Transcription of Bacillus subtilis degR is sigma D dependent and suppressed by multicopy proB through sigma D

Glucose controls manganese homeostasis through transcription factors regulating known and newly identified manganese transporter genes in Bacillus subtilis

Mn2+ is an essential nutrient whose concentration is tightly controlled in bacteria. In Bacillus subtilis, the Mn2+-activated transcription factor MntR controls Mn2+ transporter genes. However, factors regulating intracellular Mn2+ concentration are incompletely understood. Here, we found that glucose addition induces an increase in intracellular Mn2+ concentration. We determined this upshift was mediated by glucose induction of the major Mn2+ importer gene mntH by the transcription factor AhrC, which is known to be involved in arginine metabolism and to be indirectly induced by glucose. In addition, we identified novel AhrC-regulated genes encoding the Mn2+ importer YcsG and the ABC-type exporter YknUV. We found the expression of these genes was also regulated by glucose and contributes to the glucose induction of Mn2+ concentrations. ycsG expression is regulated by MntR as well. Furthermore, we analyzed the interaction of AhrC and MntR with the promoter driving ycsG expression and examined the Mn2+-dependent induction of this promoter to identify the transcription factors responsible for the Mn2+ induction. RNA-Seq revealed that disruption of ahrC and mntR affected the expression of 502 and 478 genes, respectively (false discovery rate, <0.001, log2[fold change] ≥ |2|. The AhrC- and/or MntR-dependent expression of twenty promoters was confirmed by LacZ analysis, and AhrC or MntR binding to some of these promoters was observed via EMSA. The finding that glucose promotes an increase in intracellular Mn2+ levels without changes in extracellular Mn2+ concentrations is reasonable for the bacterium, as intracellular Mn2+ is required for enzymes and pathways mediating glucose metabolism.

Glucose-Mediated Protein Arginine Phosphorylation/Dephosphorylation Regulates ylxR Encoding Nucleoid-Associated Protein and Cell Growth in Bacillus subtilis

Glucose is the most favorable carbon source for many bacteria, and these bacteria have several glucose-responsive networks. We proposed new glucose responsive system, which includes protein acetylation and probable translation control through TsaEBD, which is a tRNA modification enzyme required for the synthesis of threonylcarbamoyl adenosine (t⁶A)-tRNA. The system also includes nucleoid-associated protein YlxR, regulating more than 400 genes including many metabolic genes and the ylxR-containing operon driven by the PylxS promoter is induced by glucose. Thus, transposon mutagenesis was performed for searching regulatory factors for PylxS expression. As a result, ywlE was identified. The McsB kinase phosphorylates arginine (Arg) residues of proteins and the YwlE phosphatase counteracts against McsB through Arg-dephosphorylation. Phosphorylated Arg has been known to function as a tag for ClpCP-dependent protein degradation. The previous analysis identified TsaD as an Arg-phosphorylated protein. Our results showed that the McsB/YwlE system regulates PylxS expression through ClpCP-mediated protein degradation of TsaD. In addition, we observed that glucose induced ywlE expression and repressed mcsB expression. It was concluded that these phenomena would cause glucose induction (GI) of PylxS, based on the Western blot analyses of TsaD-FLAG. These observations and the previous those that many glycolytic enzymes are Arg-phosphorylated suggested that the McsB/YwlE system might be involved in cell growth in glucose-containing medium. We observed that the disruption of mcsB and ywlE resulted in an increase of cell mass and delayed growth, respectively, in semi-synthetic medium. These results provide us broader insights to the physiological roles of the McsB/YwlE system and protein Arg-phosphorylation.

Bacillus subtilis Nucleoid-Associated Protein YlxR Is Involved in Bimodal Expression of the Fructoselysine Utilization Operon (frlBONMD-yurJ) Promoter

Bacteria must survive harsh environmental fluctuations at times and have evolved several strategies. “Collective” behaviors have been identified due to recent progress in single-cell analysis. Since most bacteria exist as single cells, bacterial populations are often considered clonal. However, accumulated evidence suggests this is not the case. Gene expression and protein expression are often not homogeneous, resulting in phenotypic heterogeneity. In extreme cases, this leads to bistability, the existence of two stable states. In many cases, expression of key master regulators is bimodal via positive feedback loops causing bimodal expression of the target genes. We observed bimodal expression of metabolic genes for alternative carbon sources. Expression profiles of the frlBONMD-yurJ operon driven by the frlB promoter (PfrlB), which encodes degradation enzymes and a transporter for amino sugars including fructoselysine, were investigated using transcriptional lacZ and gfp, and translational fluorescence reporter mCherry fusions. Disruption effects of genes encoding CodY, FrlR, RNaseY, and nucleoid-associated protein YlxR, four known regulatory factors for PfrlB, were examined for expression of each fusion construct. Expression of PfrlB-gfp and PfrlB-mCherry, which were located at amyE and its original locus, respectively, was bimodal; and disruption of ylxR resulted in the disappearance of the clear bimodal expression pattern in flow cytometric analyses. This suggested a role for YlxR on the bimodal expression of PfrlB. The data indicated that YlxR acted on the bimodal expression of PfrlB through both transcription and translation. YlxR regulates many genes, including those related to translation, supporting the above notion. Depletion of RNaseY abolished heterogenous expression of transcriptional PfrlB-gfp but not bimodal expression of translational PfrlB-mCherry, suggesting the role of RNaseY in regulation of the operon through mRNA stability control and regulatory mechanism for PfrlB-mCherry at the translational level. Based on these results, we discuss the meaning and possible cause of bimodal PfrlB expression.

