Spo0A-Dependent Activation of an Extended -10 Region Promoter in Bacillus subtilis

At the onset of endospore formation in Bacillus subtilis theDNA-binding protein Spo0A directly activates transcription frompromoters of about 40 genes. One of these promoters, Pskf, controlsexpression of an operon encoding a killing factor that actson sibling cells. AbrB-mediated repression of Pskf providesone level of security ensuring that this promoter is not activatedprematurely. However, Spo0A also appears to activate the promoterdirectly, since Spo0A is required for Pskf activity in a ${Delta}$ abrBstrain. Here we investigate the mechanism of Pskf activation.DNase I footprinting was used to determine the locations atwhich Spo0A bound to the promoter, and mutations in these siteswere found to significantly reduce promoter activity. The sequencenear the –10 region of the promoter was found to be similarto those of extended –10 region promoters, which containa TRTGn motif. Mutational analysis showed that this extended–10 region, as well as other base pairs in the –10region, is required for Spo0A-dependent activation of the promoter.We found that a substitution of the consensus base pair forthe nonconsensus base pair at position –9 of Pskf produceda promoter that was active constitutively in both ${Delta}$ abrB and ${Delta}$ spo0A ${Delta}$ abrB strains. Therefore, the base pair at position –9of Pskf makes its activity dependent on Spo0A binding, and theextended –10 region motif of the promoter contributesto its high level of activity.

INTRODUCTION

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Introduction

Bacillus subtilis initiates a complex developmental programthat leads to the differentiation of the cell into a dormantendospore as the final step in a series of responses to nutrientdepletion (for a review, see reference 18). Initiation of thisdifferentiation is dependent upon phosphorylation of a responseregulator, Spo0A (6). A complex signal transduction networkcomprising multiple kinases and phosphatases controls the levelof phosphorylated Spo0A (Spo0A $~$ P) in the cells (6, 16). Spo0A $~$ Pdirectly regulates expression of about 121 genes through eitherrepression or activation (14) by binding specifically to a 7-bpDNA element, referred to as an 0A box (5'-TGNCGAA-3') (24, 31).For example, Spo0A $~$ P binding directly represses the promotersfor abrB, fruR, flgB, ftsE, sdp, and rocD (14, 17, 20). Othergenes are directly activated by Spo0A $~$ P (14, 17, 20), and stillothers are activated by Spo0A $~$ P indirectly (14, 24). For example,the spo0H gene is repressed by AbrB until Spo0A $~$ P produced atthe end of the exponential-growth phase represses abrB, relievingspo0H from AbrB-mediated repression (28). Moreover, Spo0A-activatedpromoters include those used by RNA polymerase containing theprimary sigma factor, ${sigma}$ ^A (e.g., spoIIG and spoIIE promoters)(20, 30) and those used by RNA polymerase containing the secondarysigma factor, ${sigma}$ ^H (e.g., spoIIA and racA promoters) (2, 3, 29),which introduces additional combinations of control.

In a strain mutant with respect to both kinA and kinB, two ofthe kinases that control the level of Spo0A $~$ P, a low level ofSpo0A $~$ P accumulates that is sufficient to repress abrB transcriptionbut insufficient for the activation of other Spo0A $~$ P-dependentgenes required for sporulation (25). Therefore, the responsesof some Spo0A-regulated promoters to Spo0A $~$ P appear to be moresensitive to Spo0A $~$ P levels than are the responses of other Spo0A-regulatedpromoters. A progressive accumulation of Spo0A $~$ P at the end ofthe exponential-growth phase produces a temporal pattern ofresponses by Spo0A-regulated promoters that reflects the specificresponse of each promoter to low- or high-threshold levels ofSpo0A $~$ P (9). Thus, in addition to the combinations of controlsdescribed above, Spo0A-regulated promoters can be classifiedas either high- or low-threshold activated or repressed promoters(9). High-threshold promoters require a high level of Spo0A $~$ Pto be activated or repressed, probably in part because the regulatoryregions for these genes have relatively weak affinities forSpo0A $~$ P, whereas low-threshold promoters respond to a low levelof Spo0A $~$ P because their regulatory regions have relatively high-affinitybinding sites for Spo0A $~$ P (9).

