Transcription of the nfrA-ywcH Operon from Bacillus subtilis Is Specifically Induced in Response to Heat

doi:10.1128/JB.182.16.4384-4393.2000

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Journal of Bacteriology, August 2000, p. 4384-4393, Vol. 182, No. 16
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Transcription of the nfrA-ywcH Operon from Bacillus subtilis Is Specifically Induced in Response to Heat

Christine Moch, Oliver Schrögel, and Rudolf Allmansberger^*

Lehrstuhl für Mikrobiologie, Universität Erlangen-Nürnberg, D-91058 Erlangen, Germany

Received 3 February 2000/Accepted 17 May 2000

	ABSTRACT

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The NfrA protein, an oxidoreductase from the soil bacterium Bacillus subtilis, is synthesized during the stationary phaseand in response to heat. Analysis of promoter mutants revealedthat the nfrA gene belongs to the class III heat shock genes inB. subtilis. An approximate 10-fold induction at both the transcriptionaland the translational levels was found after thermal upshock.This induction resulted from enhanced synthesis of mRNA. Geneticand Northern blot analyses revealed that nfrA and the gene downstreamof nfrA are transcribed as a bicistronic transcriptional unit.The unstable full-length transcript is processed into two shorttranscripts encoding nfrA and ywcH. The nfrA-ywcH operon is notinduced by salt stress or by ethanol. According to previouslypublished data, the transcription of class III genes in generalis activated in response to the addition of these stressors. However,this conclusion is based on experiments which lacked a valid control.Therefore, it seems possible that the transcription of all classIII genes is specifically induced by heatshock.

	INTRODUCTION

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The continuous demand of Bacillus subtilis to adapt to ever-changing conditions in its natural environment has forced thegeneration of complex regulatory mechanisms governing the transcriptionof stress-specific proteins. Stress-inducible genes from B. subtilisin general are subdivided into three groups (17, 18). ClassI genes are specifically induced by heat stress (17). The well-knownchaperonins GroEL, GroES, DnaK, DnaJ, and GrpE are encoded bygenes belonging to this group (30, 41, 48, 54, 55).The transcription of the respective genes is regulated by HrcA,a transcription repressor which binds to the CIRCE element (43,56, 57, 59). Genes transcribed in a $sigma$ ^B-dependent manner constitute class II stress-responsive genes(17, 18). $sigma$ ^B activity is triggered by different kinds of stress and by starvation(5, 7-9). Members of the last group of stress-induced genes,class III, are induced not by starvation but by several differentstressful conditions. The transcription of class III genes isneither repressed by HrcA nor solely dependent on $sigma$ ^B. The regulator of the clpC operon, which encodes class III proteins,is known (11, 27). This operon is transcribed by the activityof RNA polymerases containing $sigma$ ^B and $sigma$ ^A (28). Nevertheless, transcription is not induced at the onsetof the stationary phase (28), likely because of the activityof this regulator (11, 27).

Some of the stress-responsive proteins are regulated by two transcription factors. clpC, dps, trxA, opuE, and clpP (1,4, 15, 29, 40, 46) are transcribed by RNA polymerasecontaining either $sigma$ ^A or $sigma$ ^B. csbB is under the additional control of $sigma$ ^X (22). The csb40 operon (50) and the yvyD gene (13) aretranscribed from $sigma$ ^B and $sigma$ ^H promoters, respectively. This genetic organization enables thebacterial cell to modulate the regulation of the respective genesin response to additionalchallenges.

In this communication, we describe the transcriptional regulation of the nfrA-ywcH operon encoding an oxidoreductase (34,58) and a putative monooxygenase. It has been shown that nfrAtranscription is induced in a $sigma$ ^D-dependent manner at the onset of the stationary phase (34).nfrA transcription is also induced by heat stress from a $sigma$ ^A-dependent promoter overlapping the $sigma$ ^D promoter. The $-$ 35 region and the region upstream of the promoterare necessary for this regulation. Ethanol stress and salt stressdo not induce nfrA transcription. We discuss the unusual inductionpattern of thispromoter.

	MATERIALS AND METHODS

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Bacterial strains and plasmids. The bacterial strains and plasmids used throughout this study are listed in Table 1. To construct pB49, the relevant partof the nfrA promoter region was amplified by PCR. Two primersthat are partially identical to sequences of the intergenic region(ipa43P_up: 5'-GTGCAGAGAATTCCACTTTTGAGATCAC-3'; ipa43P_down: 5'-CACAAAAACCTCCTGATCACTTTTTATC-3')were used to amplify the promoter region. The PCR product wasdigested with EcoRI and cloned into EcoRI- and SnaBI-digestedpDL (57). The sequences of the resulting fragment and all otherfragments obtained by PCR were verified by DNA sequencing.

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TABLE 1. Strains and plasmids used in this study

Mutations in the nfrA promoter region were obtained by PCR mutagenesis. To this end, the promoter region present in plasmidpDIPA4 was amplified in a reaction buffer containing manganeseand a reduced amount of nucleotides (10) with the primers pDL(5'-GGGTAACTATTGCCGATGATAAGC-3') and IPA43P (5'-GATTGTGTTATTGATCACAAAAACC-3').The products were digested with EcoRI and SnaBI and ligated toplasmid pDL (57) hydrolyzed with the same enzymes. On average,2 out of 100 nucleotides were mutated (data not shown). Portionsof the P_xylA-P_nfrA hybrids were constructedby hybridizing two oligonucleotides with each other and Klenowfilling in the protrudingends.