Bacillus subtilis YlxR, Which Is Involved in Glucose-Responsive Metabolic Changes, Regulates Expression of tsaD for Protein Quality Control of Pyruvate Dehydrogenase

Glucose is the most favorable carbon source for many bacteria, which have several glucose-responsive gene networks. Recently, we found that in Bacillus subtilis glucose induces the expression of the extracellular sigma factor genes sigX and sigM through the acetylation of CshA (RNA helicase), which associates with RNA polymerase (RNAP). We performed a transposon mutagenesis screen for mutants with no glucose induction (GI) of sigX-lacZ. While screening for such mutants, we recently found that the GI of sigX/M involves YlxR, a nucleoid-associated protein (NAP) that regulates nearly 400 genes, including metabolic genes. It has been shown that acetylated CshA positively regulates expression of ylxR-containing operon. Here, we report additional mutations in yqfO or tsaD required for the GI of sigX. YqfO contains a universally conserved domain with unknown function. YqfO and YlxR were found to regulate expression of the tsaEBD-containing operon. Mutational analysis using lacZ fusions revealed the adenine-rich cis-element for YlxR. TsaD is a component of the TsaEBD enzyme required for the synthesis of threonylcarbamoyl adenosine (t6A). The t6A modification of tRNA is universal across the three domains of life. Western blot analysis showed that the tsaD mutation in the presence of glucose reduced levels of soluble PdhA, PdhB, and PdhD, which are subunits of the pyruvate dehydrogenase complex (PDHc). This resulted in severely defective PDHc function and thus reduced concentrations of cellular acetyl-CoA, a reaction product of PDHc and plausible source for CshA acetylation. Thus, we discuss a suggested glucose-responsive system (GRS) involving self-reinforcing CshA acetylation. This self-reinforcing pathway may contribute to the maintenance of the acetyl-CoA pool for protein acetylation.

Newly Identified Nucleoid-Associated-Like Protein YlxR Regulates Metabolic Gene Expression in Bacillus subtilis

Expression of genes encoding NAPs is often temporally regulated. According to results from single-cell analysis, the ylxR gene is induced by glucose and expressed in a bistable mode. These characteristics have not previously been reported for NAP gene expression. Transcriptional profiling of the ylxR disruptant revealed a change in the expression levels of approximately 400 genes, including genes for synthesis of 12 amino acids and 4 nucleotides, in addition to the SigX/M regulons. Thus, YlxR is a critical regulator of glucose response in B. subtilis.

Glucose is the most favorable carbon source for the majority of bacteria, which have several glucose-responsive gene networks. Recently, we found that in Bacillus subtilis, glucose induces expression of the extracellular sigma factor genes sigX/M. To explore the factors affecting this phenomenon, we performed a transposon mutagenesis screen for mutants with no glucose induction (GI) of sigX-lacZ and identified ylxR. YlxR is widely conserved in eubacteria. Further analysis revealed that ylxR is induced by glucose addition. In vitro DNA-binding and cytological studies suggested that YlxR is a nucleoid-associated protein (NAP) in B. subtilis. In many cases, NAPs influence transcription, recombination, and genome stability. Thus, we performed transcriptome sequencing (RNA-Seq) analysis to evaluate the impact of ylxR disruption on the transcriptome in the presence of glucose and observed that YlxR has a profound impact on metabolic gene expression in addition to that of four sigma factor genes. The wide fluctuations of gene expression may result in abolition of GI of sigX/M in the ylxR disruptant.

IMPORTANCE Expression of genes encoding NAPs is often temporally regulated. According to results from single-cell analysis, the ylxR gene is induced by glucose and expressed in a bistable mode. These characteristics have not previously been reported for NAP gene expression. Transcriptional profiling of the ylxR disruptant revealed a change in the expression levels of approximately 400 genes, including genes for synthesis of 12 amino acids and 4 nucleotides, in addition to the SigX/M regulons. Thus, YlxR is a critical regulator of glucose response in B. subtilis.

Dual Regulation of Bacillus subtilis kinB Gene Encoding a Sporulation Trigger by SinR through Transcription Repression and Positive Stringent Transcription Control

It is known that transcription of kinB encoding a trigger for Bacillus subtilis sporulation is under repression by SinR, a master repressor of biofilm formation, and under positive stringent transcription control depending on the adenine species at the transcription initiation nucleotide (nt). Deletion and base substitution analyses of the kinB promoter (P_kinB) region using lacZ fusions indicated that either a 5-nt deletion (Δ5, nt -61/-57, +1 is the transcription initiation nt) or the substitution of G at nt -45 with A (G-45A) relieved kinB repression. Thus, we found a pair of SinR-binding consensus sequences (GTTCTYT; Y is T or C) in an inverted orientation (SinR-1) between nt -57/-42, which is most likely a SinR-binding site for kinB repression. This relief from SinR repression likely requires SinI, an antagonist of SinR. Surprisingly, we found that SinR is essential for positive stringent transcription control of P_kinB. Electrophoretic mobility shift assay (EMSA) analysis indicated that SinR bound not only to SinR-1 but also to SinR-2 (nt -29/-8) consisting of another pair of SinR consensus sequences in a tandem repeat arrangement; the two sequences partially overlap the ‘-35’ and ‘-10’ regions of P_kinB. Introduction of base substitutions (T-27C C-26T) in the upstream consensus sequence of SinR-2 affected positive stringent transcription control of P_kinB, suggesting that SinR binding to SinR-2 likely causes this positive control. EMSA also implied that RNA polymerase and SinR are possibly bound together to SinR-2 to form a transcription initiation complex for kinB transcription. Thus, it was suggested in this work that derepression of kinB from SinR repression by SinI induced by Spo0A∼P and occurrence of SinR-dependent positive stringent transcription control of kinB might induce effective sporulation cooperatively, implying an intimate interplay by stringent response, sporulation, and biofilm formation.

PrgU: a suppressor of sex pheromone toxicity in Enterococcus faecalis

Upon sensing of the peptide pheromone cCF10, Enterococcus faecalis cells carrying pCF10 produce three surface adhesins (PrgA, PrgB or Aggregation Substance, PrgC) and the Prg/Pcf type IV secretion system and, in turn, conjugatively transfer the plasmid at high frequencies to recipient cells. Here, we report that cCF10 induction is highly toxic to cells sustaining a deletion of prgU, a small orf located immediately downstream of prgB on pCF10. Upon pheromone exposure, these cells overproduce the Prg adhesins and display impaired envelope integrity, as evidenced by antibiotic susceptibility, misplaced division septa and cell lysis. Compensatory mutations in regulatory loci controlling expression of pCF10-encoded prg/pcf genes, or constitutive PrgU overproduction, block production of the Prg adhesins and render cells insensitive to pheromone. Cells engineered to overproduce PrgB, even independently of other pCF10-encoded proteins, have severely compromised cell envelopes and strong growth defects. PrgU has an RNA-binding fold, and prgB-prgU gene pairs are widely distributed among E. faecalis isolates and other enterococcal and staphylococcal species. Together, our findings support a model in which PrgU proteins represent a novel class of RNA-binding regulators that act to mitigate toxicity accompanying overproduction of PrgB-like adhesins in E. faecalis and other clinically-important Gram-positive species.

