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ClpE from Lactococcus lactis Promotes Repression of CtsR-Dependent Gene Expression

Department of Dairy and Food Science, The Royal Veterinary and Agricultural University, DK-1958 Frederiksberg C,¹ BioCentrum-DTU, Technical University of Denmark, DK-2800 Lyngby,³ Department of Veterinary Microbiology, The Royal Veterinary and Agricultural University, DK-1870 Frederiksberg C, Denmark,⁴ Faculty of Veterinary Medicine, Department of Basic Veterinary Sciences, University of Helsinki, Finland²

Received 11 March 2003/ Accepted 6 June 2003

	ABSTRACT

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

	INTRODUCTION

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ClpC and ClpE belong to the highly conserved HSP100/Clp family of ATPases that are widely distributed in prokaryotic and eukaryotic cells. These proteins have been implicated in a variety of biological processes either as parts of proteolytic complexes that also include the ClpP protease or as molecular chaperones (reviewed in reference 41). Members of the ClpC subfamily are found in gram-positive bacteria and plants, and they have been shown to be important for controlling growth at high temperatures, sporulation, competence, and virulence (31, 34, 35, 38, 39, 47). The ClpE subfamily is characterized by the presence of an amino-terminal zinc-binding motif, and so far alleles have been identified only in gram-positive bacteria (11, 19, 32). The typical feature of the ClpE (11, 19, 32) and ClpX (50) subfamily proteins is an N-terminal zinc-binding domain, a so-called zinc finger, whose presence in certain proteins was first noted by Miller and coworkers (28). While the function of this domain in ClpE is unknown, such motifs are often involved in DNA binding and protein-protein interactions (5, 24, 25, 43). Inactivation of clpE alleles has generally had minor phenotypic effects (11, 19), although a Listeria monocytogenes clpE mutant had a higher growth rate at elevated temperatures and showed attenuated virulence (32).

Expression of the clp genes is regulated by the negative regulator CtsR. Homologues of CtsR have been identified in a number of gram-positive bacteria, and CtsR has been shown to bind to well-conserved DNA-binding sites present in the promoter regions of target genes (12, 22, 33). In the absence of stress expression of the CtsR regulon is repressed by CtsR binding; however, when cells are stressed, CtsR binding is released and expression is temporally induced. In the continued presence of stress the activity of CtsR is restored, and genes belonging to the CtsR regulon are re-repressed. This pattern of temporal derepression followed by repression has been observed in other stress regulatory systems. In Bacillus subtilis the heat shock regulator, HrcA, requires the GroE chaperonin for DNA binding (29). When stress is encountered, GroE is titrated by the accumulation of misfolded proteins, and HrcA is unable to bind DNA. As the concentration of chaperones is increased as part of the heat shock response, free GroE becomes available to promote binding of HrcA to DNA (30). In B. subtilis and L. monocytogenes it has been observed that expression of the CtsR regulon is derepressed in the absence of clpC (11, 12, 32), suggesting that ClpC could be a modulator of CtsR activity. In this study, we investigated the role of the ClpC and ClpE ATPases in controlling expression of the CtsR-regulated clpP gene in the gram-positive bacterium Lactococcus lactis, which is widely used in production of a variety of dairy products. Our results show that in L. lactis ClpE is involved in restoring the repressed state of clpP expression following a heat shock, and we propose that this effect is mediated through an interaction between CtsR and the zinc-binding motif in the N-terminal region of ClpE. To our knowledge, this is the first report of a role for this motif that is conserved in the ClpE subfamily of Clp ATPases.