The progressive accumulation of Spo0A $~$ P allows cells to try less-drasticresponses to nutrient depletion before commitment to differentiationinto a dormant cell type. Moreover, Spo0A phosphorylation occursin only a fraction of the population (7, 9, 10). Activationof Spo0A in this fraction of the population enables these cellsto delay progression into sporulation by activating two operons,the sporulation killing factor (skf) and the sporulation delayingprotein (sdp) operons (10). The products of these two operonsprevent non-Spo0A $~$ P-expressing sibling cells from sporulating(sdp) and cause them to lyse (skf). The cells that have activatedSpo0A early are then able to feed off the nutrients released,allowing them to continue growing and thus to delay their differentiationinto dormant endospores. The skf promoter must be highly activeto drive production of the secreted toxin, and it must be activatedearly in response to low levels of phosphorylated Spo0A (9,10). However, its expression must be tightly regulated to preventpremature expression of the killing factor. Here we investigatehow this promoter can be both highly active in response to lowlevels of Spo0A $~$ P and tightly controlled to prevent prematureexpression of the toxin.

The sequence of the skf promoter, which is activated by lowlevels of Spo0A $~$ P (9), appears to indicate that Spo0A $~$ P may directlyactivate this promoter by a mechanism that is different fromthat of the spoIIG promoter, which has been studied more extensively(4, 12, 19-21, 23). Comparison of the relative affinities ofSpo0A for the high- and low-threshold promoters shows that spoIIGhas a K_d of 1,700 nM whereas the skf promoter has an apparentK_d value of 26 nM (9). A bioinformatics search identified twoSpo0A binding sites (14); however, the search did not revealother features of the skf promoter that would contribute toits positive regulation by low levels of Spo0A $~$ P.

Here we report that skf is a ${sigma}$ ^A-dependent promoter with multipleSpo0A binding sites, two of which span the –35 region.Moreover, upstream of the mapped transcriptional start siteis a sequence that is very similar to the TRTGn motif foundin extended –10 promoters in Bacillus subtilis (13, 26,27), another feature that is not present in the spoIIG promoter.We show that this sequence is necessary for the high level ofSpo0A-dependent promoter activity. We also describe other featuresof this promoter that are necessary for its tight regulationby Spo0A.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and culture media. Routine microbiological manipulations and procedures were carriedout by standard techniques as described in reference 8. Theconcentrations of antibiotics used for selection on Luria broth(LB) or Difco sporulation medium (DSM) were 5 µg/ml forchloramphenicol, 100 µg/ml for spectinomycin, 10 µg/mlfor kanamycin, and 100 µg/ml for ampicillin. Cultureswere grown in LB, and sporulation was induced by nutrient exhaustionin DSM. Competent cells were prepared and transformed by thetwo-step method as described in reference 8.

To create the abrB deletion strain (CMBS001) (Table 1), the5'- and 3'-flanking DNA of abrB was PCR amplified from chromosomalDNA. The 5'-flanking DNA PCR product was cloned into pDG784digested with SphI and PstI. The 3'-flanking DNA PCR fragmentwas then cloned into the resulting plasmid digested with BamHIand EcoRI to generate plasmid pDG784abrB. Plasmid pDG784abrBwas sequenced to ensure the correct DNA sequences of the clonedfragments and was used to transform competent JH642. Kanamycin-resistantcolonies were selected and analyzed further by PCR to determinewhether substitution of the kanamycin resistance cassette forabrB occurred, as described in reference 12.

