Roles of DnaK and RpoS in Starvation-Induced Thermotolerance of Escherichia coli

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J Bacteriol, February 1998, p. 846-854, Vol. 180, No. 4
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Roles of DnaK and RpoS in Starvation-Induced Thermotolerance of Escherichia coli

David Rockabrand,¹ Kevin Livers,¹ Tess Austin,¹ Robyn Kaiser,¹ Debra Jensen,² Richard Burgess,² and Paul Blum¹^,^*

School of Biological Sciences, University of Nebraska, Lincoln, Nebraska 68588-0666,¹ and McArdle Laboratory, University of Wisconsin, Madison, Wisconsin 53706²

Received 24 April 1997/Accepted 14 December 1997

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

DnaK is essential for starvation-induced resistance to heat, oxidation, and reductive division in Escherichia coli. Studiesreported here indicate that DnaK is also required for starvation-inducedosmotolerance, catalase activity, and the production of the RpoS-controlledDps (PexB) protein. Because these dnaK mutant phenotypes closelyresemble those of rpoS ( $sigma$ ³⁸) mutants, the relationship between DnaK and RpoS was evaluateddirectly during growth and starvation at 30°C in strains withgenetically altered DnaK content. A starvation-specific effectof DnaK on RpoS abundance was observed. During carbon starvation,DnaK deficiency reduced RpoS levels threefold, while DnaK excessincreased RpoS levels nearly twofold. Complementation of the dnaKmutation restored starvation-induced RpoS levels to normal. RpoSdeficiency had no effect on the cellular concentration of DnaK,revealing an epistatic relationship between DnaK and RpoS. Proteinhalf-life studies conducted at the onset of starvation indicatethat DnaK deficiency significantly destabilized RpoS. RpoH ( $sigma$ ³²) suppressors of the dnaK mutant with restored levels of RpoSand dnaK rpoS double mutants were used to show that DnaK playsboth an independent and an RpoS-dependent role in starvation-inducedthermotolerance. The results suggest that DnaK coordinates sigmafactor levels in glucose-starved E. coli.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Starvation of Escherichia coli for carbon results in a near-immediate halt in cell division and the establishment of a dormant-or stationary-phase state (3, 35, 36). This state is distinguishedfrom the preceding growth period by a unique physiological resistanceto otherwise lethal stresses (13, 25, 52), reflecting thecoordinate expression of stationary phase-specific genes. Theresponse to carbon starvation is physiologically unlike that todeprivation of other nutrients, such as nitrogen or phosphorus.Carbon-starved cells rapidly readjust their rate of cell divisionand cease growth, whereas cells starved for other nutrients, suchas nitrogen or phosphorus, respond sluggishly (12, 62). Carbonstarvation therefore represents an efficient method for studyingthe stationary phase and also likely mimics common oligotrophicenvironmental conditions confronting other bacterial species (43).Regardless of which stimulus precipitates stationary phase, manycommon features characterize such nongrowing or dormant cells.Consequently, the high-cell-density stationary phase observedin rich undefined media is commonly employed for studies on stationary-phasegene expression and genetics (reviewed in references 17 and20).

When carbon for growth is limited, protein synthesis largely stops and cell survival and persistence rest on the integrityof protein synthesized at an earlier, prestarvation time. Maintenanceof protein structure during growth is determined largely by theactivity of protein chaperones, many of which are ATP-dependentenzymes such as DnaK (16, 37). This enzyme promotes structuralrearrangements in proteins and can be stimulated by the cochaperones,DnaJ and GrpE. In growing cells, loss of DnaK results in temperature-restricteddivision and defective expression of heat shock proteins (6,7). Starvation protein synthesis is also defective in a dnaKmutant (59). Such defects may underlie the observation thatDnaK deficiency mitigates starvation-induced physiological readjustments,particularly starvation-induced resistance to heat, oxidation,and reductive division (52). Interestingly, these particulardnaK mutant phenotypes are possessed by rpoS mutants (19, 21,30, 38, 54). Though a clear role for DnaK in the stationaryphase is evident from studies on DnaK deficiency, an excess ofthis chaperone elicits additional physiological alterations whichare again evident only in stationary-phase cells. Overproductionof DnaK is specifically bactericidal in the stationary phase,and this toxicity can be partially ameliorated by cooverproductionof DnaJ (2). The basis of this effect is as yet unclear, thoughsuppressor analysis of stationary-phase DnaK toxicity has ledto the recovery of multicopy genes which overcome this effect.One of these has been identified as edd and encodes the firstcommitted enzyme of the Entner-Doudoroff pathway for hexose catabolism(53). Inactivation of this gene by the insertion of a stop codonprevented suppression and suggests a role for this pathway instationary-phase metabolism.

The RpoS sigma factor controls expression of a diversity of genes, many of which are critical in the stationary phase (20,33). Specific examples particularly notable because of theirrole in starvation-induced physiological alterations include katE,encoding catalase HPII (23, 34), and dps (1), also calledpexB (31), encoding a small histone-like nonspecific DNA bindingprotein. However, additional genes involved in osmotolerant growth(22) and low-temperature growth (58) are now also known tobe controlled by RpoS. Such observations expand the role of RpoSbeyond the stationary phase. Increased expression of stationary-phaseRpoS-regulated genes requires an increase in the abundance ofRpoS. Such changes reflect alterations in rpoS expression at thelevel of transcription initiation, translation elongation, andposttranslational events resulting in increased RpoS stability(29, 39, 61). Variation in the allelic state of rssB/sprEindicates that this locus acts as an unlinked negative regulatorof RpoS abundance in the exponential phase (45, 51). RpoSabundance during growth also depends in part on the ClpX/P heatshock proteins (56) as well as on the absolute temperature ofcultivation (58). Since heat shock of growing cells elicitsan increase in the abundance of RpoS, a role for additional regulatoryfactors of RpoS abundance appears likely (26).

