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.     

Genetic mapping and biochemical characterization of suppressor mutations sukA and sukB for a dnaK7(Ts) mutation of Escherichia coli K-12.

Temperature-resistant pseudorevertants were isolated from a dnaK7(Ts) mutant of Escherichia coli K-12. Two of these pseudorevertants were shown to carry suppressor mutations, sukA and sukB, respectively. Genetic mapping by conjugation and P1-transduction revealed that these suppressor mutations were located at two distinct sites between 76 and 77 min close to the suhA and rpoH genes. Labeled cellular proteins were extracted from suppressor mutants grown at various temperatures and subjected to SDS-gel electrophoresis. Autoradiograms of the gels indicated that these suppressor mutations each resulted in increased synthesis of the heat shock protein Lon (an ATP-dependent protease, La) at both permissive and nonpermissive temperatures.     

Overproduction of FtsZ suppresses sensitivity of lon mutants to division inhibition.

Escherichia coli lon mutants are sensitive to UV light and other DNA-damaging agents. This sensitivity is due to the loss of the lon-encoded ATP-dependent proteolytic activity which results in increased stability of the cell division inhibitor SulA. Introduction of the multicopy plasmid pZAQ containing the ftsZ gene, which is known to increase the level of FtsZ, suppressed the sensitivity of lon mutants to the DNA-damaging agents UV and nitrofurantoin. Alterations of pZAQ which reduced the expression of ftsZ reduced the ability of this plasmid to suppress the UV sensitivity. Examination of the kinetics of cell division revealed that pZAQ did not suppress the transient filamentation seen after exposure to UV, but did suppress the long-term inhibition that is normally observed. lon strains carrying pZAQ could stably maintain a multicopy plasmid carrying sulA (pBS2), which cannot otherwise be introduced into lon mutants. In addition, the increased temperature sensitivity of lexA(Ts) strains containing pBS2 was suppressed by pZAQ. These results suggest that SulA inhibits cell division by inhibiting FtsZ and that this interaction is stoichiometric.     

Regulation of breakdown of canavanyl proteins in Escherichia coli by growth conditions in Ion+ and Ion− cells

In vivo rates of proteolysis of canavanyl proteins were compared in lon+ and lon- Escherichia coli strains following growth in a variety of media. Both lon+ and lon- cells grown rapidly in complex media possessed higher levels of constitutive degradative activity than when cultured in minimal media. Pre-growth of lon+ cells in the presence of canavanine induced proteolytic activity following growth in minimal media as did stress agents such as heat, alcohol and puromycin: the lon mutant did not show the increased activity following canavanine treatment. The results suggest the presence of a proteolytic activity which selectively degrades aberrant proteins which does not involve protease La, the product of the lon gene, and which furthermore is regulated in part by growth conditions independently of the stress response.     

Oxidatively denatured proteins are degraded by an ATP-independent proteolytic pathway in Escherichia coli

E. coli contains a soluble proteolytic pathway which can recognize and degrade oxidatively denatured proteins and protein fragments, and which may act as a "secondary antioxidant defense." We now provide evidence that this proteolytic pathway is distinct from the previously described ATP-dependent, and protease "La"-dependent, pathway which may degrade other abnormal proteins. Cells (K12) which were depleted of ATP, by arsenate treatment or anaerobic incubation (after growth on succinate), exhibited proteolytic responses to oxidative stress which were indistinguishable from those observed in cells with normal ATP levels. Furthermore, the proteolytic responses to oxidative damage by menadione or H2O2 were almost identical in the isogenic strains RM312 (a K12 derivative) and RM1385 (a lon deletion mutant of RM312). Since the lon (or capR) gene codes for the ATP-dependent protease "La," these results indicate that neither ATP nor protease "La" are required for the degradation of oxidatively denatured proteins. We next prepared cell-free extracts of K12, RM312, and RM1385 and tested the activity of their soluble proteases against proteins (albumin, hemoglobin, superoxide dismutase, catalase) which had been oxidatively denatured (in vitro) by exposure to .OH, .OH + O2- (+O2), H2O2, or ascorbate plus iron. The breakdown of oxidatively denatured proteins was several-fold higher than that of untreated proteins in extracts from all three strains, and ATP did not stimulate degradation. Incubation of extracts at 45 degrees C, which inactivates protease "La," actually stimulated the degradation of oxidatively denatured proteins. Although Ca2+ had little effect on proteolysis, serine reagents, transition metal chelators, and hemin effectively inhibited the degradation of oxidatively denatured proteins in both intact cells and cell-free extracts. Degradation of oxidatively denatured proteins in cell-free extracts was maximal at pH 7.8, and was unaffected by dialysis of the extracts against membranes with molecular weight cutoffs as high as 50,000. Our results indicate the presence of a neutral, ATP- and calcium- independent proteolytic pathway in the E. coli cytosol, which contains serine- and metallo- proteases (with molecular weights greater than 50,000), and which preferentially degrades oxidatively denatured proteins.     

