INTRODUCTION

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The soil bacterium Bacillus subtilis has evolved elaborate regulatory systems to adapt and survive under various environmental conditions. Alternative  factors provide one means of modulating gene expression in response to changes in environment. Alternative  factors in B. subtilis control sporulation (^H, ^E, ^F, ^G, and ^K); chemotaxis, motility, and autolysis (^D); and general stress responses (^B) (15). Sequencing of the B. subtilis genome has revealed seven previously unidentified  factors that are members of the extracytoplasmic function (ECF) subfamily (28).

ECF  factors are found in a wide variety of gram-positive and gram-negative bacteria and often regulate gene expression in response to extracytoplasmic stimuli (32). For example, ECF  factors regulate genes involved in ferric citrate uptake and periplasmic protein proteolysis in Escherichia coli (3, 8); nickel and cobalt efflux in Alcaligenes eutrophus (30); antibiotic production, oxidative stress responses, and cell wall modification in Streptomyces spp. (26, 43, 44); and alginate and exotoxin secretion in Pseudomonas aeruginosa (18, 41). ECF  factors are typically regulated by a cotranscribed anti- factor that is targeted to the cell membrane. Thus, expression of the  factor operon leads to the synthesis of inactive -anti- complexes that are then regulated by signals that inhibit anti- function. These signals are likely to include alterations in the chemical composition or structure of the cell envelope.

The physiological functions of the ECF  factors of B. subtilis are not well understood, and mutants with mutations in each of the seven  factors are all viable. Only three of these regulators have been studied in detail (20-24): a sigX mutant is slightly more sensitive to heat and oxidative stress, a sigM mutant is unable to grow in high concentrations of salt, and a sigW mutant is altered in resistance to cell wall biosynthesis inhibitors. The ^X regulon is expressed during late logarithmic growth, while the ^W regulon is activated early in stationary phase (21, 22). Derepression of  factor regulons, by mutation of the corresponding anti- factor, can also lead to phenotypic alterations. Increased expression of the ^X regulon in an anti- (rsiX) mutant represses expression of ^W (22) and leads to reduced competence (61).

To investigate the roles of B. subtilis ECF  factors, we used consensus-based promoter searches to identify genes under the control of ^X and ^W (23, 24). The ^X regulon includes a putative glucosyltransferase (CsbB), a regulator of autolysin expression (LytR), and a response regulator aspartate phosphatase (RapD). Recent results indicate that ^X also regulates the D-alanylation of teichoic acids and membrane phospholipid composition (M. Cao, J. Qiu, and J. D. Helmann, unpublished results). Proteins dependent on ^W for expression include a fosfomycin resistance determinant (FosB), a penicillin binding protein (PBP4*), signal peptide peptidase (YteI), an ATP-binding cassette transporter (YknXYZ), a nonheme bromoperoxidase (YdjP), epoxide hydrolase (YfhM), several small hydrophobic peptides (YvlC, YxzE, and YdjO), and a large number of membrane proteins of unknown function (23). At least four additional genes (abh, divIC, yrhH, and ywbN) are apparently transcribed by both ^X and ^W (22). The characterization of these two regulons suggests that ^X regulates cell envelope modification processes while ^W regulates detoxification responses and the production of antimicrobial compounds.

To further define the physiological roles of ^X and ^W in B. subtilis, we have used mini-Tn10 mutagenesis to identify mutants with increased ^W or ^X activity. The resulting transposon insertions indicate that defects in transport, cell density signaling, sugar metabolism, and antimicrobial production affect the activity of these  factors. However, the signals that activate ^X appear to be largely distinct from those that activate ^W.