To better understand the significance of the apparent stationary-phase phenotypic overlap between dnaK and rpoS mutants, adnaK null mutant (49) as well as an otherwise isogenic wild-typeand rpoS null mutant strains were analyzed for additional rpoS-likedefects. We report here that the dnaK mutant has several of thesame phenotypes as rpoS mutants, which result from an apparentdefect in RpoS metabolism. Consequently, these findings suggestthat DnaK plays only an indirect role in the starvation response.While these studies were under way, a role for DnaK in modulatingRpoS levels during heat shock was reported (44). The physiologicalsignificance of this observation, however, was not apparent. Inaddition, it was reported that DnaK deficiency elevated exponential-phaseRpoS levels sixfold while decreasing carbon starvation-inducedlevels only slightly. The physiological significance of theseresults was not examined. These findings contrast with resultsobtained with rpoS::lacZ fusions which indicate that RpoS is significantlydestabilized during growth and starvation by a mutation in dnaK(44). Failure of an rpoH missense mutant (sidB1) to suppressthe dnaK mutant's effects on RpoS were interpreted as evidencefor the exclusion of a role for other heat shock proteins suchas ClpP/X from this process. To resolve the interplay betweenDnaK and RpoS in starvation-related phenotypes, we used additionalrpoH mutant alleles and a dnaK rpoS double mutant to study thisprocess. The results solve apparent discrepancies and indicatethat dnaK plays two roles in starvation-related phenotypes; oneis mediated through RpoS, and the other controls the physiologicalstatus of starving cells in an rpoS-independent manner.

	MATERIALS AND METHODS

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Bacterial strains, plasmids, and cell cultivation. E. coli strains, plasmids, and phages used in this study are listed in Table 1. Plasmid isolation and subcloning procedureswere performed as described previously (2). The pBN15 plasmid-bearing derivative of PBL501, strain PBL504, was constructed bytransformation at 30°C. The Dps-producing plasmid pBN49 was constructedby subcloning an 8-kb BamHI-HindIII fragment containing the entiredps gene from phage $lambda$ -205 (27) into pACYC184 (9) previouslydigested with BamHI and HindIII. Phage $lambda$ and phage P1 were grownas described previously (4). Strain PBL502 was constructedby generalized transduction with phage P1_vir grown onAMS150 (Table 1), which contained a transposon Tn10 insertionin rpoS (katF13::Tn10; 34) to transduce PBL500 to tetracyclineresistance. The rpoS deletion strain, PBL503, was constructedby transposon-mediated deletion formation as described previously(5). The extent of the rpoS deletion was mapped by analyzinggenes flanking rpoS, including mutS (61.5 min) for the counterclockwisedirection and cysC (61.85) for the clockwise direction. The insertionsite of the Tn10 in rpoS was identified previously in the 5' endof the rpoS coding region at base 196 (24). Deletion of the3' end of the rpoS gene was indicated by the apparent loss ofmutS (10). PBL503, containing the mutS deletion, had a forwardmutation rate to streptomycin resistance of 1.14 × 10⁷ compared to 3.5 × 10⁹ for the otherwise isogenic wild-type parent strain, PBL502. TherpoS deletion did not extend as far as cysC, as PBL503 remainedprototrophic. The rpoS deletion is designated $Delta$ mutS-rpoS458.

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TABLE 1. Strains, plasmids, and phages used in this study

RpoH suppressors of the $Delta$ dnaK52 mutation were isolated as described previously (6). Three independent and spontaneous isolateswere mapped by phage P1 transduction and shown to be 50% linkedto zhh-21::Tn10. Complementation analysis with the rpoH expressionplasmid, pDS2 (18), was used to verify that the mutations werein rpoH. pDS2 restored both the filamentous cell morphology andthe reduced viability in all three isolates, characteristic ofDnaK deficiency during growth in LB medium (6). To evaluatethe starvation-related phenotypes of these rpoH suppressors inotherwise wild-type backgrounds, the $Delta$ dnaK52 mutation in rpoHsuppressor 1 was removed by phage P1 cotransduction with the linkedinsertion, thr-34::Tn10, generating PBL713, and complemented bytransformation with plasmid pBN15 (pP_tac::dnaK⁺J⁺ lacI⁺ bla⁺), generating PBL711.

Cell densities of cultures were monitored spectrophotometrically at a wavelength of 600 nm. All cultures were incubated at30°C in M9 minimal medium (42) containing 0.05% (wt/vol) glucoseand shaken at 150 rpm with 1-liter Erlenmeyer flasks in shakingwater baths (model G76; New Brunswick). dnaK mutants have beenreported to accrue spontaneous mutations during prolonged incubationon a solid medium (6). Care therefore was taken to avoid suchevents during studies of the unsuppressed dnaK mutant throughthe use of freshly streaked plates. LB plates were used to determineviable cell counts as described previously (52). Chloramphenicoland tetracycline were added at final concentrations of 25 µg/ml,kanamycin was added at 75 µg/ml, and ampicillin and streptomycinwere added at 100 µg/ml. All cultures were maintained in exponential-phasegrowth by repeated subculturing for a minimum of 10 generationsprior to collection of the first exponential-phase sample.

Salt tolerance measurements were performed after 1 day of glucose starvation by adding dry sodium chloride powder, with stirringto a final concentration of 2.5 M. The cultures were then maintainedwith gentle agitation at 30°C for the duration of the experiment.The number of viable cells per milliliter was determined by platingdiluted culture samples onto LB plates in duplicate.

