., 70 to 75%). Inactivation of clpB in Synechococcus sp. strain PCC 7942 resulted in no significant differences from the wild-type phenotype under optimal growth conditions. In the wild type, two forms of ClpB were induced during temperature shifts from 37 to 47.5 or 50 degrees C, one of 92 kDa, which matched the predicted size, and another smaller protein of 78 kDa. Both proteins were absent in the delta clpB strain. The level of induction of the two ClpB forms in the wild type increased with increasingly higher temperatures, while the level of the constitutive ClpC protein remained unchanged. In the delta clpB strain, however, the ClpC content almost doubled during the heating period, presumably to compensate for the loss of ClpB activity. Photosynthetic measurements at 47.5 and 50 degrees C showed that the null mutant was no more susceptible to thermal inactivation than the wild type. Using photosynthesis as a metabolic indicator, an assay was developed for Synechococcus spp. to determine the importance of ClpB for acquired thermotolerance. Complete inactivation of photosynthetic oxygen evolution occurred in both the wild type and the delta clpB strain when they were shifted from 37 directly to 55 degrees C for 10 min. By preexposing the cells at 50 degrees C for 1.5 h, however, a significant level of photosynthesis was retained in the wild type but not in the mutant after the treatment at 55 degrees C for 10 min. Cell survival determinations confirmed that the loss of ClpB synthesis caused a fivefold reduction in the ability of Synechococcus cells to develop thermotolerance. These results clearly show that induction of ClpB at high temperatures is vital for sustained thermotolerance in Synechococcus spp., the first such example for either a photosynthetic or a prokaryotic organism.     

The Escherichia coli heat shock protein ClpB restores acquired thermotolerance to a cyanobacterial clpB deletion mutant

In both prokaryotes and eukaryotes, the heat shock protein ClpB functions as a molecular chaperone and plays a key role in resisting high temperature stress. ClpB is important for the development of thermotolerance in yeast and cyanobacteria but apparently not in Escherichia coli. We undertook a complementation study to investigate whether the ClpB protein from E coli (EcClpB) differs functionally from its cyanobacterial counterpart in the unicellular cyanobacterium Synechococcus sp. PCC 7942. The EcClpB protein is 56% identical to its ClpB1 homologue in Synechococcus. A plasmid construct was prepared containing the entire E coli clpB gene under the control of the Synechococcus clpB1 promoter. This construct was transformed into a Synechococcus clpB1 deletion strain (deltaclpB1) and integrated into a phenotypically neutral site of the chromosome. The full-length EcClpB protein (EcClpB-93) was induced in the transformed Synechococcus strain during heat shock as well as the smaller protein (EcClpB-79) that arises from a second translational start inside the single clpB message. Using cell survival measurements we show that the EcClpB protein can complement the Synechococcus deltaclpB1 mutant and restore its ability to develop thermotolerance. We also demonstrate that both EcClpB-93 and -79 appear to contribute to the degree of acquired thermotolerance restored to the Synechococcus complementation strains.     

Cloning and characterization of two cellulase genes from Lentinula edodes

The effect of overproduction of the Hsp70 system proteins (DnaK, DnaJ, GrpE) and/or ClpB (Hsp100) from plasmids on the process of formation and removal of heat-aggregated proteins from Escherichia coli cells (the S fraction) was investigated by sucrose density gradient centrifugation. Two plasmids were employed: pKJE7 carrying the dnaK/dnaJ/grpE genes under the control of the araB promoter and pClpB carrying the clpB gene under the control of its own promoter (sigma(32)-dependent). In the wild-type cells the S fraction after 15 min of heat shock amounted to 21% of cellular insoluble proteins (IP), and disappeared 10 min after transfer of the culture to 37 degrees C. In contrast to this, in the clpB mutant the S fraction was larger (35% IP) and its elimination was retarded, nearly 60% of the aggregated proteins remained stable 30 min after heat shock. This result points to the importance of ClpB in removal of the heat-aggregated proteins from cells. Overproduction of the Hsp70 system proteins (exceeding by about 1.5-fold that of wild-type) in wild-type and DeltaclpB cells completely prevented the formation of the S fraction during heat shock. Overproduction of ClpB (exceeding by about eight-fold that of wild-type) in the same background did not prevent protein aggregation after heat shock and only partly compensated for the effect of the mutation in the clpB gene. Monitoring the S fraction during co-production of DnaK/DnaJ/GrpE and ClpB in the DeltaclpB mutant revealed that both the levels of expression and the ratios of ClpB to Hsp70 system proteins had a significant effect on the formation and removal of protein aggregates in heat-shocked E. coli cells. In the presence of excess ClpB, an increase in the levels of DnaK, DnaJ and GrpE was required to prevent aggregate formation upon heat shock or to efficiently remove protein aggregates after heat shock. Therefore, it is supposed that a high level of ClpB under some conditions, especially at insufficient levels of Hsp70 system proteins, may support protein aggregation resulting from heat shock and may lead to stabilization of hydrophobic aggregates.     