Glucose Induces ECF Sigma Factor Genes, sigX and sigM, Independent of Cognate Anti-sigma Factors through Acetylation of CshA in Bacillus subtilis

Extracytoplasmic function (ECF) σ factors have roles related to cell envelope and/or cell membrane functions, in addition to other cellular functions. Without cell-surface stresses, ECF σ factors are sequestered by the cognate anti-σ factor, leading to inactivation and the resultant repression of regulons due to the inhibition of transcription of their own genes. Bacillus subtilis has seven ECF σ factors including σ^X and σ^M that transcribe their own structural genes. Here, we report that glucose addition to the medium induced sigX and sigM transcription independent of their anti-σ factors. This induction was dependent on an intracellular acetyl-CoA pool. Transposon mutagenesis searching for the mutants showing no induction of sigX and sigM revealed that the cshA gene encoding DEAD-box RNA helicase is required for gene induction. Global analysis of the acetylome in B. subtilis showed CshA has two acetylated lysine residues. We found that in a cshA mutant with acetylation-abolishing K to R exchange mutations, glucose induction of sigX and sigM was abolished and that glucose addition stimulated acetylation of CshA in the wild type strain. Thus, we present a model wherein glucose addition results in a larger acetyl-CoA pool, probably leading to increased levels of acetylated CshA. CshA is known to associate with RNA polymerase (RNAP), and thus RNAP with acetylated CshA could stimulate the autoregulation of sigX and sigM. This is a unique model showing a functional link between nutritional signals and the basal transcription machinery.

Post-transcriptionally generated cell heterogeneity regulates biofilm formation in Bacillus subtilis

Bacillus subtilis forms biofilms in appropriate environments by producing extracellular matrices. Genes required for matrix formation, for example tapA, are regulated by the SinI/SinR/SlrR system. SinR is the repressor for tapA. SinI and SlrR inhibit DNA-binding of SinR. sinI and sinR constitute two-gene operon, and sinR has its own promoter. During biofilm formation, a portion of the population differentiates into matrix-producing cells. This is thought to be caused by Spo0A-dependent, heterogeneous expression of the PsinI promoter, whereas the PsinR promoter is expressed homogeneously. However, we observed that at its original locus, overall sinI transcription was almost homogeneous, because upstream read-through transcription from PyqHG would overcome expression of PsinI. When we used translational sinI-gfp and sinR-mCherry reporters at their original loci, their fluorescence distribution patterns in the cell population were clearly bimodal. This bimodal expression might be caused by cell-to-cell variations of mRNA stability. This study shows that the post-transcriptionally regulated bimodal expression of SinI and SinR is important for bacterial cell-fate determination.

Bacillus subtilis degSU operon is regulated by the ClpXP-Spx regulated proteolysis system

The DegS-DegU two-component regulatory system regulates many cellular events in Bacillus subtilis. Genes for DegSU constitutes an operon directed by the P1 promoter and downstream degU is autoregulated via the P3 promoter activated by phosphorylated DegU. In the Gram-positive bacteria, Spx plays a major role in the protection system against oxidative stresses as a transcriptional regulator. Spx is a substrate of the ATP-dependent ClpXP protease. It regulates diamide-stress regulon in addition to many genes with unknown functions. We have found that null mutations for clpX and clpP, which encode the subunits for the protease ClpXP, enhanced the DegU level through activation of the P1 promoter. We isolated four suppressors for the clpP-enhancing effect. Whole-genome sequencing of the suppressors revealed that two have a point mutation in spx and the rest have a deletion of spx. The clpP-enhancing effect on degS-lacZ expression was abolished in the spx disruptant. These results show that the degSU operon is a new target of Spx-mediated positive regulation. Furthermore, we found that the P1 promoter was induced by glucose and that this induction was greatly reduced in the spx mutant. These results suggested that Spx-mediated glucose induction at the P1 promoter.

Regulation of the response regulator gene degU through the binding of SinR/SlrR and exclusion of SinR/SlrR by DegU in Bacillus subtilis

Bacillus subtilis DegU is a response regulator of the DegS-DegU two-component regulatory system. Phosphorylated DegU (DegU-P) controls many genes and biological processes, such as exoprotease and γ-polyglutamic acid production, in addition to the degU gene, by binding to target gene promoters. Nonphosphorylated DegU and low levels of DegU-P are required for swarming motility and genetic competence. The DNA-binding repressors SinR and SlrR are part of a double-negative feedback loop and comprise the epigenetic switch governing biofilm formation. In this study, we found that SinR repressed degU. Furthermore, SlrR, which interacts with SinR through protein-protein interaction, seems to have an active role in degU expression in in vivo lacZ analysis. An in vitro transcription assay supported this observation. An electrophoretic mobility shift assay (EMSA) showed that SinR bound to the degU promoter and that SlrR formed a complex with SinR on the degU promoter. In EMSA, DegU-P excluded the SinR/SlrR complex but not SinR from the degU promoter in the presence of RNA polymerase. These findings suggest that DegU-P interacts with SlrR. In support of this hypothesis, disruption of the slrR gene resulted in decreased degU expression. This newly identified regulatory mechanism for degU is considered to be sequential transcription factor replacement.

Identification of the sequences recognized by the Bacillus subtilis response regulator YclJ

The Bacillus subtilis yclJ gene encodes an OmpR-type response regulator of a two-component regulatory system with unknown function. A previous DNA microarray experiment suggested that multicopy yclJ greatly enhances the expression of several operons in a cognate kinase (YclK)-deficient strain. To confirm this, lacZ fusion analysis was performed in the yclK background with overexpressed yclJ. As a result, yclHI, ykcBC, and yngABC were indeed positively regulated by YclJ. Gel retardation and DNase I footprint analyses revealed that YclJ binds to the promoter regions of yclHI, ykcBC, and yngABC. Nucleotide sequence analysis of the binding regions suggested that YclJ recognizes a direct repeat of the consensus sequence TTCATANTTT, the upstream half of which has close similarity to the consensus binding sequence of the other OmpR family response regulator PhoP. LacZ fusion analysis of the control region of yngA with deletion or point mutation confirmed that the YclJ-binding sequence is required for the YclJ-mediated activation of yngA. Furthermore, we identified two more YclJ-regulated genes, yycA and yfjR, using bioinformatic analysis of the B. subtilis genome, and it was shown that YclJ binds to those promoters and controls the expression of those genes.