Dps protein purification and antibody production. A 1-liter culture of strain PBL505, incubated for 5 days at 37°C with shaking in LB medium containing chloramphenicol, wascentrifuged for 10 min at 6,000 rpm at 4°C. The remainder of thepurification was performed as previously described (1). Briefly,the cell pellet was lysed by passage through a French pressurecell, and the resulting lysate was clarified by ultracentrifugationand fractionated by ammonium sulfate precipitation. The samplewas applied to a Sephadex G-200 column, and Dps was recoveredin the void volume. The protein was precipitated again with ammoniumsulfate and resuspended in a high-salt buffer. The sample wasthen applied to a Sepharose 6B column, and Dps-containing fractionswere recovered and applied to a DNA-cellulose column. Dps waseluted from the column with a linear sodium chloride gradientin which Dps eluted at 200 mM sodium chloride. Purity of the Dpsfractions was determined by Coomassie blue R-250 staining.

Anti-Dps polyclonal antibodies were produced by injection of 100 µg of the purified Dps protein into a New Zealand White rabbit,followed by booster shots of equivalent amounts of antigen attwo 2-week intervals. Serum was collected after an additional2 weeks and purified by precipitation with acetone powders asdescribed previously (2) with wild-type exponential-phase cellextracts. Antibodies were purified by affinity chromatographywith protein A-Sepharose as described previously (28).

Catalase assays. The catalase assays were performed by placing 1 ml of cell culture into a prewarmed (30°C), stirred oxygen electrode (RankBrothers). The cell culture was equilibrated at 30°C for 1 minprior to the addition of hydrogen peroxide to a final concentrationof 100 mM. A computer was attached to the oxygen electrode fordata collection, and sample readings were made at a rate of threetimes per second. Oxygen production was measured for a minimumof one min, and the amount produced was calculated as describedpreviously (14). Differential rates of enzyme synthesis weredetermined as described previously (50, 55). Variation incatalase activity between replicates was less than 4%.

In vivo labeling of proteins and immunoprecipitation. GroEL heat shock induction ratios were determined as described previously (8). To determine the half-life of RpoS at theonset of starvation, cells were grown in M9 medium containing0.05% glucose. After reaching the onset of starvation, the culturewas labeled with ³⁵S-Translabel (1,000 Ci/mmol; ICN) at 20 µCi of culture per mlfor 1 min at 30°C. The sample was chased with 10 mM (each) nonradioactivemethionine and cysteine for 20 s at 30°C. Samples consisting of3.0 × 10⁹ cells were then removed, and protein was precipitated by theaddition of ice-cold 50% (wt/vol) trichloroacetic acid (TCA) andkept on ice for 30 min. The precipitated protein was removed bycentrifugation at 13,000 × g for 10 min, and the pellet was washedsuccessively with ice-cold solutions of 10% (wt/vol) TCA, 5% (wt/vol)TCA, and 100% acetone. The samples were then dried and resuspendedin 0.5 ml of PBS-D (20 mM sodium phosphate, 150 mM sodium chloride[pH 7.4], 1% [vol/vol] Triton X-100, 1% [wt/vol] sodium deoxycholate,and 0.1% [wt/vol] sodium dodecyl sulfate [SDS]). Insoluble proteinwas removed by centrifugation at 13,000 × g for 10 min. RpoS wasimmunoprecipitated by the addition of 25 µl of anti-RpoS monoclonalantibody ascitic fluid (1RS1) (47), and the samples were incubatedfor 2 h at 4°C, with gentle agitation. The antigen-antibody complexwas removed by the addition of protein A-Sepharose 4B (Sigma)with 350 µg of protein A per reaction and incubated for 3 h at4°C with gentle agitation. Samples were then centrifuged at 13,000× g for 10 min, and the pellet was washed three times in PBS-D.The washed pellets were resuspended in 33 µl in a solution containing250 mM Tris-HCl (pH 6.8), 2% SDS, 0.75 M 2-mercaptoethanol, 10%glycerol and boiled for 10 min, and 3.3 µl was removed to determineradioactivity. Bromphenol blue was added to the remaining sampleto a final concentration of 20 µg/ml prior to analysis by SDS-polyacrylamidegel electrophoresis (PAGE). Proteins were detected by autoradiographywith Kodak XAR film.

SDS-PAGE and Western blot analysis. To quantitate total RpoS levels by Western blot analysis, cells from cultures grown at 30°C were concentrated by centrifugationat 13,000 × g, and the resulting cell pellets were resuspendedin 25 mM Tris-HCl-40 mM glycine (pH 6.8). Samples were removedto determine protein concentrations by the bicinchoninic acidprotein assay (Pierce). The remaining sample was adjusted to 250mM Tris-HCl (pH 6.8), 2% SDS, 0.75 M 2-mercaptoethanol, 10% glycerol,20 µg of bromphenol blue per ml, boiled for 10 min, and frozenat $-$ 20°C for later use.

Proteins were resolved by SDS-PAGE, with 9% (wt/vol) acrylamide separating gels and 10% (wt/vol) acrylamide stacking gels,as described previously (15), with prestained low-molecular-weightmarkers (Bio-Rad). Western blots were prepared essentially asdescribed previously (15). Western blots were processed anddeveloped with the ECL reagent system according to the manufacturer'sprotocol (Amersham). Western blots were probed with a 1:1,000dilution of the anti-RpoS antibody 1RS1 (47) and then a 1:1,000dilution of sheep anti-mouse horseradish peroxidase conjugate(GibcoBRL). As a reference to normalize development of all Westernblots for RpoS content, 111 ng of protein of strain PBL504 following2 h of starvation was included as an internal standard. RpoS signalintensity was linear within the range of detection as determinedby regression analysis of PBL504 extracts (r² = 0.99) analyzed in amounts of 0.111, 0.333, 1.0, 3.0, and 9.0µg of protein. Chemiluminescence was detected by exposing KodakXAR film. Exposed films were analyzed by densitometry with a GDS7500densitometer and gel base/gel blot software (Ultraviolet Products).

