Role of AbrB in Spo0A- and Spo0B-dependent utilization of a sporulation promoter in Bacillus subtilis

Physical map of the Bacillus cereus chromosome

A physical map of the Bacillus cereus chromosome has been constructed by aligning 11 NotI fragments, ranging in size from 200 to 1,300 kilobases. The size of the chromosome is about 5.7 megabases. This is the first Bacillus genome of which a complete physical map has been described.

Bacillus subtilis expressing a haemolysin gene from Listeria monocytogenes can grow in mammalian cells

Intracellular parasites can be classified into those that reside within a host vacuole and those which grow directly in the host cytoplasm. Members of the latter group, which includes Rickettsia, Shigellae, Trypanosoma cruzi, and Listeria monocytogenes, possess haemolytic activity associated with the ability to enter the host cytoplasm. Therefore mutants of L. monocytogenes lacking a pore-forming haemolysin, listeriolysin O, do not escape from the endosomal compartment and consequently fail to become established in the cytoplasm. To examine the role of listeriolysin O, we cloned the structural gene for the L. monocytogenes haemolysin, hlyA, into an asporogenic mutant of Bacillus subtilis under the control of an IPTG-inducible promoter. After being internalized by the macrophage-like cell line J774, haemolytic B. subtilis disrupted the phagosomal membrane and grew rapidly within the macrophage cytoplasm. These results show that a single gene product is sufficient to convert a common soil bacterium into a parasite that can grow in the cytoplasm of a mammalian cell.

Cascade regulation of spore coat gene expression in Bacillus subtilis

Endospores of the Gram-positive bacterium Bacillus subtilis are encased in a tough protein shell known as the coat. The coat is composed of a dozen or more different structural proteins. We report the identification of and studies on the regulation of promoters governing the expression of coat protein (cot) genes designated B to E encoding polypeptides of 59, 12, 11 and 24 kDa, respectively. We show that transcription of genes B, C and D is governed by single promoters and that transcription of gene E is governed by tandem promoters designated P1 and P2. In extension of recent work on the transcription of cot gene A and the mother-cell regulatory genes gerE, sigK and spoIIID, we show that genes involved in coat formation are turned on in a regulatory cascade of at least four co-ordinately controlled gene sets. The cascade consists of: cotE as transcribed from its P1 promoter and spoIIID, which are turned on during hours three to four of sporulation; cotE as transcribed from its P2 promoter and sigK, which are turned on during hour five by the appearance of the product (a small DNA-binding protein) of spoIIID; cotA, cotD and gerE, which are turned on during hours five to six by the appearance of the product (sigma factor sigma K) of sigK; and cotB and cotC, which are turned on during hour seven by the appearance of the product (an inferred DNA-binding protein) of gerE. The cascade is hierarchical in that the first three gene sets each contain the regulatory gene that turns on the expression of the next gene set in the pathway. We also show that the level of expression of a member (cotC) of the terminal class of gene expression is strongly influenced by medium and that this effect directly or indirectly depends on the product of sporulation gene spoIV A.

The SpoOA protein of Bacillus subtilis is a repressor of the abrB gene

The spoOA gene of Bacillus subtilis is critical for the initial stages in the developmental cycle leading to the formation of an endospore. We show that one function of the SpoOA protein is to negatively regulate another regulatory locus, abrB, which controls the expression of many genes associated with the onset of sporulation. Purified SpoOA protein binds to a specific region of the abrB promoter and functions as a repressor of transcription in an in vitro assay. The binding of the SpoOA protein is independent of the binding of the AbrB protein, which is known to autoregulate its expression. This independence mirrors the temporal sequence of events in abrB control.