To obtain pDXYL10, pDXYL1035, and pDXYL35, respectively, the oligonucleotides $-$ 10EcoRI (5'-CATGAGAATTCGAAAAACTAAAAAAAATATTGAAAATACTGTTTTTTTCGGATATG-3')and $-$ 10SnaBI (5'-GTATCACTTTTTATCATATCCGAAAAAAACAG-3'), $-$ 10/35EcoRI(5'-CATGAGAATTCGAAAAACTAAAATCACTTTTGAGATCACTTTTTTTCGG-3') and $-$ 10/35SnaBI (5'-GTATCACTTTTTATCATATCCGAAAAAAAGTGATCTCAAAAGTG-3'),and $-$ 35EcoRI (5'-CATGAGAATTCGAAAAACTAAAATCACTTTTGAGATCACTTTTGAGG-3')and $-$ 35SnaBI (5'-GTACTTATTTTAATCTTAAATAACCTCAAAAGTGATCTCAAAAGT-3')were used. Double-stranded DNA was digested with EcoRI and ligatedto EcoRI-SnaBI-digested plasmid pDL. Plasmids pDXYL10 $Delta$ 2 and pDXYL35 $Delta$ 2were constructed by amplifying the inserts of pDXYL10 and pDXYL35with the primers pDL and DXYL10 $Delta$ 2 (5'-GTATCACTTTTTATCATATCCGAAAAAAAGTATT-3')and the primers pDL and DXYL35 $Delta$ 2 (5'-GTACTTATTTTAATCTTAAATAACCAAAAGTGATCTC-3'),respectively. The products were digested with EcoRI and ligatedto EcoRI-SnaBI-digested plasmid pDL. Plasmid pDXYL was constructedby amplifying the xylA promoter region with the primers xyl_up(5'-GAAAAACTAAAAAAAATATTGAAAATAC-3') and xyl_down (5'-GTACTTATTTTAATCTTAAATAACCTCATC-3').The fragment was ligated to SnaBI-digested plasmidpDL.

Plasmids pIPA8 and pIPA14 were obtained by cloning the 1.5-kbp NciI fragment or the 1-kbp AflIII fragment, respectively, intothe SmaI-digested pIC20H (31). The NciI fragment encodes nfrA,and the AflIII fragment encodes the intergenic region betweennfrA and ywcH and the 5' part of ywcH. pIPA43 was constructedby amplifying the 5' end of nfrA. pIPA44 was obtained by amplifyingthe 3' end of nfrA, the intergenic region, and the 5' end of ywcH.Internal sequences of nfrA were amplified with the primers SDIPA-Eco(5'-ACGAATTCTAAGGAGGTTTTTGTGATGAAT-3'; identical to positions3911038 to 3911017 in reference 36) and IPA62-Sac (5'-TAATCCGCGGACAGCTCACGTTTTTTC-3';identical to positions 3910834 to 3910858 in reference 36).The fragment used to clone pIPA44 was constructed by amplifyingchromosomal DNA with the primers YWCH7 (5'-GGGGATCAGGAATTCGATGAGGATGAGG-3';identical to positions 3910135 to 3910123 in reference 36) andYWCH8 (5'-AGCACTGTACCGCGGCAGCATGACTCC-3'; identical to positions3930848 to 3909874 in reference 36). Both products of amplificationwere digested with EcoRI and SacII and cloned into pMUTIN2 (49)digested with the same enzymes. Plasmid pIPA44E was constructedby amplifying chromosomal DNA with the primers YWCH5 (5'-TTCGGAATGAATTCGACAAGGTG-3';identical to positions 3910610 to 3910588 in reference 36) andYWCH6 (5'-TCCCTACCACGGATCCTCATCGTA-3'; identical to positions3910099 to 3910123 in reference 36). The fragment was digestedwith EcoRI and BamHI and ligated to plasmid pDH32M (24) hydrolyzedwith the same enzymes. Plasmid pDIPA44 was constructed by hydrolyzingpIPA6 (34) with XhoI. The 1,275-bp fragment encoding the 3'end of nfrA, the intergenic region, and the 5' end of ywcH wascloned into XhoI-hydrolyzed pKL4 (42).

RNA analysis. Cells were grown as described below. RNA was isolated using an RNeasy kit (Qiagen, Hilden, Germany) according to the manufacturer'sinstructions. To obtain a probe for the S1 nuclease assay, wehydrolyzed plasmid pIPA8 with NcoI and labeled it with [ $alpha$ -³²P]dATP. The radioactive fragment was digested with NruI, and a912-bp fragment was isolated. S1 nuclease analysis was performedas described elsewhere (37) using limiting amounts of nuclease.Northern blotting was done as described previously (2). Equalamounts of RNA were loaded in each lane. As a probe, we used either(i) an internal fragment of nfrA obtained by PCR amplificationwith plasmid pIPA11 (34) as a template and the primers "primerI" and "primer II" described previously (34) or (ii) an internalfragment of ywcH created by amplification of the plasmid pIPA14insert with the universal and reverse primers (Pharmacia, Freiburg,Germany). To determine the sizes of the respective fragments,the signals were compared with the RNA size marker of United StatesBiochemicals (Bad Homburg, Germany). All experiments were reproducedat leastonce.

