Sequence and transcription mapping of Bacillus subtilis competence genes comB and comA, one of which is related to a family of bacterial regulatory determinants

Characterization of the srfA locus of Bacillus subtilis: only the valine-activating domain of srfA is involved in the establishment of genetic competence

srfA is a locus required for the production of the lipopeptide antibiotic surfactin. This locus is also necessary for efficient sporulation and competence development. Mutations in the 5' portion of the srfA operon affect all three of these processes, whereas mutations in the 3' portion of srfA only affect sporulation and surfactin production. Analysis of the proteins encoded by the srfA locus revealed seven large domains which are likely to be responsible for the activation and binding of the seven amino acids of surfactin. Identification of the amino acid that is activated by the srfA domains was determined by amino acid-dependent pyrophosphate exchange reactions on partially purified cell extracts of strains carrying different srfA mutations. These results indicate colinearity between the order of the domains in the srfA locus and the amino acid sequence of surfactin. The minimal genetic element of srfA required for the establishment of competence was shown to be the 5' region of the second open reading of srfA, which encodes the valine activation domain. This portion of srfA, when cloned on a plasmid, complemented the competence deficiency of a srfA deletion mutant in trans.

Mutational analysis of the regulatory region of the srfA operon in Bacillus subtilis

Transcription of the Bacillus subtilis srfA operon is dependent on the transcriptional activator ComA. Mutational analysis of the srfA regulatory region suggests that two regions of dyad symmetry upstream of the srfA promoter may function in transcriptional activation by facilitating a cooperative interaction between ComA dimers.

A gene cluster involved in aerial mycelium formation in Streptomyces griseus encodes proteins similar to the response regulators of two-component regulatory systems and membrane translocators

Mutants of Streptomyces griseus deficient in A-factor production are sporulation negative, since A-factor is an essential hormonal regulator for the induction of morphological and physiological differentiation in this bacterium. A DNA fragment which induced aerial mycelium formation and sporulation in an A-factor-deficient mutant strain, S. griseus HH1, was cloned from this mutant strain. Subcloning experiments and nucleotide sequencing showed that two open reading frames, ORF1 with 656 amino acids and ORF2 with 201 amino acids, were required in order to induce sporulation. The amino acid sequence of ORF1 significantly resembled that of the Escherichia coli HlyB protein, a member of a family of bacterial membrane proteins engaged in ATP-dependent secretion mechanisms. Conserved features of this surface translocator family, such as the transmembrane structure predicted by their hydropathy profiles and the amino acid sequence forming an ATP-binding fold, were also conserved in ORF1. The ORF1 gene appeared to constitute a transcriptional unit with an additional upstream gene encoding ORF3, which was greatly similar to ORF1 in size and amino acid sequence. The other protein, ORF2, showed significant end-to-end homology with the E. coli uhpA product, a regulatory protein for the uptake of sugar phosphates. Like UhpA as a response regulator of a bacterial two-component regulatory system, ORF2 contained a helix-turn-helix DNA-binding domain at its COOH-terminal portion and an Asp residue (Asp-54) probably to be phosphorylated at its NH2-terminal portion. An amino acid replacement from Asp-54 to Asn resulted in the loss of the ability of ORF2 to induce sporulation in strain HH1.

Regulation of peptide antibiotic production in Bacillus

In Bacillus species, starvation leads to the activation of a number of processes that affect the ability to survive during periods of nutritional stress. Activities that are induced include the development of genetic competence, sporulation, the synthesis of degradative enzymes, motility, and antibiotic production. The genes that function in these processes are activated during the transition from exponential to stationary phase and are controlled by mechanisms that operate primarily at the level of transcription initiation. One class of genes functions in the synthesis of special metabolites such as the peptide antibiotics tyrocidine and gramicidin S as well as the cyclic lipopeptide surfactin. These genes include the grs and tyc operons in Bacillus brevis, which encode gramicidin S synthetase and tyrocidine synthetase, respectively, and the srfA operon of Bacillus subtilis which encodes the enzymes of the surfactin synthetase complex. Peptide antibiotic biosynthesis genes are regulated by factors as diverse as the early sporulation gene product Spo0A, the transition-state regulator AbrB, and gene products (ComA, ComP, and ComQ) required for the initiation of the competence developmental pathway.