A target for carbon source-dependent negative regulation of the citB promoter of Bacillus subtilis

Expression of the aconitase (citB) gene of Bacillus subtilis is subject to catabolite repression in cells grown in minimal media. In nutrient broth medium, citB expression is low in growing cells but is induced when cells enter sporulation. A 600-base-pair DNA fragment that extends from positions -400 through +200, relative to the transcription start site, was shown to include all of the cis-acting sequences necessary for catabolite repression and sporulation-associated regulation. This was demonstrated by fusing this DNA fragment to the Escherichia coli lacZ gene, integrating the fusion in the amyE locus of the B. subtilis chromosome, and measuring the regulation of expression of beta-galactosidase. By creating a series of deletions from either end of the 600-base-pair fragment, it was possible to define a target for catabolite repression; at least part of this target lies within the sequence between positions -84 and -68. DNA fragments that included positions -84 through +36, when carried on high-copy plasmids, caused derepression of aconitase synthesis, as if a negative regulator were being titrated. The same plasmids caused derepression of citrate synthase activity as well. Deletion of the sequence between positions -84 and -67 abolished this titration effect for both enzymes. Mutations that altered the target for catabolite repression also affected the inducibility of citB at the onset of sporulation, at least when sporulation was induced by the addition of decoyinine, an inhibitor of guanine nucleotide synthesis. When sporulation was induced by exhaustion of nutrient broth, there was no detectable difference in expression of citB-lacZ fusions whether or not they had the citB sequence from positions -84 to -67, suggesting that the mechanisms of regulation of citB in minimal medium and nutrient broth are different.

Negative regulator of sigma G-controlled gene expression in stationary-phase Bacillus subtilis

In some media, Bacillus subtilis can maintain a prolonged stationary growth phase; however, in other media, nutrient depletion triggers a complex differentiation that culminates in production of a dormant endospore. This differentiation requires the expression of many genes. We found that during the stationary phase in media in which the cells do not form endospores and do not normally express these sporulation-essential genes, a recessive mutation in spoIIAB caused increased transcription of a set of genes essential for sporulation. Evidently, the wild-type product of spoIIAB acts during the stationary phase to prevent expression of additional sporulation-specific genes.

Molecular biology of antibiotic production in Bacillus

Several species of the genus Bacillus produce peptide antibiotics which are synthesized either through a ribosomal or non-ribosomal mechanism. The antibiotics gramicidin, tyrocidine, and bacitracin are synthesized nonribosomally by the multienzyme thiotemplate mechanism. Surfactin and mycobacillin are also synthesized nonribosomally but by a mechanism that, apparently, is distinct from that of the multienzyme thiotemplate. Other antibiotics such as subtilin are gene encoded and are ribosomally synthesized. Molecular genetic and DNA sequence analysis have shown that biosynthesis genes for some antibiotics are clustered into polycistronic transcription units and are under the control of global regulatory systems that govern the expression of genes that are induced when Bacillus cells enter stationary phase of growth. Future experiments involving the molecular dissection of peptide antibiotic biosynthesis genes in Bacillus will be attempted in hopes of further examining the mechanism and regulation of antibiotic production.

AbrB, a regulator of gene expression in Bacillus, interacts with the transcription initiation regions of a sporulation gene and an antibiotic biosynthesis gene

The abrB gene of Bacillus subtilis is believed to encode a repressor that controls the expression of genes involved in starvation-induced processes such as sporulation and the production of antibiotics and degradative enzymes. Two such genes, spoVG, a sporulation gene of B. subtilis, and tycA, which encodes tyrocidine synthetase I of the tyrocidine biosynthetic pathway in Bacillus brevis, are negatively regulated by abrB in B. subtilis. To examine the role of abrB in the repression of gene transcription, the AbrB protein was purified and then tested for its ability to bind to spoVG and tycA promoter DNA. In a gel mobility shift experiment, AbrB was found to bind to a DNA fragment containing the sequence from -95 to +61 of spoVG. AbrB protein exhibited reduced affinity for DNA of two mutant forms of the spoVG promoter that had been shown to be insensitive to abrB-dependent repression in vivo. These studies showed that an upstream A + T-rich sequence from -37 to -95 was required for optimal AbrB binding. AbrB protein was also observed to bind to the tycA gene within a region between the transcription start site and the tycA coding sequence as well as to a region containing the putative tycA promoter. These findings reinforce the hypothesis that AbrB represses gene expression through its direct interaction with the transcription initiation regions of genes under its control.