Autoregulation of the Bacillus subtilis response regulator gene degU is coupled with the proteolysis of DegU-P by ClpCP

The response regulator DegU and its cognate kinase DegS constitute a two-component system in Bacillus subtilis that regulates many cellular processes, including exoprotease production and competence development. Using DNA footprint assay, gel shift assay and mutational analyses of P3degU-lacZ fusions, we showed that phosphorylated DegU (DegU-P) binds to two direct repeats (DR1 and DR2) of the consensus DegU-binding sequence in the P3degU promoter. The alteration of chromosomal DR2 severely decreased degU expression, demonstrating its importance in positive autoregulation of degU. Observation of DegU protein levels suggested that DegU is degraded. Western blot analysis of DegU in disruption mutants of genes encoding various ATP-dependent proteases strongly suggested that ClpCP degrades DegU. Moreover, when de novo protein synthesis was blocked, DegU was rapidly degraded in the wild-type but not in the clpC and clpP strains, and DegU with a mutated phosphorylation site was much stable. These results suggested preferential degradation of DegU-P by ClpCP, but not of unphosphorylated DegU. We confirmed that DegU-P was degraded preferentially using an in vitro ClpCP degradation system. Furthermore, a mutational analysis showed that the N-terminal region of DegU is important for proteolysis.

Regulation of Bacillus subtilis aprE expression by glnA through inhibition of scoC and sigma(D)-dependent degR expression

Expression of the gene for the extracellular alkaline protease (aprE) of Bacillus subtilis is subject to regulation by many positive and negative regulators. We have found that aprE expression was increased by disruption of the glutamine synthetase gene glnA. The increase in aprE expression was attributed to a decreased in expression of scoC, which encodes a negative regulator of aprE expression. The glnA effect on scoC expression was abolished by further disruption of tnrA, indicating that aprE expression is under global regulation through TnrA. In the scoC background, however, aprE expression was decreased by glnA deletion, and it was shown that the decrease was due to a defect in positive regulation by DegU. Among the genes that affect aprE expression through DegU, the expression of degR, encoding a protein that stabilizes phosphorylated DegU, was inhibited by glnA deletion. It was further shown that the decrease in degR expression by glnA deletion was caused by inhibition of the expression of sigD, encoding the sigma(D) factor, which is required for degR expression. In accordance with these findings, the expression levels of aprE-lacZ in glnA scoC degR and scoC degR strains were identical. These results led us to conclude that glnA deletion brings about two effects on aprE expression, i.e., a positive effect through inhibition of scoC expression and a negative effect through inhibition of degR expression, with the former predominating over the latter.

Promoter selectivity of the Bacillus subtilis response regulator DegU, a positive regulator of the fla/che operon and sacB

Background

The response regulator DegU and its cognate histidine kinase DegS constitute a two-component system in the Gram-positive soil bacterium Bacillus subtilis. Unphosphorylated and phosphorylated forms of DegU are known to activate target gene transcription in B. subtilis. Although phosphorylated DegU (DegU-P) regulates more than one hundred and twenty genes, the targets of unphosphorylated DegU are unknown, except for comK.

Results

We found that the fla/che (flagella and chemotaxis) operon is positively regulated by unphosphorylated DegU. The effect was most prominent in a strain bearing the functional swrAA gene, a positive regulator of fla/che. Unphosphorylated DegU bound to two regions in the fla/che regulatory region containing an inverted repeat-like sequence that resembles the inverted repeat (IR) in the comK promoter. Mutational analysis revealed that positive regulation of fla/che by SwrAA requires DegU-binding. An analysis of the DegU-P-regulated gene sacB (levansucrase gene) by footprint and mutational analyses revealed that DegU-P bound to a direct repeat (DR) of the DegU-recognition motifs, which has been shown to be functional in vivo, while unphosphorylated DegU did not. These results strongly suggest that the arrangement of the DegU-binding motifs determines whether unphosphorylated DegU or DegU-P binds to the sacB promoter. The hypothesis was confirmed by observing degS-independent expression when the DR in the sacB-lacZ fusion was changed to an IR, suggesting that unphosphorylated DegU regulates the sacB promoter through the newly created IR. This was confirmed by binding of unphosphorylated DegU to the IR in the sacB promoter.

Conclusion

This study demonstrated that DegU positively regulates flgB and sacB through its binding to the promoter regions. We demonstrated that DegU-P prefers binding to DR but not to IR in the sacB promoter.

Identification of the sequences recognized by the Bacillus subtilis response regulator YrkP

The Bacillus subtilis yrkP gene encodes a response regulator of a two-component regulatory system of unknown function. A previous DNA microarray experiment suggested that multicopy yrkP greatly enhanced the expression of yrkN, the ykcBC operon, and yrkO, which encodes a putative transporter. Here, lacZ fusion analysis confirmed these results and also revealed that YrkP autoregulates the putative yrkPQR operon, indicating that yrkPQR and yrkO form a divergon structure. In addition, real-time PCR analysis revealed that transcription of yrkO, yrkN, and ykcBC was significantly reduced in the yrkP strain. Hence, YrkP positively regulates the expression of these genes. Gel retardation analyses showed that YrkP bound to the promoter regions of yrkO, yrkN, and ykcB, albeit with lower binding affinities to the latter two promoters. The in vitro binding of YrkP to the promoter region of the yrkPQR and yrkO divergon was then analyzed by DNase I footprinting analysis. This revealed that YrkP recognizes three regions containing single-motifs or a direct repeat of the ten-base sequence [T/G]TCA[T/C]AAATT. lacZ fusion analysis of deleted and mutagenized promoter regions of yrkO and yrkPQR divergon confirmed that the three YrkP-binding regions are needed for the YrkP-mediated activation of yrkO and/or yrkPQR.

The PUA domain - a structural and functional overview

The pseudouridine synthase and archaeosine transglycosylase (PUA) domain is a compact and highly conserved RNA-binding motif that is widespread among diverse types of proteins from the three kingdoms of life. Its three-dimensional architecture is well established, and the structures of several PUA-RNA complexes reveal a common RNA recognition surface, but also some versatility in the way in which the motif binds to RNA. The PUA domain is often part of RNA modification enzymes and ribonucleoproteins, but it has also been unexpectedly found fused to enzymes involved in proline biosynthesis, where it plays an unknown role. The functional impact of the domain varies with the protein studied, ranging from minor to essential effects. PUA motifs are involved in dyskeratosis congenita and cancer, pointing to links between RNA metabolism and human diseases.