Cloning and sequence analysis of genes for dehalogenation of 4-chlorobenzoate from Arthrobacter sp. strain SU

Strains of Arthrobacter catalyze a hydrolytic dehalogenation of 4-chlorobenzoate (4-CBA) to p-hydroxybenzoate. The reaction requires ATP and coenzyme A (CoA), indicating activation of the substrate via a thioester, like that reported for Pseudomonas sp. strain CBS3 (J. D. Scholten, K.-H. Chang, P. C. Babbit, H. Charest, M. Sylvestre, and D. Dunaway-Mariano, Science 253:182-185, 1991). The dehalogenase genes of Arthrobacter sp. strain SU were cloned and expressed in Escherichia coli. Analyses of deletions indicate that dehalogenation depends on three open reading frames (ORFs) which are organized in an operon. There is extensive sequence homology to corresponding gene products in Pseudomonas sp. strain CBS3, suggesting that ORF1 and ORF2 encode a 4-CBA-CoA-ligase and a 4-CBA-CoA dehalogenase, respectively. ORF3 possibly represents a thioesterase, although no homology to the enzyme from Pseudomonas sp. strain CBS3 exists.

Sporulation regulatory protein GerE from Bacillus subtilis binds to and can activate or repress transcription from promoters for mother-cell-specific genes

The mother-cell line of gene expression during sporulation in Bacillus subtilis is a hierarchical cascade consisting of at least four temporally controlled gene sets, the first three of which each contain a regulatory gene for the next gene set in the pathway. gerE, a member of the penultimate gene set, is a regulatory gene whose products is required for the transcriptional activation of genes (coat protein genes cotB and cotC) in the last gene set. The gerE product also influences the expression of other members of the penultimate gene set (coat protein genes cotA and cotD appear to be repressed and activated, respectively). We now report that the purified product of gerE (GerE) is a DNA-binding protein that adheres to the promoters for cotB and cotC. We also show that GerE stimulates cotB and cotC transcription in vitro by RNA polymerase containing the mother-cell sigma factor sigma K. These findings support the view that GerE is a positively acting, regulatory protein whose appearance at a late stage of development directly activates the transcription of genes in the last known temporal class of mother-cell-expressed genes. In addition, GerE stimulates cotD transcription and inhibits cotA transcription in vitro by sigma K RNA polymerase, as expected from in vivo studies, and, unexpectedly, profoundly inhibits in vitro transcription of the gene (sigK) that encodes sigma K. The effects of GerE on cotD and sigK transcription are just the opposite of the effects exerted by the earlier-appearing, mother-cell regulatory protein spoIIID, suggesting that the ordered appearance of first SpoIIID, then GerE, ensures proper flow of the regulatory cascade controlling gene expression in the mother cell.

Early spo gene expression in Bacillus subtilis: the role of interrelated signal transduction systems

The early spo genes are subject to a number of different control mechanisms. We found that at least one histidine kinase, SpoIIJ, is important for the expression of early spo genes but that two others, ComP and DegS, also affect sporulation, especially when SpoIIJ is absent. This indicates the existence of a signal transduction network which may gather information from several sources to feed into the sporulation pathway. Early spo gene expression is inhibited by overproduction of two response regulators, SpoOF and ComA. This effect is eliminated by the elevated presence of their cognate histidine kinases, SpoIIJ and ComP, respectively. This suggests that the unphosphorylated response regulators cause the inhibition of sporulation.

