Induction of extracytoplasmic function sigma factors in Bacillus subtilis cells with defects in lipoteichoic acid synthesis.

Lipoteichoic acid (LTA) is an important cell envelope component of Gram-positive bacteria. Bacillus subtilis has four homologous genes for LTA synthesis: ltaS (yflE), yfnI, yqgS and yvgJ. The products LtaS (YflE), YfnI and YqgS are bona fide LTA synthetases, whereas YvgJ functions only as an LTA primase. To clarify whether defects in LTA on the cell envelope trigger extracytoplasmic function (ECF) sigma factors, mRNA levels of the autoregulated ECF sigma factors in cells with singly and multiply deleted alleles of the ltaS homologues were examined by real-time RT-PCR. This revealed that sigM and sigX were induced in cells with a null allele of ΔltaS and ΔyfnI, respectively, and that no ECF sigma factor was induced in cells with a single null allele of ΔyqgS or ΔyvgJ. In cells with double null alleles (ΔltaS and ΔyfnI), sigW and ylaC were induced in addition to sigM and sigX. Cells with triple null alleles (ΔltaS ΔyfnI and ΔyqgS) showed a pattern of induction similar to that of the double null. In cells with quadruple null alleles, sigV and sigY were newly induced. Cells with ΔltaS had approximately 1/4 the diglucosyldiacylglycerol and over 10 times the CDP-diacylglycerol of wild-type cells. Compensatory elevation of the mRNA level of other homologues was observed (in ΔltaS cells the level of yfnI was elevated; in ΔyfnI cells that of yqgS and yvgJ was elevated; both were even higher in ΔltaS ΔyfnI cells). In ΔltaS cells, the mRNA level of yfnI was corroborated to be regulated by σ(M), which is activated in the null mutant cells. In ΔyfnI cells, the mRNA levels of yqgS and yvgJ reverted to less than those of wild-type when a defective sigX allele was introduced. Since sigX was activated in cells with ΔyfnI, this suggests that the induction of yqgS and yvgJ is dependent on σ(X). The LTAs produced by the four ltaS homologues seem to play distinct physiological roles to maintain the full function of LTA on the B. subtilis cell envelope.

The genome of Bacillus subtilis phage SP10: a comparative analysis with phage SPO1.

A nucleotide sequence of the whole genome of Bacillus subtilis phage SP10 was determined. It was composed of 143,986 bp with 236 putative open reading frames (ORFs). Sixty-five of 236 predicted ORFs showed high similarity to that of SPO1, and the genome organizations of the two phages were similar to each other. SP10 belongs to the Myoviridae family, for which the well-studied phage SPO1 is the representative phage. Hence, we compared SP10 to SPO1. The SP10 genome DNA showed different sensitivity to restriction enzymes than SPO1, due to differences in base modification. According to transcriptional analysis, the gene expression of regulatory network of SP10 was similar to SPO1. It was observed that RNA polymerase containing sigma-A was inactive in directing the host genes but active in directing the phage genes. It appeared that the association of sigma-A with the core enzyme complex of RNA polymerase was strengthened during development.

Heterologous expression of the Oceanobacillus iheyensis SigW and its anti-protein RsiW in Bacillus subtilis.

Pairs of the ECF sigma factor and its anti-sigma factor, SigW and RsiW, of Bacillus-related species that inhabit extreme environments were heterologously expressed in B. subtilis. All the RsiWs, membrane proteins, failed to fill their function of repressing cognate SigW activity, despite their close structural similarities. Particularly, uncontrolled expression of Oceanobacillus iheyensis OISigW due to abortive OIRsiW was harmful to B. subtilis. Analysis of revertants of this growth defect and site-directed mutagenesis indicated that the insertion of six and a minimum of three hydrophobic amino acid residues occurring in the transmembrane region allowed OIRsiW to function as anti-OISigW. Subcellular localization of OIRsiW was detected by immunoblot analysis, suggesting that both the wild-type and the mutant form of OIRsiW were localized to the membrane. An appropriate length of a transmembrane region required for proper integration into the membrane after translocation might vary among these Bacillus-related species.

Transcriptomic and phenotypic characterization of a Bacillus subtilis strain without extracytoplasmic function σ factors.

