Cloning and nucleotide sequence of senN, a novel 'Bacillus natto' (B. subtilis) gene that regulates expression of extracellular protein genes

Inhibition of Bacillus subtilis scoC expression by multicopy senS

The Bacillus subtilis aprE gene, which encodes the extracellular alkaline protease, is regulated by many positive and negative transcriptional regulators. SenS is one such positive regulator consisting of 65 amino acids. We found that the senS gene on a multicopy plasmid, pSEN24, caused an increase in aprE expression in strains carrying the upstream region of aprE up to -340 with respect to the transcription initiation site but not in a strain carrying the region up to -299, which is within the binding site of the negative regulator ScoC (Hpr). Epistatic analysis showed that the pSEN24 effect was lost in a scoC-deleted mutant. In accordance with these results, the scoC transcription level as assayed by a scoC-lacZ fusion and Northern analysis was greatly reduced in the cells carrying pSEN24. From these results we conclude that multicopy senS enhances aprE expression by suppressing the transcription of scoC.

Multiple copies of the proB gene enhance degS-dependent extracellular protease production in Bacillus subtilis

Bacillus subtilis secretes extracellular proteases whose production is positively regulated by a two-component regulatory system, DegS-DegU, and other regulatory factors including DegR. To identify an additional regulatory gene(s) for exoprotease production, we performed a shotgun cloning in the cell carrying multiple copies of degR and found a transformant producing large amounts of the exoproteases. The plasmid in this transformant, pLC1, showed a synergistic effect with multiple copies of degR on the production of the extracellular proteases, and it required degS for its enhancing effect. The DNA region responsible for the enhancement contained the proB gene, as shown by restriction analyses and sequence determination. The proB gene encoding gamma-glutamyl kinase was followed by the proA gene encoding glutamyl-gamma-semialdehyde dehydrogenase at an interval of 39 nucleotides, suggesting that the genes constitute an operon. pLC1 contained the complete proB gene and a part of proA lacking the proA C-terminal region. It was also found that proB on the chromosome showed a synergistic effect with multiple copies of degR. We consider on the basis of these results that the metabolic intermediate, gamma-glutamyl phosphate, would transmit a signal to DegS, resulting in a higher level of phosphorylated DegU. Possible involvement of DegR in this process is discussed.

Glucitol induction in Bacillus subtilis is mediated by a regulatory factor, GutR

Expression of the glucitol dehydrogenase gene (gutB) is suggested to be regulated both positively and negatively in Bacillus subtilis. A mutation in the gutR locus results in the constitutive expression of gutB. The exact nature of this mutation and the function of gutR are still unknown. Cloning and characterization of gutR indicated that this gene is located immediately upstream of gutB and is transcribed in the opposite direction relative to gutB. GutR is suggested to be a 95-kDa protein with a putative helix-turn-helix motif and a nucleotide binding domain at the N-terminal region. At the C-terminal region, a short sequence of GutR shows homology with two proteins, Cyc8 (glucose repression mediator protein) and GsiA (glucose starvation-inducible protein), known to be directly or indirectly involved in catabolite repression. Part of the C-terminal conserved sequence from these proteins shows all the features observed in the tetratricopeptide motif found in many eucaryotic proteins. To study the functional role of gutR, chromosomal gutR was insertionally inactivated. A total loss of glucitol inducibility was observed. Reintroduction of a functional gutR to the GutR-deficient strain through integration at the amyE locus restores the inducibility. Therefore, GutR serves as a regulatory factor to modulate glucitol induction. The nature of the gutR1 mutation was also determined. A single amino acid change (serine-289 to arginine-289) near the putative nucleotide binding motif B in GutR is responsible for the observed phenotype. Possible models for the action of GutR are discussed.

Transcriptional regulation of the Bacillus subtilis glucitol dehydrogenase gene

The regulatory region of the Bacillus subtilis glucitol dehydrogenase (gutB) gene was divided into three subregions: a promoter, an upstream positive regulatory region, and a downstream negative regulatory region. Data from primer extension, deletion, and site-directed mutagenesis analyses were consistent with two possible models for the gutB promoter. It is either a sigma A-type promoter with an unusually short spacer region (15 bp) or a special sigma A promoter which requires only the hexameric -10 sequence for its function. Sequence carrying just the promoter region (from -48 to +6) failed to direct transcription in vivo. An upstream regulatory sequence was essential for glucitol induction. When this sequence was inserted in a high-copy-number plasmid, an effect characteristic of titration of a transcriptional activator was seen. Downstream from the promoter, there is an imperfect, AT-rich inverted repeat sequence. Deletion of this element did not lead to constitutive expression of gutB. However, the induced gutB expression level was enhanced three- to fourfold.