Detection of Dps by Western blot analysis was performed as described above with the following two exceptions; proteins wereresolved by SDS-PAGE, 14.5% (wt/vol) acrylamide separating gelsand 10% (wt/vol) acrylamide stacking gels, and purified Dps wasincluded in all blots as an internal standard for normalizationof results. Detection of DnaK by Western blot analysis was performedas described previously (2).

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Growth of the dnaK mutant. Strains containing the $Delta$ dnaK52 mutation can be readily cultured at 30°C. However, even at this reduced temperature, this straincontinues to exhibit a reduced growth rate and a filamentous morphologyin exponential phase (6, 7). To minimize the possible contributionof growth-related dnaK mutant defects on the starvation response,additional growth conditions which overcame these phenotypes wereidentified. We have demonstrated previously that the filamentousphenotype is suppressed during growth in a defined medium (52).In addition, more-gentle culture agitation overcame the defectin growth rate. Excessive agitation of the cultures (240 rpm)decreased the specific growth rate (k = 0.28) and final cell densities(1.5 × 10⁸ CFU/ml) of the dnaK mutant cells relative to those of an otherwiseisogenic wild-type strain. Consequently, the results presentedhere utilized the slower agitation rate of 150 rpm. At this rateof agitation, all strains examined had identical specific growthrates (k = 0.693) and cell densities (3.0 × 10⁸ CFU/ml) at the onset of starvation. Stationary phase was elicitedby depletion of growth-limiting levels of glucose. Twenty-fourhours after the onset of starvation, the variation in cell numbersbetween the wild type and the mutant strains was less than 15%.

Starvation-induced catalase activity in dnaK and rpoS mutant strains. Levels of catalase increase in the stationary phase and result from elevated expression of katE (46). Catalase was thereforeexamined as an additional indicator of the cellular response tostarvation in the dnaK mutant strain. Catalase-specific activitywas similar among the four strains during growth (Fig. 1A, arrows1 through 6). Differential rates of catalase synthesis producedduring exponential phase were 9.4 nanoatoms of O/min/µg of proteinfor the wild-type strain, 8.8 for the dnaK mutant strain, 8.8for the rpoS mutant strain, and 9.4 for the complemented dnaKmutant strain. In stationary phase, the wild-type and complementeddnaK mutant strains exhibited increased levels of catalase activityreaching 35 nanoatoms of O/min/µg of protein (Fig. 1A). However,the catalase activity of the dnaK and rpoS mutants did not increasein response to starvation and instead remained at prestarvationlevels. By 4 h after the onset of starvation, the wild-type strainhad 3.5-fold more catalase activity than the rpoS or dnaK mutantstrains. The increased catalase activity in these strains remainedevident even after 24 h in stationary phase.

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FIG. 1. Catalase activity, salt tolerance, and Dps/PexB levels during growth and starvation in wild-type and dnaK mutant strains. (A) Catalase activity of exponential-phase and glucose-starved cells. The strains are PBL500 (wild type; circles), PBL501 ( $Delta$ dnaK52; squares), PBL504 ( $Delta$ dnaK52/pP_tac::dnaK⁺J⁺; triangles), and PBL503 ( $Delta$ mutS-rpoS458; inverted triangles). Cell densities were as follows: 0.1 (arrow 1), 0.15 (arrow 2), 0.2 (arrow 3), 0.25 (arrow 4), 0.4 (arrow 5), 0.6 starvation onset (arrow 6), 2 h after onset (arrow 7), 4 h after onset (arrow 8), and 24 h after onset (arrow 9). The onset of starvation is indicated (closed arrow). The values shown are the averages of three replicates. (B) Salt tolerance in glucose-starved cells. Cultures were examined following 24 h of carbon starvation for resistance to killing by exposure to 2.5 M sodium chloride for the times indicated. The strains are indicated as for panel A. (C) Levels of Dps/PexB. The strains used were PBL500 (wild type) (a), PBL501 ( $Delta$ dnaK52) (b), and PBL504 ( $Delta$ dnaK52/pP_tac::dnaK⁺J⁺) (c). Western blots were probed with anti-Dps polyclonal antisera. Lanes: 1 and 2, exponential growth (A, arrows 1 and 4); 3, onset of starvation (arrow 6); 4, 2 h after starvation onset (arrow 7); 5, 4 h after onset (arrow 8); 6, 24 h after onset (arrow 9); and 7, purified Dps protein standard.

Starvation responses of dnaK and rpoS mutant strains to sodium chloride exposure. dnaK mutants are sensitive to sodium chloride exposure in exponential phase (41), while rpoS mutants are sensitive to thisstress in the stationary phase (38). However, the response ofthe dnaK mutant to this challenge in the stationary phase wasunknown. To examine this question, the wild type, the otherwiseisogenic dnaK mutant, the rpoS mutant, and the complemented dnaKmutant were subjected to 24 h of starvation and then exposed to2.5 M sodium chloride. The cultures were then incubated further,with continued starvation, and periodically sampled to determinethe number of viable cells (Fig. 1B). The wild-type and complementeddnaK mutant strains retained greater than 50% viability over a24-h period. However, the viability of the dnaK and rpoS mutantstrains decreased to less than 0.01% of untreated controls atnearly identical rates of 4.2%/h. These results indicate thatDnaK is required for starvation-induced osmotolerance.

