The Alternative Sigma Factor {sigma}B of Bacillus cereus: Response to Stress and Role in Heat Adaptation

A gene cluster encoding the alternative sigma factor ${sigma}$ ^B, threepredicted regulators of ${sigma}$ ^B (RsbV, RsbW, and RsbY), and one proteinwhose function is not known (Orf4) was identified in the genomesequence of the food pathogen Bacillus cereus ATCC 14579. Westernblotting with polyclonal antibodies raised against ${sigma}$ ^B revealedthat there was 20.1-fold activation of ${sigma}$ ^B after a heat shockfrom 30 to 42°C. Osmotic upshock and ethanol exposure alsoupregulated ${sigma}$ ^B, albeit less than a heat shock. When the intracellularATP concentration was decreased by exposure to carbonyl cyanidem-chlorophenylhydrazone (CCCP), only limited increases in ${sigma}$ ^Blevels were observed, revealing that stress due to ATP depletionis not an important factor in ${sigma}$ ^B activation in B. cereus. Analysisof transcription of the sigB operon by Northern blotting andprimer extension revealed the presence of a ${sigma}$ ^B-dependent promoterupstream of the first open reading frame (rsbV) of the sigBoperon, indicating that transcription of sigB is autoregulated.A second ${sigma}$ ^B-dependent promoter was identified upstream of thelast open reading frame (orf4) of the sigB operon. Productionof virulence factors and the nonhemolytic enterotoxin Nhe ina sigB null mutant was the same as in the parent strain. However, ${sigma}$ ^B was found to play a role in the protective heat shock responseof B. cereus. The sigB null mutant was less protected againstthe lethal temperature of 50°C by a preadaptation to 42°Cthan the parent strain was, resulting in a more-than-100-fold-reducedsurvival of the mutant after 40 min at 50°C.

INTRODUCTION

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Introduction

Bacillus cereus is a spore-forming gram-positive rod that isincreasingly being recognized as a food-borne pathogen. It maycause illness through the production of a range of virulencefactors. The most important virulence factors are a heat-stableemetic toxin, which causes vomiting, and several enterotoxinsthat cause diarrhea (14, 23). The symptoms of food-borne diseasecaused by B. cereus are generally mild and self-limiting, butin rare instances they can also be life-threatening, as wasshown in 1998 when a food-poisoning outbreak in France, whichwas attributable to B. cereus, caused the deaths of three persons.The B. cereus strain that caused this outbreak produced a novelcytotoxin, CytK, which caused necrotic enteritis (30). B. cereuscan also be the causative agent of other diseases, such as periodontitis,fulminant endophthalmitis, and meningitis in immunocompromisedpatients (2, 11, 12).

Because of the ubiquitous presence of B. cereus in the environment,it can easily contaminate food production or processing systems(23). B. cereus has the potential for multiple adaptive responsepathways (20). These pathways may contribute to survival ofthe cells during food processing and storage and thus may contributeto the importance of B. cereus as a food-borne pathogen. Vegetativecells of B. cereus also play an important role in the pathogenesisof food-borne illness, because they produce the diarrheal enterotoxinsin the host small intestine (31). In this situation, B. cereushas to deal with the stresses that it experiences in the gastrointestinaltract. Indeed, for some food-borne pathogens, the ability tomount a stress response is a prerequisite for virulence in thegastrointestinal tract (10).

Taxonomically, B. cereus is closely related to Bacillus thuringiensisand Bacillus anthracis. Together with Bacillus weihenstephanensisand Bacillus mycoides, these organisms form the B. cereus group.The members of this group are genotypically so similar thatit has been proposed that the members of the B. cereus groupshould be considered members of the same species (17). However,the phenotypic differences among B. cereus, B. anthracis, andB. thuringiensis are substantial. While B. cereus causes generallymild cases of food-borne illness, B. anthracis is the etiologicalagent of the often lethal disease anthrax (22). B. thuringiensis,on the other hand, is generally considered a beneficial microorganism;it produces insecticidal toxins and is widely used as a biologicalcontrol agent to counter insect pests in agriculture (41). Whole-genomesequencing of B. cereus ATCC 14579 (20) and B. anthracis Ames(39) and suppressive subtraction hybridization (38) have revealedsome distinct genomic differences that distinguish B. cereusand B. thuringiensis from B. anthracis, but these differencesdo not seem to explain the phenotypic disparities in the B.cereus group mentioned above. The functional properties thatdifferentiate these organisms are thought to be mostly causedby genes carried on plasmids or, possibly, by altered gene expressionamong strains (39).

Previously, a number of stress-induced proteins of B. cereuswere identified by two-dimensional gel electrophoresis. Theseproteins included RsbV, the antagonist of the anti-sigma factorof ${sigma}$ ^B, which was found to be upregulated during heat shock (33).This strongly suggested that a ${sigma}$ ^B response is triggered duringheat shock and potentially also under other stress conditions. ${sigma}$ ^B has been studied extensively in several gram-positive bacteria.This protein is a secondary subunit of RNA polymerase that isknown to play an important role in regulating gene expressionwhen there are major changes in the environment. The model organismfor study of ${sigma}$ ^B is Bacillus subtilis (see reference 36 for arecent review). sigB null mutants of B. subtilis have decreasedresistance to heat, acid, ethanol, salt, and oxidative stress(35). Similar effects have also been described for sigB nullmutants of the human pathogens Listeria monocytogenes and Staphylococcusaureus (1, 5, 7, 8).

The regulatory network leading to expression of ${sigma}$ ^B in B. subtilishas been extensively studied for a number of years. Two differentiallyregulated pathways lead to activation of ${sigma}$ ^B in B. subtilis. Thefirst pathway is induced under environmental stress conditions(like ethanol exposure and osmotic shock), and the second pathwayis induced by a decrease in the level of intracellular ATP (36,48). The regulatory network leading to ${sigma}$ ^B activation and repressionfunctions by a so-called partner switching mechanism. In thissystem, interactions between the anti-sigma factor of ${sigma}$ ^B (RsbW)and the anti-sigma factor antagonist (RsbV) and more regulatorsfurther upstream in the regulatory cascade are controlled byserine phosphorylation and dephosphorylation. This leads tothe formation or dissociation of protein-protein complexes,which can finally lead to the release of ${sigma}$ ^B from an RsbW- ${sigma}$ ^B complex(35). More than 200 general stress response genes are underthe control of ${sigma}$ ^B in B. subtilis, and these genes encode proteinswith a wide variety of cellular functions (19, 34, 37). In B.anthracis the alternative sigma factor ${sigma}$ ^B was shown to be a minorvirulence factor and to be activated during the stationary growthphase and after a heat shock (9).