Bacillus subtilis encodes seven extracytoplasmic function (ECF) σ factors. Three (σ(M), σ(W), and σ(X)) mediate responses to cell envelope-active antibiotics. The functions of σ(V), σ(Y), σ(Z), and σ(YlaC) remain largely unknown, and strong inducers of these σ factors and their regulons have yet to be defined. Here, we define transcriptomic and phenotypic differences under nonstress conditions between a strain carrying deletions in all seven ECF σ factor genes (the Δ7ECF mutant), a ΔMWX triple mutant, and the parental 168 strain. Our results identify >80 genes as at least partially dependent on ECF σ factors, and as expected, most of these are dependent on σ(M), σ(W), or σ(X), which are active at a significant basal level during growth. Several genes, including the eps operon encoding enzymes for exopolysaccharide (EPS) production, were decreased in expression in the Δ7ECF mutant but affected less in the ΔMWX mutant. Consistent with this observation, the Δ7ECF mutant (but not the ΔMWX mutant) showed reduced biofilm formation. Extending previous observations, we also note that the ΔMWX mutant is sensitive to a variety of antibiotics and the Δ7ECF mutant is either as sensitive as, or slightly more sensitive than, the ΔMWX strain to these stressors. These findings emphasize the overlapping nature of the seven ECF σ factor regulons in B. subtilis, confirm that three of these (σ(M), σ(W), and σ(X)) play the dominant role in conferring intrinsic resistance to antibiotics, and provide initial insights into the roles of the remaining ECF σ factors.

Induction of extracytoplasmic function sigma factors in Bacillus subtilis cells with membranes of reduced phosphatidylglycerol content.

The Bacillus subtilis gene pgsA, which codes for the phosphatidylglycerophosphate synthase that catalyzes the committed step for the synthesis of phosphatidylglycerol (PG), is essential since Pspac-pgsA cells require IPTG for growth. Removal of the inducer caused a dramatic decrease of PG content in the membranes of cells and retarded growth. At 60 min and 120 min after removal, it was reduced to 14.1% and 8.9% of total lipid, respectively, from an initial content of 28.1%. We conjectured that the activity of some extracytoplasmic function (ECF) sigma factors, most of which are caught and regulated directly by cognate transmembrane anti-sigma factors, are affected by altered lipid composition of the membranes. Induction of the activities of ECF sigma factors (sigma(M) and sigma(V)) was observed after removal of IPTG, though that of sigma(V) was small. But other ECF sigma factors (sigma(W), sigma(X), sigma(Y), sigma(YlaC) and sigma(Z)) and the general stress sigmas sigma(B) and sigma(I) were not induced. Especially sigma(M) was activated strongly with the reduction of PG content and sustained a high level of activity, in contrast to the transient activation in PG normal cells after exposure to high salinity. This study demonstrates a new relationship between the alterations of lipid composition in the membranes and the activation of ECF sigma factors.

A viable Bacillus subtilis strain without functional extracytoplasmic function sigma genes.

We constructed a Bacillus subtilis Marburg strain that harbors deletion mutations in all seven extracytoplasmic function (ECF) sigma genes. The strain shows wild-type growth at 37 degrees C both in a complex and in a synthetic medium and exhibits wild-type sporulation. ECF sigma genes of B. subtilis are dispensable as long as no stress is imposed, although they seem to be required for quick response to stresses.

Glucomannan utilization operon of Bacillus subtilis.

This study characterizes the glucomannan utilization operon (gmuBACDREFG, formerly ydhMNOPQRST) of Bacillus subtilis. Transcription of the operon is induced by konjac glucomannan and requires the last mannanase gene (gmuG). Cellobiose and mannobiose, possible degradation products of glucomannan by GmuG, are strong inducers of transcription. It is shown that an internal regulator gene (gmuR) encodes a repressor of the operon, as disruption of this gene enhances transcription of the operon in the absence of inducers. The expression of the glucomannan utilizing operon of B. subtilis is thus induced by degraded glucomannan products, and repressed by an internal repressor.

Functional analysis of the plastid and nuclear encoded CbbX proteins of Cyanidioschyzon merolae.

CbbX is believed to be a transcriptional regulator of the subunit genes (rbcL and rbcS) of RuBisCO (Ribulose 1,5-bisphosphate carboxylase/oxygenase) as well as possibly a molecular chaperon of RuBisCO subunit assembly. The unicellular red alga Cyanidioschyzon merolae strain 10D possesses two distinct cbbX genes; one is part of the plastid genome and the other is found in the cell nucleus, whereas the RuBisCO operon (rbcL-rbcS-cbbX) is located only on the plastid genome. We examined the role of CbbX proteins of C. merolae in the expression of the RuBisCO operon. First, His-tagged nuclear and plastid CbbX proteins were produced in Escherichia coli and purified by affinity column chromatography. Both proteins showed binding activity to upstream of the coding region of rbcL. Yeast two hybrid analysis showed direct interaction between nuclear and plastid CbbX proteins but no interaction were found among CbbX, RbcL and RbcS. Then the transcription initiation site of the RuBisCO operon of C. merolae was determined. Next, in order to examine the role of CbbX in vivo, we constructed a plasmid carrying the promoter region of the RuBisCO operon fused to Escherichia coli lacZ, and introduced it into E. coli cells into which a cloned nuclear or plastid cbbX gene under IPTG inducible promoter control was also introduced. Expression of LacZ in the transformed E.coli was observed. Enforced expression of either one of the cbbX genes resulted in a remarkable reduction of lacZ expression suggesting that CbbXs are rather transcriptional regulators than the molecular chaperon of RuBisCO. We discuss the mechanism by which the nuclear and plastid CbbX proteins regulate the RuBisCO operon of C. merolae.

