Sodium Dodecyl Sulfate Hypersensitivity of clpP and clpB Mutants of Escherichia coli

We studied the hypersensitivity of clpP and clpB mutants of Escherichia coli to sodium dodecyl sulfate (SDS). Both wild-type E. coli MC4100 and lon mutants grew in the presence of 10% SDS, whereas isogenic clpP and clpB single mutants could not grow above 0.5% SDS and clpA and clpX single mutants could not grow above 5.0% SDS. For wild-type E. coli, cellular ClpP levels as determined by Western immunoblot analysis increased ca. sixfold as the levels of added SDS increased from 0 to 2%. Capsular colanic acid, measured as uronic acid, increased ca. sixfold as the levels of added SDS increased from 2 to 10%. Based on these findings, 3 of the 19 previously identified SDS shock proteins (M. Adamowicz, P. M. Kelley, and K. W. Nickerson, J. Bacteriol. 173:229-233, 1991) are tentatively identified as ClpP, ClpX, and ClpB.     

Regulation and Physiological Significance of ClpC and ClpP in Streptococcus mutans

Tolerance of environmental stress, especially low pH, by Streptococcus mutans is central to the virulence of this organism. The Clp ATPases are implicated in the tolerance of, and regulation of the response to, stresses by virtue of their protein reactivation and remodeling activities and their capacity to target misfolded proteins for degradation by the ClpP peptidase. The purpose of this study was to dissect the role of selected clp genes in the stress responses of S. mutans, with a particular focus on acid tolerance and adaptation. Homologues of the clpB, clpC, clpE, clpL, clpX, and clpP genes were identified in the S. mutans genome. The expression of clpC and clpP, which were chosen as the focus of this study, was induced at low pH and at growth above 40 degrees C. Inactivation of ctsR, the first of two genes in the clpC operon, demonstrated that CtsR acts as a repressor of clp and groES-EL gene expression. Strains lacking ClpP, but not strains lacking ClpC, were impaired in their ability to grow under stress-inducing conditions, formed long chains, aggregated in culture, had reduced genetic transformation efficiencies, and had a reduced capacity to form biofilms. Comparison of two-dimensional protein gels from wild-type cells and the ctsR and clpP mutants revealed many changes in the protein expression patterns. In particular, in the clpP mutant, there was an increased production of GroESL and DnaK, suggesting that cells were stressed, probably due to the accumulation of denatured proteins.     

Role of Clp protease subunits in degradation of carbon starvation proteins in Escherichia coli.

When deprived of a carbon source, Escherichia coli induces the synthesis of a group of carbon starvation proteins. The degradation of proteins labeled during starvation was found to be an energy-dependent process which was inhibited by the addition of KCN and accelerated when cells were resupplied with a carbon source. The degradation of the starvation proteins did not require the ATP-dependent Lon protease or the energy-independent proteases protease I, protease IV, OmpT, and DegP. During starvation, mutants lacking either the ClpA or ClpP subunit of the ATP-dependent Clp protease showed a partial reduction in the degradation of starvation proteins. Strains lacking ClpP failed to increase degradation of starvation proteins when glucose was added to starving cells. The clpP mutants showed a competitive disadvantage compared with wild-type cells when exposed to repeated cycles of carbon starvation and growth. Surprisingly, the glucose-stimulated, ClpP-dependent degradation of starvation proteins did not require either the ClpA or ClpB protein. The patterns of synthesis of starvation proteins were similar in clpP+ and clpP cells. The clpP mutants had reduced rates of degradation of certain starvation proteins in the membrane fraction when a carbon source was resupplied to the starved cells.     

Inactivation of a gene that is highly conserved in Gram-positive bacteria stimulates degradation of non-native proteins and concomitantly increases stress tolerance in Lactococcus lactis

Exposure of cells to elevated temperatures triggers the synthesis of chaperones and proteases including components of the conserved Clp protease complex. We demonstrated previously that the proteolytic subunit, ClpP, plays a major role in stress tolerance and in the degradation of non-native proteins in the Gram-positive bacterium Lactococcus lactis. Here, we used transposon mutagenesis to generate mutants in which the temperature- and puromycin-sensitive phenotype of a lactococcal clpP null mutant was partly alleviated. In all mutants obtained, the transposon was inserted in the L. lactis trmA gene. When analysing a clpP, trmA double mutant, we found that the expression normally induced from the clpP and dnaK promoters in the clpP mutant was reduced to wild-type level upon introduction of the trmA disruption. Additionally, the degradation of puromycyl-containing polypeptides was increased, suggesting that inactivation of trmA compensates for the absence of ClpP by stimulating an as yet unidentified protease that degrades misfolded proteins. When trmA was disrupted in wild-type cells, both stress tolerance and proteolysis of puromycyl peptides was enhanced above wild-type level. Based on our results, we propose that TrmA, which is well conserved in several Gram-positive bacteria, affects the degradation of non-native proteins and thereby controls stress tolerance.     