	MATERIALS AND METHODS

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Bacterial strains, plasmids, and growth conditions. The strains and plasmids used in this study are listed in Table 1. L. lactis strains were grown in M17 (44) supplemented with 0.5% glucose (GM17 medium). Escherichia coli XL1-Blue (Stratagene) was grown in Luria-Bertani broth. When needed, tetracycline (8 µg/ml for E. coli and 2 µg/ml for L. lactis), erythromycin (200 µg/ml for E. coli and 2 µg/ml for L. lactis), or chloramphenicol (25 µg/ml for E. coli and 6 µg/ml for L. lactis) was added. For clpP'-gusA expression studies saturated overnight cultures of L. lactis strains grown at 30°C were diluted 1:1,000 in GM17 medium preheated at 30°C. Strains were grown in water baths at different temperatures, and growth was monitored by determining the optical density at 600 nm (OD₆₀₀). Cell samples (1.5 ml) were collected at appropriate intervals, and cell pellets were stored at -80°C until they were used for ß-glucuronidase (GusA) activity determinations.

Construction of chromosomal clpC and clpE deletion mutants. A replacement recombination technique was used to construct two recombinant strains of L. lactis MG1363 with deletions in the clpC or clpE gene. Gene replacement vectors were constructed by using plasmid pGh8 (26) with the thermosensitive pG⁺host origin of replication (6). For the clpC replacement vector, a 2.5-kb region from MG1363 chromosomal DNA was amplified by using primers p1 (5'-ATAAGATATCACTGACAGAACGTGAAG-3') and p2 (5'-ATTTGTCGACTTAATCTCACCCGAGAG-3'). The resulting fragment was digested with EcoRV and SalI, and this was followed by ligation with SmaI/SalI-digested pBluescriptII SK+ (Stratagene). A deletion was made in the 2.5-kb insert by removing a 1.2-kb internal EcoRI fragment. The resulting 1.3-kb insert was cloned as a BamHI-SalI fragment into the corresponding sites of pGh8 to obtain pHI1910, the final clpC replacement vector. The clpE deletion vector was made by amplifying two regions with primers p3 (5'-CATCTCTAGAGGCAGCAGTTGACCAACTC-3') and p4 (5'-GACCTGCAAAGCACTGAAGATATCG-3') and with primers p5 (5'-ATCCTGCAATGGGTGCAAG-3') and p6 (5'-TGATGTCGACTTATCATCTGGTTGGGAAC-3'). The resulting products were cut with XbaI/SspI and SspI/SalI, respectively, and ligated with XbaI/SalI-digested pG⁺host8. The resulting clpE deletion vector (pHI1909) carried 700-bp fragments in both sides of a 2-kb deletion. For integration of replacement vectors, the transformed, tetracycline-resistant L. lactis colonies were grown overnight at 37°C in GM17 broth containing 2 µg of tetracycline per ml and plated on GM17 agar containing 2 µg of tetracycline per ml, and this was followed by incubation overnight at 37°C. To allow excision of the integrated vectors from the chromosome, the integrants were grown overnight at 28°C and plated on GM17 agar plates containing tetracycline (2 µg/ml); this was followed by incubation at 28°C. The excised plasmid was cured by incubating the strains at 37°C in GM17 medium with no antibiotic. Tetracycline-sensitive colonies were tested by PCR for the presence of the wild-type gene or a gene carrying an internal deletion. The clone carrying a 1.2-kb deletion in clpC and the clone carrying a 2-kb deletion in clpE were designated L. lactis HI1924 and HI1931, respectively.

Construction of L. lactis strains with a chromosomal clpP'-gusA transcriptional fusion. To monitor expression of the clpP gene, a 330-bp DNA fragment that included the region from nucleotide -160 to nucleotide 170 with respect to the transcriptional start site of clpP transcription (14) was amplified by PCR by using primers p7 (5'-AACAGATCTAGAGGCCAAAAATCATCG C-3') and p8 (5'-ATATCTGCAGCACGTTCACCACGG-3'). The amplified product was cloned as an XbaI/PstI fragment into the corresponding site in promoter-reporter integration vector pLB85 (9) to obtain pPV33. The pPV33 plasmid was analyzed by sequencing prior to integration into the phage attachment site in L. lactis MG1363 (wild type) and its mutant derivatives PV1 (ctsR) (48), HI1931 (clpE) (this study), and HI1924 (clpC) (this study) to obtain L. lactis PV28, PV29, PV30, and PV31, respectively.