Restriction and modification of SP10 phage by BsuM of Bacillus subtilis Marburg.

Bacillus subtilis Marburg has only one intrinsic restriction and modification system BsuM that recognizes the CTCGAG (XhoI site) sequence. It consists of two operons, BsuMM operon for two cytosine DNA methyltransferases, and BsuMR operon for a restriction nuclease and two associated proteins of unknown function. In this communication, we analyzed the BsuM system by utilizing phage SP10 that possesses more than twenty BsuM target sequences on the phage genome. SP10 phages grown in the restriction and modification-deficient strain could not make plaques on the restriction-proficient BsuMR(+) indicator strain. An enforced expression of the wild type BsuMM operon in the BsuMR(+) indicator strain, however, allowed more than thousand times more plaques. DNA extracted from SP10 phages, thus, propagated became more but not completely refractory to XhoI digestion in vitro. Thus, the SP10 phage genome DNA is able to be nearly full-methylated but some BsuM sites are considered to be unmethylated.

Transcriptional analysis of the ylaABCD operon of Bacillus subtilis encoding a sigma factor of extracytoplasmic function family.

The ylaABCD operon of Bacillus subtilis contains four predicted ORFs in the order ylaA, ylaB, ylaC and ylaD, where ylaC is assumed to code for a sigma factor of the extracytoplasmic function (ECF) family. Predicted YlaD may function as the anti-YlaC factor as it has an oxidative stress sensing domain similar to that of the RsrA, which is the anti-sigma factor of SigR, an ECF sigma of Streptomyces coelicolor. Northern blot analysis of the ylaABCD operon revealed two transcriptional products resulting from a distal promoter upstream of ylaA and from an internal promoter located at the first codon of ylaC. Both transcription start sites were determine by primer extension and 5'-RACE PCR. The transcription from the distal promoter was initiated by over-expression of YlaC on a multi-copy plasmid and depended on YlaC. DNA sequences of the -35 and -10 regions were similar to those recognized by other ECF sigmas of B. subtilis. On the other hand the transcription from the internal promoter was induced by oxidative stress and depended on Spx, which is an oxidative stress responding factor interacting with the alpha subunit of RNA polymerase core enzyme. The latter transcription depended possibly on SigA. We could not detect translation of YlaC from this transcript. Experiments with ylaD-disruption or co-overexpression of ylaD with ylaC suggested that YlaD functions as the anti-YlaC factor. Although YlaD has an oxidative stress sensing domain, oxidative stress did not induce the whole ylaABCD operon.

Organization and expression of the Bacillus subtilis sigY operon.

We investigated the organization and expression of the Bacillus subtilis sigY operon, the first gene of which codes for sigmaY, a member of the extracytoplasmic function (ECF) family of sigma factors. The sigY operon, comprising six genes (sigY, yxlC, D, E, F, and G), was induced upon nitrogen starvation; it was continuously transcribed from the 31st base upstream of sigY to a neighboring convergent gene, yxlH, resulting in a 4.2-kb mRNA. The expression of the sigY operon was also positively autoregulated through sigmaY, suggesting that its transcription is likely to be directed by sigmaY. Deletion analysis of the sigY promoter, which was localized by primer extension, revealed the promoter region of sigY with the "-10" and "-35" sequences of CGTC and TGAACG, respectively. The latter sequence was distinct from those recognized by sigmaW, sigmaX, and sigmaM. The sigmaY-directed transcription of sigY was under negative regulation involving YxlD. sigY disruption affected sporulation induced by nitrogen starvation, but sigY induction upon nitrogen starvation was not associated with the sporulation process. The organization and function of the sigY operon are significantly conserved in several microorganisms living in adverse living environments.

Altered gene expression in the transition phase by disruption of a Na+/H+ antiporter gene (shaA) in Bacillus subtilis.