Transcriptional regulation of Bacillus subtilis glucose starvation-inducible genes: control of gsiA by the ComP-ComA signal transduction system

The Bacillus subtilis glucose starvation-inducible transcription units, gsiA and gsiB, were characterized by DNA sequencing, transcriptional mapping, mutational analysis, and expression in response to changes in environmental conditions. The gsiA operon was shown to consist of two genes, gsiAA and gsiAB, predicted to encode 44.9- and 4.8-kDa polypeptides, respectively. The gsiB locus contains a single cistron which encodes a protein of unusual structure; most of its amino acids are arranged in five highly conserved, tandemly repeated units of 20 amino acids. The 5' ends of gsiA and gsiB mRNAs were located by primer extension analysis; their locations suggest that both are transcribed by RNA polymerase containing sigma A. Expression of both gsiA and gsiB was induced by starvation for glucose or phosphate or by addition of decoyinine, but only gsiA was induced by exhaustion of nutrient broth or by amino acid starvation. Regulation of gsiA expression was shown to be dependent upon the two-component signal transduction system ComP-ComA, which also controls expression of genetic competence genes. Mutations in mecA bypassed the dependency of gsiA expression on ComA. Disruption of gsiA relieved glucose repression of sporulation but did not otherwise interfere with sporulation, development of competence, motility, or glucose starvation survival. We propose that gsiA and gsiB are members of an adaptive pathway of genes whose products are involved in responses to nutrient deprivation other than sporulation.

Role of the Bacillus subtilis gsiA gene in regulation of early sporulation gene expression

The Bacillus subtilis gsiA operon was induced rapidly, but transiently, as cells entered the stationary phase in nutrient broth medium. A mutation at the gsiC locus caused sporulation to be defective and expression of gsiA to be elevated and prolonged. The sporulation defect in this strain was apparently due to persistent expression of gsiA, since a gsiA null mutation restored sporulation to wild-type levels. Detailed mapping experiments revealed that the gsiC82 mutation lies within the kinA gene, which encodes the histidine protein kinase member of a two-component regulatory system. Since mutations in this gene caused a substantial blockage in expression of spoIIA, spoIIG, and spoIID genes, it seems that accumulation of a product of the gsiA operon interferes with sporulation by blocking the completion of stage II. It apparently does so by inhibiting or counteracting the activity of KinA.

Molecular characterization and regulation of the rhizosphere-expressed genes rhiABCR that can influence nodulation by Rhizobium leguminosarum biovar viciae

A group of four rhi (rhizosphere-expressed) genes from the symbiotic plasmid of Rhizobium leguminosarum biovar viciae has been characterized. Although mutation of the rhi genes does not normally affect nodulation, in the absence of the closely linked nodulation genes nodFEL, mutations in the rhi genes can influence the nodulation of the vetch Vicia hirsuta. The DNA sequence of the rhi gene region reveals four large open reading frames, three of them constituting an operon (rhiABC) transcribed convergently toward the fourth gene, rhiR. rhiABC are under the positive control of RhiR, the expression of which is repressed by flavonoids that normally induce nod gene expression. This repression, which requires the nodD gene product (the transcriptional activator of nod gene expression), may be due to a cis effect caused by a high level of NodD-dependent expression from the adjacent nodO promoter, which is transcribed divergently from rhiR. RhiR shows significant similarities to a subfamily of transcriptional regulators that includes the LuxR and UvrC-28K proteins. RhiA shows limited homology to a short domain of the lactose permease, LacY, close to a region thought to be involved in substrate binding. No strong homologies were found for the other rhi gene products. It appears that RhiA and RhiB are cytoplasmic, whereas RhiC is a periplasmic protein, since it has a typical N-terminal transit sequence and a rhiC-phoA protein fusion expresses alkaline phosphatase activity. The biochemical role of the rhi genes has not been established, but it appears that they may play a role in the plant-microbe interaction, possibly by allowing the bacteria to metabolize a plant-made metabolite.