	MATERIALS AND METHODS

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Bacterial strains, plasmids, and growth conditions. All the bacterial strains and plasmids used in this study are listed in Table 1. Bacterial cultures were grown at 37°C with aeration in liquid Luria-Bertani medium (LB) (53) or Tris-Spizizen salts (TSS) minimal medium (16) containing either D-glucose or D-mannose as the sugar and auxotrophic requirements. Plates contained 1.25% Bacto Agar (Difco) and 40 µg of X-Gal (5-bromo-4-chloro-3-indolyl--D-galactopyranoside) per ml. Ampicillin (100 µg/ml) or spectinomycin (SPC) (200 µg/ml) was used for the selection of E. coli strains. Erythromycin (1 µg/ml) and lincomycin (25 µg/ml) (for testing macrolide-lincosamide-streptogramin B [MLS] resistance), SPC (100 µg/ml), neomycin (8 µg/ml), kanamycin (15 µg/ml), and chloramphenicol (2 to 5 µg/ml) were used for the selection of various B. subtilis strains.

View this table: [in this window] [in a new window]   TABLE 2.   Characterization of genes which affect W and X activity

Construction of mini-Tn10 libraries. Random mini-Tn10 libraries of B. subtilis strains were contructed using the plasmid pIC333 (57). This plasmid contains a ColE1 origin and a thermosensitive origin of replication for gram-positive bacteria (inactive at temperatures greater than 35°C). B. subtilis strains HB7070 (P_W-cat-lacZ) and HB7022 (P_X-cat-lacZ) were transformed with pIC333 with selection for Spc^r on LB plates incubated overnight at 28°C. Single colonies were inoculated into 2 ml of LB-SPC and incubated at 28°C overnight. Following a 1:100 dilution in the same medium, the cultures were grown for 3 h at 28°C, then shifted to 37°C, and grown for at least another 5 h. Diluted aliquots of these cultures were plated onto LB and LB-SPC plates and incubated overnight at 37°C. The rest of the culture was collected by centrifugation and resuspended in LB containing 15% glycerol for storage at 80°C. The transposition frequency was estimated from the ratio of the number of colonies on LB-SPC to that on LB and was in the general range (0.01 to 1%) reported for this system.

DNA manipulations and sequencing. Isolation of B. subtilis chromosomal DNA and transformations were done by standard procedures (16). Restriction endonucleases and DNA ligase (New England Biolabs, Inc., Beverly, Mass.) were used according to the manufacturer's instructions. Plasmid rescue experiments were performed as previously described (6). PCR experiments used for cloning DNA into plasmids were performed by using the Expand High Fidelity PCR System (Boehringer Mannheim) according to the manufacturer's instructions. DNA was purified by using the QIAprep Spin Miniprep and PCR purification and gel extraction kits (Qiagen Inc., Chatsworth, Calif.). DNA sequencing was performed with AmpliTaq-FS DNA polymerase and dye terminator chemistry at the DNA Services Facility of the Cornell New York State Center for Advanced Technology-Biotechnology.

Screening and identification of mini-Tn10 mutants up-regulated in ^W and ^X activity. Initially, several mini-Tn10 libraries of B. subtilis HB7070 were plated onto LB-SPC at a density of approximately 150 transposants per plate. The majority of colonies were light blue after 1 day of growth at 37°C; however, some colonies exhibited enhanced -galactosidase (-Gal) activity. Three colonies (W1, W2, and W3) from different mini-Tn10 libraries with enhanced -Gal activity were further characterized. Also, several mini-Tn10 libraries of B. subtilis HB7070 and HB7022 were plated onto LB-SPC containing chloramphenicol (2 to 5 µg/ml) at a density of approximately 10,000 transposants per plate. Several mutants which grew faster on these plates and had elevated -Gal activity were further characterized. The phenotypes were linked to the mini-Tn10 Spc^r marker by transformation. Plasmids containing the mini-Tn10 element with a ColE1 origin, the ampicillin resistance gene, and flanking B. subtilis chromosomal DNA were recovered from selected mutant strains. DNA sequence upstream and downstream of the transposon was obtained using two primers corresponding to the left and right ends of the mini-Tn10, as described previously (4).