Hyperprotease-Producing Mutants of Bacillus subtilis

A number of mutants of Bacillus subtilis producing high levels of extracellular protease have been isolated. Analysis of culture supernatants of these mutants has shown that the total amount of proteolytic activity is elevated from 16- to 37-fold over the wild strain. The elevated activity was due to a simultaneous increase in both the neutral and alkaline protease. All of the mutants genetically analyzed were found linked to the argC4 marker by PBS-1 transduction analysis.     

Lysis of Escherichia coli by the bacteriophage phi X174 E protein: inhibition of lysis by heat shock proteins.

Lysis of Escherichia coli by the cloned E protein of bacteriophage phi X174 was more rapid than expected when bacteria were shifted from 30 to 42 degrees C at the time of E induction. Since such treatment also induces the heat shock response, we investigated the effect of heat shock proteins on lysis. An rpoH mutant was more sensitive to lysis by E, but a secondary suppressor mutation restored lysis resistance to parental levels, which suggests that the sigma 32 subunit itself did not directly increase lysis resistance. At 30 degrees C, mutants in five heat shock genes (dnaK, dnaJ, groEL, groES, and grpE) were more sensitive to lysis than were their wild-type parents. The magnitude of lysis sensitivity varied with mutation and strain background, with dnaK, dnaJ, and groES mutants consistently exhibiting the greatest sensitivities. Extended protection against lysis occurred when overproduction of heat shock proteins was induced artificially in cells that contained a plasmid with the rpoH+ gene under control of the tac promoter. This protective effect was completely abolished by mutations in dnaK, dnaJ, or groES but not by grpE or groEL mutations. Altered membrane behavior probably explains the contradiction whereby an actual temperature shift sensitized cells to lysis, but production of heat shock proteins exhibited protective effects. The results demonstrate that E-induced lysis can be divided into two distinct operations which may now be studied separately. They also emphasize a role for heat shock proteins under non-heat-shock conditions and suggest cautious interpretation of lysis phenomena in systems where E protein production is under control of a temperature-sensitive repressor.     

Involvement of the chaperonin dnaK in the rapid degradation of a mutant protein in Escherichia coli.

The ability of Escherichia coli rapidly to degrade abnormal proteins is inhibited by mutations affecting any of several heat shock proteins (hsps). We therefore tested whether a short-lived mutant protein might become associated with hsps as part of its degradation. At 30 degrees C, the non-secreted mutant form of alkaline phosphatase, phoA61, is relatively stable, and very little phoA61 is found associated with the hsp dnaK. However, raising the temperature to 37 degrees C or 41 degrees C stimulated the degradation of this protein, and up to 30% of cellular phoA61 became associated with dnaK, as shown by immunoprecipitation and Western blot analysis. Also found in complexes with phoA61 were the hsps, protease La and grpE (but no groEL, or groES). The rapid degradation of phoA61 at 37 degrees C and 41 degrees C is in part by protease La, since it decreased by 50% in lon mutants. This process also requires dnaK, since deletion of this gene prevented phoA61 degradation almost completely (unless a wild-type dnaK gene was introduced). In contrast, the missense mutation, dnaK756, enhanced phoA61 degradation. The dnaK756 protein also was associated with phoA61, but this complex, unlike that containing wild-type dnaK could not be dissociated by ATP addition. Furthermore, in a grpE mutant, the degradation of phoA61 and the amount associated with dnaK increased, while in a dnaJ mutant, phoA61 degradation and its association with dnaK decreased. Thus, complex formation with dnaK appears essential for phoA61 degradation by protease La and some other cell proteases, and a failure of the dnaK to dissociate normally may accelerate proteolytic attack.(ABSTRACT TRUNCATED AT 250 WORDS)     

Species variation in ATP-dependent protein degradation: protease profiles differ between mycobacteria and protease functions differ between Mycobacterium smegmatis and Escherichia coli

We report here that the existence of the potentially broad substrate specificity protease Lon (also called La), is evolutionarily discontinuous within the order Actinomycetales. Lon homologues were identified in the fast-growing species Mycobacterium smegmatis, and the slow-growing species Micobacterium avium and Mycobacterium intracellulare. However, Lon homologues were not detected in the slow-growing species Mycobacterium tuberculosis, Mycobacterium bovis, or Mycobacterium leprae; or in the non-mycobacterial Actinomycetale Corynebacterium glutamica. To characterize the function of the Lon protease within the Actinomycetales, a viable M. smegmatis Deltalon strain was constructed, demonstrating that lon is not essential under certain conditions. Surprisingly, lon was also dispensable in M. smegmatis cells already lacking intact 20S proteasome alpha- and beta-subunit genes (called prcA and prcB, respectively). Creation of the later double deletion strain (prcBA::kan Deltalon) necessitated use of a novel gene deletion strategy that does not require an antibiotic resistance marker. The M. smegmatis prcBA::kan Deltalon double mutants displayed wild type (wt) growth rates and wt stress tolerances. In addition, the M. smegmatis prcBA::kan Deltalon double mutants degraded at wt rates the broad spectrum of truncated proteins induced by treating cells with puromycin. This later result was in sharp contrast to those in Escherichia coli, where either lon or hslUV single mutants are strongly impaired in their degradation of puromycyl peptides (hslV is a prcB homologue). Overall these data suggested that mycobacterial species contain additional ATP-dependent proteases that have broad substrate specificity. Consistent with this suggestion, M. smegmatis and M. tuberculosis each contain at least one homologue of ClpP, the proteolytic subunit common to the ClpAP and ClpXP proteases.     

