Forespore-Specific Expression of Bacillus subtilis yqfS, Which Encodes Type IV Apurinic/Apyrimidinic Endonuclease, a Component of the Base Excision Repair Pathway

The temporal and spatial expression of the yqfS gene of Bacillussubtilis, which encodes a type IV apurinic/apyrimidinic endonuclease,was studied. A reporter gene fusion to the yqfS opening readingframe revealed that this gene is not transcribed during vegetativegrowth but is transcribed during the last steps of the sporulationprocess and is localized to the developing forespore compartment.In agreement with these results, yqfS mRNAs were mainly detectedby both Northern blotting and reverse transcription-PCR, duringthe last steps of sporulation. The expression pattern of theyqfS-lacZ fusion suggested that yqfS may be an additional memberof the E ${sigma}$ ^G regulon. A primer extension product mapped the transcriptionalstart site of yqfS, 54 to 55 bp upstream of translation startcodon of yqfS. Such an extension product was obtained from RNAsamples of sporulating cells but not from those of vegetativelygrowing cells. Inspection of the nucleotide sequence lying upstreamof the in vivo-mapped transcriptional yqfS start site revealedthe presence of a sequence with good homology to promoters precedinggenes of the ${sigma}$ ^G regulon. Although yqfS expression was temporallyregulated, neither oxidative damage (after either treatmentwith paraquat or hydrogen peroxide) nor mitomycin C treatmentinduced the transcription of this gene.

INTRODUCTION

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Introduction

Endogenous and environmental factors such as reactive oxygenspecies, UV light, and chemical carcinogens alter the chemicalstructure of DNA bases, producing lesions that are substratesfor a myriad of DNA glycosylases of the base excision repair(BER) pathway (27). The apurinic/apyrimidinic (AP) sites generatednot only by the action of DNA glycosylases but also by the spontaneousdepurination and depyrimidination of DNA (29, 30) are inherentlytoxic and highly mutagenic and thus should be rapidly processedand eliminated (31). The first catalytic event during the repairof AP sites is carried out by AP endonucleases, which cleavethe DNA backbone immediately 5' of an AP site, generating a5' deoxyribose-phosphate group and a 3' deoxyribose-hydroxylgroup. AP endonucleases have been classified into two families,namely, ExoIII and type IV AP endonucleases (3, 13), and theseenzymes have been conserved across the species of the threedomains of life (23).

Dormant spores of Bacillus subtilis are more resistant thantheir vegetatively growing counterparts to several chemicalsubstances, including acids, bases, alkylating agents, and oxidizingagents (reviewed in references 40, 41, and 58). The existenceof core coats, the low permeability of spores to hydrophiliccompounds, and the protection of spore DNA from damage by itssaturation with ${alpha}$ /ß-type small acid-soluble proteins(SASPs) account for this resistance (reviewed in references40, 56, and 58). It has been demonstrated that ${alpha}$ /ß-typeSASPs slow DNA depurination-depyrimidination, as well as hydroxylradical-induced DNA backbone cleavage, thus contributing tospore resistance to heat and oxidizing agents (reviewed in references40 and 58). ${alpha}$ /ß-type SASPs bind to spore DNA and arein part responsible of the strong resistance of B. subtilisspores to UV light (reviewed in references 40, 41, and 58);however, these DNA-binding proteins do not confer protectionto DNA against base alkylation (55).

The genome of B. subtilis (26) possesses genes that potentiallyencode ExoIII and type IV AP endonucleases, namely, exoA andyqfS, whose products show a high level of homology to ExoIIIand type IV AP endonucleases, respectively. Although the enzymologyof B. subtilis ExoA has been studied in detail (53), nothinghas been reported regarding the mechanisms that control itsexpression during growth and sporulation of B. subtilis.

The expression of DNA repair systems in the gram-positive spore-formingbacterium B. subtilis has been shown to be differentially regulatedduring growth and differentiation (4, 11, 32, 34), as well asduring spore germination and outgrowth (54). DNA lesions acquiredduring unpredictable periods of B. subtilis spores dormancymust be necessarily corrected during germination by spore-specificexpressed DNA repair systems (reviewed in references 40 and58). The best example studied thus far is the correction ofthe UV-C induced spore photoproduct (5-thyminil-5,6-dihydrothymine)through both the specific spore photoproduct lyase protein (SplB)and the general excision-repair system (UVR) (reviewed in references40 and 41). However, during unpredicted periods of spore dormancyB. subtilis spores could potentially accumulate, in additionto spore photoproduct (SP), different types of DNA lesions,such as strand brakes, cyclobutane pyrimidine dimers (CPDs),chemically altered bases, and AP sites that could affect essentialfunctions such as transcription and replication during germination(40). Although the expression of splB in the forespore compartmentby ${sigma}$ ^G RNA polymerase has been widely substantiated (44, 45),few data exist in the literature concerning the expression ofother specific or general DNA repair systems in the foresporecompartment.

