The Alternative Sigma Factor {sigma}H Is Required for Toxin Gene Expression by Bacillus anthracis

Expression of the structural genes for the anthrax toxin proteinsis coordinately controlled by host-related signals, such aselevated CO₂, and the trans-acting positive regulator AtxA.In addition to these requirements, toxin gene expression isunder growth phase regulation. The transition state regulatorAbrB represses atxA expression to influence toxin synthesis.During the late exponential phase of growth, when AbrB levelsbegin to decrease, toxin synthesis increases. Here we reportthat toxin gene expression also requires the presence of sigH,a gene encoding the RNA polymerase sigma factor associated withdevelopment in Bacillus subtilis. In the well-studied B. subtilissystem, ${sigma}$ ^H is required for sporulation and other post-exponential-phaseprocesses and is part of a feedback control pathway for abrBexpression. Our data indicate that a Bacillus anthracis sigH-nullmutant is asporogenous and toxin deficient. Yet the sigma factoris required for toxin gene expression in a manner that is independentof the pathway leading to post-exponential-phase gene expression. ${sigma}$ ^H positively controls atxA in an AbrB-independent manner. Thesefindings, combined with previous observations, suggest thatthe steady-state level of atxA expression is critical for optimaltoxin gene transcription. We propose a model whereby, undertoxin-inducing growth conditions, control of toxin gene expressionis fine-tuned by the independent effects of ${sigma}$ ^H and AbrB on theexpression of atxA.

INTRODUCTION

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Introduction

Expression of the structural genes for the anthrax toxin proteinsPagA (protective antigen), Cya (edema factor), and Lef (lethalfactor) is coordinately controlled by host-related signals andtrans-acting regulatory genes. The toxin genes are located noncontiguouslywithin a 30-kb region of the 182-kb Bacillus anthracis virulenceplasmid pXO1. Two pXO1-encoded regulators of toxin gene expressionhave been reported, PagR and AtxA. The pagR gene encodes a weakrepressor of the bicistronic pagAR operon (25) and negativelyaffects the expression of the chromosomal S-layer genes sapand eag (34). Purified PagR has been shown to bind sequenceswithin the pagA, sap, and eag promoter regions; however, alignmentof the protected sequences does not reveal a PagR consensussequence (34).

AtxA is a positive regulator of pagAR, cya, and lef as wellas a number of other plasmid- and chromosome-carried genes (6,24, 29). AtxA controls gene expression in trans, but the molecularmechanism for this regulation is unknown. AtxA is predictedto be a 56-kDa basic protein with a weak helix-turn-helix motiflocated at the amino terminus. Yet specific nucleic acid bindingactivity has not been ascribed to this protein, and there areno obvious similarities in the promoter regions of the AtxA-controlledgenes. Moreover, consensus sequences for recognition by RNApolymerase sigma factors are generally not apparent for AtxA-dependenttranscription start sites.

In addition to the pXO1-encoded regulators, a chromosomal gene,abrB, has been reported to affect anthrax toxin gene expression.Extensive studies in Bacillus subtilis have revealed that AbrBis a transition state regulator that plays a critical role inthe suppression of post-exponential-phase gene expression duringthe logarithmic phase of growth (42). Optimal toxin synthesisby B. anthracis occurs during growth at 37°C in CasaminoAcids medium containing bicarbonate (11, 48). In these conditions,toxin gene expression reaches a maximum during the late exponentialphase of growth, coinciding with a decrease in abrB transcription.A B. anthracis abrB deletion mutant produces higher levels ofall three toxin proteins, and toxin gene expression peaks earlierduring growth (46).

The abrB effect on toxin gene expression may be due in partto the repression of atxA transcription. Saile and Koehler (46)demonstrated elevated transcripts of atxA in an abrB-null mutantof B. anthracis, and Strauch et al. (54) reported recently thatB. anthracis AbrB binds to specific DNA sequences in the atxApromoter region. Nevertheless, there is evidence that abrB controlstoxin gene expression in an atxA-independent manner. Baillieet al. (3) reported that a B. subtilis abrB-null mutant harboringthe cloned pagA gene produced elevated levels of protectiveantigen. Considering that B. subtilis does not appear to containan atxA homologue, this effect is independent of atxA.

The B. subtilis AbrB is a pleiotropic regulator and binds tothe promoter regions of multiple target genes (42). One AbrBtarget is sigH (19, 53), a gene encoding the alternative sigmafactor ${sigma}$ ^H, which plays an important role in post-exponential-phasegene expression. The ${sigma}$ ^H RNA polymerase holoenzyme recognizesand transcribes genes associated with the transition to thestationary phase of growth, including genes for cytochrome biogenesis,generation of potential nutrient sources, transport, and cellwall metabolism (7), as well as genes important for competenceand sporulation initiation (16). In B. subtilis, a complex signaltransduction phosphorelay system keeps the initiation of sporulationunder stringent control by regulating the phosphorylation ofthe master response regulator, Spo0A (23, 38-41).