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TABLE 1. Bacterial strains used in this study

To clone the skf promoter, the DNA region from the stop codon(TAA) of ybcM (the upstream gene adjacent to the skf operon)to the start codon (ATG) of skfA (the first structural geneof the skf operon) was PCR amplified with oligonucleotides GNC1and GNC2 (Table 2) and inserted into EcoRI- and HindIII-digestedpBG1PLK to create pBG1PLK-SKF. The plasmid was checked by sequencingand used to transform competent JH642 to chloramphenicol resistance.Integration of pBG1PLK-SKF into the wild-type B. subtilis chromosomalamyE locus by homologous recombination was confirmed by testingfor loss of amylase production by iodine staining and by PCRand DNA sequencing. The resulting strain was later transformedwith ${Delta}$ abrB and/or ${Delta}$ spo0A knockout plasmids (12), producing correspondingB. subtilis strains (Table 1).

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TABLE 2. Oligonucleotides used for PCR, sequencing, and mutagenesis

Overlapping PCR was used to introduce base pair substitutionsin the wild-type skf promoter. First, two QuikChange oligonucleotideswere designed that were complementary to each other and annealedto the skf promoter but carried the desired nucleotide change.Each was used in combination with an external oligonucleotide(GNC1 or GNC2) to perform PCR using the plasmid pBG1PLK-SKFas the template. The two amplified products, which correspondto the 5' and 3' portions of the skf promoter and partiallyoverlap the mutated region, were gel purified. The productswere then mixed, annealed, and used as the template for thesecond step of PCR performed with the two external primers,GNC1 and GNC2. The product obtained, which should carry theskf promoter sequence with the desired substitution, was sequencedand then inserted into EcoRI- and HindIII-digested pBG1PLK.The resulting plasmids (Table 1) were then used to transformcompetent JH642.

RNA preparations. Cultures of B. subtilis strains THWB2, THWB18, THWB24 and THWB9(Table 1) were incubated in DSM. Two hours after the end ofthe exponential-growth phase, the bacteria were harvested bycentrifugation and stored at –80°C. RNA was preparedas described in reference 8.

Primer extension reactions. A total of 100 ng of primer GNC12 (Table 2) was end labeledwith [ ${gamma}$ -³²P]ATP by use of T4 polynucleotide kinase from New EnglandBiolabs. The labeled primer was purified using an Amersham BiosciencesMicroSpin G-25 column (Amersham Pharmacia Biotech, Piscataway,N.J.). A 15-ng volume of this purified labeled primer was addedto 50 µg of total RNA along with hybridization buffer(150 mM KCl, 10 mM Tris [pH 8.3], and 1 mM EDTA) in a finalvolume of 30 µl. The RNA and labeled primer were incubatedin 90 µl of elongation buffer (20 mM Tris [pH 8.3], 10mM MgCl₂, 7 mM dithiothreitol) at 30°C for 16 h. A totalof 20 units of avian myeloblastosis virus reverse transcriptase(Promega) was added, and the reaction mixture was incubatedat 42°C for 1 h. The extension was terminated by adding205 µl diethyl pyrocarbonate water, and the extensionproducts were digested with 4.2 µg RNase A at 37°Cfor 15 min. The products were extracted with 300 µl phenol:chloroform:isoamylalcohol (25:24:1) and precipitated by adding 30 µl of3 M sodium acetate and 2.5 volumes of ethanol. The dried pelletwas then suspended in 4 µl Tris-EDTA and 2 µl formamidesequencing loading buffer and subjected to electrophoresis ina 6% polyacrylamide gel containing 7 M urea, alongside a sequencingreaction ladder generated with labeled primer GNC12.

Preparation of end-labeled DNA and DNase I footprinting. The oligonucleotide SKF3For (50 pmol) was labeled with [ ${gamma}$ -³²P]ATPby use of T4 polynucleotide kinase (NEB) per the manufacturer'sinstructions. The probe was separated from unincorporated nucleotideswith a G-25 MicroSpin column (Amersham Pharmacia Biotech, Piscataway,N.J.). The purified labeled probe was used in a PCR containing36 pmol of unlabeled SKF4Rev primer and Herculase DNA polymerase(Stratagene). The PCR product was purified by elution from aG-50 MicroSpin column (Amersham Pharmacia Biotech, Piscataway,N.J.).