In this paper, we describe the sigB operon of B. cereus ATCC14579 and a predicted novel regulator of ${sigma}$ ^B activity (RsbY),which is located directly downstream of the sigB operon. ${sigma}$ ^B wasactivated under several stress conditions, particularly duringheat shock but also during other stresses, such as osmotic upshockand ethanol exposure. No correlation between intracellular ATPlevels and ${sigma}$ ^B activation was found, indicating that ${sigma}$ ^B activationis not triggered by energy depletion. We mapped two ${sigma}$ ^B-dependentpromoters in the ${sigma}$ ^B operon, which revealed the transcriptionalorganization of the ${sigma}$ ^B operon in B. cereus. Finally, a sigB nullmutant exhibited impaired survival at 50°C after preadaptationto 42°C compared to the survival of the parent strain. Thisindicates that ${sigma}$ ^B plays a role in the adaptive response of B.cereus during heat stress.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains, culture media, growth conditions, and plasmids. B. cereus ATCC 14579 was cultured in brain heart infusion (BHI)medium at 30°C with aeration at 200 rpm. All Escherichiacoli strains were cultured in Luria broth at 37°C (40).E. coli DH5 ${alpha}$ (40) was used as a general-purpose cloning host.E. coli BL21-Codonplus-(DE3)-RIL (Stratagene, La Jolla, Calif.)was used as the host for SigB overproduction. E. coli HB101/pRK24(44) was used as the donor host in conjugation experiments.The antibiotics used were ampicillin at a concentration of 50µg/ml, kanamycin at a concentration of 70 µg/ml,erythromycin at a concentration of 150 µg/ml (for E. coli)or 5 µg/ml (for B. cereus), spectinomycin at a concentrationof 100 µg/ml, and polymyxin B at a concentration of 50µg/ml for counterselection against E. coli upon conjugation.The plasmids used in this study are listed in Table 1.

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TABLE 1. Plasmids used in this study

DNA manipulation and sequencing. Plasmid DNA was purified with a Qiaprep Spin Miniprep kit (Westburg,Leusden, The Netherlands). B. cereus chromosomal DNA was isolatedby using a Wizard genomic DNA purification kit (Promega, Madison,Wis.) according to the manufacturer's instructions. DNA sequencingwas performed with an ABI Prism 377 DNA sequencer (Applied Biosystems,Foster City, Calif.) and a DYEnamic ET terminator cycle sequencingkit (Amersham Biosciences, Roosendaal, The Netherlands). Restrictionendonucleases and DNA ligase (MBI Fermentas GmbH, St. Leon-Rot,Germany) were used according to the manufacturer's instructions.PCR experiments for cloning DNA into vectors were performedwith Pwo polymerase (Roche Diagnostics, Almere, The Netherlands).The oligonucleotides used are listed in Table 2.

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TABLE 2. Oligonucleotides used in this study

The B. cereus ATCC 14579 genome sequence database was used throughoutthis study (http://www.integratedgenomics.com). Comparisonswith the B. anthracis Ames genome and the unfinished B. cereusATCC 10897 genome were made by using BLAST with microbial genomesat http://www.ncbi.nlm.nih.gov/cgi-bin/Entrez/genom_table_cgi.Comparisons with the incomplete B. thuringiensis subsp. israelensisATCC 35646 genome were made at ERGO Light (http: //www.ergo-light.com).The free energy of stem-loop structures was calculated by usingthe Mfold server at http://mfold.burnet.edu.au.

Overexpression and purification of ${sigma}$ ^B in E. coli and generation of polyclonal antibodies. sigB was amplified from B. cereus chromosomal DNA by PCR byusing primers OEcSigBF and OEcSigBR, which introduced an NcoIsite and an XhoI site, respectively. The PCR product was clonedinto pET28-b (Novagen, Madison, Wis.), and the resulting vector(pMT01) was transformed into E. coli BL21-Codonplus-(DE3)-RIL.To produce SigB, a 200-ml culture of this strain was grown at37°C in Luria broth with kanamycin. When the cells reachedthe mid-logarithmic phase (optical density at 600 nm [OD₆₀₀], $~$ 0.5), isopropyl-ß-D-thiogalactopyranoside (IPTG) wasadded to a final concentration of 1 mM, and incubation was continuedfor 2 h. Cells were then harvested, resuspended in lysis buffer(50 mM HEPES-NaOH [pH 7.5], 0.5 M NaCl, 1 mM dithiothreitol,5 mM Pefabloc, 0.5 mg of lysozyme per ml), and incubated for30 min at 4°C. Cells were then lysed by addition of TritonX-100 to a final concentration of 1% and subsequent sonication.The extract was then treated with DNase I (20 µg/ml) for1 h at 37°C. The insoluble fraction containing the inclusionbodies was centrifuged (30,000 x g, 20 min, 4°C) and washedtwice with phosphate-buffered saline with 1% Triton X-100. Thewashed pellet was resuspended in 20 ml of binding buffer (20mM sodium phosphate buffer [pH 7.4], 8 M urea, 0.5 M NaCl, 10mM imidazole, 1 mM dithiothreitol, 5 mM Pefabloc, 10% glycerol)and kept at 4°C for 1 h. After removal of debris by centrifugation,an aliquot of the supernatant, corresponding to 12 mg of protein,was loaded on a 1-ml Hi-Trap chelating HP Ni²⁺ column (AmershamBiosciences). The column was then washed with 10-ml portionsof binding buffer containing decreasing concentrations of urea(8, 6, 4, 2, 1, and 0 M), which allowed on-column refoldingof the protein. The protein was then eluted with an imidazolegradient (20 to 500 mM) and dialyzed against dialysis buffer(50 mM sodium phosphate buffer [pH 7.8], 0.3 M NaCl, 50% glycerol).Protein purity was assessed by Coomassie blue staining of asodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis(PAGE) gel. The protein concentration was measured by the bicinchoninicacid assay.