As mentioned above, in the genome of B. subtilis exists an openreading frame (ORF), yqfS, whose predicted product shows 53%homology with the type IV AP endonuclease of Escherichia coli.We describe here the expression of the cloned yqfS gene of B.subtilis from an IPTG (isopropyl-ß-D-thiogalactopyranoside)-induciblepromoter in E. coli. Our results demonstrate that a His₆-YqfSpurified enzyme is able to process the cleavage of abasic sitesin the DNA. In addition, our results demonstrated that the expressionof yqfS is forespore specific but was not induced by the stressimposed by superoxide radicals, by hydrogen peroxide, or bythe DNA-damaging agent mitomycin C.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains, plasmids, and growth conditions. B. subtilis and E. coli strains used in the present study areshown in Table 1. Plasmids used in this work are listed in Table1. Media used were Difco sporulation medium (DSM) (52) and Luria-Bertani(LB) medium (38). When appropriate, antibiotics were added tothe medium at the following final concentrations: chloramphenicol,3 µg/ml; ampicillin, 50 µg/ml; and kanamycin, 10µg/ml. Liquid cultures were shaken at 250 rpm at 37°C.Cultures on solid medium were grown at 37°C. The opticaldensity (OD) of liquid cultures was monitored with a PharmaciaUltrospec 2000 spectrophotometer set at 600 nm.

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TABLE 1. Strains and plasmids used in this study

Genetic and molecular biology techniques. Preparation of competent E. coli or B. subtilis cells and theirtransformation with DNA was performed as described elsewhere(5, 49). Extraction of chromosomal DNA from B. subtilis wascarried out according to the protocol of Cutting and VanderHorn (12). Small-scale preparation of plasmid DNA from E. colicells, enzymatic manipulations, and agarose gel electrophoresiswere performed by standard techniques (49). Large-scale preparationand purification of plasmid DNA was accomplished by using commercialion-exchange columns according to the instructions of the supplier(Qiagen, Inc., Valencia, Calif.). Nucleic acid sequencing bydideoxynucleotide chain termination (50) was performed withthe Thermo Sequenase radiolabeled terminator cycle sequencingkit (U.S. Biochemical Corporation, Cleveland, Ohio). Sequencingproducts were analyzed by autoradiography after electrophoresisthrough a 6% polyacrylamide sequencing gel. Alternatively, DNAplasmids purified through Qiagen columns were processed forsequencing in a Perkin-Elmer (Norwalk, Conn.) model 377A automatedDNA sequencer.

Cloning of yqfS and construction and integration of a yqfS-lacZ gene fusion. The complete yqfS gene was amplified by PCR with genomic DNAfrom B. subtilis 168 as a template and the oligonucleotide primers5'-GGGAATTCGCCGAAGAAGGTTAAGCC-3' (forward) and 5'-CGGGATCCGGCCGTTGAAGTAGCGAACC-3'(reverse). The primers were designed to insert EcoRI and BamHIsites (underlined). Amplification was performed on 0.1 µgof chromosomal DNA by using an MJ Research (Watertown, Mass.)Minicycler with Vent DNA polymerase (New England Biolabs, Beverly,Mass.) according to the manufacturer's recommendations. The1,181-bp PCR fragment extending from 110 bp upstream of theyqfS start codon through 157 bp downstream of the yqfS stopcodon was digested with SmaI and BamHI and ligated into pUC18to generate pPERM253. pPERM253 was replicated in E. coli XL1-Blue,and the cloned yqfS gene was sequenced on both strands.

Construction of an in-frame translational yqfS-lacZ fusion wasperformed in the integrative plasmid pJF751 (17) by insertinga 472-bp EcoRI-NaeI fragment from plamid pPERM253 into pJF751previously digested with EcoRI and SmaI. The resulting construction,containing the yqfS-lacZ fusion and designated pPERM317, waspropagated into E. coli XL1-Blue. Plasmid pPERM317 was introducedby transformation into competent cells of B. subtilis 168, andtransformants were selected on solid DSM containing chloramphenicol.

Purification of His₆-YqfS and substrates for AP endonuclease activity. E. coli PERM348 containing plasmid pPERM348 (Table 1) was grownin 50 ml of LB medium, supplemented with ampicillin (100 µg/ml),at 37 ^oC to an OD at 600 nm (OD₆₀₀) of 0.5. Expression of yqfSwas induced during 4 h at 37°C by the addition of IPTG to0.5 mM. Cells were collected by centrifugation and washed twotimes with 10 ml of 50 mM Tris-HCl (pH 7.5)-300 mM NaCl (bufferA). The cells were disrupted in 10 ml of the same buffer containinglysozyme (10 mg/ml) for 30 min at 37°C. The cell homogenatewas subjected to centrifugation to eliminate undisrupted cellsand cell debris, and the supernatant was applied to a 5-ml nickel-nitrilotriaceticacid-agarose column previously equilibrated with buffer A. Thecolumn was washed with 50 ml of buffer A containing 10 mM imidazoleplus 50 ml of buffer A containing 20 mM imidazole, and the proteinbound to the resin was eluted with 15 ml of buffer A containing100 mM imidazole; 2-ml fractions were collected during thislast step. Aliquots (15 µl) of the cell homogenate, theflowthrough, and the bound fractions were analyzed by sodiumdodecyl sulfate-polyacrylamide gel electrophoresis.