${sigma}$ ^H, AbrB, and Spo0A are all part of a feedback mechanism thatultimately controls the expression of each regulator and iscritical for sporulation initiation. During the logarithmicphase of growth, sigH expression is repressed by AbrB, resultingin relatively low-level expression of ${sigma}$ ^H targets (19, 53). Asa culture transitions into the stationary phase, phosphorylationof Spo0A increases, leading to gradual activation of Spo0A (50).Phosphorylated Spo0A represses the transcription of abrB (21,52), resulting in increased levels of ${sigma}$ ^H. The spo0A gene hastwo promoters, one recognized by the housekeeping sigma factor, ${sigma}$ ^A, and the other recognized by ${sigma}$ ^H (43). The elevated Spo0A levelsin the stationary phase are attributed to enhanced spo0A transcriptionwhen ${sigma}$ ^H levels are high. Therefore, abrB expression in B. subtilisis increased in a sigH-null mutant that produces low levelsof Spo0A (54).

In B. anthracis, AbrB represses the toxin regulator atxA (46,54). As predicted from the B. subtilis model in which abrB expressionis subject to control by ${sigma}$ ^H and Spo0A, the activity of a reportergene driven by the atxA promoter is reduced in B. subtilis spo0Aand sigH mutants (54). Moreover, the increased atxA promoteractivity exhibited by a B. subtilis abrB mutant is comparableto the activities of double mutants with abrB and sigH or abrBand spo0A deleted (54).

In the work presented here, we further explored the relationshipbetween anthrax toxin gene expression and the multicomponentsystem controlling growth phase-specific gene expression anddevelopment that is well studied in B. subtilis. As is truefor ${sigma}$ ^H function in B. subtilis, the B. anthracis sigH gene isrequired for sporulation, demonstrating a role for this alternativesigma factor in post-exponential-phase gene regulation. However,our data show that SigH controls toxin gene expression independentlyof AbrB, indicating an additional function for SigH in B. anthracis.Thus, SigH joins AbrB as another key player in the disparateprocesses of sporulation and toxin synthesis by B. anthracis.

MATERIALS AND METHODS

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Materials and Methods

Growth conditions. Escherichia coli strains JM109 and GM2163 (New England Biolabs,Beverly, MA) were grown in Luria-Bertani (LB) broth (47) andused as hosts for cloning. B. anthracis strains were grown inLB broth to obtain cells for transductions, electroporations,and DNA extraction. B. anthracis culture supernatants and cellextracts for Western hybridization and ß-galactosidaseassays were obtained from cells grown as follows. A sample froman overnight culture grown at 30°C with agitation in LBbroth containing 0.5% glycerol and appropriate antibiotics wasused to inoculate 45 ml of CACO₃ medium (CA medium [56] bufferedwith 100 mM HEPES [pH 8.0] and 0.8% [wt/vol] sodium bicarbonate)in a 250-ml Erlenmeyer flask. Cultures were incubated at 37°Cin an atmosphere containing 5% CO₂. Antibiotics were purchasedfrom Sigma-Aldrich (St. Louis, MO) or Fisher Scientific (Fairlawn,NJ) and added to media (concentrations are indicated in parentheses)when appropriate: ampicillin (100 µg/ml), erythromycin(150 µg/ml for E. coli; 5 µg/ml for B. anthracis),kanamycin (20 µg/ml for E. coli; 100 µg/ml for B.anthracis), and spectinomycin (50 µg/ml for E. coli; 100µg/ml for B. anthracis). All other chemicals were purchasedfrom Sigma Aldrich unless indicated otherwise.

DNA isolation and manipulation. Extraction of chromosomal DNA from B. anthracis cultures wascarried out using a Mo Bio genomic isolation kit (Mo Bio Laboratories,Solana Beach, CA). Preparation of plasmid DNA from E. coli,transformation of E. coli, and recombinant DNA techniques wereperformed using standard procedures (2). B. anthracis was electroporatedwith unmethylated plasmid DNA from E. coli GM2163 as describedelsewhere (29). Restriction enzymes and T4 DNA ligase were purchasedfrom Promega (Madison, WI) and Fisher Scientific, and Taq DNApolymerase was purchased from New England Biolabs (Beverly,MA).

Strain construction. Table 1 contains a complete list of B. anthracis strains used,including relevant characteristics. The B. anthracis sigH-nullmutant UT198 was constructed by replacing the sigH gene (NC003997.3;nucleotides [nt] 102990 to 103646) with the ${Omega}$ -km2 element, usinga previously described protocol (29). B. anthracis strain UT301was created by double-crossover recombination of sigH and upstreamregulatory elements into the chromosomal plcR locus (NC003997.3;nt 1133897 to 1134781). To create UT301, plasmid pUTE719, containingthe ${Omega}$ -spc element flanked by DNA sequences found upstream anddownstream of the plcR gene, was constructed. The plcR-flankingsequences were amplified with primer pairs CR123 (5'-GAGCTCGGATCCCGATTCAATTCGGCTCACTT-3')/ES40(5'-AACTCCAGTGTTGCGGAAACGTTAAAGA-3') and CR124(5'-GAGCTCTTGAAAACGCAATTGCAAAC-3')/ES43(5'-ACGCGTCGACTCGTATCTCCTGCCCAATTC-3') and Pfu Turbo DNA polymerase(Stratagene, La Jolla, CA). The plcR-flanking regions and the ${Omega}$ -spc element were cloned into pUTE583 (12) such that a uniqueSacI site was located between the ${Omega}$ -spc element and the downstreamflanking region. Primers MH187 (5'-CCCGAGCTCGGAAGAATCAAACTGCAGATG-3')and MH188 (5'-CCCGAGCTCGTATCTTTCATCGTAGAG-3') were used to amplifya 1,209-bp fragment containing the sigH gene and its predictedpromoter region. The PCR product was digested with SacI andcloned into pUTE719. The resulting construct, pUTB1, was electroporatedinto UT198, and the resulting strain was cultured to facilitaterecombination as described previously (46).