Rabbit serum containing anti- ${sigma}$ ^B antibodies was prepared by EurogentecS.A. (Herstal, Belgium) according to the company's standardprotocol. Two rabbits were used to raise antibodies against ${sigma}$ ^B. At the start of the protocol 100 µg of purified ${sigma}$ ^B wasmixed with Freund's adjuvant and injected intradermally. After14, 28, and 56 days booster injections consisting of 100 µgof antigen mixed with incomplete Freund's adjuvant were administered.Finally, the animals were bled at day 66. The serum of the animalwith the highest antibody titer was used for all experiments.

Protein extraction and immunoblotting techniques. Total cellular protein was extracted by bead beating as describedpreviously (33). The protein concentration was determined bythe bicinchoninic acid assay. Samples containing 40 µgof protein were loaded on two SDS-PAGE gels. One of the gelswas used in Western blotting experiments, and the other gelwas stained with Coomassie blue and visually inspected to confirmthat equal amounts of protein were loaded.

Proteins were separated by SDS-PAGE by using 15% polyacrylamidegels and a Criterion II vertical electrophoresis system (Bio-Rad,Richmond, Calif.). Bio-Rad's broad-range prestained SDS-PAGEstandards were used as molecular weight markers. After electrophoresis,proteins were electroblotted at 100 V onto nitrocellulose membranes.After the membranes were blocked by incubation with TBS (20mM Tris-HCl [pH 7.5], 500 mM NaCl) with 0.1% sodium caseinate,the blots were incubated with TBS-0.05% Tween 20 supplementedwith 2,000-fold-diluted rabbit immune serum containing the polyclonalanti- ${sigma}$ ^B antibodies. Immunocomplexes were incubated with goatanti-rabbit peroxidase (Bio-Rad) and were visualized with 3,3'-diaminobenzidinetetrahydrochloride. The signal intensities of the Western blotswere quantified by using the Gel-Pro Analyzer software package(Media Cybernetics, Silver Spring, Md.).

Determination of the intracellular ATP pool. ATP was measured by the firefly luciferase assay by using thethe LuminATE luciferin-luciferase reagent (Celsis, Landgraaf,The Netherlands). Cells were lysed by adding 1 ml of cultureto 2 ml of absolute ethanol that was prechilled to -20°C.The suspension was incubated for 10 min at -20°C beforethe luciferase reaction results were determined with a Lumacbiocounter M2500. To correct for ATP present in the culturebroth, 1-ml aliquots of the cultures were centrifuged (12,000x g, 1 min), and each supernatant was analyzed to determinethe ATP concentration as described above.

Construction of a sigB null mutant. First, an erythromycin resistance cassette was amplified frompUC18ERY with primers EryCasF and EryCasR. After digestion withXbaI and BamHI, the erythromycin resistance cassette was clonedinto pAT ${Delta}$ S28, resulting in pAT ${Delta}$ S28ery. Subsequently, a 1.2-kbdownstream flanking region of sigB, which contained 82 bp ofthe 3' end of sigB, was amplified by PCR with primers FlSigbdownFand FlSigbdownR and, after digestion with XmaI and EcoRI, insertedinto pAT ${Delta}$ S28ery, resulting in pAT ${Delta}$ S28eryBY. Finally, a 1.2-kbupstream flanking region of sigB, which contained 96 bp of the5' end of sigB, was amplified by PCR with primers FlSigbupFand FlSigbupR and, after digestion with XbaI, inserted intopAT ${Delta}$ S28eryBY, resulting in pAT ${Delta}$ sigB. The orientation of the insertsin the vector was checked by restriction analysis and sequencing.The vector was then transformed into E. coli HB101/pRK24, andthe resulting strain was used in conjugation experiments withB. cereus. Conjugation was carried out by using the standardprotocol for conjugative plasmid transfer from E. coli to gram-positivebacteria (4). Transconjugants were selected for erythromycinresistance and screened for spectinomycin sensitivity. PCR andSouthern analysis confirmed that the strains selected harboredthe deleted allele of sigB and that the erythromycin resistancecassette had recombined into the chromosome through a double-crossoverevent rather than integration of the entire plasmid (data notshown). The B. cereus sigB null mutant was designated B. cereusFM1400.

Isolation of total RNA, Northern blotting, and primer extension. Total RNA was isolated from B. cereus by using Trizol (Invitrogen,Breda, The Netherlands). After precipitation of the nucleicacid, the residual DNA was removed with 10 U of RNase-free DNaseI (Roche). After phenol-chloroform extraction and precipitation,the RNA was quantitated by measuring the OD₂₆₀. All RNA sampleshad an OD₂₆₀/OD₂₈₀ ratio of $>=$ 1.9.

RNA was separated on a 1.2% agarose-0.66 M formaldehyde-morpholinepropanesulfonicacid (MOPS) gel, which was electrophoresed at 40 V (constantvoltage) and blotted onto Zeta-Probe membranes (Bio-Rad). Blotswere hybridized and washed according to the manufacturer's instructions.Internal PCR fragments of rsbV (generated with primers PrRsbVFand PrRsbVR, resulting in a 270-bp product) and orf4 (generatedwith primers PrOrf4F and PrOrf4R, resulting in a 302-bp product)were used as probes. Gel-purified probes were radiolabeled with[ ${alpha}$ -³²P]dATP by nick translation. After hybridization and washing,the blots were exposed to a PhosphorImager screen. After exposurefor 16 to 72 h, the screen was scanned with a Storm 840 system(Amersham Biosciences). A 0.24- to 9.5-kb RNA ladder (Invitrogen)was used to determine the transcript sizes.