Two types of substrates were prepared to assay AP endonucleaseactivity of His₆-YqfS, namely, pBluescript (Stratagene), whichwas partially depurinated after a previously described protocol(28) and a 5'-end-radiolabeled double-stranded 19-mer nucleotidecontaining a single abasic site (20).

The endonuclease activity of His₆-YqfS against pBluescript containingAP sites (AP-pB) was determined in a mixture reaction of 25µl containing 600 ng of purified His₆-YqfS and 100 ngof substrate in 50 mM Tris-HCl (pH 7.5) containing 1 mM dithiothreitol.The reactions were incubated at 37°C for 30 min and analyzedby electrophoresis on a 1% agarose gel stained with ethidiumbromide.

Endonuclease activity against the double-stranded radiolabeled19-mer containing a single AP site was performed in a totalvolume of 15 µl containing 50 mM Tris-HCl (pH 7.5), 1mM dithiothreitol, and 500 nmol of unlabeled and 10 nmol ofdouble-stranded radiolabeled 19-mer containing a single AP site.Different amounts of His₆-YqfS were added to the mixture reactionsand incubated for 30 min at 37°C. The reactions were separatedon a 20% denaturing acrylamide gel and then subjected to autoradiography.

Cell growth and enzymatic assays. B. subtilis strains carrying the yqfS-lacZ fusion were grownand allowed to sporulate in liquid DSM. Samples of 1.5 ml werecollected during vegetative growth and throughout sporulation.Cells were washed with 0.1 M Tris-HCl (pH 7.5) and processedfor determination of ß-galactosidase (42) and glucosedehydrogenase (GDH) activities (19, 42). The ß-galactosidaseactivities were determined in cell extracts obtained from mothercells and forespore fractions prepared according to a previouslydescribed protocol (36, 44).

Northern blot and primer extension experiments. The total RNA for both Northern blotting experiments and mappingof the 5'end of yqfS was isolated as previously described (35).Northern blots were performed with RNA samples isolated fromstrains B. subtilis 168 and WN118 (sigG mutant). RNA samples(20 µg) were separated by electrophoresis through 1% agarose-formamidegel and transferred to a high-bound nylon membrane. The membranecontaining the transferred RNA was hybridized at 70°C witha 1,181-pb EcoRI-BamHI fragment from pPERM253 containing theentire yqfS sequence. The probe was labeled by random primingwith [ ${alpha}$ -³²P]dCTP by using the Rediprime II DNA labeling systemaccording to the instructions of the provider (Amersham Biosciences,Buckinghamshire, England). Detection of hybrids was performedby autoradiography exposing the membrane to Kodak X-Omat films.

The 5' end of yqfS was mapped by primer extension (37) of yqfStranscripts produced during sporulation. To this end, totalRNA was isolated from vegetative and sporulating cells of B.subtilis PERM317. In order to obtain the maximum amount of yqfStranscripts during sporulation, we monitored the expressionof ß-galactosidase activity directed by the yqfS-lacZfusion in this strain. The total RNA (40 µg from eachsample) was hybridized with the 20-mer oligonucleotide 5'-CGGCGCGTATTTTGCGGTGC-3',which was complementary to the yqfS mRNA from nucleotides 106to 124 downstream from the putative yqfS translational startcodon. The oligonucleotide was labeled on its 5' end with [ ${gamma}$ -³²P]ATPand T4 polynucleotide kinase. The primer was extended with Moloneymurine leukemia virus reverse transcriptase, and the extendedproducts were separated by electrophoresis through a 6% polyacrylamideDNA sequencing gel. The position of the extended products wasdetermined by running a sequencing reaction generated with thesame 20-base primer and a 1,978-bp PCR product (PCR RS) extendingfrom 247 bp upstream of the yqfR start codon to 416 bp downstreamof the start codon of yqfS (Fig. 1).

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FIG. 1. yqfS region of the B. subtilis chromosome and DNA sequences lying upstream of the yqfS ORF. (A) Genetic organization of the yqfS locus between indicated coordinates of the B. subtilis chromosome (filled box). Dashed lines above the ORFs (arrows) show the DNA fragments cloned into the indicated plasmids. Downstream of yqfU ORF a putative transcriptional terminator is shown (stem-loop structure). (B) Sequence of the intergenic region between yqfR and yqfS. The in vivo-mapped transcriptional start site of yqfS is indicated by an asterisk immediately downstream of the -10 and -35 sequences that might function as a promoter for RNA polymerase- ${sigma}$ ^G. RBS (putative ribosome-binding site).

RT-PCR experiments. Total RNA from vegetative or sporulating B. subtilis 168 cells,grown in DSM, was isolated by using the TRI reagent (MolecularResearch Center, Inc.). Reverse transcription-PCRs (RT-PCRs)were performed with the RNA samples and a Master Amp RT-PCRkit (Epicentre Technologies) according to the instructions ofthe provider. The primers used for RT-PCRs were 5'-CCTGTTGCTGAGAATAGGC-3'(forward) and 5'-CGGCGCGTATTTTGCGGTGG-3' (reverse) to generatea 132-bp RT-PCR product extending from 4 bp upstream from thestart codon of yqfS to 128 bp downstream of this point (Fig.1). As a control, in each experiment, the absence of chromosomalDNA in the RNA samples was assessed by mounting PCRs with VentDNA polymerase (New England Biolabs) and the set of primersdescribed above.