Isolation and characterization of sfp: a gene that functions in the production of the lipopeptide biosurfactant, surfactin, in Bacillus subtilis

The sfp gene is required for cells of Bacillus subtilis to become producers of the lipopeptide antibiotic surfactin. sfp was isolated and its nucleotide sequence was determined. sfp was expressed in Escherichia coli and its putative product was purified for use in antibody production and in amino acid sequence analysis. The gene was plasmid-amplified in B. subtilis, where it conferred a Srf+ phenotype on sfp0 (surfactin non-producing) cells. Overproduction of Sfp in B. subtilis did not cause production of an increased amount of surfactin and resulted in the repression of a lacZ transcriptional fusion of the srfA operon, which encodes enzymes that catalyze surfactin synthesis. We propose that sfp represents an essential component of peptide synthesis systems and also plays a role, either directly or indirectly, in the regulation of surfactin biosynthesis gene expression.

The primary role of comA in establishment of the competent state in Bacillus subtilis is to activate expression of srfA

The establishment of genetic competence in Bacillus subtilis requires the genes of the competence regulon which function in the binding, processing, and transport of DNA. Their expression is governed by multiple regulatory pathways that are composed of the comA, comP, sin, abrB, spo0H, spo0K, spo0A, degU, and srfA gene products. Among these, srfA is thought to occupy an intermediate position in one of the pathways that controls late competence gene expression. The full expression of srfA requires the gene products of comP, comA, and spo0K. To determine the role of these genes in the regulation of competence development, the expression of the srfA operon was placed under control of the isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible promoter Pspac and the expression of the Pspac-srfA construct was examined in mutants blocked in early competence. By monitoring the IPTG-induced expression of Pspac-srfA with a srfA-lacZ operon fusion, it was observed that srfA expression was no longer dependent on the products of comP, comA, and spo0K. Production of the lipopeptide antibiotic surfactin in Pspac-srfA-bearing cells was induced in the presence of IPTG and was independent of ComP and ComA. Competence development was induced by IPTG and was independent of comP, comA, and spo0K in cells carrying Pspac-srfA. These results suggest that the ComP-ComA signal transduction pathway as well as Spo0K is required for the expression of srfA in the regulatory cascade of competence development. Studies of Pspac-srfA also examined the involvement of srfA in the growth stage-specific and nutritional regulation of a late competence gene.

Growth stage signal transduction and the requirements for srfA induction in development of competence

srfA is an operon needed for the development of genetic competence in Bacillus subtilis. This operon is normally expressed at a low level during growth, and its transcription increases sharply just before the transition to stationary phase. The genetic requirements for the full expression of srfA were previously examined in several laboratories and shown to include spo0A, spo0H, spo0K, comQ, and comA. In the present study these results were confirmed with an isogenic set of strains. We have also shown that comP is needed for srfA expression but that other regulatory genes required for competence (degU, sin, and abrB) are not needed for the expression of srfA. We have used the expression of srfA under control of the regulatable Pspac promoter to study the kinetics of competence development and to determine whether the genes ordinarily required for expression of srfA are needed for any additional roles during the development of competence. When expression of srfA was driven from Pspac, competence was expressed constitutively throughout growth. Furthermore, when srfA was expressed from Pspac, the spo0K, comQ, comP, and comA determinants were no longer required for the expression of competence. We conclude therefore that the multiple signals which trigger the initiation of competence development in relation to growth stage are ordinarily received prior to the increase in srfA expression. We propose that these signals are mediated by the products of spo0K, comQ, comP, and comA, resulting in the phosphorylation of ComA by ComP. This in turn would enable ComA to function as a positive transcription factor for srfA, leading to the elaboration of the srfA product(s) and the consequent initiation of competence. We also propose that this is the major, and possibly the only, role for the spo0K, comQ, comP, and comA products during competence development.