General methods. Unless indicated otherwise, bacteria were grown at 37°C. Nutrient broth (NB) (Oxoid, Basingstoke, United Kingdom) was usedas a growth medium for B. subtilis, and Luria broth (39) wasused for Escherichia coli. $beta$ -Galactosidase assays were performedas described previously (42). Activity is reported in Millerunits (33). Each experiment was reproduced at least three timeswith independent transformants. Only the results of a single experimentare presented. Standard methods were carried out as describedpreviously (39). Western blot analysis was done as describedpreviously (34). Equal amounts of protein were loaded in eachlane.

	RESULTS

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nfrA transcription is induced specifically by heat. While screening for salt stress-induced genes, we isolated the nfrA gene (data not shown). We wanted to test whether NfrAis a general stress protein or is induced by specific kinds ofstress. To do so, we created a fusion of P_nfrA to bgaB,encoding a $beta$ -galactosidase which is not degraded in response tostress (42, 57). The resulting plasmid was integrated intothe B. subtilis 168 chromosome to yield B. subtilis DIPA4 (34).This strain was grown to the early mid-log phase in NB. Stresswas applied either by shifting part of the culture to 49°C orby adding ethanol or NaCl to a final concentration of 5% or 0.5M, respectively. P_nfrA-dependent BgaB activity was inducedabout 10-fold by heat shock, but no significant induction wasobtained with ethanol or salt (Fig. 1A). Identical results wereobtained using MOPSO minimal medium (26) with succinate as aC source (data not shown). Our original test for salt stress inductionwas based on direct quantification of mRNA as described previously(29). Obviously, the results obtained with gene fusions differedfrom these original data. This difference is discussed below.

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FIG. 1. (A) Induction of P_nfrA by different kinds of stress. $beta$ -Galactosidase ( $beta$ -gal) expression in response to different stressors was determined. $beta$ -Galactosidase activity was plotted versus time. Filled bars, control at 37°C; empty bars, heat-shocked cells; shaded bars, salt-stressed cells; hatched bars, cells grown in the presence of 5% ethanol. Samples were collected at different times after stress was applied. All experiments were done in triplicate. (B) Influence of temperature on the heat shock response. Cells were grown at 37°C before an aliquot was shifted to a new temperature. Samples were collected at different times after stress was applied. $beta$ -Galactosidase activity was plotted versus time. Filled circles, control at 37°C; empty circles, 45°C; squares, 47°C; triangles, 49°C; inverted triangles, 51°C; diamonds, 53°C; hexagons, 55°C. (C) Western blot analysis of NfrA synthesis. Equal amounts of cell extracts were subjected to Western blot analysis. Samples were taken from stressed and unstressed cells at different times after stress was applied.

To analyze the heat induction in more detail, we grew B. subtilis DIPA4 in NB and induced heat shock by incubating part ofthe culture at an elevated temperature. Samples were removed atshort intervals, and P_nfrA-dependent $beta$ -galactosidaseactivity was determined. The patterns of induction of promoteractivity were similar at all temperatures up to 51°C, but themaximal activity was modulated in response to the severity ofthe heat shock. At temperatures higher than 51°C, induction wasabolished (Fig. 1B).

The transcriptional start site of the nfrA transcript was mapped for unstressed cells (34). The same experiment was performedwith RNA isolated from stressed cells. The start site of the transcriptdid not change after thermal upshock (data notshown).

To test whether the induction of transcription results in an elevated level of NfrA protein, we grew B. subtilis 168 to theearly exponential phase and applied heat shock. Crude proteinwas isolated. Western blot analysis revealed that the amount ofNfrA was increased severalfold in response to the shock (Fig.1C).

The heat response of nfrA is mediated at the transcriptional level. To test whether the increase in P_nfrA-dependent $beta$ -galactosidase activity in response to heat shock is in fact dueto an induction of P_nfrA activity, we directly determinedthe amount of the nfrA transcript. B. subtilis DIPA4 was grownto the early log phase at 37°C and then shifted to 50°C. Cellswere harvested before and at intervals after stress was applied.RNA was isolated, and equal amounts of RNA were used for Northernblot analysis. As shown in Fig. 2A two bands were obtained witha nfrA-specific probe. The first one was 0.8 kb, and the secondone was 2.0 kb. Within the first 9 min after heat shock, the intensitiesof both bands increased about 10-fold. This result is in accordancewith the results obtained with the P_nfrA-bgaB fusion.The amount of specific mRNA started to decline 15 min after heatshock was applied. The addition of NaCl or ethanol had no significanteffect on the nfrA mRNA amount (data not shown). In addition,we tested the effects of puromycin addition on P_nfrAactivity. B. subtilis DIPA4 was grown to an optical density at600 nm (OD₆₀₀) of 0.2, puromycin was added to a final concentrationof 20 µg/ml, and samples were removed at intervals. RNA was isolatedand used for analysis. There was a steady increase in the nfrAmRNA amount (Fig. 2B).

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FIG. 2. Northern blot analysis of nfrA transcription. Heat stress was applied. At the indicated times, cells were harvested and RNA was isolated. Equal amounts of RNA were used for the analysis. The positions of the 23S and 16S rRNAs are indicated. (A) RNA from heat-shocked cells. Time after heat shock and growth temperature are indicated. Different bands of 0.8 and 2 kb are visible. (B) RNA from puromycin-treated cells. Puromycin (20 µg/ml) (+) was added to the cell suspension; $-$ , no puromycin. Cells were harvested at the indicated times, and RNA was isolated.