RESULTS

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Results

Cloning of yqfS. The existence of a type IV AP endonuclease in the genome ofB. subtilis was investigated by using the primary structureof E. coli Nfo (51) as a query to search against the databaseof National Center for Biotechnology Information with a GappedBLAST program (2). As described in Materials and Methods, thisapproach was used to retrieve a gene termed yqfS from the genomeof B. subtilis (26). Analysis of the yqfS primary structurerevealed an ORF of 891 bp with enough information for the synthesisof a predicted protein of 31 kDa. Amino acid alignments showedthat YqfS possesses homologies of 53, 52, and 32% with E. coliNfo (51), Saccharomyces cerevisiae Apn1 (46), and Thermotogamaritima endonuclease IV (20), respectively.

Purification and enzymatic activity of YqfS. The His₆-YqfS protein synthesized in E. coli was purified tohomogeneity by metal chelate affinity chromatography, yieldinga 36-kDa protein (data not shown).

To corroborate the predicted AP endonuclease activity of YqfS,two enzymatic assays were performed. First, the His₆-YqfS pureenzyme was incubated with a partially depurinated plasmid DNAas a substrate (AP-pB). The results presented in Fig. 2 revealthe conversion of the closed covalently circular depurinatedplasmid (CCC) to the open circular form (OC) due to single-strandbreaks performed by the His₆-YqfS purified protein (lane 3).As shown in Fig. 2 (lane 4), the nondepurinated plasmid (U-pB)was not a substrate for the His-tagged YqfS protein. Controlsshown in Fig. 2 revealed that neither the untreated nor thedepurinated plasmid were converted to the OC form in the absenceof the His6-YqfS protein (lanes 1 to 2). Second, a 5'-end radiolabeleddouble-stranded 19-mer nucleotide containing a single AP sitewas used as a substrate for the YqfS pure protein. Essentially,different amounts of the His₆-tagged protein were incubatedwith 510 nM of this AP substrate. The products of the reactionanalyzed on a denaturing polyacrylamide gel revealed that theendonucleolytic activity of YqfS at the AP site was dependenton the concentration of the enzyme used (Fig. 3A, lanes 2 to6). To better evaluate this conclusion, these results were analyzedby densitometry, thereby corroborating that cleavage of theAP substrate by His₆-YqfS is concentration dependent (Fig. 3B).Although the radiolabeled 20-bp-mer was also cleaved by E. coliNfo (Fig. 3A, lane 7), it was observed that a fraction of thesubstrate was partially degraded (Fig. 3A, lane 1). The resultspresented in Fig. 3A (lane 7) also revealed that another fractionof the radiolabeled substrate was inaccessible to the enzyme;such a fraction most probably corresponded to nondepurinatedcompound. These results demonstrate for the first time thatthe product encoded by the yqfS gene possesses activity of APendonuclease, a result in agreement with its high structuralsimilarity to the family IV AP endonucleases.

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FIG. 2. Endonuclease activity of His₆-YqfS against a plasmid containing AP sites. Aliquots (600 ng) of His₆-YqfS were incubated with 100 ng of either untreated (U-pB [lane 4]) or AP-containing sites (AP-pB [lane 3]) of pBluescript. Lane 1, AP sites-containing plasmid incubated with 50 mM Tris-HCl (pH 7.5)-300 mM NaCl; lane 2, untreated plasmid incubated with 50 mM Tris-HCl (pH 7.5)-300 mM NaCl. The reactions were incubated at 37°C for 30 min and then analyzed by electrophoresis on a 1% agarose gel stained with ethidium bromide.

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FIG. 3. Endonuclease activity of His₆-YqfS against a double-stranded 19-mer containing a single AP site. (A) A total of 510 nmol of 5'-end-radiolabeled double-stranded 19-mer nucleotide containing a single AP site was incubated for 30 min at 37°C with different concentrations of His₆-YqfS. The reactions were separated on a 20% denaturing acrylamide gel and then subjected to autoradiography. Lane 1, no enzyme; lanes 2 to 6, 0.3, 0.6, 1.2, 2.4, and 3.6 µg of His₆-YqfS, respectively; lane 7, 2 U of E. coli Nfo. Radioactively labeled cleaved (C) and uncleaved (U) strands are as indicated. (B) Densitometry of the experiment shown in panel A; the percentage of uncleaved substrate was plotted as a function of the amount of His₆-YqfS added to the reaction.