For DNase I protection assays, end-labeled DNA fragments werepreincubated with or without the purified C-terminal domainof Spo0A (C-Spo0A), purified as described in reference 22, for15 min in assay buffer [20 mM TrisCl (pH 7.4), 50 mM KCl, 1mM dithiothreitol, poly(dI-dC) (2 ng/µl), 400 µlMgCl₂, 200 µM CaCl₂, bovine serum albumin (100 µg/ml)].DNase I prepared from lyophilized enzyme (Sigma) was added at100 ng/ml for 1 min at 37°C. The digestion was quenchedby the addition of 10 volumes of ice-cold precipitation buffer(570 mM NH₄OAc, 50 µg tRNA/ml, 80% ethanol). Electrophoreticanalysis was carried out by resuspending the dried pellet fromthe protection reaction in 80% formamide-50 mM Tris-HCl-50 mMborate-1.4 mM Na₂-EDTA-0.1% (wt/vol) xylene cyanol-0.1% (wt/vol)bromophenol blue. After denaturation by incubation at 90°Cfollowed by chilling in ice, the samples were electrophoresedthrough 8% (wt/vol) acrylamide-8.3 M urea gels alongside a sequencingreaction generated with the labeled primer. The electrophoresisbuffer was 90 mM Tris-HCl-89 mM borate-2.5 mM Na₂-EDTA. Afterelectrophoresis, the gels were exposed to KODAK XAR-2 film at–79°C with an intensifying screen.

ß-Galactosidase activity. Duplicate cultures were incubated in DSM with chloramphenicol(5 µg/ml). After 2 h of growth, two 300-µl aliquotsof each culture were collected every half hour for 6 h. Thefirst of these aliquots was used to measure the optical density,while bacteria from the second aliquot were harvested by centrifugationand stored at –80°C until assayed for ß-galactosidase(8).

RESULTS

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Results

Anatomy of the skf promoter. We used primer extension analysis to determine the start pointof skf transcription. RNA was isolated about 2.5 h after theend of the exponential-growth phase from cultures of four strains(wild type, ${Delta}$ spo0A, ${Delta}$ abrB, and ${Delta}$ spo0A ${Delta}$ abrB) that contained an skfA'-'lacZtranslational fusion integrated at the amyE locus of the chromosome.A primer complementary to part of the lacZ sequence was usedin primer extension reactions, and the products were analyzedas described in Materials and Methods. The major transcriptionproduct found in RNA isolated from an otherwise wild-type strainmapped to a position 53 bp upstream from the start codon ofskfA, AUG (Fig. 1 and 2). This product was absent in RNA isolatedfrom an spo0A null strain (Fig. 2, lane h). In results consistentwith measurements of the ß-galactosidase accumulatedby the strains (see below), the RNA transcript was most abundantin RNA isolated from an abrB mutant strain (Fig. 2, lane a)and was present at a low level in a spo0A and abrB double-mutantstrain (Fig. 2, lane b). The start point of transcription seenis consistent with the effects of mutations on promoter activitydescribed below. A transcript that mapped to the same startpoint was observed in experiments using a primer that was complementaryto part of the wild-type allele of skfA at its normal chromosomallocation (data not shown).

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FIG. 1. Anatomy of the skf promoter. The sequence shown is the nontranscribed strand and includes the minimal region required for wild-type promoter activity. The start point of transcription is indicated as +1. The vertical arrows show the activity of each mutated promoter relative to that of the wild-type promoter on a log scale as indicated by the vertical line on the right. The region of the nontemplate strand that was protected from DNase I by C-Spo0A is indicated by broken lines below the sequence. The extended –10 region is denoted by the solid underline. Sequences similar to the consensus for Spo0A binding sites are indicated with the numbers 1 to 4, and horizontal arrows indicate the orientation of these asymmetric sites.