Primer extension analysis was performed as described by Kuiperset al. (24). The oligonucleotides used were PERsbV and PEOrf4,which are complementary to rsbV and orf4, respectively. Fourpicomoles of primer was added to 50 µg of RNA in reactionbuffer containing 10 nmol of dCTP, 10 nmol of dGTP, 10 nmolof dTTP, and 3.3 nmol of [ ${alpha}$ -³²P]dATP. cDNA was synthesized byaddition of 200 U of Superscript II RNase H^- reverse transcriptase(Invitrogen) and incubation for 10 min at 42°C, followedby addition of 10 nmol of cold dATP and incubation for 10 minat 42°C; the final volume of the reaction mixture was 20µl. After the enzyme was inactivated by heating the preparationfor 15 min at 70°C, 12 µl of formamide loading dye(95% formamide, 18 mM EDTA, 0.025% SDS, xylene cyanol, bromophenolblue) was added. After the samples were denatured by heatingthem at 80°C for 10 min, 5-µl aliquots were analyzedon a 7 M urea-8% PAGE sequencing gel prior to visualizationby autoradiography. Sequence ladders were obtained by cloningtemplate DNA (generated with PERsbV and SeqRsbV, resulting ina 941-bp product, and with PEOrf4 and SeqOrf4, resulting ina 1,429-bp product) into pGEM-T (Promega) and performing radioactivesequencing with a T7 DNA polymerase sequencing kit (USB, Cleveland,Ohio) with the same primers that were used for the primer extensionreaction.

Assay for virulence factors and heat resistance of B. cereus cells. Protease, lecithinase, and hemolytic activities were assayedon BHI agar plates supplemented with 5% milk, 5% egg yolk, and5% sterile sheep blood (Biotrading, Mijdrecht, The Netherlands),respectively. Two microliters of an overnight culture of B.cereus was spotted on each plate. The plates were examined after24 h of incubation at 30 and 37°C. The presence of enterotoxinsin the supernatants of overnight cultures of B. cereus was determinedwith a Tecra BDE kit (Tecra Diagnostics, Frenchs Forest, Australia),which detects the NheA subunit of the nonhemolytic enterotoxinNhe.

The heat resistance of vegetative B. cereus cells was assayedas described previously (33). Briefly, cells from a culturein the mid-logarithmic growth phase were exposed to a lethaltemperature (50°C) with or without preexposure to 42°Cfor 30 min. Survival at 50°C was determined by plating appropriatedilutions on BHI agar plates, followed by overnight incubationat 30°C. For all heat exposures, three independent experimentswere performed, and samples were plated in duplicate for eachtime point.

RESULTS

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Results

Sequence analysis of the ${sigma}$ ^B gene cluster in B. cereus ATCC 14579. A gene cluster encoding ${sigma}$ ^B and its regulators was identifiedin the recently completed genome sequence of B. cereus ATCC14579 (20) (Fig. 1). This gene cluster consisted of five openreading frames, which encode regulators of ${sigma}$ ^B activity, the ${sigma}$ ^Bstructural gene, and a protein with an unknown function. Theproducts of all these open reading frames exhibit high aminoacid identity with homologues encoded in the recently completedB. anthracis Ames genome (39), the unfinished B. cereus ATCC10897 genome, and the unfinished B. thuringiensis subsp. israelensisATCC 35646 genome, highlighting the close relationship amongthe different members of the B. cereus group. All of the openreading frames, except orf4, also have homologues in B. subtilis(26) with amino acid identities between 31 and 56% (Fig. 1).

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FIG. 1. Diagram of the organization of the sigB gene cluster of B. cereus ATCC 14579. The large arrows represent open reading frames and indicate their orientations and sizes. The code numbers of these open reading frames in the B. cereus genome database (20) are RZC05131, RZC05126, RZC05124, RZC05127, and RZC05128. The predicted sizes of the encoded proteins (in amino acids [aa]) are also indicated. Predicted terminators downstream of orf4 and rsbY are indicated by stem-loop structures. ${sigma}$ ^B-dependent promoters identified in this study are indicated by small arrows. The levels of amino acid identity with homologues of the open reading frames in B. anthracis Ames (39), B. cereus ATCC 10987 (http://www.tigr.org), B. thuringiensis subsp. israelensis ATCC 35646 (http://www.ergo-light.com), and B. subtilis 168 (26) are indicated at the bottom. Note that in B. subtilis 168 the gene encoding the RsbY homologue (rsbP) is not located directly downstream of the sigB operon like rsbY in the B. cereus group.

The first open reading frame of the gene cluster is rsbV, whichencodes a 111-amino-acid protein with the predicted functionof an anti-sigma factor antagonist. The next open reading frameis rsbW, which is predicted to encode an 160-amino-acid proteinthat can function as an anti-sigma factor of ${sigma}$ ^B. The sigB geneoverlaps rsbW for 12 codons and codes for a protein consistingof 258 amino acids. The overlap between rsbW and sigB is conservedin B. subtilis (13 codons overlap), L. monocytogenes (13 codonsoverlap), and S. aureus (8 codons overlap) (1, 21, 25, 50).In B. subtilis these genes have been shown to be translationallycoupled, ensuring that equimolar amounts of ${sigma}$ ^B and its cognateanti-sigma factor are present (3). The fourth open reading framewas designated orf4 and could code for a 148-amino-acid protein.The BLAST hit in the GenBank database with the highest significancefor the gene encoding this protein is the B. anthracis homologue(96% identity), which is also situated directly downstream ofsigB. Orf4 from B. cereus is distantly related to bacterioferritinsand Dps-like DNA binding proteins, as previously reported forOrf4 of B. anthracis (9). A homologue with an unknown functionfrom the recently discovered and sequenced organism Oceanobacillusiheyensis strain HTE831 (29, 43) is also relatively closelyrelated to Orf4, with a level of identity of 63%. This homologueis not part of the ${sigma}$ ^B operon of O. iheyensis. Directly downstreamof orf4 a stem-loop structure was identified, which may functionas a terminator. The free energy of formation of this structureis -9.4 kcal/mol.