Expression of a yqfS during growth and sporulation. The strain B. subtilis PERM317 harboring a single copy of theyqfS-lacZ fusion was grown in DSM to induce sporulation. Determinationof yqfS-directed ß-galactosidase activity during growthand sporulation stages revealed a temporal pattern of expression.Although no ß-galactosidase activity was detectedduring vegetative growth, Fig. 4 reveals that enzymatic activitywas detectable after T₀, reached a maximum during T₆ and T₇,and then decreased. The expression pattern of the reporter gene(Fig. 4) was similar to that observed for genes whose expressionoccurs during the last steps of sporulation in the foresporecompartment, such as the operon splA-splB (44), gdh (39), andssp (35, 36) genes. To further investigate this observation,two approaches were followed. First, cell fractioning experimentswere performed to investigate whether the expression of thereporter gene occurred inside of the spore. The results of Fig.4 show that ß-galactosidase activity started to accumulateinside of the forespores from sporulation stage T₅ and continuedto accumulate until at least stage T₉.

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FIG. 4. Expression of a yqfS-lacZ translational fusion during growth and sporulation of B. subtilis. B. subtilis PERM317 was grown to sporulation in liquid DSM ( ${blacksquare}$ ). Samples were collected at different times and treated with lysozyme, and the extracts were assayed for either ß-galactosidase ( ${diamondsuit}$ ) or GDH (•) activity. The ß-galactosidase activity inside of the forespore lysozyme-resistant fraction ( ${blacktriangleup}$ ) was assayed as described in Materials and Methods.

The cell extracts used to determine ß-galactosidaseactivity were also assayed for GDH activity, an enzyme encodedby the stage III, forespore-specific gdh gene (19, 39). Theresults shown in Fig. 4 revealed that the expression patternsof the yqfS-lacZ fusion and the GDH activity followed essentiallyidentical kinetics, strongly indicating that yqfS gene expressionis activated in the forespore compartment during the last stepsof sporulation.

To further support this contention, Northern blot experimentswere performed with total RNA isolated from cells of strainB. subtilis PERM168 collected before and after the onset ofsporulation. The results (Fig. 5A) indicated that yqfS mRNAappeared as a 2.3-kb band during sporulation stages T₅ throughT₉, observing a major hybridization signal at T₇. As shown inFig. 5A, no signal was detected in the blot with RNA isolatedfrom cells growing exponentially, supporting the conclusionthat yqfS expression is sporulation specific. Moreover, RT-PCRexperiments resulted in the major amplification of a yqfS productwhen total RNA isolated from sporulating cells was used as atemplate. Figure 5B shows that the RT-PCR product of yqfS (132bp) was more abundant with RNA samples of the step T₇ of sporulation.

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FIG. 5. Northern blot (A) and RT-PCR analysis (B) of yqfS transcription during vegetative growth and sporulation. (A) B. subtilis 168 was induced to sporulate in liquid DSM. Total RNA was isolated (35) during the times (in hours) indicated (T₀ = end of exponential growth). Then, 20-µg samples were separated on agarose-formaldehyde gels (lower panel) and transferred to nylon membranes. The membrane was hybridized with a ³²P-labeled 1,181-bp fragment encompassing the entire yqfS sequence as described in Materials and Methods. (B) RNA samples (1 µg) isolated from a B. subtilis 168 DSM culture at the times indicated (in hours) were processed for RT-PCR analysis as described in Materials and Methods. The arrowhead shows the size of the expected RT-PCR product.

${sigma}$ ^G dependence of yqfS expression. The expression of forespore specific genes in B. subtilis iscarried out through the sequential action of two temporallyexpressed RNA polymerases containing either ${sigma}$ ^F or ${sigma}$ ^G factors (21,43). However, as shown above, the expression pattern of theyqfS-lacZ fusion was very similar to the ${sigma}$ ^G-dependent gdh gene,suggesting that yqfS is under the control of ${sigma}$ ^G-containing RNApolymerase. This notion was directly tested by two differentapproaches. First, the yqfS-lacZ fusion was introduced by transformationinto competent cells of B. subtilis WN126 harboring a deletionof the ${sigma}$ ^G gene, an spo mutant in which sporulation is arrestedduring stage III (24, 60). The resulting strain, B. subtilisPERM336, grown in DSM expressed very low levels of yqfS-directedß-galactosidase activity during both vegetative- andstationary-growth phases (data not shown). Consistent with thisresult, the levels of GDH in this strain were almost zero (datanot shown).

In a second approach, Northern blot experiments were performedwith RNA isolated from vegetative and stationary cells of B.subtilis sigG ${Delta}$ 1 grown in liquid DSM. The results shown in Fig.6A revealed the lack of yqfS mRNAs in this sigG mutant geneticbackground, since no hybridization signal was detected duringboth exponential-growth-phase and stationary-growth-phase cells.Such a result was also confirmed by RT-PCR experiments, whichfailed to amplify the 132-bp yqfS fragment from RNA samplesisolated before and after the onset of sporulation (Fig. 6B).Taken together, these results are consistent with yqfS expressionbeing dependent on ${sigma}$ ^G RNA polymerase.