Sigma H-directed transcription of citG in Bacillus subtilis

The RNA polymerase sigma factor sigma H is essential for the onset of endospore formation in Bacillus subtilis. sigma H also is required for several additional stationary-phase-specific responses, including the normal expression of several genes that are required for the development of competence for DNA uptake. It is necessary to identify the genes that are transcribed by sigma H RNA polymerase (E sigma H) in order to understand the role of this sigma factor during the transition from exponential growth to stationary phase. Feavers et al. (Mol. Gen. Genet. 211:465-471, 1988) proposed that citG, the structural gene for fumarase, is transcribed from two promoters, one of which (citGp2 [P2]) may be used by E sigma H. It is likely that the citGp2 promoter is used by E sigma H because we found that this promoter was used accurately in vitro by E sigma H and directed expression of xylE in vivo. This xylE expression was dependent on spo0H, the structural gene for sigma H, and was independent of the citGp1 promoter. Comparison of the nucleotide sequences of several sigma H-dependent promoters showed that these sequences were similar at two regions approximately 10 and 35 base pairs upstream from the start points of transcription. These sequences may signal recognition of these promoters by E sigma H. Primer extension analyses were used to examine transcription from three sigma H-dependent promoters during growth and sporulation. The citGp2 promoter appeared to be active during the middle and late stages of exponential growth, whereas activation of the spoIIA promoter was delayed until after the end of exponential growth. Evidently, promoters used by E sigma H can display different temporal patterns of expression.

Cloning and characterization of srfB, a regulatory gene involved in surfactin production and competence in Bacillus subtilis

A Tn917 insertion mutation srfB impairs the production of the lipopeptide antibiotic surfactin in Bacillus subtilis. srfB is located between aroG and ald in the B. subtilis genome, as determined by phage PBS1 transduction mapping, and is not linked to the previously described surfactin loci sfp or srfA. A srfB mutant was found to be also deficient in the establishment of competence. SP beta phage-mediated complementation analysis showed that both competence and surfactin production were restored in the srfB mutant by a single DNA fragment of 1.5 kilobase pairs. The sequence of the complementing DNA revealed that the srfB gene is comA, an early competence gene which codes for a product similar to that of the activator class of bacterial two-component regulatory systems. The srfB mutation impaired the expression of a srfA-lacZ fusion, suggesting that surfactin production is positively regulated at the transcriptional level by the srfB (comA) gene product.

Identification and characterization of genes controlled by the sporulation-regulatory gene spo0H in Bacillus subtilis

We describe a general strategy for the identification of genes that are controlled by a specific regulatory factor in vivo and the use of this strategy to identify genes in Bacillus subtilis that are controlled by spo0H, a regulatory gene required for the initiation of sporulation. The general strategy makes use of a cloned regulatory gene fused to an inducible promoter to control expression of the regulatory gene and random gene fusions to a reporter gene to monitor expression in the presence and absence of the regulatory gene product. spo0H encodes a sigma factor of RNA polymerase, sigma H, and is required for the extensive reprograming of gene expression during the transition from growth to stationary phase and during the initiation of sporulation. We identified 18 genes that are controlled by sigma H (csh genes) in vivo by monitoring expression of random gene fusions to lacZ, made by insertion mutagenesis with the transposon Tn917lac, in the presence and absence of sigma H. These genes had lower levels of expression in the absence of sigma H than in the presence of sigma H. Patterns of expression of the csh genes during growth and sporulation in wild-type and spo0H mutant cells indicated that other regulatory factors are probably involved in controlling expression of some of these genes. Three of the csh::Tn917lac insertion mutations caused noticeable phenotypes. One caused a defect in vegetative growth, but only in combination with a spo0H mutation. Two others caused a partial defect in sporulation. One of these also caused a defect in the development of genetic competence. Detailed characterization of some of the csh genes and their regulatory regions should help define the role of spo0H in the regulation of gene expression during the transition from growth to stationary phase and during the initiation of sporulation.