The last open reading frame in the sigB gene cluster is rsbY.The 380-amino-acid protein that could be encoded by this openreading frame contains a C-terminal PP2C serine phosphatasedomain and an N-terminal response regulator receiver domainhomologous to CheY. The latter domain retained the highly conservedand functionally important residues equivalent to D12, D13,the phosphorylation site D57, T87, and K109 of CheY (49). Previously,rsbY was not identified in B. anthracis (9), presumably becausean incomplete version of the B. anthracis genome sequence wasused. A new search of the genomes available for the B. cereusgroup revealed that in all cases rsbY is present and locateddirectly downstream of orf4. The closest well-described relativeof RsbY is RsbP in B. subtilis. RsbP is also a two-domain protein;the N-terminal domain is a sensor PAS domain, while the C-terminaldomain is a PP2C serine phosphatase domain. RsbP is activatedupon energy stress and is then able to dephosphorylate RsbV,leading to ${sigma}$ ^B activation (46). Directly downstream of rsbY astrong stem-loop structure with a calculated free energy offormation of -20.6 kcal/mol was identified.

The genome of B. cereus ATCC 14579 was also searched for homologuesof other regulators (RsbQ, -R, -S, -T, -U, and -X) of the environmentalstress and energy stress pathway of ${sigma}$ ^B activation in B. subtilis.RsbU exhibited some homology with the C-terminal part of RsbYand with stage II sporulation protein E, but the other ${sigma}$ ^B regulatorsof B. subtilis have no apparent homologues in B. cereus ATCC14579.

Overexpression of sigB in E. coli, purification of ${sigma}$ ^B, and generation of anti- ${sigma}$ ^B antibodies. To analyze the role of ${sigma}$ ^B in the stress response of B. cereus,we raised polyclonal antibodies against ${sigma}$ ^B to determine intracellular ${sigma}$ ^B levels under a variety of stress conditions. To obtain sufficientamounts of antigen for the immunization protocol, ${sigma}$ ^B was overexpressedin E. coli. The sigB gene was cloned into the overexpressionvector pET28-b, creating a fusion with six C-terminal histidineresidues. Subsequently, ${sigma}$ ^B was purified by Ni²⁺ affinity chromatography.In the standard overexpression host E. coli strain BL21 ${lambda}$ DE3(pLysS),only very limited production of ${sigma}$ ^B could be obtained (data notshown), presumably because of the differences in codon usagebetween E. coli and B. cereus. In the codon bias-adjusted BL21derivative E. coli BL21-Codonplus-(DE3)-RIL, ${sigma}$ ^B production wasdramatically increased. Purification of ${sigma}$ ^B resulted in a >95%pure protein as judged on a Coomassie blue-stained SDS-PAGEgel. The purified protein was then used for generation of polyclonalantibodies against ${sigma}$ ^B (Fig. 2). Even when the histidine tag wastaken into account, ${sigma}$ ^B migrated as a slightly larger proteinin the SDS-PAGE gel than predicted on the basis of its predictedmolecular mass (29 kDa). This is a property of many sigma factorsbecause of highly positive and negative charge clusters in theproteins (6, 13, 15, 42). The antiserum that was raised against ${sigma}$ ^B reacted specifically with purified ${sigma}$ ^B, although some cross-reactionwas also seen with larger proteins in the purified ${sigma}$ ^B sample(Fig. 2).

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FIG. 2. Overproduction and purification of ${sigma}$ ^B. (Left panel) SDS-PAGE of protein extracts from E. coli BL21-Codonplus-(DE3)-RIL carrying either pET28-b or pMT01. (Right panel) Immunodetection of ${sigma}$ ^B with anti- ${sigma}$ ^B antiserum. Ten micrograms of protein was loaded for each sample. Lane 1, crude protein extract from E. coli carrying pET28-b; lane 2, crude protein extract from E. coli carrying pMT01; lane 3, crude protein extract from E. coli carrying pMT01 after induction with 1 mM IPTG for 2 h; lane 4, inclusion bodies isolated from E. coli carrying pMT01 after induction with 1 mM IPTG for 2 h; lane 5, representative fraction of purified ${sigma}$ ^B after elution from an Ni²⁺ affinity column. The arrow indicates the position of the overproduced ${sigma}$ ^B protein.

Activation of ${sigma}$ ^B under stress conditions. To characterize the ${sigma}$ ^B response of B. cereus under stress conditions, ${sigma}$ ^B levels in total protein extracts from stressed B. cereus cellswere determined by Western blotting by using the anti- ${sigma}$ ^B antiserum.The antiserum reacted strongly with a protein band at 34 kDa,which corresponded to the expected migration of native ${sigma}$ ^B inB. cereus. This band was absent when protein extracts from theB. cereus sigB null mutant (see below) were studied, confirmingthat it was indeed ${sigma}$ ^B.

We found that several types of stress can lead to activationof ${sigma}$ ^B (Fig. 3A). In cells taken from a culture in the mid-logarithmicgrowth phase (OD₆₀₀, 0.4 to 0.5), low levels of ${sigma}$ ^B were present,but upon exposure to stress conditions, the ${sigma}$ ^B levels rose rapidly.To quantify activation of ${sigma}$ ^B under stress conditions, we determinedthe signal intensities of the ${sigma}$ ^B bands (Fig. 3B). The greatesteffect was observed after a heat shock at 42°C. Densitometricanalysis of the ${sigma}$ ^B band on the Western blot revealed that therewas 20.1-fold activation of ${sigma}$ ^B. In an overnight culture, whichhad been in the stationary phase for several hours, ${sigma}$ ^B was foundto be expressed at levels that were 5.0 fold higher than thelevels in cells in the mid-logarithmic growth phase. Additionof 4% ethanol or 2.5% NaCl or an acid shock at pH 5.2 led to4.6-, 4.2-, and 1.8-fold induction of ${sigma}$ ^B, respectively. A limitedeffect on ${sigma}$ ^B levels was observed after oxidative stress inducedby addition of 50 µM H₂O₂ or the thiol-specific oxidizingagent diamide at a concentration of 1 mM (1.5- and 1.6-fold ${sigma}$ ^B activation, respectively).