A Novel Two-domain Architecture Within the Amino Acid Kinase Enzyme Family Revealed by the Crystal Structure of Escherichia coli Glutamate 5-kinase

Glutamate 5-kinase (G5K) makes the highly unstable product glutamyl 5-phosphate (G5P) in the initial, controlling step of proline/ornithine synthesis, being feedback-inhibited by proline or ornithine, and causing, when defective, clinical hyperammonaemia. We determined two crystal structures of G5K from Escherichia coli, at 2.9 A and 2.5 A resolution, complexed with glutamate and sulphate, or with G5P, sulphate and the proline analogue 5-oxoproline. E. coli G5K presents a novel tetrameric (dimer of dimers) architecture. Each subunit contains a 257 residue AAK domain, typical of acylphosphate-forming enzymes, with characteristic alpha(3)beta(8)alpha(4) sandwich topology. This domain is responsible for catalysis and proline inhibition, and has a crater on the beta sheet C-edge that hosts the active centre and bound 5-oxoproline. Each subunit contains a 93 residue C-terminal PUA domain, typical of RNA-modifying enzymes, which presents the characteristic beta(5)beta(4) sandwich fold and three alpha helices. The AAK and PUA domains of one subunit associate non-canonically in the dimer with the same domains of the other subunit, leaving a negatively charged hole between them that hosts two Mg ions in one crystal, in line with the G5K requirement for free Mg. The tetramer, formed by two dimers interacting exclusively through their AAK domains, is flat and elongated, and has in each face, pericentrically, two exposed active centres in alternate subunits. This would permit the close apposition of two active centres of bacterial glutamate-5-phosphate reductase (the next enzyme in the proline/ornithine-synthesising route), supporting the postulated channelling of G5P. The structures clarify substrate binding and catalysis, justify the high glutamate specificity, explain the effects of known point mutations, and support the binding of proline near glutamate. Proline binding may trigger the movement of a loop that encircles glutamate, and which participates in a hydrogen bond network connecting active centres, which is possibly involved in the cooperativity for glutamate.

The Bacillus subtilis NatK–NatR two-component system regulates expression of the natAB operon encoding an ABC transporter for sodium ion extrusion

A previous microarray analysis suggested that multicopy yccH, encoding a function-unknown response regulator, enhances expression of natAB, which encodes a two-gene ATP-binding cassette transporter involved in the extrusion of sodium ions. The two-component regulatory system YccG-YccH was therefore renamed NatK-NatR. Here, this observation was confirmed by a lacZ fusion analysis using a strain carrying natA-lacZ. Further, in both natK and natR mutants, natA-lacZ expression was completely abolished, indicating that the NatK-NatR system positively regulates the expression of natAB. In a gel retardation analysis, NatR bound to the natA promoter region. Using purified His-tagged NatR, DNase I footprinting analysis of the natA promoter region suggested that a direct repeat of [TTCA(G)CGACA], separated by a 12 bp space, would be recognized by NatR. Deleted and mutagenized promoter regions of natA were analysed using a lacZ fusion, and it was confirmed that the direct repeat is critical for natA activation by NatR.

Bacillus subtilis rapD, a direct target of transcription repression by RghR, negatively regulates srfA expression

The Bacillus subtilis genome encodes eleven Rap proteins, which are conserved tetratricopeptide-containing regulatory proteins. Of those characterized to date, all except RapI negatively regulate response regulators, including Spo0F, ComA and DegU, via protein-protein interactions. RapD has not yet been fully characterized. It was examined whether RapD inhibits the expression of spoIIE, srfA and aprE, which are Spo0F-, ComA- and DegU-regulated genes, respectively. It was observed that multicopy rapD inhibited srfA expression, which suggests that RapD inhibits ComA. This was reinforced by the fact that multicopy rapD also blocked the expression of rapC and rapF, which belong to the ComA regulon. The expression of rapD was reported to depend on the extracytoplasmic function sigma factor SigX. DNA microarray analysis and gel retardation assays revealed that rapD expression is directly repressed by RghR. Thus, the ComA regulon is regulated by rapD in a SigX- and RghR-dependent manner.

Superoxide stress decreases expression of srfA through inhibition of transcription of the comQXP quorum-sensing locus in Bacillus subtilis

During the course of screening for competence-deficient mutants in the mutant collection constructed by the Japan Consortium of Bacillus Functional Genomics, a disruption mutant of sodA encoding superoxide dismutase was identified as a mutant with decreased transformation efficiency. In fact, in the sodA mutant we observed a severe decrease in the expression of srfA required for the development of genetic competence. Northern and primer extension analyses revealed inhibition of the transcription of the comQXP quorum-sensing locus in the sodA mutant, thereby preventing srfA expression. Furthermore, an excess amount of superoxide anion induced by the addition of paraquat also resulted in a decrease in comQXP transcription. Thus, it was concluded that high levels of superoxide are able to inhibit specifically the transcription of the comQXP operon. In support of this conclusion, the effect of added paraquat was significantly alleviated in a comX-independent srfA expression system.

Bacillus subtilis RghR (YvaN) represses rapG and rapH, which encode inhibitors of expression of the srfA operon

Rap proteins regulate the activity of response regulators including Spo0F, DegU and ComA. We found that overexpression of either RapG or RapH severely downregulated the expression of srfA, which belongs to the ComA regulon. Disruption of those genes, however, showed small effects on srfA expression. These observations suggested that Bacillus subtilis cells possess a repressor for rapG and rapH. To identify candidate repressors we developed a novel transcription factor array (TF array) assay, in which disruptions of 287 genes encoding regulatory proteins were independently transformed into a strain carrying rapH-lacZ and the resultant transformants were grown on agar plates containing Xgal to detect beta-galactosidase activity. We identified a yvaN disruptant which showed a rapH-overproducing phenotype. DNA microarray analysis of the yvaN mutant suggested that both rapG and rapH were overproduced, leading to inhibition of srfA expression. In a gel retardation assay, purified His-tagged YvaN specifically bound to promoter sequences of rapG and rapH. Further footprint and gel retardation analyses using various deleted probes uncovered critical sequences for YvaN binding. In addition, a lacZ fusion analysis confirmed the significance of YvaN binding for transcription regulation of rapG and rapH. Thus, YvaN was renamed RghR (rapG and rapH repressor). As the rapH gene is activated by ComK and RapH inhibits comK indirectly, this constitutes an autoregulatory loop modulated by RghR.