ß-Glucuronidase assays. GusA activity in L. lactis strains was qualitatively assayed on GM17 agar plates containing 0.5 mM 5-bromo-4-chloro-3-indolyl-ß-D-glucuronic acid (X-Gluc) (Biosynth AG, Staad, Switzerland). Fresh colonies were streaked on X-Gluc plates, and the GusA activity was determined visually by accumulation of a blue color after 24 h of incubation at 30 or 37°C.

For quantitative GusA assays cells were grown exponentially to an OD₆₀₀ of 0.3 to 0.4, and samples were harvested and frozen. For quantification cells were thawed on ice and disrupted with glass beads (diameter, 0.1 mm; Sigma) in a homogenizer (Fastprep FB 120; Savant) for 45 s. Disrupted cells were placed on ice and resuspended in 300 µl of ice-cold GusA buffer (34). Cell debris and glass beads were removed by centrifugation at 12,000 x g for 5 min at 4°C. Determination of GusA specific activity in the cell extracts was performed essentially as described previously (37) by using 4-nitrophenyl-ß-D-glucuronic acid (Biosynth AG) at a concentration of 1.5 mM in reaction buffer. The protein concentrations in cell extracts were determined as described by Bradford (8) by using the Bio-Rad protein assay with bovine serum albumin as the standard. Statistical comparisons were made by using Student's t test.

RNA methods. For total RNA isolation from L. lactis strains, the cells were grown exponentially at 25°C in GM17 medium to an OD₆₀₀ of 0.3 to 0.4, after which heat stress was applied by transferring the tubes to 38.5°C. Total RNA was isolated from cell samples incubated for 0, 5, 20, or 45 min at 38.5°C by using an RNeasy Mini kit (Qiagen) as described previously (48). RNA gel electrophoresis, blotting, and hybridization were performed as described previously (36, 48). The clpP- and dnaK-specific probes were obtained by PCR by using primers p9 (5'-CAAATTCTATCATTGCC-3') and p10 (5'-GAGCGATTAGAATTATCAGCAAGG-3') and primers p11 (5'-CTGCTGAAAGCTACCTTGGCG-3') and p12 (5'-CAGCTGGTTGATTATCAGCGG-3'), respectively. Probes were labeled with [-³²P]dATP (>3,000 Ci/mmol; Amersham Pharmacia Biotech). Following hybridization and washes the membranes were scanned and quantified by using a PhosphorImager (Storm system; Molecular Dynamics) and ImageQuaNT (version 4.2; Molecular Dynamics). The amounts of RNA on the membranes were corrected by probing the membranes with a probe specific for L. lactis 16S rRNA obtained by PCR performed with primers p13 (5'-TACGGYTACCTTTGTTACGACT-3') and p14 (5'-AGAGTTTGATCMTGGCTCAG-3').