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TABLE 1. B. anthracis strains used in this study

Microscopy. B. anthracis cells were visualized using a Labophot Nikon microscope,and pictures were obtained using a COOLPIX995 digital camera.

Western blot analysis. Culture supernatants were filtered through 0.2-µm-pore-sizesyringe filters (Corning, Corning, NY). For detection of protectiveantigen (PA), lethal factor (LF), and edema factor (EF), sampleswere treated and visualized as described previously (46). Equalvolumes of culture supernatants were used to compare toxin levelsin the parent and mutant strains. Cell extracts were preparedand probed for the presence of ${sigma}$ ^H as follows. Cell pellets from1-ml samples were resuspended in 1x phosphate-buffered saline(PBS) and mechanically sheared by using a mini-bead beater 8(MBB8) (Biospec Products, Bartlesville, OK), incubated for 5min at 65°C, and sheared again for 1 min. Cell debris waspelleted at 16,000 x g for 10 min. Supernatant fractions weretreated with 40 µl of 25x stock protease inhibitor cocktail(Roche, Indianapolis, IN). The protein concentration was determinedby using a BCA assay kit (Pierce, Rockford, IL) with bovineserum albumin as the standard, following the manufacturer'sinstructions. Samples containing 4 µg of total proteinwere resolved on 15% sodium dodecyl sulfate-polyacrylamide gels,transferred, and blocked in 1x TBS-T (20 mM Tris base, 137 mMNaCl, 0.1% Tween 20 [pH 7.6]) containing 5% milk as describedpreviously (46). The membranes were probed using rabbit antiseraraised against B. subtilis ${sigma}$ ^H and SigA, at dilutions of 1:500and 1:1,000, respectively, in 1x TBS-T-5% milk (46).

ß-Galactosidase assays. One-milliliter culture samples were collected hourly from theearly logarithmic (3 h) to the 3-h post-stationary phase ofgrowth (10 h). ß-Galactosidase assays were performedaccording to Miller (36). Cell extracts were prepared as describedfor Western blot analysis (above). At least three independentcultures were assayed for enzyme activity. The figures showdata from representative experiments.

Bioinformatics analyses. The predicted amino acid sequences of ${sigma}$ ^H from B. anthracis andB. subtilis were aligned using ClustalW. The NCBI BlastP programwas used to identify B. anthracis homologs of B. subtilis genesknown to be transcribed by ${sigma}$ ^H RNA polymerase. The predicted aminoacid sequences for the B. subtilis Spo0A, Spo0F, Spo0M, CitG,KinA, PhrC, PhrI, Spo0M, SpoVG, SpoVS, and SigA proteins werecompared by BLAST analysis against the sequence of the B. anthracisAmes genome (NC003997). Genes encoding the proteins with thehighest percent identity were considered for analysis. Uponidentification of a candidate gene, the sequence of the 500nucleotides upstream of the predicted translational start wasexamined for the presence of a ${sigma}$ ^H consensus. Wherever possible,the promoter regions of the B. subtilis genes were aligned withthe B. anthracis sequences using ClustalW.

Purification of B. anthracis ${sigma}$ ^H. Sequences corresponding to the B. anthracis sigH locus wereamplified from genomic DNA using PCR with primers YC85 (5'-CACCATGGAAGCAGGCTTCGTAAGTG-3')and YC86 (5'-ATTTGAAGTGGTACTCTCTCTC-3'). The resulting productwas cloned into the protein expression vector pET101/D-TOPO(Invitrogen, Carlsbad, CA) to give plasmid pUTE493. The plasmidwas constructed such that C-terminally His-tagged ${sigma}$ ^H was expressedfrom a T7 promoter. pUTE493 was introduced into E. coli BL21(DE3),and the recombinant B. anthracis protein was expressed and purifiedfrom the strain under denaturing conditions according to themanufacturer's instructions (QIAexpress; QIAGEN, Valencia, CA).Recombinant ${sigma}$ ^H was dialyzed overnight in refolding buffer followingthe protocol described by Haldenwang et al. (22).

In vitro runoff transcription assays. To create templates for in vitro runoff transcription reactions,blunt-ended DNA fragments corresponding to the pagA, lef, andcya promoter regions from positions –90 to +88, –70to +132 and –122 to +63, respectively, relative to themain transcriptional start sites, and to the spoVG and atxApromoter regions from positions –243 to +1 and –870to +1, respectively, relative to the translational start, wereamplified by PCR using Deep Vent DNA polymerase. Each PCR productwas purified using Zymoclean reagents (Orange, CA), concentrated4 times and quantified by measuring absorbance at an opticaldensity of 260 nm.