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FIG. 2. Primer extension analysis of the skf promoter. Total RNA isolated 2.5 h after the end of the exponential-growth phase from four B. subtilis strains ( ${Delta}$ abrB background [lane a], ${Delta}$ spo0A ${Delta}$ abrB background [lane b], a wild-type strain [lane c], or ${Delta}$ spo0A background [lane h]) was used for primer extension as described in Materials and Methods. The primer extension product, and therefore the putative start point of transcription, is indicated by an arrow on the left and by +1 on the right of the figure. The DNA sequence generated by dideoxy sequencing using the same primer is shown in lanes d, e, f, and g. The letter above each of these lanes indicates the dideoxynucleotide used to terminate each reaction. The two vertical columns on the left of the figure indicate the DNA sequence of the region.

We used the C-terminal domain of Spo0A (C-Spo0A), which bindsand activates transcription independently of phosphorylation(11), in DNase I footprinting to precisely determine the site(s)at which Spo0A binds within the skf promoter. C-Spo0A protecteda region extending approximately from bases –14 to –72on the nontemplate strand of the skf promoter (Fig. 3). Withinthis protected region it was apparent that there were siteswith different affinities. When the lowest amount of C-Spo0Awas added (12 nM), we observed protection from bases –20to –53 (Fig. 3, lane b), with base –19 showing hypersensitivityto cleavage that gradually diminished with increasing amountsof C-Spo0A. On the other hand, base –27 shows increasedhypersensitivity with increasing concentrations of C-Spo0A (Fig.3, lanes c to f). Examination of the sequence within this regionfor Spo0A binding sites identified a region centered at –28that is a perfect match to the consensus Spo0A binding site(5'-TGNCGAA-3') (box 1 in Fig. 1) and other sites partiallymatching the consensus Spo0A binding site (boxes 2 to 4 in Fig.1). Another DNase I-protected site was observed between bases–50 and –72 when we used higher concentrations ofC-Spo0A (Fig. 3, lanes d to f). Spo0A is thought to bind asa head-to-tail dimer (31), and therefore we denote 0A boxes1 and 2 as site 1 and boxes 3 and 4 as site 2. Site 1 is a higher-affinitysite than site 2, which was expected because it contained theperfect consensus 0A binding site. In addition to these sites,titration with C-Spo0A also showed protection and hypersensitivebands downstream from the start point of transcription. Theresults determined by Fujita et al. (9) suggest that high levelsof Spo0A act as a repressor for this promoter, perhaps by bindingto these downstream sites. Since binding to these sites wouldmean that the promoter is repressed at higher levels of Spo0A,and with our interest being in how the promoter is activated,we did not try to resolve all the binding sites beyond the startpoint of transcription. Examination of C-Spo0A binding by useof the same DNA fragment that had been end labeled on the templatestrand showed a similar pattern of protection where site 1 hadgreater affinity than site 2 and sites beyond the transcriptionalstart site had the lowest affinity (data not shown). Examinationof site 1 and site 2 in relationship to other conserved elementsof the promoter shows a poorly conserved –35-like elementcentered at positions –32 and –33, which lies betweenthe two 0A boxes of site 1 (Fig. 1). This places the highestaffinity 0A binding site downstream of this –35-like element.