The shaA gene (sodium-hydrogen antiporter gene A, identical to mrpA) is largely responsible for Na+ extrusion in Bacillus subtilis. The disruption of shaA combined with a low concentration of NaCl completely abolishes sporulation but allows normal growth. To investigate the role of shaA and shaA-mediated sodium ion homeostasis in sporulation, we performed a comprehensive study of expression profiles of eight alternative sigma factors, sigmaB and the seven extracytoplasmic function sigma factors (sigmaM, sigmaV, sigmaW, sigmaX, sigmaY, sigmaZ, and sigmaYlaC) in an attempt to determine the global change of gene expression that results from a disturbance of Na+ homeostasis caused by shaA disruption. Induction of sigmaB activity in the transition phase was impaired in the shaA mutant, and this effect was enhanced in the presence of 30 mM NaCl. Salt stress activation of sigmaB occurred normally in the shaA mutant. sigmaM-, sigmaW-, sigmaX-dependent transcription and sigZ transcription was also induced in the transition phase of the wild-type, which was modulated by shaA disruption. The induction of sigmaM-dependent transcription was enhanced in the shaA mutant, while that of sigmaX-dependent transcription and sigZ transcription was decreased. sigmaW-dependent transcription was increased throughout the growth phase of the shaA mutant, which was consistent with the result of proteome analysis. We conclude that shaA disruption resulted in the modulated induction of alternative sigma factor activities, which would be problematic for the cell upon entering the sporulation stage.

DNA microarray analysis of Bacillus subtilis sigma factors of extracytoplasmic function family.

Target gene candidates of the seven extracytoplasmic function (ECF) sigma factors of Bacillus subtilis have been surveyed using DNA microarray analysis of mRNA extracted from cells grown in Luria-Bertani broth, in which an ECF sigma factor gene was placed under the control of the spac promoter on multicopy plasmid pDG148 and overexpressed. The number of target candidates for each of the sigma factors varied greatly, and a total of 278 genes were selected. Interestingly, the above target gene candidates shared only one gene out of 94 target genes of the general stress sigma B that have been reported in the literature thus far. Furthermore, lacZ-fusion experiments based on the results of DNA microarray analysis indicated that each ECF sigma factor directs transcription of its own operon, with the exception of sigZ. The DNA microarray data collected in this study are available at the KEGG Expression Database web site (http://www.genome.ad.jp/kegg/expression/).

Identification of the nonA and nonB loci of Bacillus subtilis Marburg permitting the growth of SP10 phage.

Mutational inactivation of both nonA and nonB genes are required for the permissiveness of Bacillus subtilis Marburg cells to infection by phage SP10. By transformational analysis of the nonA strain with DNAs from gently lysed protoplasts carrying the integrative plasmid pMUTIN (em) insertions in every 20 kb along the whole chromosome, we have identified the nonA to be the cured state of endogenous prophage SPbeta. Direct DNA sequencing, on the other hand, revealed one nonsense mutation of nonB in ydiR, which is a component gene of the intrinsic restriction system BsuMR of B.subtilis Marburg. Introduction of the wild type ydiR into the nonB strain at aprE locus resulted in complementation of nonB. Furthermore, as the SP10 genome was found to possess multiple BsuM target sites, it is considered that SP10 can infect and multiply in B.subtilis cells, which are SPbeta free and possess a defective BsuMR restriction system.

Inhibitory effect of prophage SPß fragments on phage SP10 ribonucleotide reductase function and its multiplication in Bacillus subtilis.

Bacteria have evolved various kinds of defense mechanisms against phage infection and multiplication. Analysis of these mechanisms is important for medical and industrial application of phages as well as for their scientific study. Strains of Bacillus subtilis Marburg strain carrying both nonA and nonB mutations are susceptible to the Bacillus phage SP10. The nonB mutation has been shown to have a compromised intrinsic restriction system. The nonA mutation represents the cured state of prophage SPß whose genome is 135 kb in length and contains 187 ORFs. For this study we investigated the molecular mechanism behind the inhibitory activity of the wild type nonA function against phage SP10 development. The progression of phage-developmental stages was examined in cells harboring wild type nonA, i.e. prophage SPß. After phage adsorption and DNA injection into host cells, the synthesis of phage specific mRNA proceeded normally. However, phage DNA synthesis was severely inhibited by some effect of wild type nonA. We thus systematically deleted portions of the prophage SPß region from the B. subtilis genome and the resultant mutant strains were examined as to whether they still retained sufficient wild type nonA functionality to inhibit SP10 phage development. The SPß region encompassing the bnrdEF gene, which codes for a putative ribonucleotide reductase (RRase), turned out to be responsible for the wild type nonA function. The phage SP10 possesses its own xnrdE gene coding for a putative RRase that complements the temperature-sensitive mutation of the host RRase gene nrdE. This complementation was blocked by an artificially induced transcription from a non-coding strand of the bnrdEF region. It is thus likely that the transcript from the bnrdEF region of SPß inhibits ribonucleotide reductase function of SP10, resulting in arrest of DNA synthesis during phage SP10 development.