Site-directed mutagenesis and complementation studies. To complement the chromosomal clpE deletion and to study the role of the putative zinc finger in ClpE, two pCI372 (17) vector-based recombinant plasmids, pPV50 and pPV52, were constructed. The 3.1-kb insert in pPV50 and pPV52 covers a chromosomal region from 700 nucleotides upstream of the ClpE translational start codon, including the putative promoter (19, 48), to 170 nucleotides downstream of the ClpE translation stop codon (19). The inserts of pPV50 and pPV52 were obtained by PCR by using primer p15 (5'-TCTCTAGAGCAGGCAGCAGTTG-3') binding upstream of the putative clpE promoter, as well as primers pzinc1 (5'-ACAGATCTATTTGTTTTTTCTGACCATTTAC-3'), pzinc2 (5'-AAATAGATCTGTGCCAAAACTGTTATCAAA-3'), pzinc3 (5'-AAATAGATCTGAGCCAAAACTGTTATCAAA-3'), and p16 (5'-TCTCGGTCGACTTGATGAGTGGATTGACGA-3'). Primers pzinc1 to pzinc3 bind to the putative zinc finger coding region of ClpE, pzinc1 is a minus-strand primer, and pzinc2 and pzinc3 are plus-strand primers. Primers pzinc1, pzinc2, and pzinc3 contain a new BglII restriction site (underlined) as a silent mutation. In addition, primer pzinc3 contains one nucleotide change (boldface type) compared to pzinc2, which results in to a change from a Cys codon (TGC) to a Ser codon (AGC). The 760- and 2,340-bp PCR products obtained with primers p15 and pzinc1 and with primers pzinc2 and p16, respectively, were digested with XbaI/BglII and BglII/SalI, respectively. The fragments were ligated to pCI372 digested with XbaI/SalI to obtain pPV50 encoding wild-type ClpE. Plasmid pPV52 that encodes ClpE with Ser at position 29 instead of Cys was obtained like pPV50, except that primer pzinc3 was used instead of pzinc2 in the PCR. The 3.1-kb inserts of pPV50 and pPV52 were sequenced, and no additional mutations were observed. The pPV50 and pPV52 plasmids were transformed into clpE strain L. lactis PV30, and expression of clpP'-gusA was measured with cells growing exponentially at 30 or 38.5°C. The effect of pPV50 on heat shock induction of clpP and dnaK was studied by performing a Northern blot analysis after transformation in L. lactis HI1931 (clpE).

ClpE purification, antibody production, and Western blot analysis. For purification of His₆-ClpE the clpE gene was amplified with primers p17 (5'-AAAGGATCCCTTTGTCAAAATTGTAATATTAATG-3') and p16 and cloned as a BamHI/SalI fragment into the pQE30 QIAexpress vector (Qiagen) to obtain pPV53. Recombinant N-terminal His-tagged ClpE was expressed and purified by standard procedures described by the manufacturer (Qiagen) and was used for antibody production in rabbits. For Western blot analysis cells were grown in GM17 medium at an elevated temperature (usually 38.5°C; the exception was the clpP mutant strain, which was grown at 37°C) until the OD₆₀₀ reached 0.4 to 0.5, and cell samples were harvested. Protein samples were separated by using the NuPAGE bis-Tris electrophoresis system (Invitrogen) and blotted onto nitrocellulose filters (pore size, 0.45 µm; Bio-Rad). Colorimetric detection of ClpE was carried out by using a rabbit polyclonal antibody (1:3,000) raised against His₆-ClpE as the primary antibody and an anti-rabbit immunoglobulin G-avidin-horseradish peroxidase conjugate (1:3,000) (Bio-Rad) as the secondary antibody. The colorimetric reaction for the filter was carried out according to the instructions provided by the manufacturer (Bio-Rad). Alternatively, a 1:40,000 dilution of the anti-ClpE antibody and a 1:50,000 dilution of the horseradish peroxidase-conjugated goat anti-rabbit immunoglobulin G (Bio-Rad) was used when the detection system based on chemiluminescence was used. Visualization of ClpE was performed with a SuperSignal West Dura extended duration kit used according to the instructions provided by the manufacturer (Pierce). Membranes were scanned with a GS-525 molecular imager system (Bio-Rad) and were analyzed with MultiAnalyst and QuantityOne software (Bio-Rad).