Levels of the rpoS-dependent protein, Dps, in starving dnaK mutants. The results of the sodium chloride tolerance and catalase activity experiments suggested that there may be a more direct linkbetween DnaK and RpoS in starving cells. To explore this possibilityfurther, expression of an RpoS-dependent gene was examined. Thedps gene (1, 31) encodes a 19-kDa DNA binding protein whoseinduction in stationary phase requires rpoS. Cell extracts derivedfrom wild-type, dnaK mutant, and dnaK-complemented cultures inthe exponential phase, at the onset of starvation, and at timesthereafter were examined for levels of the Dps protein with anti-Dpspolyclonal antibodies (Fig. 1C). Dps was readily detected after2 h following the onset of starvation in the wild-type strain(Fig. 1C, blot a, lane 4) and in the complemented dnaK mutant(Fig. 1C, blot c, lane 4) and increased to maximal levels by 24h (lane 6). However, Dps was undetectable in the dnaK mutant even24 h after the onset of starvation (Fig. 1C, blot b, lane 6).

Accumulation of RpoS in a dnaK mutant strain. One mechanism to explain the phenotypic overlap between dnaK and rpoS mutants is that DnaK deficiency results in a reductionin RpoS activity or concentration and therefore reduces RpoS-dependentgene expression. This possibility was examined by measuring levelsof RpoS in the wild-type strain (Fig. 2A), the dnaK mutant strain(Fig. 2B), and the complemented dnaK mutant strain (Fig. 2C) byWestern blot analysis with an RpoS-specific monoclonal antibody.Levels of RpoS during exponential phase in the dnaK mutant strain,when adjusted for total protein, were equal to the otherwise isogenicwild-type strain. In response to starvation, RpoS levels increased10-fold in the wild-type strain, while in the dnaK mutant strain,rpoS levels increased slightly but overall remained at a lowerlevel. At the onset of starvation in the dnaK mutant strain, RpoSlevels were 3.5-fold lower than the levels in the wild-type strain(Fig. 2D). Interestingly, in the complemented dnaK mutant strain,RpoS levels were nearly twofold higher than those in the wild-typestrain (Fig. 2D). This last result is consistent with an increasein levels of DnaK which occurs in that strain in stationary phase,resulting from elevated expression from the plasmid-encoded P_tacpromoter (2). Western blot analysis indicated that at the timeof the maximal increase in RpoS abundance, DnaK levels were fourfoldgreater than in the wild-type strain (data not shown). Twenty-fourhours after the onset of starvation, the level of RpoS in thewild-type and the complemented dnaK mutant strains decreased by33 and 50%, respectively; however, no change in RpoS levels wasobserved in the dnaK mutant strain.

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FIG. 2. Accumulation of RpoS in exponential- and stationary-phase wild-type and dnaK mutant cells. Western blots of total cell extracts of PBL500 (wild type) (A), PBL501 ( $Delta$ dnaK52) (B), and PBL504 ( $Delta$ dnaK52/pP_tac::dnaK⁺J⁺) (C) probed with anti-RpoS monoclonal antisera. Lanes: 1 to 5, exponential phase (Fig. 1A, arrows 1 through 5); 6, onset of starvation; 7, 2 h after onset; 8, 4 h after onset; 9, 24 h after onset; 10, PBL503 ( $Delta$ mutS-rpoS458) 2 h after onset. (D) Densitometric analysis of the bands shown in panels A through C. Symbols: circles, PBL500; squares, PBL501; triangles, PBL504. Five micrograms of protein was loaded per lane. Blots were developed to achieve equivalent band intensity of a constant amount of an RpoS-containing extract (PBL504, lanes not shown). Signal intensity was linear within the range of detection as determined by regression analysis of PBL504 extracts (r² = 0.99). The onset of glucose starvation is indicated by the arrow.

The exponential-phase RpoS levels observed in the dnaK mutant were not elevated relative to those of the otherwise isogenicwild-type strain, in contrast to a previous report (44). Inaddition, the reduction in starvation-induced RpoS levels reportedhere was significantly more pronounced (threefold versus 40%)than reported previously. To resolve these differences, the consequenceof more-rapid culture agitation on RpoS levels in the dnaK mutantwas examined (Fig. 3). Duplicate cultures of the wild type (PBL500)and the dnaK mutant (PBL501) were sampled periodically for RpoSdetermination, and then one of each of the duplicate cultureswas shifted to a more rapid rate of agitation. RpoS levels increasedrapidly upon the shift in the dnaK mutant but not in the wild-typestrain, indicating that this condition imposes some sort of RpoS-inducingstress. This result is consistent with the reduction in growthexhibited by the dnaK mutant and likely explains why RpoS levelswere highly induced in a dnaK mutant strain in a previous study(44).

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FIG. 3. Induction of RpoS levels by increased culture agitation in a dnaK mutant. (A) Western blot of samples. Odd-numbered lanes, PBL500 (wild type); even-numbered lanes, PBL501 ( $Delta$ dnaK52). In lanes 1, 2, 5, 6, 9, 10, 13, 14, 17, and 18, cultures were only agitated slowly. In lanes 3, 4, 7, 8, 11, 12, 15, 16, 19, and 20, cultures were agitated slowly and then rapidly. Cell densities at an optical density at 600 nm were 0.1 (lanes 1 through 4), 0.2 (lanes 5 through 8), 0.3 (lanes 9 through 12), 0.4 (lanes 13 through 16), and 2 h after the onset of starvation (lanes 17 through 20). (B) Levels of RpoS determined from the data shown in panel A. Values are normalized to the levels in the wild-type strain at early exponential phase (optical density at 600 nm [OD_A600 = 0.1). Open bars, wild type, slow agitation; closed bars, $Delta$ dnaK52, slow agitation; stippled bars, wild type, shifted agitation; hatched bars, $Delta$ dnaK52, shifted agitation.