The ClpB protein from Campylobacter jejuni: molecular characterization of the encoding gene and antigenicity of the recombinant protein

The ClpB heat-shock protein is necessary for the survival of Escherichia coli cells upon sudden increase of temperature. Using a PCR-based genomic walking method, the nucleotide sequence of a clpB homolog from Campylobacter jejuni was determined. The clpB gene encodes a protein of 857 amino acid (aa) residues, with a predicted molecular mass of 95.3kDa. Alignment of the deduced aa sequence with other known bacterial ClpB proteins revealed overall identity from 47% (E. coli) to 61% (Helicobacter pylori). Within the clpB promoter region, as indicated by primer extension analysis, we identified a sequence identical to the E. coli sigma70 consensus promoter. Northern blot analysis confirmed that clpB is heat-inducible in C. jejuni. The ClpB protein, fused to a 6xHis tag, was synthesized in E. coli and purified by metal-affinity and size exclusion chromatography. In ELISA studies, IgA levels reactive to recombinant ClpB were significantly higher in sera of patients with prior C. jejuni infections than in sera obtained from healthy control persons.     

Small heat shock proteins, ClpB and the DnaK system form a functional triade in reversing protein aggregation

Small heat shock proteins (sHsps) can efficiently prevent the aggregation of unfolded proteins in vitro. However, how this in vitro activity translates to function in vivo is poorly understood. We demonstrate that sHsps of Escherichia coli, IbpA and IbpB, co-operate with ClpB and the DnaK system in vitro and in vivo, forming a functional triade of chaperones. IbpA/IbpB and ClpB support independently and co-operatively the DnaK system in reversing protein aggregation. A delta ibpAB delta clpB double mutant exhibits strongly increased protein aggregation at 42 degrees C compared with the single mutants. sHsp and ClpB function become essential for cell viability at 37 degrees C if DnaK levels are reduced. The DnaK requirement for growth is increasingly higher for delta ibpAB, delta clpB, and the double delta ibpAB delta clpB mutant cells, establishing the positions of sHsps and ClpB in this chaperone triade.     

Induction of the heat shock protein ClpB affects cold acclimation in the cyanobacterium Synechococcus sp. strain PCC 7942.

The heat shock protein ClpB is essential for acquired thermotolerance in cyanobacteria and eukaryotes and belongs to a diverse group of polypeptides which function as molecular chaperones. In this study we show that ClpB is also strongly induced during moderate cold stress in the unicellular cyanobacterium Synechococcus sp. strain PCC 7942. A fivefold increase in ClpB (92 kDa) content occurred when cells were acclimated to 25 degrees C over 24 h after being shifted from the optimal growth temperature of 37 degrees C. A corresponding increase occurred for the smaller ClpB' (78 kDa), which arises from a second translational start within the clpB gene of prokaryotes. Shifts to more extreme cold (i.e., 20 and 15 degrees C) progressively decreased the level of ClpB induction, presumably due to retardation of protein synthesis within this relatively cold-sensitive strain. Inactivation of clpB in Synechococcus sp. increased the extent of inhibition of photosynthesis upon the shift to 25 degrees C and markedly reduced the mutant's ability to acclimate to the new temperature regime, with a threefold drop in growth rate. Furthermore, around 30% fewer delta clpB cells survived the shift to 25 degrees C after 24 h compared to the wild type, and more of the mutant cells were also arrested during cell division at 25 degrees C, remaining attached after septum formation. Development of a cold thermotolerance assay based on cell survival clearly demonstrated that wild-type cells could acquire substantial resistance to the nonpermissive temperature of 15 degrees C by being pre-exposed to 25 degrees C. The same level of cold thermotolerance, however, occurred in the delta clpB strain, indicating ClpB induction is not necessary for this form of thermal resistance in Synechococcus spp. Overall, our results demonstrate that the induction of ClpB contributes significantly to the acclimation process of cyanobacteria to permissive low temperatures.     