Degradation of the nfrA transcript is influenced by heat shock. The amount of mRNA is influenced by two different parameters, the rate of RNA synthesis and the rate of RNA decay. Therefore,we wanted to test whether the stability of the nfrA mRNA is influencedby heat shock. We grew B. subtilis DIPA4 to an OD₆₀₀ of 0.25 andsubjected part of the culture to heat shock; the rest was allowedto grow at 37°C. Rifampin (10-µg/ml final concentration) was addedto both suspensions 5 min after heat stress was applied. Sampleswere removed at intervals, and RNA was isolated. Northern blotanalysis of both the stressed and the unstressed samples revealedthat there was a modest influence of heat shock on the half-lifeof the nfrA mRNA. To determine this influence, the data were analyzedusing the regression function of the SigmaPlot program (SPSS Inc.,Chicago, Ill.). The half-life of the 0.8-kb mRNA at 37°C was about4 min and the half-life at 50°C was about 2 min (Fig. 3). We werenot able to exactly determine the half-life of the 2.0-kb mRNAbecause this mRNA vanished immediately after the addition of rifampin.Therefore, we conclude that the half-life of this mRNA was lessthan 1 min.

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FIG. 3. Decay of nfrA mRNA before and after heat shock. RNA was isolated at different times after stress was applied. (A) Decay of the nfrA mRNA at 37°C. (B) Decay of the nfrA mRNA at 50°C. (C) Decay curves for the nfrA mRNAs at 37°C (empty circles) and 50°C (filled circles). The amount of RNA at time zero was set to 1 for both graphs. Times after the addition of rifampin are given.

Mutations in the putative $sigma$ ^A promoter influence P_nfrA activity. Besides a putative $sigma$ ^A consensus sequence, the region upstream of the mRNA 5' end includes sequences with homology to the $sigma$ ^B and $sigma$ ^D consensus sequences. Transcription of nfrA during the stationaryphase is $sigma$ ^D dependent (34). To test which sigma factor is responsible forthe heat shock induction of nfrA, we modified the sequence ofthe promoter region cloned into pDIPA4. First, we constructedpB49, a derivative of the promoter without the region upstreamof the $-$ 35 region. The BgaB activity of the resulting B. subtilisstrain, B49, was decreased; induction by heat shock was also reducedbut was not abolished. These results indicate that the upstreamregion is necessary for full promoter activity and for some ofthe regulation. Therefore, we decided to modify the sequence ofpDIPA4 (34) by nonspecific PCR mutagenesis (10).

Plasmids were isolated and sequenced, and mutant plasmids were integrated into the B. subtilis 168 chromosome. The activitiesof different promoter variants are depicted in Fig. 4. Most mutationshad only a modest influence on promoter activity. Only two positionsof the proposed nfrA promoter deviated from the $sigma$ ^A consensus sequence. All mutations which caused a complete lossof promoter activity were either mutations within the $-$ 10 or $-$ 35region of the putative $sigma$ ^A promoter or deletions in the spacer between both regions. A mutationupstream of the $-$ 35 region, C-43A, also had a severe negativeeffect on promoter activity. Mutations within the long poly(dT)blocks in the spacer between the $-$ 10 and $-$ 35 regions or the blockoverlapping the $-$ 35 region caused a 3- to 10-fold reduction inpromoter activity. The same was true for two additional mutationsupstream of the $-$ 35 region, T-40C and G-44T, respectively. Thirteenout of 41 mutations had only a slight effect on promoter activity.Two mutations within the putative $-$ 35 region, T-32C and G-31A,had no effect or caused even a slight increase in promoter activity.One point mutation resulted in elevated promoter activity. Thismutation, G-15T, lies within the $-$ 16 region, a sequence whichenhances the activity of several $sigma$ ^A promoters (19, 47). All promoter derivatives with significantactivity during exponential growth were induced in response toheat shock.

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FIG. 4. Sequence of the P_nfrA promoter region. The putative $-$ 10, $-$ 16, and $-$ 35 regions are indicated by gray backgrounds. The $sigma$ ^D promoter (34) is indicated by boxes. Only the effects of single mutations within this region are shown. Mutations resulting in elevated promoter activity are shown above the wild-type sequence; mutations resulting in reduced transcriptional activity are shown below. M, A or C; S, G or C; K, G or T; V, A, G, or C.

Additionally, we created B. subtilis DIPA4 derivatives harboring mutations in genes encoding putative sigma factors (36)or known regulators of stress-responsive genes (11, 27, 43,56). We inactivated sigB, sigD, sigM, sigV, sigW, sigX, sigY,sigZ, ylaC, ykoZ, hrcA, and ctsR. None of these mutations hadan effect on the heat shock induction of P_nfrA (datanotshown).

The $-$ 35 and upstream regions are important for heat induction. We were unable to find mutations which specifically abolished the heat shock induction of P_nfrA. Our assumption wasthat the DNA sequences responsible for promoter activity and regulationoverlap each other. Therefore, we created derivatives of the nfrApromoter by exchanging parts of this promoter with homologousparts of the B. subtilis xylA promoter (14). As described above,the upstream region influences promoter activity and heat shockinduction. The sequence upstream of P_xylA, which is necessaryfor the full activity of this promoter (25), had no positiveeffect on the nfrA promoter (Fig. 5). The hybrid promoter wasstill induced by heat shock, albeit at a reduced level. The samewas true for all promoter derivatives containing the $-$ 35 regionof the nfrA promoter. The $-$ 10 region of P_nfrA was insufficientfor heat shock induction.