Generation of B. subtilis mutants HB300, HB301, and HB302. DNA upstream of and including the 5' end of the yqgE gene was amplified from B. subtilis chromosomal DNA using primers 425 (5'-TTGAATTCTTCTTTTTACATATCTCGG-3') and 426 (5'-CAGGATCCTGTCTATTTTTTTGGCTAACCG-3'). The ~320-bp PCR product was digested with EcoRI and BamHI (sites underlined) and cloned into pMUTIN4 (64) to generate pMUTIN-yqgE. This plasmid was then transformed into strain CU1065 to generate strain HB300. DNA upstream of and including the truncated yshB gene (caused by the mini-Tn10 insertion) from strain W14 was amplified using primers 508 (5'-ATGGATCCGCCGGGCGGTTTTGCCTG-3') and 509 (5'-ATCAGAATTCAAGATGTGTATCCACC-3'). The ~640-bp PCR product encoding a hydrophobic peptide from the 5' sequence of yshB was digested with BamHI and EcoRI and cloned into pXT, a derivative of pDG1731 allowing gene expression from the P_xylA xylose-inducible promoter and integration by a double-crossover event at the thrC locus (T. Msadek, unpublished data). The resulting plasmid, pXT-yshB', was linearized with ScaI and transformed into strain CU1065 to generate strain HB301. To generate a yjdD mutant, an internal fragment of the yjdD gene was amplified from B. subtilis chromosomal DNA using primers 511 (5'-AGGAATTCTGCAAAAAGCTGCTGACAGAC-3') and 512 (5'-AAGGATCCAGTCGCCGCAATATAACCGC-3'). The ~590-bp PCR product was digested with EcoRI and BamHI and cloned into pMUTIN4 to generate pMUTIN-yjdD. This plasmid was then transformed into strain CU1065 to generate HB302.

-Gal assays. To determine the -Gal activities of various strains, cells were diluted 1:100 from an overnight culture grown in LB containing the necessary antibiotics into LB. Samples were then collected from the phase of growth when the relevant  factor is most active. For strains containing the P_W-cat-lacZ fusion, samples were taken at T₁ (1 h after the end of exponential growth), and for strains containing the P_X-cat-lacZ fusion, samples were taken at T₂. The assay used for determining -Gal levels by the method of Miller has been described previously (6, 34). All assays were performed on duplicate samples, and the values were averaged.

Computer analysis. To determine the loci in which the mini-Tn10 had been inserted, the sequence of chromosomal DNA flanking the mini-Tn10 was compared with the B. subtilis genome using the BLAST program (2) available on the SubtiList website (37) at http://www.pasteur.fr/Bio/SubtiList.html. Searches of B. subtilis protein sequences in other databases were performed using BLASTP (2) at http://www.ncbi.nlm.nih.gov/BLAST/ using the unfiltered setting. Protein localization and transmembrane domains were predicted using both the PSORT (38) and TMPred (19) programs available at http://psort.nibb.ac.jp:8800/form.html and http://www.isrec.isb-sib.ch/software/TMPRED_form.html, respectively.

	RESULTS

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Rationale for mutant isolation. To assess the activity of ^W and ^X in vivo, we used strains [HB7070 (P_W-cat-lacZ) and HB7022 (P_X-cat-lacZ)] containing operon fusions to the autoregulatory promoters, P_W and P_X. These promoters are specifically recognized by each  factor in vivo and in vitro (21, 22). Since each promoter drives expression of an operon encoding both chloramphenicol resistance (cat) and -Gal (lacZ), this system is suitable for both genetic screens and selections for increased promoter activity (56).