Effects of degU32(Hy), degQa and degR Pleiotropic Regulatory Genes on the Growth and Protease Fermentation of Bacillus Subtilis Ki-2-132

Effects of degU32 (Hy), degR genes from Bacillus subtilis 168 and degQa gene from Bacillus amyloliquefaciens on Bacillus subtilis Ki-2-132 cell growth, sporulation and protease fermentation were investigated by introducing these genes into B. subtilis Ki-2-132 chromosome and/or cytoplasm. Although the genes come from different species and strains, they showed pleiotropic effects in B. subtilis Ki-2-132. B. subtilis Ki-2-132degU32 (Hy) showed increased protease production, and when cooperating with degQa either in plasmid or in chromosome, further altered cell growth, increased protease production and affected the spore formation in a glucose and dosage dependent manner. By contrast, degR did not significantly affect the protease productivity in degU32 (Hy) mutant, consisting with that DegR was used to stabilise DegU-phosphate, which in degU32 (Hy) strain no longer further amplify the DegU-phosphate effect.

Dissection of Escherichia coli glutamate 5-kinase: functional impact of the deletion of the PUA domain

Glutamate 5-kinase (G5K) catalyzes the controlling first step of the synthesis of the osmoprotective amino acid proline, which feed-back inhibits G5K. Microbial G5K generally consists of one amino acid kinase (AAK) and one PUA (named after pseudo uridine synthases and archaeosine-specific transglycosylases) domain. To investigate the role of the PUA domain, we have deleted it from Escherichia coli G5K. We show that wild-type G5K requires free Mg for activity, it is tetrameric, and it aggregates to higher forms in a proline-dependent way. G5K lacking the PUA domain remains tetrameric, active, and proline-inhibitable, but the Mg requirement and the proline-triggered aggregation are greatly diminished and abolished, respectively, and more proline is needed for inhibition. We propose that the PUA domain modulates the function of the AAK domain, opening the way to potential PUA domain-mediated regulation of G5K; and that this domain moves, exposing new surfaces upon proline binding.

The crystal structure of Pyrococcus furiosus UMP kinase provides insight into catalysis and regulation in microbial pyrimidine nucleotide biosynthesis

UMP kinase (UMPK), the enzyme responsible for microbial UMP phosphorylation, plays a key role in pyrimidine nucleotide biosynthesis, regulating this process via feed-back control and via gene repression of carbamoyl phosphate synthetase (the first enzyme of the pyrimidine biosynthesis pathway). We present crystal structures of Pyrococcus furiosus UMPK, free or complexed with AMPPNP or AMPPNP and UMP, at 2.4 A, 3 A and 2.55 A resolution, respectively, providing a true snapshot of the catalytically competent bisubstrate complex. The structure proves that UMPK does not resemble other nucleoside monophosphate kinases, including the UMP/CMP kinase found in animals, and thus UMPK may be a potential antimicrobial target. This enzyme has a homohexameric architecture centred around a hollow nucleus, and is organized as a trimer of dimers. The UMPK polypeptide exhibits the amino acid kinase family (AAKF) fold that has been reported in carbamate kinase and acetylglutamate kinase. Comparison with acetylglutamate kinase reveals that the substrates bind within each subunit at equivalent, adequately adapted sites. The UMPK structure contains two bound Mg ions, of which one helps stabilize the transition state, thus having the same catalytic role as one lysine residue found in acetylglutamate kinase, which is missing from P.furiosus UMPK. Relative to carbamate kinase and acetylglutamate kinase, UMPK presents a radically different dimer architecture, lacking the characteristic 16-stranded beta-sheet backbone that was considered a signature of AAKF enzymes. Its hexameric architecture, also a novel trait, results from equatorial contacts between the A and B subunits of adjacent dimers combined with polar contacts between A or B subunits, and may be required for the UMPK regulatory functions, such as gene regulation, proposed here to be mediated by hexamer-hexamer interactions with the DNA-binding protein PepA.

Characterization of the replication region of plasmid pLS32 from the Natto strain of Bacillus subtilis

Plasmid pL32 from the Natto strain of Bacillus subtilis belongs to a group of low-copy-number plasmids in gram-positive bacteria that replicate via a theta mechanism of replication. We studied the DNA region encoding the replication protein, RepN, of pLS32, and obtained the following results. Transcription of the repN gene starts 167 nucleotides upstream from the translational start site of repN. The copy number of repN-coding plasmid pHDCS2, in which the repN gene was placed downstream of the IPTG (isopropyl-1-thio-beta-D-galactopyranoside)-inducible Pspac promoter, was increased 100 fold by the addition of IPTG. Histidine-tagged RepN bound to a specific region in the repN gene containing five 22-bp tandem repeats (iterons) with partial mismatches, as shown by gel retardation and foot printing analyses. Sequence alterations in the first three iterons resulted in an increase in plasmid copy number, whereas those in either the forth or fifth iteron resulted in the failure of plasmid replication. The iterons expressed various degrees of incompatibility with an incoming repN-driven replicon pSEQ243, with the first three showing the strongest incompatibility. Finally, by using a plasmid, pHDMAEC21, carrying the sequence alterations in all the five iterons in repN and thus unable to replicate but encoding intact RepN, the region necessary for replication was confined to a 96-bp sequence spanning the 3'-terminal half of the fourth iteron to an A+T-rich region located downstream of the fifth iteron. From these results, we conclude that the iterons in repN are involved in both the control of plasmid copy number and incompatibility, and we suggest that the binding of RepN to the last two iterons triggers replication by melting the A+T-rich DNA sequence.

Bacillus subtilis SalA (YbaL) negatively regulates expression of scoC, which encodes the repressor for the alkaline exoprotease gene, aprE

During the course of screening for exoprotease-deficient mutants among Bacillus subtilis gene disruptants, a strain showing such a phenotype was identified. The locus responsible for this phenotype was the previously unknown gene ybaL, which we renamed salA. The predicted gene product encoded by salA belongs to the Mrp family, which is widely conserved among archaea, prokaryotes, and eukaryotes. Disruption of salA resulted in a decrease in the expression of a lacZ fusion of the aprE gene encoding the major extracellular alkaline protease. The decrease was recovered by the cloned salA gene on a plasmid, demonstrating that the gene is involved in aprE expression. Determination of the cis-acting region of SalA on the upstream region of aprE, together with epistatic analyses with scoC, abrB, and spo0A mutations that also affect aprE expression, suggested that salA deficiency affects aprE-lacZ expression through the negative regulator ScoC. Northern and reverse transcription-PCR analyses revealed enhanced levels of scoC transcripts in the salA mutant cells in the transition and early stationary phases. Concomitant with these observations, larger amounts of the ScoC protein were detected in the mutant cells by Western analysis. From these results we conclude that SalA negatively regulates scoC expression. It was also found that the expression of a salA-lacZ fusion was increased by salA deficiency, suggesting that salA is autoregulated.