Identification of Bacillus subtilis genes expressed early during sporulation

Labelled cDNA transcribed in vitro from early-sporulation RNA was enriched for sporulation-specific sequences by subtractive hybridization to an excess of vegetative RNA and used to probe libraries of Bacillus subtilis chromosomal DNA. From the initial collection of clones that coded for RNAs transcribed preferentially during sporulation, several were subcloned and studied in more detail. It was found that two clones contained sequences (dciA and dciB) that had an undetectable level of transcription during vegetative growth but had transcripts that started to appear no later than eight minutes after induction of sporulation. A third DNA segment (dciC) was expressed at a low level in vegetative cells and increased within four minutes after induction of sporulation. The effects of spoO mutations, i.e. mutations that prevent cells from reaching stage I of the sporulation process, were tested. Induction of the dciA and dciB transcripts was significantly reduced in strains carrying mutations in the spoOA and spoOH genes but not in a spoOB mutant strain. In addition, a product of the abrB locus, a locus in which mutations are known to partially overcome the pleiotropic effect of spoOA and spoOB mutations, seemed to be required for dciA and dciB expression.

Regulatory studies on the promoter for a gene governing synthesis and assembly of the spore coat in Bacillus subtilis

gerE is a regulatory gene of Bacillus subtilis that governs the synthesis and assembly of the spore coat and is required for the production of spores that are lysozyme-resistant and germination-proficient. We report the identification of the promoter for gerE and studies on the regulation of its expression. We show that gerE is switched on at the fourth hour of sporulation (stage-V) and that this expression is restricted to the mother-cell chamber of the sporangium. Dependency studies in which the level of gerE expression was measured in 36 different developmental mutants indicate that efficient expression of gerE requires the products of almost all spo0-IV genes tested as well as certain spoV genes. On the basis of its time of induction, compartmentalization of expression and pattern of dependence on other spo genes, gerE is inferred to be regulated co-ordinately with the previously studied spore coat protein gene cotA. gerE and cotA may be members of a developmental regulon of genes whose products are involved in the assembly of the spore coat.

cis sequences involved in modulating expression of Bacillus licheniformis amyL in Bacillus subtilis: effect of sporulation mutations and catabolite repression resistance mutations on expression

Nutrient conditions which trigger sporulation also activate expression of the Bacillus licheniformis alpha-amylase gene, amyL. Glucose represses both spore formation and expression of amyL. A fusion was constructed between the B. licheniformis alpha-amylase regulatory and 5' upstream sequences (amyRi) and the Escherichia coli lacZ structural gene to identify sequences involved in mediating temporal activation and catabolite repression of the amyL gene in Bacillus subtilis. amyRi-directed expression in a variety of genetic backgrounds and under different growth conditions was investigated. A 108-base-pair sequence containing an inverted repeat sequence, ribosome-binding site, and 26 codons of the structural gene was sufficient to mediate catabolite repression of amyL. spo0 mutations (spo0A, spo0B, spo0E, and spo0H) had no significant effect on temporal activation of the gene fusion when the recipient strains were grown in nonrepressing medium. However, in glucose-grown cultures the presence of a spo0A mutation resulted in more severe repression of amyRi-lacZ. In contrast, a spo0H mutation reduced the repressive effect of glucose on amyRi-lacZ expression. The spo0A effect was relieved by an abrB mutation. Initiation of sporulation is not a prerequisite for either temporal activation or derepression of alpha-amylase synthesis. Mutations causing resistance to catabolite repression in B. subtilis GLU-47, SF33, WLN30, and WLN104 also relieved catabolite repression of amyRi-lacZ.

Mutation changing the specificity of an RNA polymerase sigma factor

We describe a mutation that changes the fine specificity of promoter selection by a secondary form of RNA polymerase holoenzyme in Bacillus subtilis. The product of regulatory gene spo0H is an RNA polymerase sigma factor called sigma H, which directs transcription of a sporulation gene known as spoVG. We show that the spo0H mutation spo0H81, which blocks transcription from the wild-type spoVG promoter, enhances transcription from a mutant form of the spoVG promoter (spoVG249) bearing a severe down-mutation (a G.C to A.T transition) at position -13 in the "-10 region." Suppression of the spoVG249 mutation is specific in the sense that the transcription from several other spoVG mutant promoters was not restored by the mutant sigma. Evidently, spo0H81 is a change-of-specificity mutation that alters sigma H-RNA polymerase in a way that decreases its capacity to use the wild-type spoVG promoter, while increasing its capacity to use the mutant promoter. Transcription experiments in vitro using RNA polymerase containing the wild-type or mutant sigma support this interpretation. The spo0H81 mutation causes a threonine (Thr100) to isoleucine substitution in a region of sigma H that is highly homologous among sigma factors of diverse origins. We discuss the possibility that Thr100 is an amino acid-base-pair contact site and that sigma factors contact the -10 region of their cognate promoters by means of amino acid residues in this highly conserved region.