	RESULTS

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L. lactis ClpE affects expression of clpP at a high temperature. In L. lactis expression of clpP is negatively regulated by CtsR (48). To investigate if the Clp ATPases, ClpC and ClpE, play a role in controlling L. lactis clpP gene expression, we constructed a transcriptional fusion of the clpP promoter region to a reporter gene, gusA encoding ß-glucoronidase (20), and inserted it into the chromosomal attachment site (attB) of phage TP901-1 (10). When we introduced this fusion into wild-type cells (MG1363) and ctsR mutant cells (PV29), we found that at 30°C clpP gene expression was increased sixfold in the absence of CtsR, which confirmed the CtsR-dependent regulation of clpP expression (data not shown). When we subsequently introduced the fusion into PV31, from which the clpC gene had been deleted, measurements of GusA activity revealed that clpP expression was unaffected by the clpC mutation at both 30 and 38.5°C (data not shown). However, in cells carrying the clpP'-gusA fusion from which clpE was deleted (PV30), the calculated mean value for the GusA specific activity, 0.124 U/mg (standard deviation, 0.035 U/mg), was significantly (P < 0.0001, as determined by Student's t test) higher than the value measured for wild-type cells growing at 38.5°C, 0.050 U/mg (standard deviation, 0.020 U/mg) (Fig. 1). At 30°C clpP expression was unaffected by the clpE deletion (data not shown). These data suggest that ClpE represses clpP gene expression at an elevated temperature.

View larger version (16K): [in this window] [in a new window]   FIG. 1. Expression of clpP is increased in a clpE deletion strain at an elevated temperature. Growth and GusA activity expressed from the clpP'-gusA fusion in L. lactis strains PV28 (wild type) (circles) and PV30 (clpE) (squares) were monitored in cells growing exponentially at 38.5°C. Solid symbols indicate OD600, and open symbols indicate GusA specific activities. One unit of activity was defined as 1 µmol of substrate (X-Gluc) hydrolyzed per min. The error bars indicate the standard errors of the means for specific activities calculated from the cell samples.

View larger version (35K): [in this window] [in a new window]   FIG. 2. Northern analysis of clpP expression in L. lactis strains MG1363 (wild type), PV1 (ctsR), and HI1931 (clpE). (A) Total RNA was isolated from cells growing exponentially at 25°C (lanes 0') and 5, 20, and 45 min after transfer to 38.5°C (lanes 5', 20', and 45', respectively) and hybridized with a probe located internal to the clpP gene. (B) Relative mRNA induction ratios in MG1363 (open bars) and HI1931 (cross-hatched bars), calculated by dividing the signal from an RNA sample by the signal from the RNA sample from the MG1363 cells at zero time. The amounts of RNA on the membrane were corrected after rRNA hybridization (data not shown). Results were obtained from two independent experiments.

View larger version (24K): [in this window] [in a new window]   FIG. 3. (A) Northern blot analysis of clpP (A) and dnaK (B) expression in L. lactis strains MG1363 (lanes 1) and HI1931 (lanes 2 and 3) carrying either pCI372 (lanes 1 and 2) or pPV50 (lanes 3). Total RNA was isolated from cells growing exponentially at 25°C (lanes 0') and 5, 20, and 45 min after transfer to 38.5°C (lanes 5', 20', and 45', respectively). The bar diagrams show the relative mRNA induction ratios in wild-type cells (MG1363 with pCI372) (solid bars) and in HI1931 cells with either pCI372 (open bars) or pPV50 (gray bars), as calculated by dividing the signal from an RNA sample by the signal from the RNA sample from the wild-type cells at zero time. The amounts of RNA on the membranes were corrected after rRNA hybridization (data not shown).

Stability of clpP mRNA is not elevated in the clpE mutant cells at 38.5°C. To examine the possibility that the clpE deletion affects the stability of clpP mRNA at a high temperature, the rate of clpP mRNA decay was investigated in both wild-type and clpE mutant cells. Both strains were grown at 38.5°C to an OD₆₀₀ of 0.3, and following inhibition of transcription by rifampin samples were withdrawn and the time-dependent decay of the clpP mRNA was determined by Northern blot analysis (Fig. 4A). A regression analysis of the data (SigmaPlot program; SPSS Inc., Chicago, Ill.) is shown in Fig. 5B. The results of two independent experiments indicated that the half-life of clpP mRNA in both wild-type cells (MG1363) and cells from which clpE was deleted was approximately 2 min. Thus, deletion of clpE does not affect the stability of the clpP transcript.