Genome-wide transcriptional profiling analysis of adaptation of Bacillus subtilis to high salinity

The gram-positive soil bacterium Bacillus subtilis often faces increases in the salinity in its natural habitats. A transcriptional profiling approach was utilized to investigate both the initial reaction to a sudden increase in salinity elicited by the addition of 0.4 M NaCl and the cellular adaptation reactions to prolonged growth at high salinity (1.2 M NaCl). Following salt shock, a sigB mutant displayed immediate and transient induction and repression of 75 and 51 genes, respectively. Continuous propagation of this strain in the presence of 1.2 M NaCl triggered the induction of 123 genes and led to the repression of 101 genes. In summary, our studies revealed (i) an immediate and transient induction of the SigW regulon following salt shock, (ii) a role of the DegS/DegU two-component system in sensing high salinity, (iii) a high-salinity-mediated iron limitation, and (iv) a repression of chemotaxis and motility genes by high salinity, causing severe impairment of the swarming capability of B. subtilis cells. Initial adaptation to salt shock and continuous growth at high salinity share only a limited set of induced and repressed genes. This finding strongly suggests that these two phases of adaptation require distinctively different physiological adaptation reactions by the B. subtilis cell. The large portion of genes with unassigned functions among the high-salinity-induced or -repressed genes demonstrates that major aspects of the cellular adaptation of B. subtilis to high salinity are unexplored so far.

Neonatal pneumonia caused by Trichomonas vaginalis

The authors present two cases of newborn babies infected by Trichomonas vaginalis (hereafter referred to as T. vaginalis) and suffering from severe congenital breathing difficulties and needing artificial respiration. Microscopic examination of the tracheal discharge revealed characteristically moving, flagellated, pear-shaped unicellular organisms. Cultures on CPLM medium proved the presence of T. vaginalis. During pregnancy the mothers' clinical status was negative and both of them mentioned leukorrhoea of changing intensity. They were regularly involved in antenatal care. The infection caused by T. vaginalis could be detected in the two mothers later by culture procedures.

Defining the Bacillus subtilis sigma(W) regulon: a comparative analysis of promoter consensus search, run-off transcription/macroarray analysis (ROMA), and transcriptional profiling approaches

The Bacillus subtilis extracytoplasmic function (ECF) sigma factor sigma(W) controls a large regulon that is strongly induced by alkali shock. To define the physiological role of sigma(W) we have sought to identify the complete set of genes under sigma(W) control. Previously, we described a promoter consensus search procedure to identify sigma(W) controlled genes. Herein, we introduce a novel method to identify additional target promoters: run-off transcription followed by macroarray analysis (ROMA). We compare the resulting list of targets with those identified in conventional transcriptional profiling studies and using the consensus search approach. While transcriptional profiling identifies genes that are strongly dependent on sigma(W) for in vivo expression, some sigma(W)-dependent promoters are not detected due to the masking effects of other promoter elements, overlapping recognition with other ECF sigma factors, or both. Taken together, the consensus search, ROMA, and transcriptional profiling approaches establish a minimum of 30 promoter sites (controlling approximately 60 genes) as direct targets for activation by sigma(W). Significantly, no single approach identifies more than approximately 80% of the regulon so defined. We therefore suggest that a combination of two or more complementary approaches be employed in studies seeking to achieve maximal coverage when defining bacterial regulons. Our results indicate that sigma(W) controls genes that protect the cell against agents that impair cell wall biosynthesis but fail to reveal any connection to operons likely to function in adaptation to alkaline growth conditions. This is consistent with the observation that a sigW mutant is unaffected in its ability to survive alkali shock. We conclude that in B. subtilis sudden imposition of alkali stress activates the sigma(W) stress response, perhaps by impairing the ability of the cell wall biosynthetic machinery to function.

DNA microarray analysis of Bacillus subtilis DegU, ComA and PhoP regulons: an approach to comprehensive analysis of B.subtilis two-component regulatory systems

We have analyzed the regulons of the Bacillus subtilis two-component regulators DegU, ComA and PhoP by using whole genome DNA microarrays. For these experiments we took the strategy that the response regulator genes were cloned downstream of an isopropyl-beta-D-thiogalactopyranoside-inducible promoter on a multicopy plasmid and expressed in disruptants of the cognate sensor kinase genes, degS, comP and phoR, respectively. The feasibility of this experimental design to detect target genes was demonstrated by the following two results. First, expression of lacZ fusions of aprE, srfA and ydhF, the target genes of DegU, ComA and PhoP, respectively, was stimulated in their cognate sensor kinase-deficient mutants upon overproduction of the regulators. Secondly, by microarray analysis most of the known target genes for the regulators were detected and, where unknown genes were found, the regulator dependency of several of them was demonstrated. As the mutants used were deficient in the kinase genes, these results show that target candidates can be detected without signal transduction. Using this experimental design, we identified many genes whose dependency on the regulators for expression had not been known. These results suggest the applicability of the strategy to the comprehensive transcription analysis of the B.subtilis two-component systems.

Positive regulation of Bacillus subtilis sigD by C-terminal truncated LacR at translational level

DegR is a positive regulator for degradative enzyme synthesis in Bacillus subtilis. The degR gene is transcribed by RNA polymerase containing delta D, and the level of its expression is low in a mecA-deficient mutant. In a search for suppressors of the mecA effect through mini-Tn10 transposon mutagenesis, a lacR mutation designated lacR288 was discovered. The B. subtilis lacR gene encodes the repressor for lacA which specifies beta-galactosidase, and therefore, inactivation of the lacR gene results in overproduction of the enzyme. In the lacR288 mutant, however, the expression of lacA was at a negligible level, indicating that the repressor activity was not destroyed by the mutation. The putative gene product of the lacR288-containing gene is a 288-amino acid protein lacking the C-terminal 42 amino acids of intact LacR and carries no extra amino acids derived from the transposon sequence. The suppression by lacR288 of the decreased degR expression in the mecA background was found to be caused by an increase in the delta D level as shown by Western blot analysis. Furthermore, the increase was due to post-transcriptional regulation of sigD, the gene encoding delta D, as revealed by using both transcriptional and translational sigD-lacZ fusions. The lacR288 mutation had no effect on the stability of the delta D protein. Based on these results we conclude that the lacR288 mutation stimulates sigD expression at the translational level.