Global role for ClpP-containing proteases in stationary-phase adaptation of Escherichia coli

To elucidate the involvement of proteolysis in the regulation of stationary-phase adaptation, the clpA, clpX, and clpP protease mutants of Escherichia coli were subjected to proteome analysis during growth and during carbon starvation. For most of the growth-phase-regulated proteins detected on our gels, the clpA, clpX, or clpP mutant failed to mount the growth-phase regulation found in the wild type. For example, in the clpP and clpA mutant cultures, the Dps protein, the WrbA protein, and the periplasmic lysine-arginine-ornithine binding protein ArgT did not display the induction typical for late-stationary-phase wild-type cells. On the other hand, in the protease mutants, a number of proteins accumulated to a higher degree than in the wild type, especially in late stationary phase. The proteins affected in this manner include the LeuA, TrxB, GdhA, GlnA, and MetK proteins and alkyl hydroperoxide reductase (AhpC). These proteins may be directly degraded by ClpAP or ClpXP, respectively, or their expression could be modulated by a protease-dependent mechanism. From our data we conclude that the levels of most major growth-phase-regulated proteins in E. coli are at some point controlled by the activity of at least one of the ClpP, ClpA, and ClpX proteins. Cultures of the strains lacking functional ClpP or ClpX also displayed a more rapid loss of viability during extended stationary phase than the wild type. Therefore, regulation by proteolysis seems to be more important, especially in resting cells, than previously suspected.     

Membrane-derived oligosaccharides (MDOs) are essential for sodium dodecyl sulfate resistance in Escherichia coli

We studied the role of membrane-derived oligosaccharides (MDOs) in sodium dodecyl sulfate (SDS) resistance by Escherichia coli. MDOs are also known as osmoregulated periplasmic glucans. Wild-type E. coli MC4100 grew in the presence of 10% SDS whereas isogenic mdoA and mdoB mutants could not grow above 0.5% SDS. Similarly, E. coli DF214, a mutant (pgi, zwf) unable to grow on glucose, exhibited conditional sensitivity to SDS in that it grew in gluconate and glucose or galactose but not in gluconate and mannose or sorbose. DF214 requires both gluconate and glucose/galactose because the gluconate is used for energy production, while glucose/galactose is used for MDO synthesis. Finally, the fate of E. coli cells subjected to SDS shock either during growth or when used as an inoculum is dependent on the presence or absence of sufficient MDOs. In both cases, cells grown under high-osmolarity (low-MDO) conditions were rapidly lysed by 5% SDS. Based on findings from a wild-type E. coli (MC4100), two mdo mutants and strain DF214 we conclude that MDOs are required for SDS resistance.     

ClpP-dependent degradation of PopR allows tightly regulated expression of the clpP3 clpP4 operon in Streptomyces lividans

Five clpP genes have been identified in Streptomyces coelicolor. The clpP1 and clpP2 genes form one operon, the clpP3 and clpP4 genes form another, and clpP5 is monocistronic. Previous studies in Streptomyces lividans have shown that the first operon (clpP1 clpP2) is required for a normal cell cycle. Expression of the second operon (clpP3 clpP4) is activated by PopR if the first operon is nonfunctional. We show here that PopR degradation is primarily dependent on ClpP1 and ClpP2, but can also be achieved by ClpP3 and ClpP4. The carboxy-terminus of PopR plays an essential part in the degradation process. Indeed, replacement of the last two alanine residues by aspartate residues greatly increased PopR stability. These substitutions did not impair PopR activity and, as expected, accumulation of the mutant form of PopR led to very strong expression of the clpP3 clpP4 operon. Increased PopR levels led to delayed sporulation. The results obtained in this study support the notion of cross-processing between ClpP1 and ClpP2.     