Regulation of transcription of the Bacillus subtilis spoIIA locus

The start point of spoIIA transcription was defined by primer extension analysis with two separate primers. It was 27 bases upstream from the putative translation initiation codon of the first open reading frame in the spoIIA locus. A region extending at least 52 bases upstream from the transcription start site was necessary for transcription, as determined with integrative plasmids. Transcription of spoIIA was dependent on the spoOA, spoOB, and spoOF loci, but this dependency was partly overcome by increasing the number of copies of the spoIIA promoter region. Transcription of spoIIA was absolutely dependent on the spoOH locus, which codes for the RNA polymerase sigma factor sigma H. Regions approximately -35 and -10 upstream from the spoIIA transcription start site showed sequence homology with Bacillus subtilis sigma H promoters.

Evidence for an additional temporal class of gene expression in the forespore compartment of sporulating Bacillus subtilis

We present evidence indicating that the previously studied, sporulation-induced gene 0.3 kb, which encodes a stable RNA present at late developmental stages, is transcribed in the forespore chamber of sporulating cells of Bacillus subtilis. Compartmentalized gene expression was demonstrated on the basis of subcellular fractionation experiments in which severalfold-higher levels of 0.3 kb-directed beta-galactosidase specific activity were observed in forespore extracts than in extracts from the mother cell and dependence studies in which 0.3 kb transcription was found to be blocked in mutants bearing mutations in spoIIIA, spoIIIE, and spoIIIG, genes which are known to govern forespore gene expression. Also, 0.3 kb transcription could be switched on during growth in cells in which transcription of the forespore regulatory gene spoIIIG was engineered to be activated in response to the lac inducer IPTG (isopropyl-beta-D-thiogalactopyranoside). Although it is transcribed in the forespore, 0.3 kb is switched on at a later developmental stage than other previously studied forespore-expressed genes, and hence it appears to be representative of an additional temporal class of compartmentalized gene expression.

Identification of a genetic locus required for biosynthesis of the lipopeptide antibiotic surfactin in Bacillus subtilis

Surfactin is a lipopeptide antibiotic produced by the cells of Bacillus subtilis ATCC 21332. A genetic locus responsible for surfactin production (sfp) was transferred from ATCC 21332 to JH642, a derivative of the standard B. subtilis 168. To study the sfp locus at the molecular level, a Tn917 insertion mutant that was blocked in surfactin production (srf) was isolated. The srf::Tn917 mutation was found to be closely linked to sfp, and both loci mapped by PBS1 phage transduction to the chromosomal region between aroI and mtlB. These studies suggest that JH642, a strain which is not a producer of surfactin (genotypically sfp0), contains at least some of the genes encoding surfactin production. Expression of the srf gene(s) was examined in both sfp and sfp0 cells by assaying beta-galactosidase activity encoded by a promoterless lacZ gene that was fused to the srf::Tn917 insertion. In cells of both strains, srf-directed beta-galactosidase activity increased when cells entered the stationary phase of the growth curve, but the activity in sfp cells was higher than that in sfp0 cells. srf-lacZ expression was partially impaired by a mutation in spo0A. In sfp0 cells, this dependence on the spo0A gene product could be entirely bypassed by an abrB suppressor mutation. In the sfp cells, the abrB mutation could not restore the defect conferred by the spo0A mutation. These data suggest that the sfp locus, which is responsible for surfactin production, alters the transcriptional regulation of srf in JH642 cells.

Critical roles of spo0A and spo0H in vegetative alkaline phosphatase production in Bacillus subtilis

Growth conditions established to optimize vegetative alkaline phosphatase production and stability in Bacillus subtilis were used to compare alkaline phosphatase synthesis and secretion in isogenic strains JH646 (spo0A12) and JH646MS (spo0A12 abrB15). A mutation in spo0A blocked vegetative alkaline phosphatase production, and a second mutation at the abrB locus resulted in hyperinduction of vegetative alkaline phosphatase. Phosphate regulation of vegetative alkaline phosphatase synthesis was unaffected in the double mutant. spo0H, on a multicopy plasmid, partially overcame the spo0A effect.