Mutational analysis of ComS: evidence for the interaction of ComS and MecA in the regulation of competence development in Bacillus subtilis

The development of Bacillus subtilis genetic competence is a highly regulated adaptive response to stationary-phase stress. A key step in competence development is the activation of the transcriptional regulator ComK, which is required for the expression of genes encoding the products that function in DNA uptake. In log-phase cultures, ComK is trapped in a complex composed of MecA and ClpC, in which it is rendered inactive. The comS gene, contained within the srf operon, is induced in response to high culture cell density and nutritional stress. Its product functions to release active ComK from the complex, allowing ComK to stimulate the transcription initiation of its own gene as well as that of the late competence operons. Western analysis showed that ComS accumulates to maximal levels between T3 and T4, mirroring the pattern of competence cell development and late competence gene expression. Experiments to examine the target of ComS activity in vitro showed that ComS binds to MecA. This is further supported by coimmunoprecipitation using anti-MecA antiserum. To clarify the role of ComS in competence regulation, a system for evaluating the effect of comS and mutant derivatives on the expression of comG, one of the late competence operons, was constructed. comS mutations, created by alanine-scanning mutagenesis, that significantly reduced comG-lacZ expression were clustered within two regions, one at the N-terminus and the other at the C-terminus of ComS. ComSI13 --> A and ComSW43 --> A were selected for further analysis as representative mutants for both regions required for ComS activity. We observed that ComSI13 --> A showed significantly reduced affinity for MecA, whereas ComSW43 --> A showed near normal binding affinity for MecA. The results show that binding to MecA is critical for ComS function, but do not rule out the possibility that ComS possesses other activities.

A novel Bacillus natto plasmid pLS32 capable of replication in Bacillus subtilis

Plasmid pLS32 is a relatively large (approximately 70 kbp), cryptic, low copy-number plasmid present in Bacillus natto. We isolated and analyzed the replication region of the plasmid in B. subtilis, and the following results were obtained: the replication region contained an open reading frame encoding a 287-amino acid protein (RepN), whose amino acid sequence was partially homologous with those of the Rep proteins encoded on plasmids pAD1 and pLJ1 isolated from Enterococcus faecalis and Lactobacillus helveticus, respectively; the replication origin (oriN) was located in the repN-coding region; the copy number of a pLS32 derivative, pBET131, was 2 to 3 per chromosome; replication of pBET131 required poll. These features show that pLS32 is a novel plasmid capable of replication in B. subtilis.

A new Bacillus subtilis gene, med, encodes a positive regulator of comK

Bacillus subtilis degR, a positive regulator of the production of degradative enzymes, is negatively regulated by the competence transcription factor ComK which is overproduced in mecA null mutants. We used transposon Tn10 to search for a mutation that reduced the repression level of degR caused by a mecA mutation. A new gene exerting positive regulation on comK was obtained and designated med (suppressor of mecA effect on degR). Sequence determination, Northern analysis, and primer extension analyses revealed that the med gene contained an open reading frame (ORF) composed of 317 codons and was transcribed into an approximately 1,250-nucleotide mRNA together with its short downstream gene. The expression of comK is positively regulated by factors such as ComK itself, ComS (SrfA)-MecA, DegU, SinR, and AbrB. Quantitative analyses using comK'-'lacZ, srfA-lacZ, degU'-'lacZ, and sinR'-'lacZ fusions showed that disruption of med caused a significant decrease in comK expression in both mecA+ and mecA strains, while expression of srfA, sinR, and degU was not affected by the mutation. An epistatic analysis revealed that overproduction of ComK resulted in alteration of med expression, suggesting a regulatory loop between comK and med. Several possible mechanisms for positive regulation of comK by Med are discussed.

RNA polymerase sigma factor determines start-site selection but is not required for upstream promoter element activation on heteroduplex (bubble) templates

Sequence-selective transcription by bacterial RNA polymerase (RNAP) requires sigma factor that participates in both promoter recognition and DNA melting. RNAP lacking sigma (core enzyme) will initiate RNA synthesis from duplex ends, nicks, gaps, and single-stranded regions. We have used DNA templates containing short regions of heteroduplex (bubbles) to compare initiation in the presence and absence of various sigma factors. Using bubble templates containing the sigmaD-dependent flagellin promoter, with or without its associated upstream promoter (UP) element, we demonstrate that UP element stimulation occurs efficiently even in the absence of sigma. This supports a model in which the UP element acts primarily through the alpha subunit of core enzyme to increase the initial association of RNAP with the promoter. Core and holoenzyme do differ substantially in the template positions chosen for initiation: sigmaD restricts initiation to sites 8-9 nucleotides downstream of the conserved -10 element. Remarkably, sigmaA also has a dramatic effect on start-site selection even though the sigmaA holoenzyme is inactive on the corresponding homoduplexes. The start sites chosen by the sigmaA holoenzyme are located 8 nucleotides downstream of sequences on the nontemplate strand that resemble the conserved -10 hexamer recognized by sigmaA. Thus, sigmaA appears to recognize the -10 region even in a single-stranded state. We propose that in addition to its described roles in promoter recognition and start-site melting, sigma also localizes the transcription start site.

FlgM is a primary regulator of sigmaD activity, and its absence restores motility to a sinR mutant

We have used mini-Tn1O mutagenesis to identify negative regulators of sigmaD activity. Nine independent insertions were mapped to five genes: flgM, flgK, fliD, fliS, and fliT, suggesting that FlgM export is regulated similarly in Bacillus subtilis and Salmonella typhimurium. We show that a deletion of flgM can restore sigmaD activity to a sinR null mutant of B. subtilis, although fla/che operon expression is affected by neither SinR nor FlgM.

Bacillus subtilis DegU acts as a positive regulator for comK expression

Bacillus subtilis ComK plays a critical role in competence development. We report that B. subtilis degR, a positive regulator for exoenzyme production, is negatively regulated by overproduced ComK caused by a mecA null mutation. To identify a positive regulator for comK expression in the mecA background, mutations that allowed the degR gene to be expressed were screened in Tn10 transposon insertion mutants. As a result, we identified degU insertion mutations as those having such a property. The degU mutation reduced comK-lacZ expression in a competence medium in both the wild-type and mecA cells in sporulation and competence media. These results indicate that the degU gene product acts as a positive regulator for comK expression even under the condition where the negative regulation of comK by MecA is released.