Stabilization of phosphorylated Bacillus subtilis DegU by DegR

The production of Bacillus subtilis extracellular proteases is under positive and negative regulation. The functional role of degR, one of the positive regulators, was studied in relation to the degS and degU gene products, which belong to the bacterial two-component regulatory system. Studies with a translational fusion between the Escherichia coli lacZ and the Bacillus subtilis subtilisin (aprE) genes indicated that the stimulatory site of DegR lay upstream of position -140, with the region upstream of position -200 being the major target. It was also found that degS and degU were epistatic to degR. These results suggested some relationship among the degR, degS, and degU gene products. The DegR protein was purified to homogeneity, and its in vitro effect on the phosphorylation reaction involving DegS and DegU was studied. For this purpose, a soluble-extract system in which the formation and dephosphorylation of DegU-phosphate could be examined was devised. The addition of DegR to the soluble-extract system enhanced the formation of DegU-phosphate. The enhancing effect was found to be due to the protection of DegU-phosphate from dephosphorylation. From these results, it was concluded that the positive effect of DegR on the production of the extracellular proteases is brought about by the stabilization of DegU-phosphate, which in turn may result in the stimulation of transcription of the exoprotease genes.

Cloning and expression of a novel protease gene encoding an extracellular neutral protease from Bacillus subtilis

We have cloned from Bacillus subtilis a novel protease gene (nprB) encoding a neutral protease by using a shotgun cloning approach. The gene product was determined to have a molecular mass of 60 kDa. It has a typical signal peptide-like sequence at the N-terminal region. The expression of nprB can be stimulated by using a B. subtilis strain, WB30, carrying a sacU(h)h mutation. Expression of this protease gene results in production of a 37-kDa protease in the culture medium. The first five amino acid residues from the N terminus of the mature protease were determined to be Ala-Ala-Gly-Thr-Gly. This indicates that the protease is synthesized in a preproenzyme form. The purified protease has a pH optimum of around 6.6, and its activity can be inhibited by EDTA, 1,10-phenanthroline (a zinc-specific chelator), and dithiothreitol. It retained 65% of its activity after treatment at 65 degrees C for 20 min. Sequence comparison indicates that the mature form of this protease has 66% homology with the two thermostable neutral proteases from B. thermoproteolyticus and B. stearothermophilus. It also shares 65, 61, and 56% homology with the thermolabile neutral proteases from B. cereus, B. amyloliquefaciens, and B. subtilis, respectively. The zinc-binding site and the catalytic residues are all conserved among these proteases. Sequence homology extends into the "propeptide" region. The nprB gene was mapped between metC and glyB and was not required for growth or sporulation.

The Bacillus subtilis sin gene, a regulator of alternate developmental processes, codes for a DNA-binding protein

The sin gene of Bacillus subtilis encodes a dual-function regulatory protein, Sin, which is a negative as well as a positive regulator of alternate developmental processes that are induced at the end of vegetative growth in response to nutrient depletion. Sin has been purified to homogeneity by using a simple two-step procedure. It was found to bind to the developmentally regulated aprE (alkaline protease) gene at two sites in vitro. The stronger Sin-binding site (SBS-1) is located more than 200 bp upstream from the transcription start site. It is required for Sin repression of aprE expression in vivo, as strains bearing SBS-1 deletions were not affected by the sin gene. The second, weaker Sin-binding site lies on a DNA fragment that contains the aprE promoter. Results of DNase I, exonuclease III, and dimethyl sulfate footprinting analysis of SBS-1 suggested that Sin binding involves two adjacent binding sites which appear to contain two different partial dyad symmetries. An analysis of the predicted amino acid sequence of Sin revealed a potential leucine zipper protein dimerization motif which is flanked by two helix-turn-helix motifs that could be involved in recognizing two different dyad symmetries.