The promoter for a sporulation gene in the spoIVC locus of Bacillus subtilis and its use in studies of temporal and spatial control of gene expression

We have identified the transcription start site and regulatory region governing the expression of a sporulation gene in the spoIVC locus of Bacillus subtilis. Efficient expression and developmental regulation of this gene was controlled from a promoter region that extended no more than 110 base pairs upstream and no more than 4 base pairs downstream from the start site of transcription, on which basis we infer that spoIVC is regulated at the level of transcription initiation. Using a transcriptional fusion of the spoIVC gene to the lacZ gene of Escherichia coli, we found that spoIVC expression was turned on at the third to fourth hour of sporulation (at about the developmental stage [IV] that its products are required in spore formation) and that this transcription was largely restricted to the mother cell chamber of the sporangium. Mutations in many different spo genes (causing blocks at stages 0 to V) were found to influence (negatively and positively) the level of spoIVC expression. Our results distinguish the mode of spoIVC regulation from that of previously studied sporulation genes and indicate that it is representative of a new regulon of mother cell-specific gene expression.

Cloning and characterization of Bacillus subtilis iep, which has positive and negative effects on production of extracellular proteases

We have isolated a DNA fragment from Bacillus subtilis 168 which, when present in a high-copy plasmid, inhibited production of extracellular alkaline and neutral proteases. The gene responsible for this activity was referred to as iep. The open reading frame of iep was found to be incomplete in the cloned DNA fragment. When the intact iep gene was reconstructed after the missing part of the iep gene had been cloned, it showed an enhancing effect on the production of the extracellular proteases. The open reading frame encodes a polypeptide of 229 amino acids with a molecular weight of ca. 25,866. Deletion of two amino acids from the N-terminal half of the putative iep protein resulted in dual effects, i.e., a decrease in the inhibitory activity shown by the incomplete iep gene and a slight increase in the enhancing activity shown by the complete iep gene. These results show that the iep gene product is a bifunctional protein, containing inhibitory and enhancing activities for the exoprotease production in the N-terminal and C-terminal regions, respectively. It was found by genetic and functional analyses that iep lies very close to sacU.

Gene encoding sigma E is transcribed from a sigma A-like promoter in Bacillus subtilis

Bacillus subtilis produces several RNA polymerase sigma factors. At least two of these factors are essential for endospore formation, sigma H, which is present in vegetative cells, and sigma E, which is produced exclusively after the start of endospore formation. The structural gene that encodes sigma E is part of the spoIIG operon, which is transcribed after the onset of sporulation. We have determined the starting point of transcription and the nucleotide sequence of the spoIIG promoter. This promoter contains sequences that are similar to those found at the -10 and -35 regions of promoters that are used by E sigma A, the primary form of RNA polymerase in vegetative cells. The unusual feature of this promoter is that these putative sigma A contact sites are separated by 22 base pairs, rather than the typical 17 or 18 base pairs. Single-base substitutions in the -10-like sequence reduced utilization of the spoIIG promoter in vivo. Furthermore, E sigma A, but not E sigma H and other secondary forms of RNA polymerase, accurately initiated transcription from the spoIIG promoter in an in vitro assay; therefore, we suggest that E sigma A transcribes the spoIIG operon in vivo. A base substitution in the -35-like sequence caused constitutive transcription from the promoter in vegetative cells; therefore, regulation of this sporulation-specific transcription may involve a novel mechanism.

Sequence analysis and regulation of the hpr locus, a regulatory gene for protease production and sporulation in Bacillus subtilis

The hyperproduction of alkaline and neutral proteases is a phenotype of mutation at the hpr locus. This locus has been cloned and sequenced and has been found to code for a protein of 23,718 Mr. The mutations hpr-1, scoC4, and catA7 were identified by sequencing as mutations within the hpr gene. The phenotype of mutations in the hpr gene is due to loss of the hpr gene product, and therefore we suggest that the hpr gene encodes a negative regulator of protease production. This negative regulator must control genes other than protease genes, and these genes must include at least one gene required for sporulation, since overproduction of the hpr gene product by cloning the locus on a multicopy vector results in the inhibition of sporulation as well as protease production. Truncated fragments of the hpr gene or its promoter do not have this phenotype. Transcription of the hpr locus is controlled by the spoOA gene. In an spoOA mutant the hpr gene transcript is constitutively overproduced, as determined by a transcription fusion to beta-galactosidase. The results are consistent with the view that the spoOA gene may control sporulation and transcription by modulating the level and activity of several regulatory proteins.