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FIG. 3. DNase I protection assay analysis of the skf promoter with C-Spo0A. A ³²P-labeled nontemplate strand of skf promoter DNA was incubated with or without purified C-Spo0A (0 to 240 nM) and subjected to DNase I digestion for 1 min at 37°C (lanes a and g, probe with no C-Spo0A added; lanes b to f, probe incubated with increasing amounts of C-Spo0A as indicated at the top of each lane). The vertical line on the right of the footprint shows the region of protection seen with 12 nM concentrations of C-Spo0A. The sequencing products generated using the same labeled primer are loaded in lanes h to k, and the letters above indicate the terminating dideoxynucleotide used in the reaction. The Spo0A binding box is indicated to the right of the sequencing ladder, and the arrows indicate the orientation of the Spo0A boxes on the skf promoter relative to the Spo0A recognition sequence (5'-TGNCGAA-3').

Spo0A binding sites are required for skf promoter activity. To test whether the sequences bound by Spo0A are required forskf promoter activity, we examined the effects of base pairsubstitutions at the consensus Spo0A binding site. The wild-typeor mutant promoters were fused to a promoterless lacZ and integratedat the amyE chromosomal locus of a wild-type strain and in isogenicderivatives containing deletions of the spo0A and/or abrB locus.In a wild-type background, lacZ production under the controlof the skf promoter was minimal until the end of the exponential-growthphase (T₀) (Fig. 4A). After this point, the activity increasedsteadily until about T₂, declining slightly as the culture approachedT₄ (Fig. 4A). Production of lacZ in a ${Delta}$ abrB strain showed a higherbasal level of transcription as well as a slightly earlier activation( $~$ T_–_0.5). The activity in this strain was significantlyhigher than that seen in the wild-type background but reacheda peak at a similar time (T_2.5). Activity in the ${Delta}$ spo0A strainremained constant throughout the time course at a level similarto the basal level seen in the wild-type strain. We also observedthe activity of the fusion in a ${Delta}$ spo0A ${Delta}$ abrB strain (Fig. 4A).As in the ${Delta}$ spo0A background, the activity in this strain waslow; however, we did note that early activity (before T₀) wasgreater than late activity (after T₀.) All of these resultswere consistent with those previously reported by Fujita etal. (9).

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FIG. 4. Effects of mutations on skf promoter activity. ß-Galactosidase levels were measured in strains (wild type [ovals], ${Delta}$ abrB [rectangles], ${Delta}$ spo0A [triangles], and ${Delta}$ spo0A ${Delta}$ abrB [diamonds]) carrying a wild-type or mutant skf promoter fused to lacZ. In all panels, solid symbols denote the wild-type promoter and open symbols denote mutant promoters. (A) Activity of the wild-type skf promoter in the various strains. (B) Effect of the C-to-G base pair substitution at position –29. (C) Effects of –10 region mutations, the T-to-A substitution at position –9 (solid line, open circles), and the A-to-T substitution at position –11 (dashed line, open circles). (D) Effects of the double-base-pair substitution TG to CT at positions –15 and –14 in wild-type and ${Delta}$ abrB strains. (E) Spo0A independence conferred on the skf promoter by the base pair substitution of T to A at position –9. The data represent the averages of two points. Positive and negative controls were examined in every experiment.

Having confirmed the findings of Fujita et al. (9), we proceededto investigate the consensus Spo0A binding site centered atposition –28. We made base substitutions at positions–25, –27, and –29. The effects of these base-substitutedpromoter fusions were then examined in the ${Delta}$ spo0A, ${Delta}$ abrB, and ${Delta}$ spo0A ${Delta}$ abrB strains (Fig. 4B). All the base substitutions hada negative effect in the ${Delta}$ abrB strain, the most dramatic resultingfrom the –29 substitution, which reduced activity to basallevel. There was no noticeable activity in the ${Delta}$ spo0A or ${Delta}$ spo0A ${Delta}$ abrB strains (data not shown). This confirmed that binding tothe high-affinity site 1 was important for regulation of theskf promoter by Spo0A. We also created a truncated version ofthe promoter in which we deleted the site 2 binding sites (0Aboxes 3 and 4) (e.g., strain AKB407) and tested the activationof the promoter in ${Delta}$ spo0A, ${Delta}$ abrB, and ${Delta}$ spo0A ${Delta}$ abrB strains. No activityfrom the promoter was detected in any of the strains (data notshown), suggesting that both sites (site 1 and site 2) are neededfor optimal activation of the promoter by Spo0A.