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FIG. 6. Northern blot (A) and RT-PCR analysis (B) of yqfS transcription during vegetative growth and sporulation of B. subtilis sigG ${Delta}$ 1 (strain WN118). (A) B. subtilis WN118 was grown in liquid DSM. Total RNA was isolated (35) during the times indicated (in hours). Samples (20 µg) were separated on agarose-formaldehyde gels (lower panel) and transferred to nylon membranes. The membrane was hybridized with a ³²P-labeled 1,181-bp fragment encompassing the entire yqfS sequence as described in Materials and Methods. (B) RNA samples (1 µg) isolated at the times indicated (in hours) from a B. subtilis sigG ${Delta}$ 1 DSM culture were processed for RT-PCR analysis as described in Materials and Methods. For the wild type (WT), the RNA was isolated from B. subtilis 168 (Fig. 5); FW was obtained with the forward primer in the absence of RNA, and RV was obtained with the reverse primer in the absence of RNA. The arrowhead shows the size of the expected RT-PCR product.

Mapping the transcriptional start site of yqfS. The genetic organization of the yqfS locus reveals that thisgene is flanked upstream by yqfR, which encodes a putative RNAhelicase, and downstream by yqfU, which encodes a protein ofunknown function (Fig. 1). The existence of only one potentialtranscriptional terminator until the end of yqfU suggests thatthe three genes could be cotranscribed as a polycistronic message.To investigate this possibility, primer extension analysis wasperformed to map the 5' ends of the mRNAs originating from upstreamfrom the yqfS coding sequence. Experiments were carried outwith total RNA isolated from B. subtilis PERM317 harboring theyqfS-lacZ fusion. Cells used to isolate RNA were harvested duringboth vegetative growth and the T₇ sporulation stage, the timeof maximum expression of the yqfS-lacZ fusion. The results shownin Fig. 7 (lane 2) revealed the synthesis of a major extensionproduct located 54 to 55 bp upstream of translation start codonof yqfS. Such an extension product was obtained only in experimentsperformed with RNA isolated from sporulating cells but not withRNA of vegetatively growing cells (Fig. 7, lane 1). Inspectionof the nucleotide sequences lying upstream of the in vivo mappedtranscriptional yqfS start site revealed the existence of sequenceswith good homology to promoters preceding genes of the ${sigma}$ ^G regulon(Fig. 8) (21, 43). A higher level of homology was found in the-35 region, which possessed three of the four absolutely conservedbases present on sigG promoters (Fig. 8). On the other hand,the -10 region conserved three of the four absolutely conservedresidues observed in such ${sigma}$ ^G promoters. However, it was foundthat the -10 and -35 regions were separated by 16 bp insteadof the reported 17 to 18 bp for the ${sigma}$ ^G consensus sequence (Fig.8).

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FIG. 7. Primer extension analysis for mapping the transcriptional start site of yqfS. Total RNA was isolated (34) from either vegetative (lane 1) or sporulating (stage T₇; lane 2) B. subtilis PERM317 cells grown in DSM. Primer extension was performed as described in Materials and Methods. The asterisk indicates the position of the primer extension product in the DNA sequence lying upstream of yqfS (see Fig. 1). The 5' end of the yqfS transcript was determined by running a DNA sequencing ladder generated with the same primer (lanes G, A, T, and C) and was labeled with an arrowhead.

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FIG. 8. Comparison of the consensus E ${sigma}$ ^G (19) promoter sequence (top line) with the putative promoter sequence lying upstream of yqfS (bottom line). Absolutely conserved (boldface) or highly conserved (underlined) bases in E ${sigma}$ ^G-type promoters (21, 43). The position of the mapped transcriptional start site of yqfS is indicated with an asterisk.

Induction of the yqfS-lacZ fusion by oxidative stress or during the SOS response. In E. coli, the expression of the type IV AP endonuclease nfogene is induced by generators of superoxide radicals, such asparaquat (8). On the other hand, B. subtilis responds to H₂O₂stress displaying an adaptive response that induces the expressionof genes such as katA (catalase), ahpCF (alkyl hydroperoxidereductase), mrgA, and the hemA operon (1, 4, 7, 9, 10, 14).We therefore investigated whether the yqfS gene in B. subtilisis also induced by the oxidative stress imposed by either superoxideradicals or hydrogen peroxide. To this end, the strain B. subtilisPERM317 containing the yqfS-lacZ fusion, integrated into theyqfS locus, was grown in LB medium to the mid-exponential phaseand treated with paraquat (10 µM) or hydrogen peroxide(200 µM). The results (Fig. 9A) revealed that, at theconcentrations tested, neither paraquat nor H₂O₂ was capableof inducing the expression of the yqfS-lacZ fusion.

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FIG. 9. Lack of induction of a yqfS-lacZ fusion by paraquat, H₂O₂, or mitomycin. B. subtilis PERM317 was grown to an OD₆₀₀ of 0.5 in either minimal Spizizen medium (A) or LB medium (B). The culture made in minimal Spizizen medium was divided into three subcultures; one (labeled "0") was left untreated, and the other two were treated with either paraquat (PQ; 10 µM) or H₂O₂ (200 µM). The LB culture was treated in the same manner except that mitomycin C (MC; 0.5 µg/ml) was added to the culture. (C) B. subtilis YB3000 was grown in LB medium to an OD₆₀₀ of 0.5; at this point, the culture was equally divided, and mitomycin C (0.5 µg/ml) was added to one of the subcultures. In all cases, the ß-galactosidase activity was determined with cell samples collected 2 h after the addition of the inducers.