Extracellular control of spore formation in Bacillus subtilis

Spore formation in the Gram-positive bacterium Bacillus subtilis has been classically viewed as an example of unicellular differentiation that occurs in response to nutritional starvation. We present evidence that B. subtilis produces an extracellular factor(s) that is required, in addition to starvation conditions, for efficient sporulation. This factor is secreted and accumulates in a cell density-dependent fashion such that cells at a low density sporulate poorly under conditions in which cells at a high density sporulate efficiently. Conditioned medium (sterile filtrate) from cells grown to a high density contains this extracellular differentiation factor (EDF-A) and stimulates spore formation of cells at low density under normal starvation conditions. EDF-A is heat-resistant, protease-sensitive, and dialyzable, indicating that it is at least in part an oligopeptide. Production of EDF-A is reduced or eliminated in spoOA and spoOB mutants, which are defective in many processes associated with the end of vegetative growth. Mutations in abrB, which suppress many of the pleiotropic phenotypes of spoOA mutants, restore production of EDF-A.

Identification of the promoter for a spore coat protein gene in Bacillus subtilis and studies on the regulation of its induction at a late stage of sporulation

The cotA (pig) gene of Bacillus subtilis encodes a 65,000 Mr protein that is a component of the spore coat and is responsible for the brown pigment characteristic of colonies in which cells are undergoing sporulation. To study developmental regulation of the cotA gene, we identified its promoter and studied its transcription in a large number of mutants blocked at various stages of sporulation and germination. Deletion analysis showed that induction and efficient transcription of cotA required DNA sequences extending no more than 55 base pairs (bp) upstream (and no more than 130 bp downstream) from the 5' terminus of cotA mRNA. Transcription from the cotA promoter was found to be switched on at approximately the time (4 to 5 h after the onset of sporulation) of spore coat synthesis and deposition. Strikingly, this transcription was substantially inhibited in almost all asporogenous mutants blocked prior to the developmental stage (V) of spore coat formation. cotA transcription was also impaired in several stage V mutants but not in other stage V mutants or in mutants blocked in germination. The germination mutant gerE caused a several-fold overexpression of cotA. The dependence of cotA expression on so many genes required at early to intermediate stages of sporulation suggests that transcription of this spore coat gene is somehow coupled (directly or through several intervening steps) to a morphological or physiological feature(s) of the developing sporangium.

Characterization of the promoter region of the Bacillus subtilis spoIIE operon

Mutations that define the spoIIE locus of Bacillus subtilis block sporulation at an early stage and recently were shown to prevent the proteolytic processing of sigma E (sigma 29) into its active form, an event that is believed to control critical changes in gene expression during the second hour of development. By taking advantage of two Tn917-mediated insertional mutations in spoIIE, we have cloned DNA spanning the locus. Gene disruption experiments with subcloned fragments transferred to integrational vectors revealed that the locus consisted of a single transcription unit about 2.5 kilobase pairs in size. Transcriptional lacZ fusions were used to show that expression of this transcription unit initiated at 1.5 h after the end of log-phase growth and depended upon the products of all spo0 loci. Expression was directed by a single promoter whose position was determined by high-resolution S1 protection mapping. A deletion analysis of the promoter region was also carried out, with novel integrational vectors based on derivatives of coliphage M13. The results indicated that a region of DNA extending from 183 to 118 base pairs upstream from the start point of transcription was required for full activity of the spoIIE promoter. The presumptive RNA polymerase-binding region of the promoter exhibited striking similarity to the spoIIG promoter and featured perfect but unusually spaced -10 and -35 consensus sequences for sigma A (sigma 43)-associated RNA polymerase.