Clp ATPases are required for stress tolerance, intracellular replication and biofilm formation in Staphylococcus aureus

The Hsp100/Clp ATPases constitute a family of closely related proteins of which some members function solely as chaperones whereas others additionally can associate with the unrelated ClpP peptidase forming a Clp proteolytic complex. We have investigated the role of four Clp ATPases in the versatile pathogen, Staphylococcus aureus. Previously, we showed that ClpX is required for expression of major virulence factors and for virulence of S. aureus, but not for survival during heat shock. In the present study, we have inactivated clpC, clpB and clpL and, while none of these mutations affected toxin production, both ClpC and ClpB and to a minor extent ClpL were required for intracellular multiplication within bovine mammary epithelial cells. These defects were paralleled by an inability of the clpC mutant to grow at high temperature and of the clpB mutant to induce thermotolerance indicating that the protective functions of these proteins are required both at high temperature and during infection. By primer extension analysis and footprint studies, we show that expression of clpC and clpB is controlled by the negative heat-shock regulator, CtsR, and that ClpC is required for its repressor activity. Thus, ClpC is a likely sensor of stress encountered during both environmental stress and infection. In addition to virulence factor production the ability to form biofilms is of importance to S. aureus as a nosocomial pathogen. Interestingly, biofilm formation was reduced in the absence of ClpX or ClpC whereas it was enhanced in the absence of ClpP. Thus, our data show that Clp proteolytic complexes and the Clp ATPases control several key processes of importance to the success of S. aureus as a pathogen.     

Homologies of Deoxyribonucleic Acids from Brucella ovis, Canine Abortion Organisms, and other Brucella Species

The bacterium that causes canine abortion has polynucleotide sequences similar, in deoxyribonucleic acid (DNA)-DNA homology studies, to those of Brucella suis and, by inference from previous data, those of B. abortus and B. melitensis as well as B. neotomae. Therefore, the organism causing canine abortion appears to be a member of the genus Brucella. DNA preparations from Serratia marcescens, Alcaligenes faecalis, and Bordetella bronchiseptica, 58, 62, and 66 mole% guanine plus cytosine, respectively, do not have detectable polynucleotide sequence homologies with B. suis DNA which is 56 mole% guanine plus cytosine. B. ovis DNA lacks some of the polynucleotide sequences present in B. suis DNA and appears to be a deletion mutant. However, a large proportion of B. ovis polynucleotides are similar to those of other Brucella species, which supports the inclusion of B. ovis in the genus.     

Disruption and analysis of the clpB, clpC, and clpE genes in Lactococcus lactis: ClpE, a new Clp family in gram-positive bacteria

In the genome of the gram-positive bacterium Lactococcus lactis MG1363, we have identified three genes (clpC, clpE, and clpB) which encode Clp proteins containing two conserved ATP binding domains. The proteins encoded by two of the genes belong to the previously described ClpB and ClpC families. The clpE gene, however, encodes a member of a new Clp protein family that is characterized by a short N-terminal domain including a putative zinc binding domain (-CX2CX22CX2C-). Expression of the 83-kDa ClpE protein as well as of the two proteins encoded by clpB was strongly induced by heat shock and, while clpC mRNA synthesis was moderately induced by heat, we were unable to identify the ClpC protein. When we analyzed mutants with disruptions in clpB, clpC, or clpE, we found that although the genes are part of the L. lactis heat shock stimulon, the mutants responded like wild-type cells to heat and salt treatments. However, when exposed to puromycin, a tRNA analogue that results in the synthesis of truncated, randomly folded proteins, clpE mutant cells formed smaller colonies than wild-type cells and clpB and clpC mutant cells. Thus, our data suggest that ClpE, along with ClpP, which recently was shown to participate in the degradation of randomly folded proteins in L. lactis, could be necessary for degrading proteins generated by certain types of stress.     