Spo0A-dependent activation of the skf promoter requires an extended –10 region. The sequence centered 10 bp upstream from the putative startpoint of transcription identified by primer extension is identicalto the consensus –10 region at five of six positions (5'-TATTAT-3')found at promoters used by RNA polymerase containing the primarysigma factor ${sigma}$ ^A (15) (Fig. 1). We examined the effects of severalsingle-base-pair substitutions to test whether this sequenceis important for promoter activity. When examined in a wild-typestrain, base substitutions at positions –10 and –11resulted in a decrease in promoter activity (Fig. 4C and datanot shown). However, substitution of A for the T at position–9, which made the –10 sequence a perfect matchto the consensus sequence, resulted in a significant increasein promoter activity (Fig. 1 and 4C). These results are consistentwith the model that RNA polymerase containing ${sigma}$ ^A uses the skfpromoter.

The sequence at the –10 region of the promoter is alsosimilar to those of extended –10 region promoters, whichcontain a TRTGn motif (1, 5, 13, 26, 27). To determine whetherthis motif played a role in promoter activity we examined theeffect of a 2-bp substitution at positions –15 and –14(T to C and G to T, respectively). The activity for this promoterwas significantly reduced in both wild-type and abrB mutantstrains (Fig. 4D). These results show that the extended –10motif, as well as other base pairs in the –10 region,is required for Spo0A-dependent activation of this promoter.

We also noted that there was a second sequence, centered between–6 and –7, that was similar to a consensus –10sequence (nontemplate strand 5'-TATCGT-3'). The short distancebetween this region and the start of transcription led us tobelieve that it was unlikely to serve as the –10 sitefor the promoter. However, a double-base-pair substitution ofAA for the CG within this sequence, which makes it more consensus-like,resulted in slightly elevated promoter activity (Fig. 1 anddata not shown). Therefore, to further test the role of thispotential –10-like sequence we examined the effect ofa single-base-pair substitution at position –4, whichalters the most highly conserved position in the –10 consensussequence (15). If this sequence were acting as a –10 elementwe would expect that this change would reduce promoter activity.However, this substitution had no effect on promoter activity(data not shown).

A mutation in the skf promoter that results in Spo0A-independent activity. Extended –10 region promoters do not require extensivesimilarity to consensus at the –35 region for their activity(1, 5, 13, 26, 27). Therefore, it was unclear why the extended–10 region of the skf promoter was insufficient for promoteractivity in the absence of Spo0A and AbrB. The –10 regionof the skf promoter contains only a single nonconsensus basepair, located at position –9. As mentioned above, a basesubstitution conferring the consensus base to this positionresulted in an overall increase in activity in the wild-typestrain. We examined the effect of this base substitution in ${Delta}$ abrB and ${Delta}$ spo0A ${Delta}$ abrB strains and found that the substitutionconferred Spo0A-independent activity to the promoter (Fig. 4E).Moreover, primer extension analyses showed that the start pointof transcription from this promoter was identical to that ofthe wild-type promoter (data not shown). These results indicatethat, at least for the skf promoter, the base pair at position–9 is critical for transcription activity and that a nonconsensusbase pair at this position results in a promoter that requiresthe assistance of Spo0A despite the presence of an extended–10 motif.

DISCUSSION

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Discussion

Expression of the skf operon must be highly activated in responseto low levels of phosphorylated Spo0A (9); however, its expressionmust be tightly regulated to prevent premature expression ofthe killing factor. This tight regulation of a highly activepromoter involves two processes. The skf promoter is repressedby AbrB (9). Synthesis of AbrB is repressed by low levels ofphosphorylated Spo0A; therefore, the production of low levelsof Spo0A leads to reduced synthesis of AbrB and therefore derepressionof the skf promoter activity. However, even in an abrB mutantstrain, skf promoter activity also requires direct activationby Spo0A. The skf promoter contains high-affinity Spo0A bindingsites, two of which span the –35 region of the promoter.We found that these sites, in addition to the upstream sites,are required for the Spo0A-dependent promoter activation.