Genetic competence in Bacillus subtilis

Genetic competence may be defined as a physiological state enabling a bacterial culture to bind and take up high-molecular-weight exogenous DNA (transformation). In Bacillus subtilis, competence develops postexponentially and only in certain media. In addition, only a minority of the cells in a competent culture become competent, and these are physiologically distinct. Thus, competence is subject to three regulatory modalities: growth stage specific, nutritionally responsive, and cell type specific. This review summarizes the present state of knowledge concerning competence in B. subtilis. The study of genes required for transformability has permitted their classification into two broad categories. Late competence genes are expressed under competence control and specify products required for the binding, uptake, and processing of transforming DNA. Regulatory genes specify products that are needed for the expression of the late genes. Several of the late competence gene products have been shown to be membrane localized, and others are predicted to be membrane associated on the basis of amino acid sequence data. Several of these predicted protein sequences show a striking resemblance to gene products that are involved in the export and/or assembly of extracellular proteins and structures in gram-negative organisms. This observation is consistent with the idea that the late products are directly involved in transport of DNA and is equally consistent with the notion that they play a morphogenetic role in the assembly of a transport apparatus. The competence regulatory apparatus constitutes an elaborate signal transduction system that senses and interprets environmental information and passes this information to the competence-specific transcriptional machinery. Many of the regulatory gene products have been identified and partially characterized, and their interactions have been studied genetically and in some cases biochemically as well. These include several histidine kinase and response regulator members of the bacterial two-component signal transduction machinery, as well as a number of known transcriptionally active proteins. Results of genetic studies are consistent with the notion that the regulatory proteins interact in a hierarchical way to make up a regulatory pathway, and it is possible to propose a provisional scheme for the organization of this pathway. It is remarkable that almost all of the regulatory gene products appear to play roles in the control of various forms of postexponential expression in addition to competence, e.g., sporulation, degradative-enzyme production, motility, and antibiotic production. This has led to the notion of a signal transduction network which transduces environmental information to determine the levels and timing of expression of the ultimate products characteristic of each of these systems.

Identification of Bacillus subtilis adaptive response genes by subtractive differential hybridization

Subtractive differential hybridization was used to identify genes in Bacillus subtilis that are induced by nutrient limitation. Several transcription units were identified. They exhibited increased transcription when cells were deprived of certain nutrients, such as glucose, ammonium, or phosphate, or when cells were treated with decoyinine. The genes have been designated dci (for decoyinine-inducible) and gsi (for glucose-starvation-inducible). Using lacZ transcriptional fusions, the dependence of dci and gsi expression on gene products of the sensor and activator classes of bacterial two-component regulatory systems was examined. Transcription of dciA was impaired by a mutation in spoOA, while expression of gsiA was dependent on the early competence genes comP and comA. The implications of these findings are discussed, and a provisional scheme for information flow during the transition phase from growth to sporulation is proposed.

Transcription initiation region of the srfA operon, which is controlled by the comP-comA signal transduction system in Bacillus subtilis

srfA is an operon required for the production of the lipopeptide antibiotic surfactin, competence development, and efficient sporulation in Bacillus subtilis. The expression of srfA is induced after the end of exponential growth and is dependent on the products of late-growth regulatory genes comP, comA, and spo0K. To begin to understand the mechanism of srfA regulation, the srfA promoter region was identified and characterized. To examine srfA promoter activity, the srfA promoter was fused to lacZ and inserted into the B. subtilis chromosome as a single copy at the SP beta prophage. The location of the transcription start site of srfA was determined by primer extension analysis and shown to be preceded by a sequence that resembles the consensus promoter recognized by the sigma A form of RNA polymerase. The srfA operon was found to have a sequence corresponding to a long, untranslated leader region of the srfA mRNA (300 bp). A nucleotide sequence and mutational analysis of the promoter identified a region of dyad symmetry required for srfA-lacZ expression. A similar sequence is found in the region upstream of the degQ promoter, transcription from which is also regulated by ComA. This region of dyad symmetry found upstream of these promoters may be the target for ComA-dependent transcriptional activation.

Sequence and properties of comQ, a new competence regulatory gene of Bacillus subtilis

The sequence and properties of the comQ gene are described. comQ was predicted to encode a 34,209-Da protein, and the product of comQ was shown to be required for the development of genetic competence. The apparent transcriptional initiation and termination sites of comQ were mapped, and the location of a likely E sigma A promoter was inferred. The expression of comQ was maximal early in growth and declined as the cells approached the stationary phase. This expression was not dependent on any of the competence regulatory genes tested (comA, comP, sin, abrB, degU, and spo0A). Disruption of comQ in the chromosome prevented the development of competence as well as the transcription of comG, a late competence operon. This disruption also decreased the expression of srfA, a regulatory operon needed for the expression of competence. These and other results suggest a role for ComQ early in the hierarchy of competence regulatory genes, probably as a component of a signal transduction system.