Role of RpoS in levels of the DnaK protein. Since RpoS affects the synthesis of many proteins, levels of DnaK were examined in an rpoS mutant to better define the epistaticrelationship between these genes. DnaK levels were examined inthe wild-type strain and in the rpoS mutant during exponentialgrowth and in response to starvation. Western blot analysis withthe anti-DnaK monoclonal antibody 2G5 (28) indicated that thelevels of DnaK were not significantly affected by RpoS deficiencyeither during growth or in response to carbon starvation (datanot shown). A starvation-induced, twofold increase in DnaK levelswas evident in both strains in comparisons between levels producedduring exponential growth and those produced 24 h after the onsetof glucose starvation.

RpoS stability in a dnaK mutant strain. Reduced RpoS accumulation in the starving dnaK mutant strain could reflect defects in either RpoS stability and/or synthesis.To look for DnaK-dependent changes in RpoS protein turnover, thehalf-life of RpoS was determined. The onset of starvation wasselected for analysis because a large difference in RpoS levelswas evident in comparisons between the wild type and the dnaKmutant (Fig. 2D). At the onset of starvation, cultures were transientlyradiolabeled and RpoS was recovered by immunoprecipitation atspecific times thereafter. The immunoprecipitates were analyzedby SDS-PAGE, and the resulting autoradiograms (Fig. 4A) were quantitated(Fig. 4B). In the wild-type strain (Fig. 4A, lanes 1 through 4),RpoS remained fully stable for the duration of the experiment(30 min), while in the dnaK mutant, the half-life of RpoS wasapproximately 20 min (Fig. 4A, lanes 5 through 8). No proteinwas detectable when identical procedures were performed on therpoS deletion mutant PBL503 (Fig. 4A, lane 9). These results indicatethat DnaK deficiency reduces starvation-induced accumulation ofRpoS by enhancing RpoS turnover.

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FIG. 4. RpoS stability at the onset of starvation in wild-type and dnaK mutant cells. (A) Autoradiograms of RpoS immunoprecipitates. Lanes: 1 through 4, PBL500 (wild type); 5 through 8, PBL501 ( $Delta$ dnaK52); 9, PBL503 ( $Delta$ mutS-rpoS458). Lanes and the duration of the methionine chase, respectively, were as follows: 1, 5 and 9, 0 min; 2 and 6, 10 min; 3 and 7, 20 min; and 4 and 8, 30 min. (B) Densitometric analysis of the bands shown in panel A. Symbols: circles, PBL500 (wild type); squares, PBL501 ( $Delta$ dnaK52). Values given are relative to time 0.

RpoH ( $sigma$ ³²) suppressors restore a subset of starvation-induced responses. To better understand the relationship between DnaK and RpoS in regulation of the starvation response to carbon deprivation,dnaK mutant suppressors which had restored wild-type levels ofRpoS were isolated (Fig. 5A). An internal control consisting ofextracts of PBL504 obtained following 2 h of glucose starvationwas included in each blot to normalize absolute amounts of RpoS.The rpoH suppressor mutants were recovered as papillae after prolongedincubation on solid medium (6, 8). The use of such strainscircumvents RpoS effects on the starvation response, which mightotherwise obscure the role of DnaK. Several such mutants wereisolated in the $Delta$ dnaK52 PBL501 background and are designated rpoHsuppressors $---$ 1, 2, or 3. They were mapped by phage P1 cotransductionwith linked transposon insertions. To verify their identity further,plasmid pDS2 (18), encoding a P_tac::rpoH gene, wasused to complement the suppressor isolates. Such suppressors exhibita defective heat shock response and can be categorized by theseverity of this defect (8). Only those alleles which exhibitno heat shock response at all fail to grow at 43.5°C on solidmedium (8). Additional Western blot analysis of these threerpoH suppressor alleles with anti-Dps polyclonal antibodies revealedthat levels of Dps were restored to wild-type levels in the dnaKmutant strains containing the rpoH suppressors (Fig. 5B). Starvation-inducedlevels of catalase production were also restored to wild-typelevels in the three suppressor isolates (data not shown). As therestoration of RpoS levels and rpoS-regulated gene expressionin the dnaK mutant strain by the rpoH-1 to rpoH-3 suppressorswas in apparent contradiction to a previous report (44), thepossible allelic difference between these suppressor mutationswas examined. The rpoH-1 mutation was selected as a representativeand analyzed for heat shock protein induction during heat shockand for growth at elevated temperature (Table 2). The rpoH-1mutant fails to induce GroEL synthesis following a temperatureshift from 30 to 42°C or to form colonies at 43.5°C. It is thereforea stronger suppressor of the dnaK mutation than the allele (sidB1)used previously (8, 44). Taken together, the results presentedhere and those previously described (44) support the idea thatat least some of the effects of the dnaK mutation on starvation-relatedprocesses are the result of effects on RpoS mediated by otherheat shock proteins. In addition, an rpoS dnaK double mutant starvedfor 24 h exhibited sensitivity to sodium chloride treatment equivalentto that of mutants containing single mutations in either genealone, suggesting that the role of dnaK in starvation-inducedosmotolerance is mediated entirely through RpoS.