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FIG. 5. Regulation of P_nfrA-P_xylA hybrids. The sequences of the respective promoter variants are shown. Sequences derived from P_xylA are shown by a shaded background. The promoters were cloned into plasmid pDL; the resulting plasmids were integrated into the amyE gene of B. subtilis 168 to give the respective B. subtilis strains. BgaB activity was determined with cell extracts from unstressed and heat-shocked cells. The induction ratios are shown at the right. The predicted transcriptional start points of the respective RNAs are indicated by bold letters. The uninduced activities (in Miller units) of the respective promoter derivatives were as follows: DIPA4, 3 ± 0.5 U; B49, 1 ± 0.1 U; DXyl1035, 0.6 ± 0.1 U; DXyl10, 62 ± 6; DXyl35, 0.6 ± 0.2 U; DXyl10 $Delta$ 2, 1 ± 0.1 U; DXyl35 $Delta$ 2, 0.5 ± 0.1 U; and DXyl, 62 ± 7 U. The activity of the control, B. subtilis DL, was 0.2 ± 0.1 U (not shown).

nfrA and ywcH are transcribed as an operon. NfrA is a flavin mononucleotide-containing oxidoreductase (34). The gene downstream of nfrA, ywcH, bears homology with amonooxygenase gene. Therefore, it seemed possible that NfrA isthe electron donor for YwcH. However, the two genes are separatedby an intergenic region of 177 bp containing a sequence proposedto be a transcriptional terminator (36). In order to determinewhether the regulation of transcription of ywcH and nfrA is similar,we created two plasmids, pIPA44E and pIPA44, by cloning the regionencoding the C-terminal part of NfrA, the intergenic region betweennfrA and ywcH, and the region encoding the N-terminal part ofYwcH into plasmids pDH32M (24) and pMUTIN2 (49), respectively.As a control, we created plasmid pIPA43 by cloning the regionencoding the 5' end of nfrA into plasmid pMUTIN2. pIPA44E wasintegrated into the amyE gene of B. subtilis 168, whereas pIPA43and pIPA44 were integrated into the nfrA and ywcH genes of B.subtilis 168. Therefore, in B. subtilis IPA44E, $beta$ -galactosidasesynthesis is controlled by promoters encoded by the fragment clonedinto pDH32M, whereas in B. subtilis IPA43 and B. subtilis IPA44, $beta$ -galactosidase expression is controlled by all promoters withinor upstream from the cloned fragment. The strains were grown inNB supplemented with glucose and glutamate. As described previously(34), the P_nfrA-dependent $beta$ -galactosidase activityof B. subtilis IPA43 commenced at the onset of the stationaryphase (Fig. 6A). The same regulatory pattern was obtained forB. subtilis IPA44, but the activity was fourfold lower. We werenot able to detect $beta$ -galactosidase activity above the backgroundin B. subtilis IPA44E.

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FIG. 6. Comparison of nfrA and ywcH induction. (A) Induction of transcriptional fusions of lacZ to the respective gene during growth in NB supplemented with glucose and glutamate. Filled circles, growth of B. subtilis IPA43, given as OD₆₀₀ units; open circles, $beta$ -galactosidase ( $beta$ -gal) activity of B. subtilis IPA43 (nfrA-lacZ fusion in nfrA); squares, $beta$ -galactosidase activity of B. subtilis IPA44 (ywcH-lacZ fusion in ywcH); inverted triangles, $beta$ -galactosidase activity of B. subtilis IPA44E (ywcH-lacZ fusion in amyE); triangles, $beta$ -galactosidase activity of B. subtilis DH32M (control). (B) Heat shock induction of nfrA and ywcH. Filled symbols, activity in cells grown at 37°C; empty symbols, activity of stressed cells; circles, B. subtilis DIPA4 (nfrA-bgaB); squares, B. subtilis DIPA44 (ywcH-bgaB).

To investigate whether ywcH transcription is induced in response to heat shock, we created plasmid pDIPA44 by cloning the1,275-bp XhoI fragment encoding the 3' end of nfrA, the intergenicregion, and the 5' end of ywcH (36) into plasmid pKL4 (42).The plasmid was integrated into the B. subtilis 168 chromosome.Heat shock induction was determined as described above. BgaB activitywas induced, but the activity was fivefold lower than the activityin B. subtilis DIPA4 (Fig. 6B).

With these results taken together, we were able to prove that the promoter driving $beta$ -galactosidase expression in B. subtilisIPA44 was not within the intergenic region between nfrA and ywcHbut was upstream of the proposed transcriptional terminator. nfrAand ywcH were transcribed as a transcriptionunit.