Recombinant B. anthracis ${sigma}$ ^H was used in combination with E. colicore RNA polymerase purchased from Epicenter (Madison, WI) forin vitro transcription reactions. For each reaction, 0.1 pmolof template DNA was added to 1x in vitro transcription buffer(Promega) supplemented with 200 mM KCl and containing 77.25nM E. coli core RNA polymerase and 480 nM ${sigma}$ ^H in a total volumeof 10 µl. Following incubation at 37°C for 30 min,ribonucleotides and [ ${alpha}$ -³²P]UTP were added to a final concentrationof 0.5 mM in a 20-µl volume. After incubation for an additional15 min at 37°C, reactions were terminated by purificationthrough G-30 columns (Bio-Rad, Hercules, CA) according to themanufacturer's protocol. Eluates were mixed with equal volumesof RNA loading buffer (0.05% bromophenol blue, 20 mM EDTA indeionized formamide [Sigma-Aldrich]) and heated at 80°Cfor 10 min prior to electrophoresis. Samples (7 µl) wereelectrophoresed at 1,400 V for 2.5 h in 8% acrylamide-7 M ureadenaturing gels. Gels were dried for 4 h using a model 583 Bio-Radgel dryer prior to exposure to photographic film at –80°Covernight. Molecular size markers were generated by in vitrotranscription of an RNA century marker template set (Ambion,Austin, TX), following the manufacturer's instructions.

RESULTS

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Results

Creation of a B. anthracis sigH-null mutant. We identified the sigH gene of B. anthracis (NC003997.3; nt102990 to 103646) on the basis of sequence homology to B. subtilissigH (NC000964.2; nt 116597 to 117253). A protein BLAST search(BlastP) revealed that BA0093 is predicted to encode a protein(NP_842661.1) that bears an 81% identity to the B. subtilis ${sigma}$ ^H (NP_387979). We constructed a sigH-null mutant, UT198, inwhich the sigH gene was replaced by a kanamycin cassette usingmethods described previously (46). As expected, the sigH mutant,UT198, was unable to sporulate (Fig. 1A). The sigH-null mutationdid not affect the growth rate when cells were cultured in CACO₃medium at 37°C in an atmosphere containing 5% CO₂, conditionsthat are optimal for toxin gene expression (11, 48) (Fig. 1B).The mutation in UT198 was complemented by placement of the sigHgene in another chromosomal locus, plcR (NC003997.3; nt 1133897to 1134781). The B. anthracis plcR gene is predicted to encodea truncated, nonfunctional protein (1, 35, 49). Recombinantstrain UT301 was derived from UT198 and harbors sigH under thecontrol of its native promoter in the plcR locus. Sporulationand ${sigma}$ ^H synthesis by UT301 are comparable to those of the parentstrain, UM44 (Fig. 1A and C).

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FIG. 1. Creation of a B. anthracis sigH-null mutant. (A) Sporulation of the parent, mutant, and complemented strains grown in PA broth (20) at 30°C. Samples were taken at the times indicated and assessed for the presence of spores using light microscopy. (B) Growth of UM44 (parent), UT198 ( ${Delta}$ sigH), and UT301 ( ${Delta}$ sigH sigH::plcR) in CACO₃ broth in 5% CO₂ at 37°C. OD600, optical density at 600 nm. (C) Synthesis of ${sigma}$ ^H by the parent and mutant strains. The culture samples were obtained during the late exponential phase of growth (5 h). Solubilized cellular protein (4 µg) was subjected to Western blot analysis using rabbit anti- ${sigma}$ ^H antibody raised against B. subtilis ${sigma}$ ^H or rabbit anti- ${sigma}$ ^A antibody raised against B. subtilis ${sigma}$ ^A (as a loading control). Lane 1, recombinant protein; lane 2, UM44; lane 3, UT198; lane 4, UT301.

Deletion of sigH results in a toxin-deficient phenotype. Considering that abrB and spo0A affect toxin gene expressionin B. anthracis (46), and considering the relationships betweensigH and these regulators in B. subtilis (50), we assessed toxinsynthesis by the B. anthracis parent and the sigH-null mutant.Equal volumes of culture supernatant fractions of strains grownin conditions that promote toxin gene expression were probedfor the relative amounts of each toxin protein. As shown inFig. 2A, at the late exponential growth phase the levels ofPA, LF, and EF in the supernatant of the UT198 (sigH) strainwere significantly lower than those in the supernatant of theUM44 (parent) culture. The toxin deficiency of UT198 was complementedby the addition of sigH in trans (UT301). UT301 produced greateramounts of PA and LF than UT198, but less PA and LF than UM44(Fig. 2A, lane 4). This result was surprising, given that ${sigma}$ ^Hsynthesis by UT301 was comparable to that of the parent strain(Fig. 1B).