Transcription of Bacillus subtilis subtilisin and expression of subtilisin in sporulation mutants

The start point for transcription of the subtilisin (aprE) gene was determined by primer extension analysis and was found to be at a point significantly different from that identified in a previously published report (S. L. Wong, C. W. Price, D. S. Goldfarb, and R. H. Doi, Proc. Natl. Acad. Sci. USA 81:1184-1188, 1984). An aprE-lacZ fusion was used to analyze expression of the promoter. Deletion analyses of the promoter were performed to determine the extent of the upstream region necessary for activity. This was found to be between -52 and -41 with respect to the transcription start site. Expression of the aprE-lacZ fusion was unimpaired in a mutant deleted for the sigma B subunit of RNA polymerase. Mutations in the gene for the sigma H subunit of RNA polymerase decreased expression of the aprE-lacZ fusion to approximately 25% of that of the wild type. These results leave the identity of the sigma factor responsible for transcription of this gene in question. Mutations in the spo0A gene drastically decreased the activity of the aprE promoter and its upstream deletion derivatives, while the abrB gene, a phenotypic suppressor of spo0 mutations, restored activity of the aprE promoter in all of the deletion derivatives. Thus, inhibition of transcription by the spo0A mutation and its restoration by an abrB mutation could not be separated from the promoter of the aprE gene.

Effect of decoyinine on the regulation of alpha-amylase synthesis in Bacillus subtilis

Decoyinine, an inhibitor of GMP synthetase, allows sporulation in Bacillus subtilis to initiate and proceed under otherwise catabolite-repressing conditions. The effect of decoyinine on alpha-amylase synthesis in B. subtilis, an event which exhibits regulatory features resembling sporulation initiation, was examined. Decoyinine did not overcome catabolite repression of alpha-amylase synthesis in a wild-type strain of B. subtilis but did cause premature and enhanced synthesis in a mutant strain specifically blocked in catabolite repression of alpha-amylase synthesis. Decoyinine had no effect on alpha-amylase enzymatic activity. Thus, it appears that the catabolite control mechanisms governing alpha-amylase synthesis and sporulation in B. subtilis differ in their responses to decoyinine and hence must consist at least partially of separate components.

Organization and regulation of an operon that encodes a sporulation-essential sigma factor in Bacillus subtilis

Deletion of sigE, the structural gene for the sporulation-induced RNA polymerase sigma factor, sigma E, prevented endospore formation by Bacillus subtilis. The effects of integration of plasmids into the sigE region of the chromosome and the use of complementation analyses demonstrated that sigE is part of an operon that includes a promoter-proximal gene, spoIIGA, that is essential for sporulation. Gene fusions to the promoter of this operon, spoIIG, demonstrated that transcription from this promoter is induced at the beginning of sporulation and is dependent on several spoO genes.

Identification of the promoter for a peptide antibiotic biosynthesis gene from Bacillus brevis and its regulation in Bacillus subtilis

Tyrocidine is a cyclic decapeptide antibiotic which is produced and secreted by stationary-phase cells of the sporeforming bacterium Bacillus brevis. We identified the promoter for the B. brevis structural gene (tycA) for tyrocidine synthetase I, the enzyme catalyzing the first step in tyrocidine biosynthesis, and studied its regulation in cells of B. brevis and Bacillus subtilis. Transcription from the tycA promoter was induced at the end of the exponential phase of the growth cycle in B. brevis cells growing in sporulation medium. To study the regulation of tycA in B. subtilis, we constructed a derivative of the B. subtilis bacteriophage SP beta containing a transcriptional fusion of the tycA promoter to the lacZ gene of Escherichia coli and introduced the tycA-lacZ operon fusion by means of specialized transduction into sporulation mutants known to be blocked in sporulation-associated antibiotic production. Our principal finding was that tycA-directed lacZ expression was impaired in the stage-0 mutants with mutations spo0A, spo0B, and spo0E but not in spo0C, spo0F, spo0H, or spo+ bacteria. The dependence on the spo0A gene product could be entirely bypassed by an abrB suppressor mutation, which caused tycA-lacZ to be transcribed constitutively at all stages of growth. A simple model is proposed for the mechanism of tycA induction based on the Spo0A-dependent inactivation of Ab-B protein, which is proposed to be a negative regulator of tycA transcription.