Isolation and analysis of mini-Tn10 mutants with increased ^W activity. Initially, several HB7070 mini-Tn10 libraries were plated onto LB plates containing SPC and X-Gal. From approximately 9,000 transposants, three mutants (W1, W2, and W3 [Table 2]) with obviously elevated -Gal activity were identified. All three have a mini-Tn10 insertion at the same position within the yvbA gene. Since these mutants were isolated from independent mini-Tn10 libraries, and one has the mini-Tn10 inserted in the opposite orientation from that of the other two, they are not siblings. YvbA is an uncharacterized member of the ArsR family of transcriptional regulators (Table 3). ArsR-like proteins (including ArsR, SmtB, ZiaR, and CadC) regulate resistance to arsenic, zinc, and cadmium (10, 25, 60, 67). Since resistance is often associated with metal ion efflux, it is possible that YvbA may regulate efflux from B. subtilis. Unlike other members of this family, YvbA does not contain cysteine residues, which have been implicated in metal binding (55).

View larger version (37K): [in this window] [in a new window]   FIG. 1.   Expression of PW-cat-lacZ (A) and PX-cat-lacZ (B) during growth in liquid culture. Strains containing PW-cat-lacZ and PX-cat-lacZ were grown to T1 and T2, respectively, and -Gal levels were determined. Results are normalized to those for wild-type strains, in which the PW-cat-lacZ and PX-cat-lacZ strains produced 28.5 and 30.5 Miller units, respectively. Error bars represent standard deviations from the mean, with n = 2. Note that, in many cases, up-regulation is not apparent in liquid culture, despite obvious effects on plates.

Transport functions. Mutants W4 and W5 possess mini-Tn10 insertions in genes yqgE and yheH which encode transmembrane proteins with similarity to multidrug efflux proteins. YheH is a putative ATP-binding protein which has been classified into subfamily 6 of the B. subtilis ATP-binding proteins (47). Subfamily 6 includes proteins which are similar to multidrug resistance proteins of eukaryotes and bacterial proteins involved in bacteriocin and hemolysin export (Table 3). YqgE has 10 to 12 potential hydrophobic domains and is similar to drug efflux proteins (Table 3). Although yqgE is located downstream of sodA (superoxide dismutase) in several Bacillus species, it has been previously shown not to be involved in SodA activity (17).

Sugar metabolism. Mutant W9 has a mini-Tn10 in the yulE gene which encodes a protein highly similar to rhamnose isomerases (Table 3). yulE is located in an operon with other genes encoding enzymes involved in rhamnose metabolism, and YulE appears to be the only rhamnose isomerase homolog in B. subtilis. Rhamnose isomerase catalyzes the interconversion of L-rhamnose and L-rhamnulose and is required for the first step in the metabolism of L-rhamnose (36). After several days of growth on minimal medium plates containing rhamnose as the sole carbon source, colonies of the yulE::Tn10 mutant become translucent, in contrast to the parent, which remains opaque. This indicates that yulE is likely to be involved in rhamnose metabolism, since this phenotype was not observed when the yulE::Tn10 mutant was grown on glucose or mannose as the sole carbon source. It is not yet clear why a defect in rhamnose metabolism might lead to increased ^W activity.

Antimicrobial synthesis. Mutant W10 has a mini-Tn10 insertion in the pksR gene implicated in the synthesis of the broad-spectrum antimicrobial compound difficidin (28). Difficidin is a highly unsaturated 22-membered macrolide phosphate compound first identified in B. subtilis strains ATCC 39320 and ATCC 39374 (69). The mini-Tn10 has been inserted into the carboxyl-terminal thioesterase domain of PksR.

Insertions in genes of unknown function. Several additional insertions identify genes of unknown function. Interestingly, at least one (and possibly two) of these genes is under ^W control. First, a mini-Tn10 insertion (W11) was identified 43 bp upstream of the ^W-controlled ysdB gene, which encodes a predicted membrane protein (23). A recent study indicates that ysdB is also partially transcribed from an upstream promoter recognized by the general stress  factor, ^B (45). Since the mini-Tn10 was inserted into the gene-proximal ^W promoter, it is predicted that ysdB is not expressed in this mutant. Since this insertion increases ^W activity, we envision a feedback process whereby the loss of this protein leads to an unidentified signal that leads to up-regulation of ^W.