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FIG. 3. Stress-induced activation of ${sigma}$ ^B in B. cereus. (A) Cellular ${sigma}$ ^B levels upon exposure to stress. Protein extracts from mid-logarithmic-phase B. cereus cells (lane 1) and stressed B. cereus cells were prepared as described in Materials and Methods. B. cereus cells in the mid-logarithmic growth phase were exposed to 4% (vol/vol) ethanol (lane 2), pH 5.2 (the pH was adjusted by addition of HCl) (lane 3), 2.5% (wt/vol) NaCl (lane 4), 50 µM H₂O₂ (lane 5), 1 mM diamide (lane 6), and 42°C for 30 min (lane 7). Proteins were also extracted from an overnight culture (lane 8). Forty micrograms of protein of each sample was loaded on the SDS-PAGE gel. Immunoblotting was performed with the sample by using the ${sigma}$ ^B antiserum. (B) Relative amounts of ${sigma}$ ^B. The signal intensities from the Western blot shown in panel A were quantified by using the Gel-Pro Analyzer software package (Media Cybernetics). The value for the mid-logarithmic-phase culture was defined as 1.

Energy stress is not an important trigger for activation of ${sigma}$ ^B. In B. subtilis, the energy stress pathway of ${sigma}$ ^B activation iscontrolled by RsbP, which responds to a decrease in the sizeof the intracellular ATP pool (46, 48). Because of the presenceof the RsbP homologue RsbY in the proteins encoded by the B.cereus sigB gene cluster, we decided to test if a reductionin the intracellular ATP level would also result in ${sigma}$ ^B activationin B. cereus. The intracellular ATP pool was depleted by usingincreasing concentrations of carbonyl cyanide m-chlorophenylhydrazone(CCCP), which is an agent that uncouples oxidative phosphorylation.A 30-min exposure to CCCP resulted in a decrease in the intracellularATP concentration and inhibition of growth (Fig. 4A). A limited ${sigma}$ ^B-activating effect ( $<=$ 2.5-fold induction on the protein level)was observed in the cultures exposed to CCCP (Fig. 4B). Duringa heat shock from 30 to 42°C for 30 min, the intracellularATP concentration rose more than twofold and the ${sigma}$ ^B level increased20.1-fold. These results indicate that the ${sigma}$ ^B response in B.cereus is not triggered by a drop in the intracellular ATP concentration,as in B. subtilis (48), but seems to occur solely under environmentalstress conditions.

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FIG. 4. Effects of CCCP on growth, the intracellular concentration of ATP, and ${sigma}$ ^B expression of B. cereus. (A) Growth (circles) and intracellular ATP concentration (bars) in B. cereus cells from a mid-logarithmic-phase culture (ML) after exposure to 1, 2, 10, and 50 µM CCCP (left panel) and after a heat shock (HS) at 42°C for 30 min (right panel). Growth of the culture was monitored by determining the increase in the OD₆₀₀ during the 30 min of exposure to CCCP or 42°C. The increase in the OD₆₀₀ over 30 min for an untreated culture was defined as 100%, and growth in the CCCP-treated and heat-shocked cultures was related to this value. Intracellular ATP concentrations were determined by the firefly luciferase assay as described in Materials and Methods. (B) Relative levels of ${sigma}$ ^B in CCCP-treated B. cereus cells (lanes 1 to 5 contained 0, 1, 2, 10, and 50 µM CCCP, respectively) and heat-shocked B. cereus cells (lane 6). The cellular levels of ${sigma}$ ^B were estimated by immunoblotting with anti- ${sigma}$ ^B antiserum and quantification of the signal by the Gel-Pro Analyzer software package as described in the text. Forty micrograms of protein from each sample was loaded on the SDS-PAGE gel used for Western blotting.

Transcriptional analysis of the sigB operon. To study transcriptional regulation of the sigB operon and thephysiological role of ${sigma}$ ^B in the resistance of B. cereus to stress,a sigB null mutant (B. cereus FM1400) was constructed, in whichthe sigB gene was disrupted by an erythromycin resistance cassette.PCR and Southern blotting analysis showed that the erythromycinresistance cassette had correctly integrated into the sigB gene(data not shown).

Transcription of the sigB operon in the sigB null mutant andits parent strain was studied. The activation of ${sigma}$ ^B under stressconditions was confirmed by Northern blot experiments performedwith RNA isolated from cultures of B. cereus FM1400 and theparent strain in the mid-logarithmic growth phase and after10 min of exposure to 42°C (Fig. 5A). In the sigB null mutant,no transcription of the sigB operon was observed under boththese conditions. In wild-type cells in the mid-logarithmicgrowth phase no transcription of the sigB operon was observed,results which corresponded to the barely detectable ${sigma}$ ^B levelsin the Western blot experiments. In the RNA isolated from wild-typecells after 10 min of exposure to 42°C, a 2.1-kb mRNA transcripthybridized with the rsbV probe, corresponding to a transcriptcovering the rsbV-rsbW-sigB-orf4 region. This transcript couldalso be visualized after the blot was probed with DNA probesspecific for rsbW and sigB (data not shown). These results demonstratethat the sigB operon is autoregulated by ${sigma}$ ^B. When an orf4-specificprobe was used, the 2.1-kb transcript was also identified aftera heat shock, but in addition a strong band at 0.5 kb was alsoobserved. This transcript could not be visualized in the RNAsamples from B. cereus FM1400, which indicates that the transcriptis ${sigma}$ ^B dependent.

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FIG. 5. Analysis of transcription of the sigB operon in B. cereus. (A) Northern blot analysis of transcription of the sigB operon. Total RNA was extracted from B. cereus ATCC 14579 and B. cereus FM1400 cells during mid-logarithmic growth in BHI medium (lanes 1 and 3, respectively) and after a 10-min exposure to 42°C (lanes 2 and 4, respectively). ³²P-labeled internal PCR products of rsbV and orf4 were used as probes. Hybridization of the probe with target RNA was visualized by exposure to a Phosphoscreen and scanning with a Storm scanner. Transcript sizes are indicated by arrowheads. (B) Primer extension analysis of promoters 5' of rsbV and orf4. For all reactions 50 µg of RNA was used. Total RNA was extracted from B. cereus ATCC 14579 and B. cereus FM1400 cells during logarithmic growth in BHI medium (lanes 1 and 3, respectively) and after a 10-min exposure to 42°C (lanes 2 and 4, respectively). Mapped transcriptional start sites are indicated by arrowheads. Lanes A, C, G, and T contained the corresponding sequencing ladders for localization of the transcripts. (C) Promoter sequence alignment for the ${sigma}$ ^B-dependent promoters 5' of rsbV and orf4. The positions of identified -35 and -10 regions are indicated. The nucleotides in boxes in the -35 and -10 regions fit the ${sigma}$ ^B promoter consensus sequence of B. subtilis (18). Uppercase letters in the B. subtilis ${sigma}$ ^B promoter consensus sequence indicate highly conserved residues, and lowercase letters indicate less conserved residues (R = A or G, W = A or T). Transcriptional start sites and ATG start codons are indicated by boldface type. Putative Shine-Dalgarno sequences are underlined.