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FIG. 2. Reduced toxin gene expression by a B. anthracis sigH-null mutant. (A) Synthesis of the toxin proteins. Supernatant samples for Western hybridization analysis were obtained during the late exponential phase of growth (5 h). Equal volumes of supernatant were probed using rabbit antisera raised against the toxin proteins as indicated. Lane 1, recombinant protein; lane 2, UM44 (parent); lane 3, UT198 (sigH); lane 4, UT301 (sigH plcR::sigH). (B) ß-Galactosidase activities of promoter-lacZ fusions in parent (circle) and sigH (square) backgrounds. pagA::lacZ, UT147 (parent) and UT199 (sigH); lef::lacZ, UT148 (parent) and UT200 (sigH); cya::lacZ, UT133 (parent) and UT201 (sigH). Specific ß-galactosidase activity (nmol o-nitrophenyl-ß-D-galactopyranoside [ONPG]/min/mg protein) is shown.

Transcriptional analysis also revealed significantly reducedexpression of the toxin genes in the sigH-null mutant comparedto that in the parent strain. UM44 (parent)- and UT198 (sigH)-derivedstrains harboring the individual transcriptional fusions pagA::lacZ,lef::lacZ, and cya::lacZ at the toxin gene loci were created,and toxin gene promoter activity was assessed as the ß-galactosidaseactivity of cells grown in conditions optimal for toxin synthesis.Throughout growth, the enzyme activities associated with thepag-lacZ, cya-lacZ, and lef-lacZ reporter genes in sigH-nullstrains were 4% or less of those observed for the parent strains(Fig. 2B). These results demonstrate that sigH affects toxingene expression at the transcriptional level.

${sigma}$ ^H affects toxin synthesis independently of AbrB. The B. anthracis abrB gene exerts a negative effect on toxingene expression. An abrB-null mutant expresses cya, lef, andpagA earlier than the parent strain during growth in batch culture,indicative of growth phase-dependent control (46). This phenotypehas been attributed to specific binding of the AbrB proteinto the promoter of the toxin gene regulator atxA (54). AtxAis a strong positive regulator of the toxin genes; the toxin-deficientphenotype of an atxA-null mutant is comparable to that of thesigH mutant (15). In B. subtilis, steady-state levels of AbrBare modulated by a feedback mechanism whereby AbrB repressessigH, ${sigma}$ ^H RNA polymerase transcribes spo0A, and phosphorylatedSpo0A represses abrB. In B. subtilis, deletion of sigH resultsin elevated levels of AbrB during the stationary phase of growth(19, 43, 50).

We reasoned that if the toxin-deficient phenotype of the B.anthracis sigH-null mutant was due solely to elevated AbrB levels,then the toxin phenotype of a sigH abrB double mutant shouldmatch that of an abrB mutant. We assessed toxin protein levelsin culture supernatants of sigH, abrB, and abrB sigH mutants.Figure 3 shows the results of Western hybridizations comparingLF production by the parent and mutant strains. As reportedpreviously (46), LF production by the abrB-null mutant was elevatedrelative to that of the parent strain. However, the sigH abrBdouble mutant exhibited an LF-deficient phenotype comparableto that of the sigH-null mutant. Similar results were obtainedwhen supernatants were probed for the other toxin components,EF and PA (data not shown). These data indicate that the SigHeffect on toxin synthesis cannot be attributed exclusively toSigH control of abrB.

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FIG. 3. Synthesis of LF by parent and mutant strains. Supernatant samples for toxin analysis were taken during the late exponential phase of growth (5 h). Lane 1, recombinant protein; lane 2, UM44 (parent); lane 3, UT198 (sigH); lane 4, UT166 (abrB); lane 5, UT291 (abrB sigH); lane 6, UT301 (sigH sigH::plcR).

${sigma}$ ^H positively regulates atxA. Other than AbrB, no trans-acting regulators have been associatedwith expression of the atxA gene. To assess the effect of SigHon atxA expression, we examined atxA promoter activity in theparent and mutant strains. As shown in Fig. 4, atxA promoteractivity was highest during the mid-exponential growth phaseand elevated in the abrB-null mutant, consistent with repressionof atxA by AbrB (46, 54). Expression of atxA was barely detectablein the sigH mutant, in agreement with the low level of toxinsynthesis by this mutant. Nevertheless, the atxA promoter activityof the abrB sigH double mutant was comparable to that of thesigH mutant, indicating that SigH positively controls atxA independentlyof AbrB.

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FIG. 4. ß-Galactosidase activities of atxA-lacZ fusions in parent and mutant strains during growth in toxin-inducing conditions. The low-copy-number plasmid pUTE411 containing a PatxA-lacZ transcriptional fusion (46) was introduced into UM44 (parent; triangle), UT198 (sigH; square), UT166 (abrB; diamond), UT291 (abrB sigH; asterisk), and UM44(pHT304-18Z) (empty vector control; circle).

The ${sigma}$ ^H consensus sequence is absent from the atxA and toxin gene promoters. In B. subtilis, genes that are recognized by ${sigma}$ ^H RNA polymeraseare preceded by a consensus sequence (4, 7, 31, 33, 44). Daiet al. (15) previously reported a single transcriptional startsite for the atxA gene that is preceded by a consensus sequencefor the housekeeping sigma factor, ${sigma}$ ^A. We examined DNA sequencesup to 1,000 nucleotides upstream of the predicted translationalstart site of atxA and detected no apparent ${sigma}$ ^H consensus sequences.Sequences corresponding to the ${sigma}$ ^H consensus are also not apparentin the toxin gene promoter regions. In fact, no consensus sequencesfor recognition by any known sigma factor are apparent in thecya and lef gene promoters or upstream of the major atxA-regulatedtranscription start site, P1, of the pagA gene. Weak, constitutivelyexpressed apparent start sites for pagA, P2, and other RNAswith 5' ends mapping downstream of P2 have been described (15,29). A consensus sequence for ${sigma}$ ^A is located upstream of P2 (15).