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FIG. 5. Western blot analysis of levels of RpoS and Dps during growth and starvation in wild-type, dnaK, rpoS, and rpoH suppressor strains. (A) Levels of RpoS. Western blot of cell extracts during growth (a) and 24 h after the onset of glucose starvation (b). Blots were probed with anti-RpoS monoclonal antibody. Lanes: 1, PBL500 (wild type); 2, PBL501 ( $Delta$ dnaK52); 3, PBL503 ( $Delta$ mutS-rpoS458); 4, PBL622 ( $Delta$ dnaK52 rpoH-1); 5, PBL623 ( $Delta$ dnaK52 rpoH-2); 6, PBL624 ( $Delta$ dnaK52 rpoH-3); 7, PBL504 ( $Delta$ dnaK52/pP_tac::dnaK⁺ J⁺) cell extracts from 2 h after the onset of starvation in both panels. (B) Levels of Dps. Western blot of cell extracts during growth (a) and after 24 h of glucose starvation (b). Blots were probed with anti-Dps polyclonal antibodies. Lanes are as indicated for panel A, except that lane 7 contains purified Dps protein standard.

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TABLE 2. Characterization of the rpoH-1 mutant allele

An independent role for DnaK in starvation thermotolerance. Examination of the thermotolerance of these strains indicates that DnaK and RpoS play important but distinct roles in starvation-inducedresistance to heating. Elimination of either dnaK or rpoS in strainswhich are otherwise isogenic results in severe thermal killingof glucose-starved cells (Fig. 6, open squares and triangles).Wild-type cells, however, exhibited only slight reductions inviable counts for the duration of the 45-min treatment (Fig. 6,open circles). Interestingly, MC4100 (44) is 15-fold more sensitiveto heat killing than the wild-type strain (PBL500) used in thepresent studies (data not shown). All three of the rpoH dnaK mutantsuppressor strains exhibited only partial restoration of thermotolerancerelative to that of their unsuppressed but otherwise isogenicdnaK mutant parent (Fig. 6, open inverted triangles, hexagons,and diamonds). Thus, these strains remained highly thermosensitiveupon starvation for glucose. To test the possibility that continuedthermosensitivity results directly from the rpoH mutation, therpoH mutation in rpoH suppressor 1 was evaluated in a dnaK⁺ background. Two strain derivatives were constructed, PBL713,in which a wild-type allele of dnaK was introduced by transduction,and PBL711, which contained a plasmid-encoded wild-type dnaK allele.Examination of the starvation-induced thermosensitivity of thesestrains (Fig. 6, closed circles and closed squares) indicatedthat the rpoH mutation did not result in thermosensitivity followingglucose starvation. Since RpoS levels are restored in the originalrpoH suppressor strains, and expression of RpoS-dependent pathwayssuch as Dps and catalase synthesis is normal, continued thermosensitivityof the rpoH dnaK double mutants indicates that DnaK is directlyrequired for starvation thermotolerance. If two distinct pathwaysfor starvation thermotolerance are present, one dependent uponRpoS and the other on DnaK, then a dnaK rpoS double mutant shouldexhibit greater heat killing than either single-mutant strainalone. Analysis of the thermotolerance of such a strain (Fig.6, closed triangles) indicated that loss of both genes resultedin significantly greater killing than that observed in the absenceof either gene alone. These results indicate that DnaK plays adistinct and RpoS-independent role in starvation thermotolerance.

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FIG. 6. Thermotolerance of glucose-starved wild-type, dnaK, rpoS, and rpoH suppressor strains. Cultures were examined following 24 h of starvation for resistance to killing by exposure to 51°C for the times indicated. The strains were as follows: PBL500 (wild type; open circles), PBL501 ( $Delta$ dnaK52; open triangles), PBL503 ( $Delta$ mutS-rpoS458; open squares), PBL603 ( $Delta$ dnaK52 rpoS13::Tn10; closed triangles), PBL622 ( $Delta$ dnaK52 rpoH-1; open diamonds), PBL623 ( $Delta$ dnaK52 rpoH-2; open hexagons), PBL624 ( $Delta$ dnaK52 rpoH-3; open inverted triangles), PBL713 (dnaK⁺ transductant of PBL622; closed circles), and PBL711 (PBL622/pP_tac::dnaK⁺J⁺; closed inverted triangles).

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The studies reported here focus on the role of DnaK in a stationary phase produced by starvation for carbon. Care was takento minimize high cell densities in batch cultures through theuse of minimal quantities of the limiting nutrient, glucose. Suchmeasures represent an effort to mimic the physiological stateconfronted by bacteria in natural environments where high celldensity conditions are generally thought less likely (43).

The dnaK mutant phenotypes observed in stationary phase result at least in part from a deficiency in the sigma factor RpoS.The reduction in stationary-phase RpoS levels (about threefold)is sufficient to preclude expression of the rpoS-dependent gene,dps (pexB), and therefore possibly other rpoS-dependent genes,such as those involved in mediating resistance to hydrogen peroxide,heat, and sodium chloride excess. This change in RpoS abundanceparallels that seen during heat stress administered to growingcells, which is sufficient for changes in RpoS-dependent geneexpression (26). A 10-fold increase in RpoS levels over thoseobserved in exponentially growing cells was detected followingthe onset of starvation in the wild-type strain, PBL500, at 30°C.This is an increase of approximately twofold over those seen previouslyat 37°C (29, 56) and is consistent with other reports indicatingthat stationary-phase expression of rpoS is elevated at reducedcultivation temperatures (58). Thus, the pleiotropic spectrumof effects resulting from RpoS deficiency in the dnaK mutant strainoffers some explanation for the apparent phenotypic overlap betweendnaK and rpoS mutants.