Isolation and characterization of lon mutants in Salmonella typhimurium.

In this paper we report the isolation and characterization of lon mutants in Salmonella typhimurium. The mutants were isolated by using positive selection by chlorpromazine resistance. The physiological and biochemical properties of the lon mutants in S. typhimurium are very similar to those of Escherichia coli lon mutants. Mutants altered at this locus contain little or no activity of the ATP-dependent protease La and show a number of pleiotropic phenotypes, including increased production of capsular polysaccharides, increased sensitivity to UV light and other DNA-damaging agents, and a decreased ability to degrade abnormal proteins.     

An analysis of the effect of changes in growth temperature on proteolysis in vivo in the psychrophilic bacterium Vibrio sp. strain ANT-300.

In the psychrophilic bacterium Vibrio sp. strain ANT-300, the rate of protein degradation in vivo, measured at fixed temperatures, increased with elevation of the growth temperature. A shift in growth temperature induced a marked increase in this rate. Dialysed cell-free extracts hydrolysed exogenous insulin, globin and casein (in decreasing order of activity) but did not hydrolyse exogenous cytochrome c. Cells contained at least seven protease separated by DEAE-Sephacel chromatography, one of which was an ATP-dependent serine protease. The ATP-dependent proteolytic activity in extracts of cells incubated for 3 h at 16 degrees C after a shift-up from 0 degrees C increased to a level 36% and 17% higher than that of cells grown at 0 degrees C and 13 degrees C, respectively. A shift-down to 0 degrees C from 13 degrees C induced only a slight increase in the proteolytic activity. Extracts of all cells, whether exposed to temperature shifts or not, showed the same temperature dependence with respect to both ATP-dependent and ATP-independent protease activity. In all the extracts these proteases also exhibited the same heat lability. The ATP-dependent protease was inactivated by incubation at temperatures above 25 degrees C. There was an increase in ATP-independent protease activity during incubation at temperatures between 25 and 30 degrees C, but a decrease at 35 degrees C and higher. These results suggest that the marked increases in proteolysis in vivo, caused by a shift in temperature, may result not only from increases in levels of ATP-dependent serine protease(s) but also from increases in the susceptibility of proteins to degradation.     

DnaK mutants defective in ATPase activity are defective in negative regulation of the heat shock response: expression of mutant DnaK proteins results in filamentation.

Site-directed mutagenesis has previously been used to construct Escherichia coli dnaK mutants encoding proteins that are altered at the site of in vitro phosphorylation (J. S. McCarty and G. C. Walker, Proc. Natl. Acad. Sci. USA 88:9513-9517, 1991). These mutants are unable to autophosphorylate and are severely defective in ATP hydrolysis. These mutant dnaK genes were placed under the control of the lac promoter and were found not to complement the deficiencies of a delta dnaK mutant in negative regulation of the heat shock response. A decrease in the expression of DnaK and DnaJ below their normal levels at 30 degrees C was found to result in increased expression of GroEL. The implications of these results for DnaK's role in the negative regulation of the heat shock response are discussed. Evidence is also presented indicating the existence of a 70-kDa protein present in a delta dnaK52 mutant that cross-reacts with antibodies raised against DnaK. Derivatives of the dnaK+ E. coli strain MC4100 expressing the mutant DnaK proteins filamented severely at temperatures equal to or greater than 34 degrees C. In the dnaK+ E. coli strain W3110, expression of these mutant proteins caused extreme filamentation even at 30 degrees C. Together with other observations, these results suggest that DnaK may play a direct role in the septation pathway, perhaps via an interaction with FtsZ. Although delta dnaK52 derivatives of strain MC4100 filament extensively, a level of underexpression of DnaK and DnaJ that results in increased expression of the other heat shock proteins did not result in filamentation. The delta dnaK52 allele could be transduced successfully, at temperatures of up to 45 degrees C, into strains carrying a plasmid expressing dnaK+ dnaJ+, although the yield of transductants decreased above 37 degrees C. In contrast, with a strain that did not carry a plasmid expressing dnaK+ dnaJ+, the yield of delta dnaK52 transductants decreased extremely sharply between 39 and 40 degrees C, suggesting that DnaK and DnaJ play one or more roles critical for growth at temperatures of 40 degrees C or greater.