We questioned whether the promoter regions of B. anthracis genestranscribed by ${sigma}$ ^H RNA polymerase contained sequences resemblingthe B. subtilis ${sigma}$ ^H consensus. We identified B. anthracis homologuesof B. subtilis genes known to be transcribed by ${sigma}$ ^H RNA polymerase.Analysis of sequences upstream of such genes revealed the presenceof sequences that closely resembled the ${sigma}$ ^H consensus sequenceestablished in B. subtilis (Table 2). Each promoter was alignedwith its B. subtilis counterpart using ClustalW (13), to comparesequence similarities and positioning of the ${sigma}$ ^H consensus. Inthe cases of spoVS, sigA, spoVG, and phrC, the distances betweenthe consensus sequences and the predicted translational startsites for the genes were very similar in the two species. TheB. subtilis consensus sequence for the –10 region (RxxGAATww;R indicates A or G; w indicates A or T [7]) was present in allof the B. anthracis promoters investigated. On the other hand,the –35 regions of the B. anthracis promoters deviatedfrom the B. subtilis ${sigma}$ ^H consensus in the third and last positions(Table 2). The –10 and –35 regions for ${sigma}$ ^H recognitionin B. subtilis are typically separated by an 11- to 12-nucleotidespacer. The B. anthracis promoter regions investigated hererevealed spacers that ranged from 10 to 14 nucleotides.

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TABLE 2. B. anthracis homologues of B. subtilis ${sigma}$ ^H RNA polymerase-transcribed genes^a

In vitro transcription of B. anthracis promoters by ${sigma}$ ^H RNA polymerase. To determine if atxA or the toxin genes are transcribed directlyby ${sigma}$ ^H RNA polymerase, we performed in vitro transcription experimentsusing recombinant B. anthracis ${sigma}$ ^H, E. coli core RNA polymerase,and B. anthracis promoter templates (Fig. 5). B. subtilis ${sigma}$ factorshave been reported to function in vitro with the E. coli coreenzyme (9, 17). The B. anthracis spoVG promoter, which bearsthe B. subtilis ${sigma}$ ^H consensus and is strongly SigH dependent inB. subtilis (10, 16), was tested as a positive control. Reactionswith the spoVG DNA template yielded an abundant RNA productof the predicted size for a runoff transcript initiated at thespoVG promoter (Fig. 5A). Thus, the purified recombinant B.anthracis ${sigma}$ ^H protein can function with core RNA polymerase todirect transcription from a B. anthracis gene promoter harboringa ${sigma}$ ^H consensus sequence.

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FIG. 5. In vitro transcription of B. anthracis promoters using recombinant ${sigma}$ ^H RNA polymerase holoenzyme. C-terminally His-tagged ${sigma}$ ^H purified from B. anthracis was used with core RNA polymerase (RNAP) from E. coli as described in Materials and Methods. The compositions of the reaction mixtures and DNA templates are as indicated. +, present; –, absent. Molecular size markers (M) shown in lane 5 are as indicated on the right.

Given the apparent lack of ${sigma}$ ^H recognition sequences in the atxA,pagA, lef, and cya gene promoters, we predicted that transcriptswould not be generated in reactions using these templates. Asexpected, the toxin promoter templates did not yield transcripts(Fig. 5C, D, and E), indicating that ${sigma}$ ^H affects pagA, lef, andcya gene expression indirectly. In some reactions, faint bandsof a size indicating nonspecific end-to-end transcription ofthe templates were observed (data not shown). The small speciesdetected in some reactions containing the pagA template (Fig.5E, lane 4) are most likely stable degradation products of end-to-endtranscripts.

As shown in Fig. 5B, lane 4, an RNA transcript was detectedin reactions with the atxA promoter template. The size of thein vitro-generated RNA product indicated a transcript initiatingapproximately 250 nt upstream of the previously reported transcriptionalstart site for atxA (14). This result was surprising because,as discussed above, sequences in this region do not resemblethe ${sigma}$ ^H consensus established for B. subtilis. Nevertheless, datafrom reverse transcription-PCRs employing RNA from culturedcells confirmed the presence of an RNA transcript in this region(data not shown).

DISCUSSION

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Discussion

The alternative sigma factors of bacteria provide mechanismsfor shifting gene expression patterns in response to a changingenvironment or phase of growth (27). Among the large numberof genes with promoters recognized by alternative sigma factorsare genes encoding virulence or virulence-associated proteins.Examples include the inlA gene of Listeria monocytogenes, theica operon in Staphylococcus aureus (27), and the exotoxin genesof various clostridial species (17). In some cases, sigma factorhomologues possess species-specific functions. For example,SigN RNA polymerase transcribes genes associated with virulencein Pseudomonas aeruginosa and Pseudomonas syringae, but SigNis not required for the transcription of virulence genes inXanthomonas campestris (26, 27). Similarly, lipase gene expressionis differentially regulated by the alternative sigma factorSigB in the closely related species Staphylococcus aureus andStaphylococcus epidermidis (27). While lipase secretion is elevatedin an S. aureus sigB-null mutant (30), secretion of processedlipase in an S. epidermidis sigB-null mutant is reduced significantly(28).