View larger version (30K): [in this window] [in a new window]   FIG. 4. Stability of clpP mRNA in wild-type and clpE L. lactis. Cells were grown in GM17 medium at 38.5°C until the OD600 reached 0.3, and rifampin (200 µg/ml) was added. (A) Representative Northern blots of RNA isolated after rifampin addition. The sampling times were 0, 1, 3, and 5 min (lanes 0', 1', 3', and 5', respectively). (B) Semilogarithmic plot of clpP mRNA decay at 38.5°C in wild-type strain L. lactis MG1363 () and its clpE derivative HI1931 ().

View larger version (28K): [in this window] [in a new window]   FIG. 5. Expression of clpP'-gusA at 30°C (A) and 38.5°C (B) in L. lactis strains PV28 (bar 1) and PV30 (bars 2 to 4) carrying pCI372 (bars 1 and 2), pPV50 (bar 3), or pPV52 (bar 4). Cells were grown in complex GM17 media, and GusA specific activities were measured by using cell samples withdrawn at an OD600of 0.3 to 0.4. One unit of activity was defined as 1 µmol of substrate (X-Gluc) hydrolyzed per min. The average GusA activities were obtained from three independent experiments.

ClpP-dependent processing of ClpE. In order to determine the amount of ClpE expressed at an elevated temperature (38.5°C), we expressed and purified a His-tagged ClpE and used this tagged ClpE to raise ClpE-specific antibodies. When we analyzed cell lysates from wild-type and ClpE mutant cells by Western blotting, we observed two ClpE-specific bands (Fig. 6A, lanes 1 and 2) in which the amount of the higher-molecular-weight ClpE (ClpE1) greatly exceeded the amount of the lower-molecular-weight ClpE (ClpE2). In cells lacking ClpE two cross-reacting bands still remained (Fig. 6A, lane 2). The sizes of these bands correspond to the sizes of the two ClpB proteins observed in a previous study (18). This finding was confirmed as the bands were not produced by a clpB deletion strain (Fig. 6A, lane 4).

View larger version (64K): [in this window] [in a new window]   FIG. 6. Western blot analysis of ClpE expression at a high temperature. Samples were electrophoresed under reducing conditions in a NuPAGE 4 to 12% bis-Tris gel, and this was followed by blotting onto a nitrocellulose filter. Colorimetric (A and B) or chemiluminescence (C) detection was used as described in Materials and Methods. (A) Western blot analysis of cell extract samples (5 µg) from wild-type strain L. lactis MG1363 (wt) and its derivatives lacking one of the Clp proteins grown at 38.5°C (except strain DFclpP, which was grown at 37°C). (B) Western blot analysis of cell extract samples (3 µg) from wild-type strain L. lactis MG1363 carrying a control vector (pCI372) and a clpE strain carrying pCI372, pPV50, or pPV52 grown at 38.5°C. (C) Western blot analysis of cell extract samples (3 µg) from wild-type strain L. lactis MG1363 and the DFclpP strain carrying pPV50 or pV52 grown at 37°C.

In addition to the specific processing of ClpE, the clpP mutation also increased the total amount of ClpE present (Fig. 6A, lane 5, and Fig. 6C, lanes 3 and 4), and the increase was accompanied by increased transcription of the gene (data not shown). Since clpE expression is negatively regulated by CtsR, our data suggest that L. lactis CtsR is a target for the ClpP protease, as has been observed in B. subtilis (12, 21).