The RpoS-related effects which result from DnaK deficiency are stationary phase specific. RpoS levels appear otherwise normalduring exponential-phase growth under the conditions used. Growthconditions were employed to minimize certain dnaK mutant phenotypes.It has been reported that the $Delta$ dnaK52 mutation results in a reducedgrowth rate (k = 0.28) compared to that of the wild type (k =0.69) at 30°C (6). We also observed this phenomenon when the $Delta$ dnaK52 mutant was agitated at 200 rpm or greater. In addition,RpoS levels are highly induced by this treatment (44), obscuringsubsequent effects resulting from starvation. However, at agitationrates of 150 rpm or less, growth rates were equal to the otherwiseisogenic wild-type strain. Growth at 30°C also was employed toavoid the dnaK mutant heat-sensitive growth phenotype (49).

Protein half-life measurements indicated that in the dnaK mutant, RpoS stability was reduced. These results suggest that DnaKsomehow stabilizes RpoS in response to carbon starvation. Interestingly,overproduction of DnaK resulting from starvation-mediated derepressionof a plasmid-encoded dnaK gene elevated stationary-phase RpoSlevels nearly twofold above those in otherwise isogenic wild-typecells. Thus, variation in DnaK abundance results in correspondingchanges in the stationary-phase levels of RpoS. Though such changesin RpoS levels were elicited by artificial manipulation of dnaKexpression, DnaK levels do increase severalfold in wild-type cellsupon carbon starvation as shown here and previously (52). Thus,DnaK may play a crucial role in adjusting stationary-phase RpoSlevels in response to carbon starvation.

Overproduction of DnaK is selectively toxic in stationary-phase cells (2). This bactericidal effect was used as the basisof a selection to recover multicopy plasmid suppressors to betterunderstand the toxicity of chaperone excess (53). Identificationof these suppressors, such as 6-phosphogluconate dehydratase,may now be explained in part by the observations presented here.Activity of 6-phosphogluconate dehydratase is elevated in thestationary phase (32), while the next enzyme in this pathway,2-keto-3-deoxy-6-phosphogluconate aldolase, is also increasedin stationary phase (48). Perhaps elevated levels of 6-phosphogluconatedehydratase overcome deleterious levels of other enzymes precipitatedby DnaK-mediated increases in RpoS by redirecting carbon fluxthrough alternative routes in this pathway.

The results presented here indicate that DnaK controls the levels of the RpoS sigma factor. Since DnaK also controls the levelsof the RpoH sigma factor (11), these results indicate that DnaKmay coordinate the levels of multiple sigma factors in E. coli.A mechanism for such coordination mediated by a single proteinhas until now been lacking. However, it would seem critical forthe maintenance of balanced gene expression during changing environmentalconditions, such as those accompanying starvation.

It is at present unclear how DnaK might affect RpoS stability, though direct and/or indirect mechanisms may be operative.Deficiency of the heat shock protease, ClpX/P, elevates RpoS levels3.2-fold during exponential-phase growth and 1.7- fold in responseto starvation (56). Since starvation increases ClpX/P by 1.5-fold(56), inactivation or blockage of ClpX/P may be required forthe starvation-induced increase in RpoS abundance. The epistaticrelationship between ClpX/P and RssB further indicates a directrole for ClpX/P in RpoS abundance (51). Thus, the role of DnaKin RpoS stability might be mediated indirectly by altering levelsof ClpX/P or RssB. Alternatively, as a direct interaction betweenDnaK and the heat shock sigma factor RpoH has been reported (40),physical contact between DnaK and RpoS also appears plausible.

RpoH levels are elevated in dnaK mutant strains (60); therefore, compensatory mutations which reduce but do not destroyRpoH activity are selected during prolonged storage on plates(6-8). Such rpoH mutant strains were isolated and studied hereto probe the relationship between DnaK and RpoS. These rpoH dnaKdouble-mutant strains exhibit normal levels of RpoS, suggestingthat the effect of the dnaK mutation on RpoS abundance is RpoHlinked, perhaps through ClpX/P. Restoration of RpoS levels wasaccompanied by recovery of catalase and induction of Dps starvation,suggesting that at least these two starvation responses operatein an RpoS-dependent fashion. DnaK apparently indirectly alterstheir expression by varying levels of RpoS. Starvation-inducedthermotolerance was, however, still defective in the rpoH dnaKmutant strains but normal in dnaK⁺ rpoH derivatives. This result suggests that DnaK plays a distinctand RpoS-independent role in starvation-induced thermotolerance.However, the relative contributions of the two proteins to theresponse appear quite unequal, suggesting that their actions duringthe development of the thermotolerant state are mechanisticallyunrelated.

	ACKNOWLEDGMENTS

We thank Carol Gross, Abdul Matin, and Graham Walker for providing strains.

This work was supported by a grant from the Department of Energy to P.B. (DE-FG02-93ER61701).

	FOOTNOTES

^* Corresponding author. Mailing address: School of Biological Sciences, E234, George Beadle Center, University of Nebraska,Lincoln, NE 68588-0666. Phone: (402) 472-2769. Fax: (402) 472-8722.E-mail: pblum{at}crcvms.unl.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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Echave, P., Esparza-Ceron, M. A., Cabiscol, E., Tamarit, J., Ros, J., Membrillo-Hernandez, J., Lin, E. C. C. (2002). DnaK dependence of mutant ethanol oxidoreductases evolved for aerobic function and protective role of the chaperone against protein oxidative damage in Escherichia coli. Proc. Natl. Acad. Sci. USA 99: 4626-4631 [Abstract] [Full Text]

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