The ClpP peptidase is the major determinant of bulk protein turnover in Bacillus subtilis

Measurements of overall protein degradation rates in wild-type and clpP mutant Bacillus subtilis cells revealed that stress- or starvation-induced bulk protein turnover depends virtually exclusively on the ClpP peptidase. ClpP is also essential for intracellular protein quality control, and in its absence newly synthesized proteins were highly prone to aggregation even at 37 degrees C. Proteomic comparisons between the wild type and a DeltaclpP mutant showed that the absence of ClpP leads to severe perturbations of "normal" physiology, complicating the detection of ClpP substrates. A pulse-chase two-dimensional gel approach was therefore used to compare wild-type and clpP mutant cultures that had been radiolabeled in mid-exponential phase, by quantifying changes in relative spot intensities with time. The results showed that overall proteolysis is biased toward proteins with vegetative functions which are no longer required (or are required at lower levels) in the nongrowing state. The identified substrate candidates for ClpP-dependent degradation include metabolic enzymes and aminoacyl-tRNA synthetases. Some substrate candidates catalyze the first committed step of certain biosynthetic pathways. Our data suggest that ClpP-dependent proteolysis spans a broad physiological spectrum, with regulatory processing of key metabolic components and regulatory proteins on the one side and general bulk protein breakdown at the transition from growing to nongrowing phases on the other.     

Mycobacterium tuberculosis ClpP Proteases Are Co-transcribed but Exhibit Different Substrate Specificities

Caseinolytic (Clp) proteases are widespread energy-dependent proteases; the functional ATP-dependent protease is comprised of multimers of proteolytic and regulatory subunits. Mycobacterium tuberculosis has two ClpP proteolytic subunits (ClpP1 and ClpP2), with both being essential for growth in vitro. ClpP1 and clpP2 are arranged in an apparent operon; we demonstrated that the two genes are co-expressed under normal growth conditions. We identified a single promoter region for the clpP1P2 operon; no promoter was detected upstream of clpP2 demonstrating that independent expression of clpP1 and clpP2 was highly unlikely. Promoter activity was not induced by heat shock or oxidative stress. We identified a regulatory region upstream of the promoter with a consensus sequence matching the ClgR regulator motif; we determined the limits of the region by mutagenesis and confirmed that positive regulation of the promoter occurs in M. tuberculosis. We developed a reporter system to monitor ClpP1 and ClpP2 enzymatic activities based on LacZ incorporating ssrAtag sequences. We showed that whilst both ClpP1 and ClpP2 degrade SsrA-tagged LacZ, ClpP2 (but not ClpP1) degrades untagged proteins. Our data suggest that the two proteolytic subunits display different substrate specificities and therefore have different, but overlapping roles in M. tuberculosis.     

The ClpP component of Clp protease is the sigma 32-dependent heat shock protein F21.5.

The genes that encode the subunits of the Clp protease of Escherichia coli, clpA and clpP, appear to be regulated differently from each other. The clpA gene does not seem to be under heat shock control (Y. S. Katayama, S. Gottesman, J. Pumphrey, S. Rudikoff, W. P. Clark, and M. R. Maurizi, J. Biol. Chem. 263:15226-15236, 1988). In contrast, the level of ClpP protein was increased in rpoH+ cells but not in null rpoH cells after an upshift in temperature from 17 to 43 degrees C. The level of ClpP protein in a null dnaK strain was also elevated relative to the level of ClpP protein in an otherwise isogenic dnaK+ strain. In two-dimensional gels, the ClpP protein was located in the position of the previously unidentified heat shock protein F21.5. No protein spot corresponding to F21.5 was present in two-dimensional gels of a null clpP strain. The clpP gene, therefore, appears to be a heat shock gene, expressed in a sigma 32-dependent manner and negatively regulated by DnaK; the product of clpP is the previously unidentified heat shock protein F21.5.     

New insights into Staphylococcus aureus stress tolerance and virulence regulation from an analysis of the role of the ClpP protease in the strains Newman, COL, and SA564

In Staphylococcus aureus, ClpP proteases were previously shown to be essential for virulence and stress tolerance in strains derived from NCTC8325. Because these strains exhibit a severely reduced activity of the alternative sigma factor, SigB, we here reassessed the role of ClpP in SigB-proficient clinical strains. To this end, clpP was deleted in strains COL, Newman, and SA564, and the strains were characterized phenotypically. The proteomic changes accomplished by the clpP deletion in the different strains were analyzed using the 2-D DIGE technique. The proteomic analyses revealed mostly conserved changes in the protein profiles of the ClpP-deficient strains. Among the strain-specific changes were the up-regulation of prophage proteins that coincided with an increased spontaneous release of prophages and the relatively poorer growth of the clpP mutants in some strain backgrounds. Interestingly, the effect of ClpP on the expression of selected virulence genes was strain-dependent despite the fact that the expression of the global virulence regulators RNAIII, mgrA, sarZ, sarR, and arlRS was similarly changed in all clpP mutants. ClpP affected the expression of sarS in a strain-dependent manner, and we propose that the differential expression of sarS is central to the strain-dependent effect of ClpP on the expression of virulence genes.     

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.