Several B. subtilis genes involved in DNA repair, such as uvrcomponents and recA, have been shown to be inducible not onlyby DNA damage but also by the physiological state of competence(32, 34, 48). These genes (din) are part of a global responsewhich in B. subtilis is called the SOS response (33). In orderto determine whether the type IV AP-endonuclease gene of B.subtilis is a component of the B. subtilis SOS regulon, thestrain containing the yqfS-lacZ fusion was grown to exponentialphase and then treated with mitomycin C to a final concentrationof 0.5 µg/ml. As shown in Fig. 9B, mitomycin C inducedthe ß-galactosidase levels of the strain B. subtilisPERM317 only 1.2 times above the levels expressed by the untreatedcontrol. In contrast with this result, when B. subtilis YB3000containing a recA-lacZ fusion was treated with mitomycin (Fig.9C), the levels of ß-galactosidase activity increased35 times.

DISCUSSION

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Discussion

B. subtilis has been studied extensively as a paradigm for bacterialdifferentiation and development. Spores produced by this organismprevent or dramatically slow the DNA damage inflicted by oxidativestress, UV light, heat and desiccation (reviewed in references40 and 58). However, during long periods of dormancy sporesaccumulate potentially lethal and mutagenic DNA damage suchas SP, strand brakes, CPDs, chemically altered bases, and APsites that could affect transcription and replication duringgermination (40, 56). Therefore, it is of interest to determinehow the many DNA repair systems present are regulated by B.subtilis, especially in relation to the sporulation and germinationprocesses.

Thus, the yqfS ORF was cloned, and the product of this genewas isolated and tested for its enzymatic activity. The resultspresented in Fig. 2 and 3 clearly indicate that this proteinhas AP endonuclease activity. Having established the natureof the product of the yqfS gene, we wanted to determine themechanism(s) that control the expression of this gene. Our datademonstrate that there is temporal and spatial expression ofthe yqfS gene. Specifically, ß-galactosidase activityfor a yqfS-LacZ reveals that this gene is not apparently transcribedduring vegetative growth but is transcribed during stages ofthe sporulation process (Fig. 4). Northern blot and RT-PCR experiments(Fig. 5) confirmed a major abundance of yqfS messengers duringstages of the sporulation process of the strain B. subtilisPERM317. These results suggested that yqfS expression is temporallyactivated and confined to the forespore compartment in accordancewith a pattern similar to that described for stage III, forespore-specificgenes (57). This suggestion was further supported not only bycell fractionation experiments, which demonstrated that yqfSexpression occurs inside of the spore, but also by the observationthat the kinetics of GDH synthesis, a stage III, forespore-specificmarker, are indistinguishable from those observed for the yqfS-lacZfusion (Fig. 4). These results strongly support the idea thatthe synthesis of the YqfS protein occurs during the last stagesof the sporulation process and is packaged in the spore.

The forespore-specific expression of the yqfS-lacZ fusion duringthe last steps of B. subtilis sporulation suggested that thetranscription of yqfS is carried out by RNA polymerase containingthe ${sigma}$ ^G factor (Fig. 4). However, gene expression inside of theforespore occurs by the sequential action of two RNA polymerasescontaining either the ${sigma}$ ^F or ${sigma}$ ^G factors (21, 25). Therefore, wecould not rule out a possible transcription of yqfS by RNA polymerase ${sigma}$ ^F. This point was addressed by measuring the levels of expressionof the yqfS-lacZ fusion introduced into a B. subtilis strainlacking the sigG gene (Table 1). The results showed that yqfS-directedß-galactosidase activity is almost null in this geneticbackground, as is the synthesis of GDH activity (data not shown).In agreement with this observation, both Northern blot and RT-PCRexperiments performed with total RNA isolated during vegetativeand stationary growth of the strain B. subtilis sigG ${Delta}$ 1 demonstratedthe absence of yqfS messengers in this mutant strain (Fig. 6).Taken collectively, these results strongly suggest that yqfSexpression occurs inside of the spore by the action of ${sigma}$ ^G-containingRNA polymerase.

Forespore-specific expressed genes such as sspA-E, splA-splB,gdh, ger, and spoVA, among others, are representative of the ${sigma}$ ^G regulon (15, 16, 19, 21, 25, 44, 45, 57). Experimental evidencehas demonstrated that these genes possess specific promotersthat are exclusively transcribed by ${sigma}$ ^G containing RNA polymerase(15, 39, 43, 44, 47). The results described above suggest thatyqfS might be a new member of this regulon. This conclusionwas strongly supported by the in vivo mapping of the transcriptionalstart site of yqfS (Fig. 7). A major extension product initiating54 to 55 bp upstream of the putative yqfS start codon was amplifiedfrom RNA samples isolated from sporulating but not from vegetativelygrowing cells (Fig. 7). Inspection of the sequences precedingthe yqfS transcriptional start site revealed the existence ofa promoter with homology to the consensus sequence of ${sigma}$ ^G promoters(21, 43). Although the -10 region of the putative yqfS promotershows a low level of homology, the -35 region almost perfectlymatched the consensus of ${sigma}$ ^G promoters (Fig. 8). One possibleproblem with the designation of this putative ${sigma}$ ^G promoter isthe spacing between the -35 and -10 regions. However, as mentionedabove, our data support the hypothesis that the yqfS gene istranscribed by a ${sigma}$ ^G-containing RNA polymerase.