The nfrA-ywcH mRNA is processed after transcription. The results described above indicate that nfrA and ywcH are transcribed from a single promoter. We isolated RNA from exponentiallygrowing B. subtilis 168, from stationary-phase cells grown inNB supplemented with glucose and glutamate (34), and from cellssubjected to heat shock. Northern blot analysis was carried outusing a ywcH-specific probe. The result of the experiment is shownin Fig. 7A. Two bands were obtained $---$ a dominant band of 1.2 kband a weaker band of 2.0 kb. Both heat shock and stationary phaseresulted in an increase in the ywcH-specific RNA amount. The lengthof the shorter transcript corresponded to the length of the ywcHgene. Therefore, we assumed that the transcript starts in frontof the ywcH gene, although we were unable to map promoter activityin that region. To test this notion, we performed a primer extensionexperiment. Depending on the conditions used to grow the bacteria,two different mRNA 5' ends were mapped (Fig. 7B). mRNA isolatedfrom heat-shocked bacteria started 11 bases in front of the ywcHgene; mRNA isolated from unstressed bacteria started 25 basesdownstream of the putative translational start codon. Additionally,we mapped the 3' end of the nfrA mRNA by S1 nuclease analysis.The 3' part of the probe used for this experiment is complementaryto the B. subtilis chromosome, whereas the 5' end is unable tohybridize to any mRNA from B. subtilis. Therefore, we were ableto detect transcripts terminating within the intergenic regionand transcripts overlapping the entire intergenic region. We obtaineda dominant signal just downstream of the stem-loop structure anda second, eightfold-weaker signal corresponding to the end ofthe homologous part of the probe (Fig. 7C).

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FIG. 7. (A) Northern blot analysis of ywcH transcription. RNA was isolated from cells before (37°C) and after (50°C) heat shock or during the exponential (OD₆₀₀ = 0.2) and stationary (OD₆₀₀ = 1.4) growth phases. Equal amounts of RNA were used for the analysis. The positions of the 23S and 16S rRNAs are indicated. Two bands specifically hybridizing to a ywcH probe were obtained. (B) Mapping of the ywcH 5' end. RNA was isolated from B. subtilis 168 grown at the indicated temperatures. The sequence ladder used as a size marker was obtained by using the same primer as that used for the primer extension reaction. The putative start codon of translation is indicated (TAC). Whereas the 5' end of the RNA is upstream from the putative translational start codon in heat-shocked cells, it is downstream from this codon in unstressed cells (arrows at left). (C) S1 nuclease mapping of the 3' end of nfrA. RNA was isolated from cells before (37°C) and after (50°C) heat shock or from stationary-phase cells grown in NB or NB with glucose and glutamate (GG). Equal amounts of RNA were used for the analysis. Restriction fragments of known lengths and a sequence ladder of a known sequence were used as size markers. Four different signals were obtained in the S1 nuclease reaction. The 912-base fragment was derived from an unprocessed probe. The 875-base fragment (large filled arrow) was obtained by S1 nuclease processing of a probe hybridized to an unprocessed nfrA-ywcH transcript. The 397-base fragment (hatched arrow) was processed at the 5' end of the stem-loop structure. The 378-base fragment (empty arrow) was processed at the single mismatch within the stem-loop structure. (D) Graphic illustration of the results obtained by S1 nuclease mapping and primer extension. The labeling of the arrows is like that in panel C. The 875-base fragment is not due to RNA processing but is specific for the strategy of the experiment. It indicates that readthrough occurs.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

nfrA and ywcH are transcribed as an operon. nfrA and ywcH are separated by a sequence generally used as a terminator (36). To our surprise, nfrA and ywcH neverthelessconstitute an operon. The stem-loop structure may neverthelessserve as a terminator. The activity of the transcriptional fusionsof ywcH to bgaB and lacZ was four- to fivefold lower than thatof the respective nfrA fusions. The existence of a putative terminatorwithin an operon was also described for the heat shock-induceddnaK operon (20, 55). We do not know whether the unusual organizationof both operons serves a specific purpose. In Agrobacterium tumefaciens,the mRNA encoding the genes groES and groEL is specifically cleavedbetween the two genes in response to heat shock, and two monocistronicmRNAs are formed. The polycistronic mRNA is the major mRNA ata low temperature (45). This situation allows differential expressionof the two proteins under stress and nonstress conditions. Theprocessing of the full-length nfrA-ywcH transcript produces twodifferent 5' ends. This finding indicates the existence of additionaltranslational control of YwcHsynthesis.

Characterization of P_nfrA. The genes induced in response to different kinds of stress have been subdivided into three groups (17, 18). Until now,no detailed promoter analysis has been undertaken for class IIIgenes. Based on sequence similarities of the regions upstreamof the mapped 5' ends of the respective mRNAs to the consensussequence, it was proposed that these genes are transcribed by $sigma$ ^A-containing RNA polymerase. Recently, a new group of genes importantfor survival at high temperatures was described (21, 22).These genes are preceded by promoters recognized by the alternativesigma factor $sigma$ ^X. nfrA transcription is specifically induced by heat. Inactivationof genes encoding putative sigma factors had no effect on theheat induction of nfrA transcription. Additionally, we mutagenizedthe promoter region. All mutations causing a complete loss ofpromoter activity resided within the important parts of the putative $sigma$ ^A promoter. Two mutations with strongly increased activity wereobtained. Both exchanges resulted in promoter derivatives fittingthe $sigma$ ^A consensus sequence better than the wild type does. Two mutations,T-32C and G-31A, do not fit into the emerging picture. Both aremutations in the putative $-$ 35 region but have no negative effecton promoter activity. Therefore, we think that it was not possibleto prove unambiguously that P_nfrA is used in a $sigma$ ^A-dependentmanner.