Isolation and analysis of mini-Tn10 mutants with increased ^X activity. In parallel with the above studies, we identified seven mini-Tn10 insertions that led to an up-regulation of a P_X-cat-lacZ operon fusion. Unexpectedly, the resulting insertions defined a distinct group of genes that are nevertheless implicated in the same general set of cellular functions: transport, sugar metabolism, and antimicrobial biosynthesis.

Transport functions. Mutant X1 has a mini-Tn10 in the yitG gene which encodes a putative transmembrane protein similar to multidrug efflux proteins. It has similarity to several characterized B. subtilis multidrug efflux proteins (Table 3) which mediate the efflux of a variety of structually diverse toxic compounds (1). Immediately downstream of the yitG gene is yitF, which encodes a protein similar to muconate cycloisomerases and mandelate racemases. These enzymes are involved in the catabolism of aromatic compounds (40). It is possible that yitG may be involved in the export of an aromatic-like compound in B. subtilis.

Sugar metabolism. Mutant X2 has a mini-Tn10 in the yjdE gene which encodes one of the three mannose-6-phosphate isomerase homologs in B. subtilis (Table 3). Mannose-6-phosphate isomerase catalyzes the interconversion of mannose-6-phosphate and fructose-6-phosphate. Located upstream of yjdE are genes encoding a putative transcriptional activator (yjdC) and a phosphoenolpyruvate:sugar phosphotransferase (PTS) enzyme II of the fructose-mannitol family of PTS permeases (yjdD) (Fig. 2). It has been recently hypothesized, from sequence comparisons, that this locus may be involved in mannose metabolism in B. subtilis (50); however, no direct experimental evidence has confirmed this.

View larger version (9K): [in this window] [in a new window]   FIG. 2.   Diagram of genes surrounding yjdE and mutant strains used in this study. The proposed function of the genes is based on homologies only. The mini-Tn10 insertion in yjdE identified from mutant X2 is indicated as a triangle with Tn10. The pMUTIN-yjdD plasmid used to disrupt yjdD contains DNA from within yjdD indicated with a line above the gene. Potential stem-loops are indicated as lollipops.

View larger version (17K): [in this window] [in a new window]   FIG. 3.   Growth of B. subtilis strains in minimal medium containing glucose or mannose as the sugar (A) or in LB with varying concentrations of mannose (B). (A) B. subtilis CU1065 (squares) and yjdE (circles) and yjdD (triangles) mutant were grown in Tris-Spizizen salts minimal medium containing either glucose (open symbols) or mannose (filled symbols) as the sugar. (B) Effect of mannose on growth of the yjdE mutant. Cells were grown in LB (open squares) or LB with 1.4 µM (filled circles), 14 µM (triangles), 0.14 mM (diamonds), or 1.4 mM (filled squares) mannose. Growth of B. subtilis CU1065 (open circles) was unaffected by mannose addition, and all growth curves were essentially superimposable.

Antimicrobial and polyketide synthesis. Three mutant strains with increased ^X activity were affected in genes known or suggested to be involved in the synthesis of antimicrobial compounds. Mutant X3 has a mini-Tn10 insertion in the srf locus near the end of the srfAB gene. The srf operon encodes subunits of the surfactin synthetase (7). Located within the srfAB gene is a small gene termed comS which encodes a protein which is involved in competence (9). However, the mini-Tn10 insertion in srfAB is located downstream of comS.

Proteins with unclear functions. Mutant X6 has a mini-Tn10 inserted in the ytxJ gene which encodes a protein of unknown function. ytxJ has been previously termed csb40, is controlled by ^B and ^H, and is strongly induced by the addition of salt to the cells (65). Upstream of ytxJ, and located in the same operon, ytxH encodes a product with similarity to plant proteins induced by desiccation stress (65).