Cloning and characterization of a pair of novel genes that regulate production of extracellular enzymes in Bacillus subtilis

Two novel Bacillus subtilis genes that regulate the production of several extracellular enzymes were clones and characterized. These two genes are organized as part of an operon. When cloned in a multicopy plasmid, the first gene (tenA, transcription enhancement) stimulates alkaline protease production at the transcriptional level. The second gene (tenI) exerts an opposite effect to reduce alkaline protease production. The production of neutral protease, levansucrase, and alkaline protease can be stimulated up to 11- to 55-fold. Thus, tenA is a new member of the deg (regulatory genes for degradative enzymes) family in B. subtilis. A functional degS product is required to observe the stimulatory effect from tenA. Between the promoter and the ribosome-binding site of tenA, there exists a terminatorlike structure. Deletion of this structure doubles the expression of tenA. Neither tenA nor tenI is essential for cell growth and the production of extracellular enzymes. However, inactivation of these genes causes a delay in sporulation. This operon is located close to tre on the genetic linkage map. The overall organization of this operon and its relationship with other known regulatory factors in the deg family are discussed.

Site-directed mutagenesis of a catabolite repression operator sequence in Bacillus subtilis

Catabolite repression of the Bacillus subtilis alpha-amylase gene (amyE) involves an operator sequence located just downstream of the promoter (amyR), overlapping the transcription start site. Oligonucleotide site-directed mutagenesis of this sequence identified bases required for catabolite repression. Two mutations increased both the 2-fold symmetry of the operator and the repression ratio. Although many mutations reduced the repression ratio 3- to 11-fold, some also caused a 2-fold or greater increase in amylase production. Others caused hyperproduction without affecting catabolite repression. Homologous sequences in other catabolite-repressed B. subtilis promoters suggest a common regulatory site may be involved in catabolite repression.

Cloning and characterization of a gene of Streptomyces griseus that increases production of extracellular enzymes in several species of Streptomyces

A 7.2 kb Bg/II restriction fragment, which increases the production of several extracellular enzymes, including alkaline phosphatase, amylase, protease, lipase and beta-galactosidase, was cloned in Streptomyces lividans from the DNA of S. griseus ATCC 10137. This gene (named saf) showed a positive gene dosage effect on production of extracellular enzymes. When the saf gene was introduced into cells in high copy numbers it delayed the formation of pigments and spores in S. lividans and also retarded actinorhodin production in Streptomyces coelicolor. The saf gene hybridized with specific bands in the DNA of several Streptomyces strains tested. A 1 kb fragment containing the saf gene was sequenced and contains an open reading frame (ORF) of 306 nucleotides which encodes a polypeptide of Mr 10,500. This ORF is contained within a fragment of 432 bp which retained activity in Streptomyces. A fragment with promoter activity is present upstream of the saf reading frame. The predicted Saf polypeptide has a strong positive charge, and does not show a typical amino acid composition for a membrane protein, and contains a DNA-binding domain similar to those found in several regulatory proteins.

Complex character of senS, a novel gene regulating expression of extracellular-protein genes of Bacillus subtilis

The senS gene of Bacillus subtilis, which in high copy number stimulates the expression of several extracellular-protein genes, has been cloned, genetically mapped, and sequenced. The gene codes for a highly charged basic protein containing 65 amino acid residues. The gene is characterized by the presence of a transcription terminator (attenuator) located between the promoter and open reading frame, a strong ribosome-binding site, and a strong transcription terminator at the 3' end of this monocistronic gene. The amino acid sequence of SenS showed partial homology with the N-terminal core binding domain region of bacterial RNA polymerase sigma factors and a helix-turn-helix motif found in DNA-binding proteins. The gene can be deleted without any effect on growth or sporulation.

Bacillus subtilis subtilisin gene (aprE) is expressed from a sigma A (sigma 43) promoter in vitro and in vivo

In vitro studies demonstrated that the Bacillus subtilis subtilisin gene (aprE) could be transcribed by RNA polymerase holoenzyme reconstituted from core and sigma A factor obtained from vegetative cells. Upstream deletions (from -45) reduced the amount of transcription from the promoter. A deletion downstream of the promoter that overlapped a putative downstream minor promoter did not affect transcription from the sigma A promoter, which indicated that the putative downstream promoter is not utilized in vivo. S1 nuclease mapping studies showed that there was a low level of transcription from the subtilisin promoter during the growth phase and that the site of transcription initiation was the same during log and stationary phases. We conclude from these findings that there is only one promoter for the subtilisin gene and that it can be transcribed by the sigma A form of RNA polymerase in vitro.