Sequence and transcriptional regulation of com101A, a locus required for genetic transformation in Haemophilus influenzae

A 2.8-kb EcoRI-BglII fragment cloned from the wild-type Haemophilus influenzae Rd chromosome is shown to increase the transformability of the Com-101 mutant through trans complementation. Deletion and sequence analyses indicate that the active region of the clone carries a 687-bp open reading frame. A 0.3-kb insertion in the corresponding EcoRI-BglII fragment of the Com-101 chromosome is shown to be a partial (331-bp) duplication of this open reading frame. The wild-type sequence produces a peptide of a size that is consistent with the sequence data when this sequence is expressed in Escherichia coli with a T7 promoter-based transcription vector. RNA hybridization analysis using a DNA probe derived from the open reading frame suggests that the sequence is transiently expressed during competence development. On the basis of these observations, it is proposed that the open reading frame corresponds to the com101A gene.

Molecular cloning of two linked loci that increase the transformability of transformation-deficient mutants of Haemophilus influenzae

A plasmid containing a 13.3-kb insert (pER194) was isolated from an EcoRI genomic library of Haemophilus influenzae on the basis of its ability to increase the transformability of the transformation-deficient mutants Com-78 and Com-101. The plasmid failed to increase the transformability of the Rec-1 and Rec-2 mutants, indicating that the mutations producing the Com-78 and Com-101 phenotypes are distinct from those giving rise to the Rec-1 and Rec-2 phenotypes. The physical mapping of the cloned fragment on the H. influenzae chromosome was found to be consistent with the genetic mapping of the Com-101 trait. A 2.8-kb EcoRI-BglII subfragment, representing one end of the 13.3-kb clone, was found to increase the transformation frequency of the Com-78 and Com-101 mutants when supplied in trans, indicating that the subfragment carries one or more loci required for chromosomal transformation. The corresponding region of the Com-101 chromosome was determined by hybridization analysis to contain a 0.3-kb insertion, suggesting that the Com-101 strain may contain an insertion mutation at this locus. A 3.0-kb EcoRI-MluI subfragment, representing the other end of the 13.3-kb EcoRI fragment, was found to increase the transformation frequency of the Com-101 mutant but not of the Com-78 mutant, suggesting that the Com-101 phenotype results from a complex genotype involving mutations at two or more transformation-related loci. This conclusion is consistent with data indicating that the Com-101 trait can be genetically separated into at least two components.

Modular structure of FixJ: homology of the transcriptional activator domain with the -35 binding domain of sigma factors

The FixL/FixJ two-component system is a global regulator of nitrogen-fixation genes in Rhizobium meliloti. The transcriptional activator FixJ contains two modules: its N-terminal module is homologous with other two-component regulators; its C-terminal module shows homology with various transcriptional activators, and with the C-terminal region of sigma factors, which is involved in the discrimination of the -35 region of bacterial promoters. We show that the C-terminal module of FixJ contains the entire transcription activation function, and that the N-terminal module regulates this activity negatively. Oligonucleotide-directed mutagenesis of the transcriptional activator module demonstrated the importance of a potential helix-turn-helix structure.