In the nonpathogenic Bacillus species B. subtilis, the alternativesigma factor ${sigma}$ ^H is required for transcription of a large numberof genes that are essential for sporulation (7, 50, 51). Asexpected, deletion of the sigH homolog in B. anthracis abolishedthe ability of the mutant to sporulate, but surprisingly, thissigma factor gene was also required for anthrax toxin gene transcription.Thus, the sigH gene, well studied in B. subtilis for its rolein development, has an additional role in B. anthracis as akey player in virulence gene expression.

In B. subtilis, the promoters of genes transcribed by ${sigma}$ ^H RNApolymerase contain a conserved DNA sequence that is recognizedby ${sigma}$ ^H. A sequence closely resembling the B. subtilis ${sigma}$ ^H consensusis present in the promoter regions of B. anthracis homologuesof B. subtilis genes known to be transcribed by ${sigma}$ ^H RNA polymerase.For the B. anthracis homologues, the sequence in the –35region differs slightly from the consensus established for theB. subtilis genes. RNA transcripts were obtained from in vitroreactions using the promoter of one representative ${sigma}$ ^H RNA polymerase-transcribedhomologue, the B. anthracis spoVG gene, as the template. Thepromoter region of atxA, the major regulator of anthrax toxingene transcription, does not bear sequence similarity to the ${sigma}$ ^H consensus sequence established for B subtilis. Nevertheless,in in vitro reactions, ${sigma}$ ^H RNA polymerase generated transcriptsfrom the atxA promoter template. No in vitro transcripts weredetected in comparable reactions employing toxin gene templates,indicating that ${sigma}$ ^H RNA polymerase-mediated transcription fromthe atxA promoter was specific. Taken together, these data indicatethat ${sigma}$ ^H controls toxin gene expression indirectly, via its directcontrol of atxA gene transcription. Moreover, the B. anthracissigma factor appears to recognize promoters lacking the ${sigma}$ ^H consensussequence established for B. subtilis ${sigma}$ ^H.

The biochemical activity of the B. anthracis ${sigma}$ ^H protein may notbe identical to that of its B. subtilis counterpart. The predictedamino acid sequences of the B. anthracis and B. subtilis ${sigma}$ ^H homologuesdiffer by two residues within region 4.2, the domain responsiblefor recognition and binding of the –35 region (Fig. 6).The B. anthracis ${sigma}$ ^H contains serine residues in positions 160and 172 that are occupied by glycine and valine residues, respectively,in the B. subtilis ${sigma}$ ^H protein. In addition to these differences,the 13 amino-terminal residues of the two proteins exhibit relativelylow amino acid sequence similarity. Comparable differences amongother sets of sigma factor homologues can result in alteredtarget specificity and binding affinity (45).

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FIG. 6. Amino acid sequence comparison of the B. anthracis (B.a) and B. subtilis (B.s) homologs. Alignment was performed using the ClustalW web-based alignment program. The underlined sequence marks the position of region 4. Region 4 makes contact with the –35 box on the target promoter. Two significant amino acid differences are boxed.

Our investigation reveals newly discovered regulatory relationshipsbetween sigH, atxA, and another anthrax toxin gene regulator,abrB, when B. anthracis is grown in conditions that favor toxingene expression. AbrB is a transition state regulator, bestcharacterized in B. subtilis, that affects the transcriptionof multiple genes in a growth phase-dependent manner (42, 50).Steady-state levels of anthrax toxin gene transcripts are increasedin a B. anthracis abrB-null mutant (46), and in vitro footprintanalyses have revealed AbrB binding sites within the atxA promoterregion (54). Thus, AbrB appears to affect toxin gene expressionby controlling the transcription of atxA.