P_nfrA regulation is not dependent on known regulators (11, 27, 43, 56) of stress-responsive genes. It isinduced by the addition of puromycin. According to the definitionof class III genes (17, 18), nfrA and ywcH belong to thisgroup of stress-responsive genes. Only recently was the creationof a new class of stress-responsive genes proposed (11). Geneswhose transcription is regulated by a novel regulator of the stressand heat shock response, CtsR, constitute class III genes accordingto this classification. According to this new definition, nfrAand ywcH are class IV stress-responsivegenes.

nfrA-ywcH transcription is specifically induced by heat. Originally, the nfrA gene was isolated when we screened for salt stress-induced genes (O. Krispin, E. Gaul, and R. Allmansberger,unpublished data). The screen was based on direct quantificationof mRNA amounts using the xynA mRNA (12, 29, 52) as a control.The unambiguous result of this experiment was that the amountof the nfrA transcript is increased in response to salt stress.To our surprise, we were unable to reproduce the results obtainedby RNA dot blotting with a P_nfrA-bgaB fusion. It turnedout that, in contrast to a statement made previously (29), theamount of the xynA transcript is severely influenced by differentkinds of stress (2). The alleged increase in nfrA mRNA wasin fact a reduction of the amount of thecontrol.

Because it is not possible to use the LacZ protein to determine heat shock induction in B. subtilis (5), a considerableamount of data concerning the stress response in B. subtilis hasbeen collected using RNA dot blots as a method to quantify theinduction of the respective genes. The control used for the firstset of these experiments (12, 29, 51) is obviously invalid(2; O. Krispin and R. Allmansberger, unpublished data). Therefore,it is very likely that the interpretation of the data presentedin the mentioned publications was incorrect (see below). It isindubitable that there was a relative increase in the synthesisof the respective proteins, because most of the genes were identifiedby sequencing of proteins whose synthesis increased in responseto different kinds of stress (6, 51). However, an increasein the relative synthesis of a protein does not prove that transcriptionof the encoding gene is induced. For example, the same resultis obtained when stress conditions reduce the translation of mostother genes. The few proteins with unchanged translational efficiencywould cause stronger signals on two-dimensional gels. This generaleffect seems possible because stress obviously reduces the mRNAstability of some genes whose stability is not influenced by specificstructures (2, 57). In contrast, the half-lives of mRNAsencoding stress-induced genes are almost unaltered in responseto stress (23, 57).

In response to the finding that the amount of xynA mRNA is severely influenced by stress, this control was not used any longer.Instead, mRNA quantifications were performed without an internalcontrol (3, 5, 12, 32, 38, 40). RNA dot blottingis a multistep experiment. For example, it is a difficult taskto obtain RNA preparations of identical quality. Therefore, weconsider a valid internal control to be a prerequisite for accuratequantifications of RNA amounts, an opinion which is supportedby the fact that the same authors who indicated that clpC transcriptionis induced by salt stress (29) reported in a recent publicationthat the regulator of clpC transcription is not induced by saltstress (27). The induction of all class III general stress proteinsactivated by several stressors was determined by RNA dot blotting.Two class III genes, htpG (44) and nfrA, are induced by heatshock only. Induction of these genes was determined by measuringthe induction of bgaB fusions to the respective promoters. Therefore,it is our suspicion that the method used to determine stress inductionin B. subtilis influences the results and the interpretation ofthe experiments considerably. In addition, salt stress and ethanolinduction of most class III genes is rather low (3, 12, 15,16, 29, 38, 40). It seems necessary to reproduce experimentsusing a different method or a valid control to determine stressinduction.

Transcription of class I and several class III genes is induced by the addition of the antibiotic puromycin (29, 35, 38,40). Class II genes are not induced by the addition of thisantibiotic. It was proposed that this difference allows the conclusionthat the signals for the induction of class I and class II genesare different (35). While the amount of the nfrA transcriptis elevated in response to puromycin treatment, the mechanismresponsible for this increase is unclear. We believe that thefact that the amounts of transcripts from class II genes are notelevated in response to puromycin treatment is insufficient toconclude the existence of different induction mechanisms for classII genes and the rest of the stress-responsive genes. The expressionof class II genes depends on the activity of the gene productencoded by sigB. Transcription of the sigB gene itself is inducedin response to stress (5, 7, 53). As a consequence, theamount of $sigma$ ^B increases and the response is amplified. It is likely that thisinduction of $sigma$ ^B synthesis is necessary to obtain strong induction of the wholeregulon. Even if puromycin addition induces $sigma$ ^B activity, the induction of the transcription of $sigma$ ^B-dependent genes will be diminished, because the majority of thisinduction is brought about by de novo synthesis of $sigma$ ^B itself, which is blocked bypuromycin.

The regulatory region and the promoter overlap. Our results indicate that heat shock-induced nfrA transcription is dependent on RNA polymerase containing $sigma$ ^A. The underlying regulatory mechanism is unknown. Nonspecificmutagenesis did not result in mutants with altered regulation.The original $-$ 10 and $-$ 35 regions of the promoter are necessaryfor full heat shock induction. We tried to identify a trans-actingregulatory protein using saturating transposon mutagenesis. Weobtained about 10⁵ independent mutants, but we were unable to identify a mutantwhich changed the regulation of nfrA transcription (data not shown).The nfrA gene promoter for B. subtilis is unusual because thedistance between the $-$ 10 and $-$ 35 regions is rather short. Therefore,it seems possible that the DNA structure itself is important forheat shock induction. For example, heat shock influences DNA supercoilingin B. subtilis (26). However, our results are insufficient toallow a definite conclusion. Additional work is necessary to elucidatethe mechanism of nfrA heat shockinduction.