Isolation and characterization of sporulation-initiation mutation in the Bacillus subtilis prfB gene.

A Bacillus subtilis prfB45 mutant grew at 42 degrees C, but its sporulation was severely defective at 37 degrees C. Sporulation-specific induction of kinA, spo0A, and spo0H genes was inhibited in the mutant. The effects of temperature up-shift and down-shift on sporulation of the prfB45 mutant was observed at an early stage of sporulation. UGA readthrough frequency at non-permissive temperatures for sporulation was higher in the mutant than in the wild-type strain. Temperature-sensitive sporulation of the prfB45 mutant was suppressed by mutations in rpsL coding for S12 of ribosomes, required for accurate termination of translation. Additionally, spontaneous second-site mutations that suppressed the sporulation phenotype of the prfB45 strain were found in the rpoB gene. These results suggest that accurate termination of translation is required for proper initiation of sporulation.

Reducing sludge production and the domination of Comamonadaceae by reducing the oxygen supply in the wastewater treatment procedure of a food-processing factory.

Sludge production was reduced remarkably by reducing the dissolved oxygen supply to less than 1 mg/l in the conventional wastewater treatment procedure of a food-processing factory that produced 180 m(3) of wastewater of biochemical oxygen demand (BOD) of about 1,000 mg/l daily. DNA was extracted from the sludge and subjected to PCR amplification. The PCR product was cloned into a plasmid and sequenced. Estimation of the resident bacterial distribution by 16S rDNA sequences before and after improvement of the system suggested a remarkable gradual change in the major bacterial population from Anaerolinaeceae (15.6%) to Comamonadaceae (52.3%), members of denitrifying bacteria of Proteobacteria. Although we did not directly confirm the ability of denitrification of the resulting sludge, a change in the major final electron acceptors from oxygen to nitrate might explain the reduction in sludge production in a conventional activated sludge process when the oxygen supply was limitted.

Regulatory role of RsgI in sigI expression in Bacillus subtilis.

The sigma gene, sigI, of Bacillus subtilis belongs to the group IV heat-shock response genes and has many orthologues in the bacterial phylum Firmicutes. The B. subtilis sigI gene is considered to constitute an operon with rsgI (regulation of sigI, formerly ykrI). As little is known about either the structure and function of the sigI-rsgI operon or the SigI regulons, the role of RsgI in heat-inducible transcription of the sigI-rsgI operon was investigated, using Northern analysis and a heat-stable beta-galactosidase reporter assay. Heat-inducible, SigI-dependent transcription of the sigI-rsgI operon was stimulated greatly by disrupting rsgI. Yeast two-hybrid analysis showed direct interaction between the N-terminal portion of the presumed RsgI protein and SigI. Without RsgI function, induction of transcription of the sigI-rsgI operon upon transient heat stress depended on dnaK activity. However, transcription of the operon was induced during growth at prolonged higher temperature even without DnaK function. Without RsgI function, sigI-rsgI operon transcription was induced after the end of growth independent of any temperature shift in a sporulation medium and toward the end of growth in a rich complex medium. Furthermore, glucose addition resulted in a strong suppression of sigI-rsgI transcription. Therefore it is hypothesized that transcription of the sigI-rsgI operon of B. subtilis is negatively regulated by the putative transmembrane protein RsgI, which moderates SigI's sensitivity to heat shock or nutritional stress.

Enhancement of glutamine utilization in Bacillus subtilis through the GlnK-GlnL two-component regulatory system.

During DNA microarray analysis, we discovered that the GlnK-GlnL (formerly YcbA-YcbB) two-component system positively regulates the expression of the glsA-glnT (formerly ybgJ-ybgH) operon in response to glutamine in the culture medium on Northern analysis. As a result of gel retardation and DNase I footprinting analyses, we found that the GlnL protein interacts with a region (bases -13 to -56; +1 is the transcription initiation base determined on primer extension analysis of glsA-glnT) in which a direct repeat, TTTTGTN4TTTTGT, is present. Furthermore, the glsA and glnT genes were biochemically verified to encode glutaminase and glutamine transporter, respectively.