An unusual feature of the skf promoter is its extended –10region motif. Many promoters in Escherichia coli and B. subtiliscontain a conserved sequence motif at the upstream end of the–10 region, the so-called extended –10 motif, orthe TRTGn motif in B. subtilis (1, 5, 13, 26, 27). In E. colithis sequence can compensate for a weakly conserved –35region. We found that the base substitutions in the TG motiflocated at positions –15 and –14 greatly reducethe Spo0A-dependent promoter activity. Evidently, RNA polymeraserequires interaction with both Spo0A and the extended –10region sequence to utilize the skf promoter efficiently. Becausethe extended –10 region plays a role in skf promoter activity,and because promoters containing extended –10 region sequencesare thought to not require sequences at their –35 regionsthat are highly similar to the consensus –35 sequence,it seemed surprising that Spo0A was required for skf promoteractivity even in the absence of AbrB repression. We found thata single-base-pair substitution at position –9 that produceda perfect match to a consensus –10 region yielded a promoterthat no longer required Spo0A for its activation. Therefore,the specific base pair at position –9 of the promotermakes skf promoter activity directly dependent on Spo0A binding,and the extended –10 region motif of the promoter contributesto its high level of activity.

The best-understood mechanism of promoter activation by Spo0Ais the activation of the high-threshold, ${sigma}$ ^A-dependent spoIIGpromoter (4, 12, 19-21, 23). In this promoter, sequences similarto the –10 and –35 hexamers, which signal recognitionof promoters by ${sigma}$ ^A-RNA polymerase, are separated by 22 bp, adistance that is ordinarily considered too great for productiveinteraction of these sequences with ${sigma}$ ^A (15). At this promoter,the consensus –35-like promoter element is centered betweenpositions –37 and –36 and is overlapped by a Spo0Abinding site (20). Based on molecular modeling and genetic assays,it has been proposed that binding of Spo0A $~$ P occludes bindingof ${sigma}$ ^A region 4 to the consensus –35-like sequence and interactionbetween Spo0A and ${sigma}$ ^A positions in region 4 of ${sigma}$ ^A 18 bp upstreamfrom the –10 region of the spoIIG promoter (12). Thispositioning of ${sigma}$ ^A allows region 2 of ${sigma}$ ^A to interact productivelywith the –10 region of the spoIIG promoter, thus stimulatingits activity. It is likely that Spo0A activates some other ${sigma}$ ^A-dependentpromoters (e.g., spoIIE and yneE) by a similar mechanism, becausethey are similar to spoIIG in that their –35-like sequencesare separated from the –10 region by 21 bp (reference30 and unpublished data). Moreover, their –35-like sequencesoverlap a Spo0A binding site (reference 30 and unpublished data).However, in contrast to these promoters the skf promoter doesnot have a consensus –35 sequence at or upstream fromits –35 region, and the positions of Spo0A binding sitesrelative to the start point of transcription for the skf promoterdiffer from the spoIIG-like promoter sites. Therefore, activationof the skf promoter by Spo0A may involve novel interactionsbetween Spo0A and RNA polymerase.

ACKNOWLEDGMENTS

We gratefully acknowledge Rich Losick and Gordon Churchwardfor their suggestions on the work.

The work was supported by Public Health Services grant GM54395from the National Institute of General Medical Sciences.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology, Emory University School of Medicine, Atlanta, GA 30322. Phone: (404) 727-5969. Fax: (404) 727-3659. E-mail: moran{at}microbio.emory.edu.

G.C., A.K., and T.H.W. contributed equally to this work.

REFERENCES

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