	DISCUSSION

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In this study, we sought to identify genes affecting the activity of ^W or ^X. We reasoned that mutations causing deficiencies in aspects of cell metabolism controlled by either ^X or ^W might lead to up-regulation of the corresponding regulons and aid in the identification of the molecular signals controlling  factor activity. Since each of these  factors is negatively regulated by a specific anti-, we anticipated that at least one class of mutations would be insertions in the anti- gene. However, we did not recover insertions in the anti- genes in this screen. This may reflect a low frequency of transposition in these genes by the Tn10 derivative employed in these studies or may simply reflect the fact that we have not saturated this screen. However, we have obtained multiple insertions in the same gene (yvbA) or in different genes in the same operon (yshB and yshD), and our collection of mutants defines several discrete functional groups: export, sugar metabolism, and antimicrobial synthesis.

Although ^W and ^X activity is affected by mutations affecting similar functions, only the yvbA::Tn10 mutation up-regulated both ^W and ^X (^W more so than ^X). For the 16 other mutants tested (yopH::Tn10 was not included), the isolated transposon insertion affected expression of one reporter fusion, but not the other, as determined by measurements of -Gal activity on solid medium. It has been previously shown that ^W and ^X coregulate several B. subtilis genes (22), and so these two  factors do overlap in function. However, our results suggest that ^W and ^X respond to distinct stimuli, consistent with the observation that these two regulons are generally induced at different growth phases (21-24).

Many of the mini-Tn10 insertions identified in this study affect genes encoding transport proteins, including several with homology to multidrug efflux proteins. For the majority of these transporters, substrates have not yet been identified. Up-regulation of  factor activity in these transport mutants may result from the inability to export toxic compounds from the cell. Another class of mutants affects genes involved in sugar metabolism. Interestingly, both rhamnose and mannose are components of cell surface polysaccharides of some gram-negative and gram-positive bacteria (14, 33). It is possible that the yulE and yjdE mutants may be affected in the synthesis of sugar-containing cell envelope components. Although N-acetyl-mannosamine is present in the linkage unit of cell wall teichoic acid, mannose-6-phosphate does not appear to be an intermediate in its synthesis (11). Further work will be needed to examine the cell envelope constituents in wild type and sigX, sigW, yulE, and yjdE mutants.

An interesting class of mutants identified in this study were affected in genes implicated in the synthesis of antimicrobials. Insertions in these genes were particularly surprising since surfactin and pliplastin are not thought to be synthesized by B. subtilis 168 (39, 63). This is due to a mutated sfp gene which encodes a phosphopantetheinyl transferase required for conversion of the peptidyl carrier domains within the multidomain synthetase enzymes from inactive apo-forms to active holo-forms (46). We suggest that another holo-acyl carrier protein synthase homolog (perhaps YdcB) may, albeit less efficiently, activate the antimicrobial synthetase subunits and allow a low level of antimicrobial production. Indeed, Sfp phosphopantetheinylates, with varying efficiency, a wide substrate spectrum, including acyl carrier protein domains of fatty acid synthases (46). If correct, it is possible that up-regulation reflects an inability to synthesize these antibiotics or, alternatively, the presence of a covalent antibiotic-synthetase complex resulting from insertions inactivating the thioesterase domain of the synthetase which is needed for release of the antibiotic. To test this latter idea, we hypothesized that transfer of these insertions into sfp⁺ strains (known to produce active synthase) might further elevate  factor activity. However, when the srfAB::Tn10 mutation was transferred to the sfp⁺ strain B. subtilis OKB105 containing the P_X-cat-lacZ fusion, no further up-regulation in ^X activity was observed.

Our results suggest that ^W and ^X respond to a variety of signals related to extracellular functions. By analogy with other ECF  factors, the increase in  factor activity is likely mediated by the corresponding anti- factors. We hypothesize that RsiW and RsiX sense, either directly or indirectly, molecules which are exported from the cell including cell density signal peptides, sugar-containing cell envelope components, and secondary metabolites such as antimicrobial compounds.