The yqfS region in the B. subtilis chromosome shows the existenceof a set of three genes located in the same orientation, inthe following order: yqfR, yqfS, and yqfU (Fig. 1). The lackof putative transcriptional terminators downstream of yqfR andyqfS suggests that the three genes are transcribed as a polycistronicunit. However, the primer extension experiments described above,together with the identification of a 2.3-kb yqfS messenger,indicate that yqfS is cotranscribed with yqfU as a bicistronicmRNA from the putative yqfS promoter just described.

Expression of the two major AP endonucleases is differentiallyregulated in E. coli. Whereas exoIII is constitutively expressed,the nfo gene is inducible by oxidative stress. Chemical compoundssuch as paraquat and menadione, which generate superoxide radicals,induce a 10- to 20-fold increase in the level of Nfo (8). Thelack of induction in the levels of expression of the yqfS-lacZfusion after the treatment of B. subtilis PERM317 with paraquat(Fig. 9) revealed that in B. subtilis the yqfS gene is not regulatedby the oxidative stress imposed by superoxide radicals.

In B. subtilis the adaptive response to H₂O₂ stress is subjectedto negative regulation by the repressor PerR, a Fur homolog(6). Treatment of B. subtilis PERM317 with H₂O₂ did not changethe levels of expression of the yqfS-lacZ fusion (Fig. 9), suggestingthat yqfS is not regulated by PerR. Consistent with these results,no cis-acting DNA sequences similar to those present in perRboxes (22) were observed around the putative promoter of yqfS.

Analysis of the upstream regions of yqfS also revealed the absenceof dinR-like boxes (11, 62). This observation is in agreementwith the lack of induction of the yqfS-lacZ fusion after thetreatment of B. subtilis PERM317 with the DNA-damaging agentmitomycin (Fig. 9).

Taking all of these results together, we conclude that althoughin E. coli the expression of nfo is linked to the oxidativestress generated by superoxide radicals (8), in B. subtilisthe regulation of yqfS expression occurs in a temporal and forespore-specificmanner and appears to be part of the ${sigma}$ ^G regulon. In addition,the lack of induction of ß-galactosidase in the yqfS-lacZfusion strains after treatment by either hydrogen peroxide orthe DNA-damaging agent mitomycin revealed that yqfS in not underthe control of the PerR or SOS regulons.

Despite the existence of spore mechanisms that prevent or alterDNA insults, potentially lethal and mutagenic damage accumulatesin DNA during long-term storage of spores in the laboratory(40, 58) and during the exposure of these spores to environmentalstresses, particularly solar radiation (40, 41, 59, 61). Interestingly,artificial and solar UV radiation induce the formation of SP,CPDs, and strand breaks but not of AP sites in B. subtilis sporeDNA (59). It remains to be investigated whether AP sites aregenerated during germination of B. subtilis spores either spontaneouslyor promoted by oxidative stress or through the action of DNAglycosylases during the elimination of chemically modified bases(18). Moreover, depending on their chemical structure, single-strandbreaks generated on spore DNA could be processed as well byYqfS during germination, since it has been well establishedthat type IV AP endonucleases are able to remove phosphoglycoaldehyde,phosphate, deoxyribose-5-phosphate, and 4-hydroxy-2-pentenalfrom the 3' terminus of duplex DNA (18). Therefore, as an obligatorystep for the correction of the different types of DNA damageprocessed by the BER pathway, YqfS may play an important rolein the repair of DNA damage inflicted on B. subtilis duringeither spore dormancy or germination.

In conclusion, we provide here for the first time evidence thatan important component of the BER system of B. subtilis, namely,the yqfS gene, is specifically expressed inside of the sporesduring the final developmental stages. Thus, together with theSplB, UVR, and Rec systems, YqfS could be part of the DNA repairproteins that increase the survival potential of B. subtilisspores.

ACKNOWLEDGMENTS

This work was supported by grant 31767-N from the Consejo Nacionalde Ciencia y Tecnología (CONACYT) of México toM.P.-R. N.U.-E. and J.M.S.-P. were supported by a Doctoral fellowshipsfrom CONACYT. R.E.Y. was supported by grant MCB-9975140 fromthe National Science Foundation.

We thank J. J. García-Soto for critical review of themanuscript and Ada A. Sandoval for technical assistance.

FOOTNOTES

* Corresponding author. Mailing address: Institute of Investigation in Experimental Biology, Faculty of Chemistry, University of Guanajuato, P.O. Box 187, Guanajuato, Gto. 36060, Mexico. Phone: (473) 73-2-00-06, x8161. Fax: (473) 73-2-00-06, x8153. E-mail: pedrama{at}quijote.ugto.mx.

REFERENCES

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