On the basis of the results obtained in the Northern blot experiments,we performed primer extension analysis and mapped two ${sigma}$ ^B-dependentpromoters in the sigB operon (Fig. 5B and C). These promotersare located upstream of rsbV and orf4, and both of them aresilent during mid-logarithmic growth but are activated upona heat shock. In B. cereus FM1400 these promoters are silentunder both conditions, showing that they are ${sigma}$ ^B dependent. Thepromoter upstream of rsbV has -35 and -10 sequences of ATGTTTAAand GGGTAA, respectively, with a spacing of 13 nucleotides.This promoter sequence closely resembles the consensus sequenceof ${sigma}$ ^B promoters in B. subtilis. For this organism, the consensussequences for the -35 and -10 regions have been described asrGGwTTrA and GGgtAt, respectively (uppercase letters indicatehighly conserved residues, and lowercase letters indicate lessconserved residues; R = A or G, W = A or T), which are separatedby 12 to 15 nucleotides (18). The promoter 5' of orf4 was alsoshown to be activated only in the wild-type strain upon heatshock. The -35 and -10 regions of this promoter are ATGTTTAAand GGGTAC, respectively, which are separated by 13 nucleotides.This means that the -35 and -10 regions of this promoter arepractically identical to the regions of the promoter 5' of rsbV;the only difference is the last residue of the -10 region (Cinstead of A).

Role of ${sigma}$ ^B in production of virulence factors and heat resistance of vegetative cells. We did not observe any radical difference between the phenotypesof the B. cereus sigB null mutant and its parent strain. Thegrowth rate at 30°C of the sigB null mutant in BHI brothdid not differ from the growth rate of the parent strain, andcultures of both strains reached the same cell density in thestationary phase. We assayed protease, lecithinase, and hemolyticactivities and the production of nonhemolytic enterotoxin byboth wild-type and sigB null mutant cells and found no significantdifferences between the strains in any of the assays. Hence, ${sigma}$ ^B does not play a role in the production of virulence factorsin B. cereus.

To examine the role of ${sigma}$ ^B in the adaptive response of B. cereus,we focused on the thermotolerance of vegetative cells. Previously,it has been shown that mid-logarithmic cells of B. cereus arevery sensitive to a high temperature (50°C) but that theycan be protected by preadaptation to a permissive temperature,42°C (33). We showed that upon heat shock from 30 to 42°Cthe ${sigma}$ ^B levels increased substantially (Fig. 3), suggesting that ${sigma}$ ^B may play a role in survival of the cells at high temperatures.Therefore, we tested the thermotolerance of B. cereus FM1400and its parent strain in the mid-logarithmic growth phase withand without preadaptation to 42°C (Fig. 6). In the nonadaptedcultures there was no significant difference between the levelsof survival of the two strains; both died rapidly at 50°C,and the viable counts were around or below the detection limitafter 20 min of incubation at 50°C. After preadaptationto 42°C, the wild-type cells showed dramatically increasedsurvival at 50°C. The sigB null mutant was also protectedby preadaptation at 42°C, but it was clearly protected lessthan the wild-type cells, which resulted in >100-fold-lowersurvival after 40 min at 50°C compared to the survival ofthe parent strain. These results demonstrate that in B. cereus ${sigma}$ ^B is involved in the protective response of vegetative cellsagainst high temperature.

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FIG. 6. Survival of of B. cereus ATCC 14579 cells (circles) and B. cereus FM1400 cells (squares) in the mid-logarithmic growth phase at 30°C (open symbols) and after pretreatment at 42°C for 30 min before exposure to 50°C (solid symbols). The averages of three independent experiments are shown. The error bars indicate standard deviations.

DISCUSSION

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Discussion

In this paper we describe the transcriptional organization andexpression of the sigB operon of B. cereus and provide dataconcerning activation of ${sigma}$ ^B upon exposure to stress. In thisstudy we also found that ${sigma}$ ^B is involved in the protective heatstress response. Our results establish a starting point forfurther studies of the role of ${sigma}$ ^B in the stress response of thefood pathogen B. cereus and related members of the B. cereusgroup. We specifically studied regulation of ${sigma}$ ^B activity, andhence we can compare and contrast the B. cereus ${sigma}$ ^B response withthe responses of other gram-positive bacteria.

Several stresses activate ${sigma}$ ^B in B. cereus. A heat shock from30 to 42°C leads to 20.1-fold activation of ${sigma}$ ^B and is byfar the most powerful trigger leading to ${sigma}$ ^B activation in B.cereus. This is in agreement with a previous study, in whichseveral stress-induced proteins of B. cereus were identifiedby two-dimensional gel electrophoresis (33). One of the proteinsidentified was the anti-sigma factor antagonist RsbV, whichwas upregulated >20-fold after a heat shock. The data obtainedsuggested that ${sigma}$ ^B is activated upon heat shock. In this study,we obtained experimental evidence that ${sigma}$ ^B is indeed activatedupon heat shock. Furthermore, we found that ${sigma}$ ^B is also activatedunder other stress conditions, albeit at a level that is anorder of magnitude less than the level during a heat shock,which may explain why the effects were not observed in a previousproteomic study by our group (33).