	ACKNOWLEDGMENTS

We thank W. Hillen for financial support. C.M. was supported by a personal grant from the Evangelischen Studienwerk Villigste.V., Germany, and O.S. was supported by theDFG.

We also thank K. Oliva for editing the manuscript. We also thank M. Hecker, Greifswald, Germany, for the ctsR-negative B.subtilis strain; J. Helman for the sigX and sigW mutants; andW. Schumann, Bayreuth, Germany, for the hrcA-negativestrain.

	FOOTNOTES

^* Corresponding author. Mailing address: Lehrstuhl für Mikrobiologie, Universität Erlangen-Nürnberg, Staudstr. 5, D-91058Erlangen, Germany. Phone: 49 9131 8528084. Fax: 49 9131 8528082.E-mail: rallmans{at}biologie.uni-erlangen.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Akbar, S., and C. W. Price. 1996. Isolation and characterization of csbB, a gene controlled by Bacillus subtilis general stress transcription factor sigma B. Gene 177:123-128[CrossRef][Medline].
2.	Allmansberger, R. 1996. Degradation of the Bacillus subtilis xynA transcript is accelerated in response to stress. Mol. Gen. Genet. 251:108-112[Medline].
3.	Antelmann, H., S. Engelmann, R. Schmid, and M. Hecker. 1996. General and oxidative stress responses in Bacillus subtilis: cloning, expression, and mutation of the alkyl hydroperoxide reductase operon. J. Bacteriol. 178:6571-6578[Abstract/Free Full Text].
4.	Antelmann, H., S. Engelmann, R. Schmid, A. Sorokin, A. Lapidus, and M. Hecker. 1997. Expression of a stress- and starvation-induced dps/pexB-homologous gene is controlled by the alternative sigma factor sigma B in Bacillus subtilis. J. Bacteriol. 179:7251-7256[Abstract/Free Full Text].
5.	Benson, A. K., and W. G. Haldenwang. 1993. The sigma B-dependent promoter of the Bacillus subtilis sigB operon is induced by heat shock. J. Bacteriol. 175:1929-1935[Abstract/Free Full Text].
6.	Bernhardt, J., U. Völker, A. Völker, H. Antelmann, R. Schmid, H. Mach, and M. Hecker. 1997. Specific and general stress proteins in Bacillus subtilis $---$ a two-dimensional protein electrophoresis study. Microbiology 143:999-1017[Abstract].
7.	Boylan, S. A., A. R. Redfield, M. S. Brody, and C. W. Price. 1993. Stress-induced activation of the sigma B transcription factor of Bacillus subtilis. J. Bacteriol. 175:7931-7937[Abstract/Free Full Text].
8.	Boylan, S. A., A. R. Redfield, and C. W. Price. 1993. Transcription factor sigma B of Bacillus subtilis controls a large stationary-phase regulon. J. Bacteriol. 175:3957-3963[Abstract/Free Full Text].
9.	Boylan, S. A., A. Rutherford, S. M. Thomas, and C. W. Price. 1992. Activation of Bacillus subtilis transcription factor sigma B by a regulatory pathway responsive to stationary-phase signals. J. Bacteriol. 174:3695-3706[Abstract/Free Full Text].
10.	Cadwell, R. C., and G. F. Joyce. 1995. Mutagenic PCR, p. 583-589. In C. W. Dieffenbach, and G. D. Dveksler (ed.), PCR primer: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
11.	Derré, I., G. Rapoport, and T. Msadek. 1999. CtsR, a novel regulator of stress and heat shock response, controls clp and molecular chaperone gene expression in Gram-positive bacteria. Mol. Microbiol. 31:117-131[CrossRef][Medline].
12.	Deuerling, E., B. Päslack, and W. Schumann. 1995. The ftsH gene of Bacillus subtilis is transiently induced after osmotic and temperature upshift. J. Bacteriol. 177:4105-4112[Abstract/Free Full Text].
13.	Drzewiecki, K., C. Eymann, G. Mittenhuber, and M. Hecker. 1998. The yvyD gene of Bacillus subtilis is under dual control of $sigma$ ^B and $sigma$ ^H. J. Bacteriol. 180:6674-6680[Abstract/Free Full Text].
14.	Gärtner, D., M. Geissendorfer, and W. Hillen. 1988. Expression of the Bacillus subtilis xyl operon is repressed at the level of transcription and is induced by xylose. J. Bacteriol. 170:3102-3109[Abstract/Free Full Text].
15.	Gerth, U., E. Krüger, I. Derré, T. Msadek, and M. Hecker. 1998. Stress induction of the Bacillus subtilis clpP gene encoding a homologue of the proteolytic component of the Clp protease and the involvement of ClpP and ClpX in stress tolerance. Mol. Microbiol. 28:787-802[CrossRef][Medline].
16.	Gerth, U., A. Wipat, C. R. Harwood, N. Carter, P. T. Emmerson, and M. Hecker. 1996. Sequence and transcriptional analysis of clpX, a class-III heat-shock gene of Bacillus subtilis. Gene 181:77-83[CrossRef][Medline].
17.	Hecker, M., W. Schumann, and U. Völker. 1996. Heat-shock and general stress response in Bacillus subtilis. Mol. Microbiol. 19:417-428[CrossRef][Medline].
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