	DISCUSSION

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Transcriptional regulators and alternative factors play crucial roles in the survival of bacteria in stress situations. In several gram-positive bacteria two major negative regulators have been identified as part of the heat shock regulatory network. HrcA controls expression of the chaperone homologues DnaK, DnaJ, GrpE, and GroEL, while CtsR primarily regulates expression of the genes encoding the Clp ATPases and the ClpP protease (12, 42). Recently, several studies have reported that the Clp ATPases influence CtsR activity. In L. monocytogenes deletion of clpC greatly increased expression of the CtsR-regulated clpE gene in the absence of heat shock, suggesting that there is regulatory cross talk between the Clp ATPases (32). Additionally, ClpC appears to be involved in transcriptional regulation of a number of other genes in this organism (34). In B. subtilis the ClpCP complex degrades CtsR at elevated temperatures following modification by the McsB arginine kinase, while CtsR is stabilized in the absence of heat shock by interaction with the zinc-binding protein McsA (23). At low temperatures CtsR is a target of the ClpXP complex, possibly to ensure low-level expression of the CtsR regulon (13).

In the present study we investigated the role of the ClpC and ClpE ATPase homologues in modulating the expression of clpP, which belongs to the CtsR regulon in L. lactis. We found that while ClpC does not affect clpP expression, ClpE is required for the normal repression of clpP expression that occurs following a heat shock. The N-terminal region of ClpE, including a putative zinc finger (19), is important for this activity as replacement of the cysteine at residue 29 with a serine resulted in prolonged heat shock induction. The effect of ClpE on clpP expression is likely to be mediated through CtsR, as heat shock induction in the absence of CtsR and heat shock induction in the absence of ClpE induced clpP equally (Fig. 2). Thus, ClpE could be a chaperone that modulates the activity of CtsR. However, if this is true, ClpE appears to have a narrow substrate specificity as the absence of ClpE did not lead to induction of the HrcA regulon known to respond to misfolded protein (30). Alternatively, ClpE could interact with CtsR in a reaction resembling the reaction of McsA and CtsR in B. subtilis. In fact, searches of the genome sequences of L. lactis (7), Streptococcus pyogenes (4), Streptococcus pneumoniae (45), Streptococcus mutans (1), Streptococcus agalactiae (46), and Lactobacillus plantarum (21) showed that while these organisms encode CtsR homologues, they appear to lack McsA counterparts (data not shown). Intriguingly, the N-terminal zinc finger domains of ClpE of these bacteria exhibit 31 to 41% identity to the first 32 amino acids of B. subtilis McsA and its homolog in Staphylococcus aureus (Fig. 7). As both ClpE and MscA have positive effects on the activity of CtsR, it is tempting to speculate that ClpE is a functional homologue of McsA.

View larger version (33K): [in this window] [in a new window]   FIG. 7. ClustalW multiple-sequence alignment of N-terminal zinc finger regions of ClpE proteins of L. lactis (LACCLPE) S. pyogenes (PYCLPE), S. pneumoniae (PNCLPE), S. mutans (MUTCLPE), S. agalactiae (AGACLPE), and L. plantarum (PLANCLPE) with the N terminus of the McsA protein of B. subtilis (SUBMCSA) and the McsA homolog of S. aureus (AURYACH). A black background indicates identical amino acids, and a grey background indicates similar amino acids.

	ACKNOWLEDGMENTS

 
We thank D. Frees, K. Savijoki, M. Kilstrup, and A. K. Nielsen for helpful discussions throughout this work. We are grateful to C. Rasmussen for excellent technical assistance.

The Danish Dairy Research Foundation, The Danish Food Research Programme (FØTEK-2) through The Centre for Advanced Food Studies (LMC), and the Academy of Finland financed this work.

	FOOTNOTES

 
* Corresponding author. Mailing address: University of Helsinki Faculty of Veterinary Medicine, Department of Basic Veterinary Sciences, Section of Microbiology, P.O Box 57, 00014 Helsinki University, Finland. Phone: 358 9 19149787. Fax: 358 9 19149799. E-mail: pekka.varmanen{at}helsinki.fi.

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