The stringent response mediator Rsh is required for Brucella melitensis and Brucella suis virulence, and for expression of the type IV secretion system virB

Physiological adaptation of intracellular bacteria is critical for timely interaction with eukaryotic host cells. One mechanism of adaptation, the stringent response, is induced by nutrient stress via its effector molecule (p)ppGpp, synthesized by the action of RelA/SpoT homologues. The intracellular pathogen Brucella spp., causative agent of brucellosis, possesses a gene homologous to relA/spoT, named rsh, encoding a (p)ppGpp synthetase as confirmed by heterologous complementation of a relA mutant of Sinorhizobium meliloti. The Rsh deletion mutants in Brucella suis and Brucella melitensis were characterized by altered morphology, and by reduced survival under starvation conditions and in cellular and murine models of infection. Most interestingly, we evidenced that expression of virB, encoding the type IV secretion system, a major virulence factor of Brucella, was Rsh-dependent. All mutant phenotypes, including lack of VirB proteins, were complemented with the rsh gene of Brucella. In addition, RelA of S. meliloti functionally replaced Brucella Rsh, describing the capacity of a gene from a plant symbiont to restore virulence in a mammalian pathogen. We therefore concluded that in the intramacrophagic environment encountered by Brucella, Rsh might participate in the adaptation of the pathogen to low-nutrient environments, and indirectly in the VirB-mediated formation of the final replicative niche.     

BmaC, a novel autotransporter of Brucella suis, is involved in bacterial adhesion to host cells

Brucella is an intracellular pathogen responsible of a zoonotic disease called brucellosis. Brucella survives and proliferates within several types of phagocytic and non-phagocytic cells. Like in other pathogens, adhesion of brucellae to host surfaces was proposed to be an important step in the infection process. Indeed, Brucella has the capacity to bind to culture human cells and key components of the extracellular matrix, such as fibronectin. However, little is known about the molecular bases of Brucella adherence. In an attempt to identify bacterial genes encoding adhesins, a phage display library of Brucella suis was panned against fibronectin. Three fibronectin-binding proteins of B. suis were identified using this approach. One of the candidates, designated BmaC was a very large protein of 340 kDa that is predicted to belong to the type I (monomeric) autotransporter family. Microscopy studies showed that BmaC is located at one pole on the bacterial surface. The phage displaying the fibronectin-binding peptide of BmaC inhibited the attachment of brucellae to both, HeLa cells and immobilized fibronectin in vitro. In addition, a bmaC deletion mutant was impaired in the ability of B. suis to attach to immobilized fibronectin and to the surface of HeLa and A549 cells and was out-competed by the wild-type strain in co-infection experiments. Finally, anti-fibronectin or anti-BmaC antibodies significantly inhibited the binding of wild-type bacteria to HeLa cells. Our results highlight the role of a novel monomeric autotransporter protein in the adhesion of B. suis to the extracellular matrix and non-phagocytic cells via fibronectin binding.     

Cloning, expression, and purification of Brucella suis outer membrane proteins

Brucella, an aerobic, nonsporeforming, nonmotile Gram-negative coccobacillus, is a NIH/CDC category B bioterror threat agent that causes incapacitating human illness. Medical defense against the bioterror threat posed by Brucella would be strengthened by development of a human vaccine and improved diagnostic tests. Central to advancement of these goals is discovery of bacterial constituents that are immunogenic or antigenic for humans. Outer membrane proteins (OMPs) are particularly attractive for this purpose. In this study, we cloned, expressed, and purified seven predicted OMPs of Brucella suis. The recombinant proteins were fused with 6-His and V5 epitope tags at their C termini to facilitate detection and purification. The B. suis surface genes were PCR synthesized based on their ORF sequences and directly cloned into an entry vector. The recombinant entry constructs were propagated in TOP 10 cells, recombined into a destination vector, pET-DEST42, then transformed into Escherichia coli BL21 cells for IPTG-induced protein expression. The expressed recombinant proteins were confirmed with Western blot analysis using anti-6-His antibody conjugated with alkaline phosphatase. These B. suis OMPs were captured and purified using a HisGrab plate. The purified recombinant proteins were examined for their binding activity with antiserum. Serum derived from a rabbit immunized intramuscularly with dialyzed cell lysate of Brucella rough mutant WRR51. The OMPs were screened using the rabbit antiserum and purified IgG. The results suggested that recombinant B. suis OMPs were successfully cloned, expressed and purified. Some of the expressed OMPs showed high binding activity with immunized rabbit antiserum.