DegS-DegU and ComP-ComA modulator-effector pairs control expression of the Bacillus subtilis pleiotropic regulatory gene degQ

Production of a class of both secreted and intracellular degradative enzymes in Bacillus subtilis is regulated at the transcriptional level by a signal transduction pathway which includes the DegS-DegU two-component system and at least two additional regulatory genes, degQ and degR, encoding polypeptides of 46 and 60 amino acids, respectively. Expression of degQ was shown to be controlled by DegS-DegU. This expression is decreased in the presence of glucose and increased under any of the following conditions: growth with poor carbon sources, amino acid deprivation, phosphate starvation, and growth in the presence of decoyinine, a specific inhibitor of GMP synthetase. In addition, expression of degQ is shown to be positively regulated by the ComP-ComA two-component system. Separate targets for regulation of degQ gene expression by DegS-DegU and ComP-ComA were located by deletion analysis between positions -393 and -186 and between positions -78 and -40, respectively. Regulation of degQ expression by amino acid deprivation was shown to be dependent upon ComA. Regulation by phosphate starvation, catabolite repression, and decoyinine was independent of the two-component systems and shown to involve sequences downstream from position -78. The ComP-ComA and DegS-DegU two-component systems seem to be closely related, sharing several target genes in common, such as late competence genes, as well as the degQ regulatory gene. Sequence analysis of the degQ region revealed the beginning of an open reading frame directly downstream from degQ. Disruption of this gene, designated comQ, suggests that it also controls expression of degQ and is required for development of genetic competence.

srfA is an operon required for surfactin production, competence development, and efficient sporulation in Bacillus subtilis

The srfA locus of Bacillus subtilis is defined by a transposon Tn917 insertion and is required for production of the peptide secondary metabolite surfactin. The srfA locus was isolated by cloning the DNA flanking srfA::Tn917 insertions followed by chromosome walking. The cloned region is an operon of over 25 kb which covers the transcription initiation region but not the intact 3' end of srfA. csh-293, which was previously identified as a Tn917lac mutation that impairs competence development and causes a conditional defect in sporulation, was known to be located in the vicinity of the srfA locus within the B. subtilis genome. The csh-293::Tn917lac mutation was discovered to cause a defect in surfactin production and was shown to be located in the srfA operon by its cotransformation with srfA mutations and by Southern hybridization analysis. Insertion mutations in srfA, created by the chromosomal integration of plasmids bearing overlapping srfA DNA fragments, were examined for their effects on surfactin production, competence, and sporulation. All three processes were found to require the intact 5' half of the srfA operon, whereas the 3' half of srfA was found to be required for sporulation and surfactin production but not competence. These experiments show that srfA gene products function in B. subtilis cell specialization and differentiation.

The regulation of genetic competence in Bacillus subtilis

Genetic competence develops as a global response of Bacillus subtilis to the onset of stationary phase, in glucose-minimal salts-based media. The onset of competence is accompanied by the expression of several late gene products that are required for the binding, processing and uptake of transforming DNA. A number of regulatory genes have been identified that are needed for the appropriate synthesis of the late gene products. The regulatory gene products include a number of known transcription factors, as well as several members of the bacterial two-component regulatory system. Genetic analysis has suggested a scheme for the flow of regulatory information signalling the onset of competence. Most of these regulatory products appear to be involved in the response to nutritional status, while the components responsible for growth stage and cell-type-specific control remain unknown. The general implications of this scheme for post-exponential expression are discussed.

Transcriptional regulation of comC: evidence for a competence-specific transcription factor in Bacillus subtilis

comC specifies a protein product that is required for genetic competence in Bacillus subtilis. The probable transcriptional start site of comC has been localized by high-resolution primer extension analysis and shown to be preceded by an appropriately positioned sequence that resembles the consensus promoter for the sigma A form of RNA polymerase. Low-resolution S1 nuclease transcription mapping was used to identify the comC terminator, which is located near a palindromic element recognizable in the DNA sequence. Deletion analysis of the sequence upstream from the likely promoter identified a region required in cis for the expression of comC. An overlapping, and possibly identical, sequence was shown to inhibit the expression of competence and of several late competence genes, when present in multiple copies. This was interpreted as due to the titration of a positively acting competence transcription factor (CTF) by multiple copies of the promoter-bearing fragment. In crude lysates of B. subtilis grown to competence, a DNA-binding activity that appeared to be specific for the comC promoter fragment was detected by gel retardation assays. This activity, postulated to be due to CTF, was detected only following growth in competence medium, only in the stationary phase of growth, and was dependent on the expression of ComA, a known competence-regulatory factor. In the presence of the mecA42 mutation, the ComA requirement for CTF activity was bypassed, and CTF activity could be detected in lysates prepared from a strain grown in complex medium. This behavior suggested that either the expression or the activation of CTF was regulated in a competence-specific manner. Comparison of the putative CTF-binding site defined by deletion analysis with a similarly positioned sequence upstream from the start site of the late competence gene comG revealed that both sequences contained palindromes, with 5 of 6 identical base pairs in each arm. It is suggested that these palindromic sequences comprise recognition elements for CTF binding and that CTF binding must occur for the appropriate expression of late competence genes.