In B. subtilis, activation of ${sigma}$ ^B in response to heat stress hasbeen well documented (16, 19, 36, 37) and seems to be signaledthrough the environmental stress pathway (48). It has been proposedthat in B. subtilis structural changes in the ribosome duringstress could lead to induction of this pathway (51). Conceivably,a similar mechanism could also be involved in triggering ${sigma}$ ^B activationin B. cereus. Energy stress can be ruled out as an importantfactor in ${sigma}$ ^B activation in B. cereus, because (i) decreasingthe intracellular ATP concentration results in limited activationof ${sigma}$ ^B ( $<=$ 2.5-fold) and (ii) during a heat shock at 42°C theintracellular concentration of ATP increases but, nevertheless, ${sigma}$ ^B is strongly activated.

Analysis of the transcriptional organization of the ${sigma}$ ^B operonrevealed that this operon is transcribed as a 2.1-kb transcriptencompassing rsbV, rsbW, sigB, and orf4. orf4 is also undercontrol of an additional ${sigma}$ ^B-dependent promoter, and this makesorf4 a member of the ${sigma}$ ^B regulon in B. cereus. The exact roleof Orf4 in the stress response of B. cereus and other membersof the B. cereus group is still unknown. This protein may functionas a bacterioferritin, as predicted on the basis of its distanthomologues, as proposed previously for Orf4 in B. anthracis(9), but experimental data are needed to verify this.

The sigB operon ends directly downstream of orf4, because thetranscripts starting upstream of rsbV and orf4 both end at thissite, which suggests that the stem-loop structure downstreamof orf4 functions as a terminator. Downstream of this structurewe identified an open reading frame, rsbY. The encoded proteinis annotated as a ${sigma}$ ^B regulatory protein. The rsbY gene was foundto be present directly downstream of the ${sigma}$ ^B operon in all membersof the B. cereus group whose genome sequences are available.The position of RsbY in the sigB operon and its domain structurestrongly suggest that it can function like the PP2C serine phosphataseproteins RsbU and RsbP in B. subtilis, which play crucial regulatoryroles in activation of ${sigma}$ ^B in that organism (36).

In other gram-positive bacteria, ${sigma}$ ^B has not been studied as extensivelyas it has been in B. subtilis, but there are some intriguingsimilarities and differences between the ${sigma}$ ^B responses of theseorganisms and the ${sigma}$ ^B response of B. cereus. In L. monocytogenes, ${sigma}$ ^B is also activated in response to different stresses, but inthis organism osmotic shock is the most powerful trigger. Heatshock is also an important activating factor, and other stresses,like ethanol stress and acid shock, result in significantlyless marked activation of ${sigma}$ ^B (1). In S. aureus, a thorough examinationof the stresses which activate ${sigma}$ ^B has not been performed, butthe available data suggest that heat shock is the most potentinducer in this organism, while ethanol shock has a limitedeffect (25). Of all the sigB operons in gram-positive bacteria,the pattern of activation in the S. aureus operon seems to bethe most comparable to the pattern in the B. cereus operon.Interestingly, in S. aureus, ${sigma}$ ^B seems to be regulated by threeRsb proteins, just as it is in B. cereus. An important differencebetween S. aureus and B. cereus, however, is the fact that thephosphatase containing the PP2C phosphatase domain is a singledomain protein (RsbU) in S. aureus (25, 50). This again underlinesthe uniqueness of ${sigma}$ ^B in the B. cereus group; both the stressesthat activate ${sigma}$ ^B and the organization of the operon are markedlydifferent from the stresses that activate ${sigma}$ ^B and the organizationof the operon in other gram-positive bacteria studied thus far.In B. cereus ${sigma}$ ^B also plays a role in protecting the cells againsthigh temperature. In B. subtilis (47) and S. aureus (5), ${sigma}$ ^B isalso involved in the protective heat stress response, but anL. monocytogenes sigB null mutant was not more heat sensitivethan its parent (7). This inconsistency in the phenotypes ofsigB null mutants may be caused by differences in the set of ${sigma}$ ^B-regulated genes in the various organisms.

The observation that ${sigma}$ ^B does not play a role in the productionof virulence factors and the nonhemolytic enterotoxin Nhe wasnot unexpected, since in the B. cereus group the productionof these factors is governed by the pleiotropic regulator PlcRand ${sigma}$ ^B seems not to be involved in transcription of the plcRgene (27, 28). However, a sigB null mutant may show a weakenedstress response. This may indirectly decrease its virulenceby impeding the growth or survival of the organism in food orthe host, analogous to the role of the stress response in thevirulence of the food pathogens L. monocytogenes and Salmonellaspp. (10).

The fact that ${sigma}$ ^B is activated when B. cereus is exposed to severaldifferent stress conditions and the observation that ${sigma}$ ^B playsa role in survival during exposure to high temperature can havesignificant consequences for the control of B. cereus. B. cereusis a pathogen whose responses to different environmental situationscan lead to cross-protection against normally lethal conditions(23, 33). The data presented here prove that ${sigma}$ ^B is activatedunder several conditions and that ${sigma}$ ^B has an important role inthe adaptive response of B. cereus. Activation of ${sigma}$ ^B may leadto increased survival of B. cereus during food processing andthus to increased risk of food poisoning outbreaks. In futureresearch, the role of ${sigma}$ ^B in the stress response of B. cereuswill be elucidated further, and studies will focus on the ${sigma}$ ^Bregulon and the pathway leading to ${sigma}$ ^B activation in B. cereus.

ACKNOWLEDGMENTS

Integrated Genomics (Chicago, Ill.) is acknowledged for useof the B. cereus genome sequence database and for release ofthe preliminary B. thuringiensis subsp. israelensis ATCC 35646genome sequence. We thank Nuno Miguel Sampaio Osóriofor performing the plate assays for B. cereus virulence factorsand Agnes Fouet for supplying pAT ${Delta}$ S28 and E. coli HB101/pRK24.

FOOTNOTES

* Corresponding author. Mailing address: Laboratory of Food Microbiology, Wageningen University, Bomenweg 2, 6703 HD Wageningen, The Netherlands. Phone: 31-317-484981. Fax: 31-317-484978. E-mail: tjakko.abee{at}wur.nl.

Present address: Department Flavour, Nutrition and Ingredients,NIZO Food Research, 6710 BA Ede, The Netherlands.

REFERENCES

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