In experiments designed to model AbrB control of atxA in B.subtilis, Strauch et al. (54) showed that the activity of anatxA promoter-lacZ transcriptional fusion is increased in aB. subtilis abrB-null mutant. In B. subtilis, AbrB is one ofthe many factors that affect ${sigma}$ ^H synthesis (54, 57). The sigHgene is subject to stringent transcriptional, posttranscriptional,and posttranslational control (32, 57). During the logarithmicphase of growth, when conditions are not conducive to sporulation,levels of ${sigma}$ ^H are relatively low. Upon entry into the stationarygrowth phase, ${sigma}$ ^H levels rise as a result of abrB repression byphosphorylated Spo0A, the master regulator of sporulation initiation.The spo0A gene has two transcriptional start sites, one of whichis ${sigma}$ ^H dependent. Thus, as a culture enters the stationary phase,the levels of Spo0A and ${sigma}$ ^H, as members of the same positive feedbackloop, rise (50). Strauch et al. (54) demonstrated that, whenB. subtilis was cultured in conditions conducive to sporulation,the activity of an atxA promoter-lacZ transcriptional fusionwas reduced in a sigH single mutant and increased in an abrBsigH double mutant. The change in atxA expression by the B.subtilis sigH mutant was attributed to ${sigma}$ ^H control of abrB viaSpo0A and AbrB control of atxA transcription. In contrast, ourexperiments investigating gene expression in B. anthracis revealedthat the sigH effect on atxA expression is not dependent uponabrB. We note that the atxA promoter-lacZ transcriptional fusionused by Strauch et al. (54) contained only 200 nt that wereupstream of the previously reported transcriptional start sitefor atxA and was thus devoid of the upstream region we haveassociated with ${sigma}$ ^H RNA polymerase-mediated transcription. Moreover,there could be species-specific or growth condition-dependentdifferences in ${sigma}$ ^H function. For our investigations, we grew B.anthracis in conditions favorable for toxin synthesis, CACO₃medium in 5% CO₂. When cultured in this manner, B. anthraciscells produce high levels of the anthrax toxin proteins yetsporulate poorly even after prolonged growth (M. Hadjifrangiskouand T. M. Koehler, unpublished data) (37).

The implication of genes associated with the complex networkof developmental control in B. anthracis toxin gene expressionis one of a few intriguing insights into relationships betweenB. anthracis sporulation and virulence. Perego and coworkers(5, 8) recently reported genetic and biochemical analyses ofcomponents of the phosphorelay signal transduction system controllingdevelopment in Bacillus species. Nine sporulation kinase geneswere identified in B. anthracis. Two of these contained frameshifts in all B. anthracis strains investigated, and one ofthem was also inactivated in a pathogenic strain of B. cereusharboring the B. anthracis toxin plasmid pXO1 (8). Their resultssuggest that acquisition of pXO1 and, possibly, virulence genesis associated with loss of sporulation sensor histidine kinaseactivities. Interestingly, in B. subtilis the sensor kinasegenes kinA and kinE have ${sigma}$ ^H-regulated promoters. We examinedthe promoter regions of the B. anthracis kinase genes for the ${sigma}$ ^H consensus sequence. With the exception of BA4223, which hasan apparent –10 sequence matching that of the ${sigma}$ ^H consensus,none of the B. anthracis kinase genes are predicted on the basisof sequence data to be transcribed by ${sigma}$ ^H RNA polymerase. Despitethe lack of a ${sigma}$ ^H consensus sequence in the promoter regions ofthese genes, the kinases may be transcribed directly by ${sigma}$ ^H RNApolymerase in B. anthracis, as we have found for atxA. Alternatively,if the kinase genes are not recognized by ${sigma}$ ^H RNA polymerase,this may be another indication that the pathway for B. anthracisdevelopment deviates from the pathway established for B. subtilis.

Additional evidence implicating pXO1 in B. anthracis developmentis the apparent incompatibility between atxA and plcR, a pleiotropicregulator of virulence genes in B. cereus and B. thuringiensis(1). The atxA gene, located on pXO1, is not found in most B.cereus and B. thuringiensis strains. The plcR gene is foundin all three species but contains a nonsense mutation in allB. anthracis strains examined (49). Mignot et al. (35) reportedthat coexpression of plcR and atxA in a pXO1⁺ background preventedB. anthracis from sporulating efficiently. The sporulation defectwas rescued in an atxA-null mutant, suggesting that the plcRand atxA regulons cannot successfully coexist in B. anthracis.

The results reported here, combined with previously publisheddata, point to multiple means of control of atxA expression.Stringent control of atxA expression is in agreement with theresults of a previous study indicating that steady-state levelsof AtxA in B. anthracis are critical for optimal toxin synthesis.A recombinant strain harboring multiple copies of atxA and producingelevated levels of AtxA exhibited reduced pagA expression (14).We have found that a recombinant strain that overexpresses sigHproduces reduced levels of the toxin proteins. Furthermore,as is true for Spo0A in B. subtilis (18), overexpression ofsigH results in a delay in the onset of sporulation when B.anthracis is cultured in conditions that favor sporulation (Hadjifrangiskouand Koehler, unpublished data). The regulatory relationshipsbetween sigH and other genes controlling development may bespecies specific and/or vary with respect to growth conditions.Altered expression and/or function of these developmental regulatorsin B. anthracis may enable the bacterium to maximize toxin productionduring growth within a host where sporulation does not occur,while maintaining the ability to initiate sporulation upon achange in environment.

ACKNOWLEDGMENTS

This work was sponsored by Public Health Service grant AI33537from the National Institutes of Health.

We thank Masaya Fujita for providing anti- ${sigma}$ ^H and anti- ${sigma}$ ^A antisera,technical advice regarding in vitro transcription reactions,and critical reading of the manuscript. We also thank JesusEraso and the laboratory of Samuel L. Kaplan for helpful discussionsand provision of reagents.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Molecular Genetics, University of Texas—Houston Medical School, 6431 Fannin St., JFB 1.765, Houston, TX 77030. Phone: (713) 500-5450. Fax: (713) 500-5499. E-mail: Theresa.M.Koehler{at}uth.tmc.edu.

Published ahead of print on 22 December 2006.

REFERENCES

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