Growth medium-independent genetic competence mutants of Bacillus subtilis

The development of competence in Bacillus subtilis is normally dependent on the growth medium. Expression of late competence genes occurs in glucose-minimal salts-based media but not in complex media. Expression is also inhibited when glutamine is added to competence medium and when glycerol is substituted for glucose. Mutations have been identified in two regulatory loci, mecA and mecB, which render competence development independent of these variables. Although in mec mutants the expression of late competence genes, as well as of competence itself, occurred in all media tested, this expression was still growth stage regulated. Thus at least some forms of medium-dependent and growth stage-specific regulation are genetically separable. One of the mecB mutations (mecB31) conferred oligosporogenicity. The mecB mutations were tightly linked by transformation to rif, lpm, and std markers and were located between rif-2103 and cysA14. The mecA42 mutant was linked by transduction to argC4.

Suppression of early competence mutations in Bacillus subtilis by mec mutations

Although competence normally develops only in glucose-minimal salts media, mecA and mecB mutations permit the expression of competence and of late competence genes in complex media as well (D. Dubnau and M. Roggiani, J. Bacteriol. 172:4048-4055, 1990). The expression of late competence genes is dependent on the products of the regulatory genes comA, comB, comP, sin, abrB, spo0H, and spo0A. We show here that this list must be extended to include degU, csh-293, and spo0K. mecA and -B mutations bypass most of these requirements, making the expression of late competence genes and of competence itself independent of all of these regulatory genes, with the exceptions of spo0A and spo0K (in the case of mecB). The expression of late competence genes in mec mutants that are deficient for each of the bypassed regulatory functions is still under growth stage-specific regulation. The implications of these findings are discussed, and a provisional scheme for the flow of information during the development of competence is proposed.

A Bacillus subtilis regulatory gene product for genetic competence and sporulation resembles sensor protein members of the bacterial two-component signal-transduction systems

A Bacillus subtilis gene, required for genetic competence, was identified immediately upstream from the previously characterized gene comA. The comA gene product has been found to exhibit amino acid sequence similarity to the so-called effector class of signal-transduction proteins. DNA sequencing of the new determinant, named comP, revealed that the carboxy-terminal domain of the predicted ComP protein is similar in amino acid sequence to that of several sensor members of the bacterial two-component signal-transduction systems. The predicted amino-terminal domain contains several hydrophobic segments, postulated to be membrane-spanning. In vitro-derived comP disruptions are epistatic on the expression of all late competence genes tested, including comG, comC, comD, and comE, but not on expression of the early gene comB. Although comA has its own promoter, some transcription of comA, especially later in growth, occurs via readthrough from comP sequences. A roughly twofold epistatic effect of a comP disruption was noted on the downstream comA determinant, possibly due to interruption of readthrough transcription from comP to comA. Overexpression of comA fully restored competence to a comP mutant, providing evidence that ComA acts after ComP, and consistent with a role for the latter protein in activation of the former, possibly by phosphorylation. ComP probably is involved in transmitting information concerning the nutritional status of the medium, particularly the presence of nitrogen- and carbon-containing nutrients. ComP was also shown to play a role in sporulation, at least partly interchangeable with that of SpoIIJ, another putative sensor protein.

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.

Molecular cloning and characterization of comC, a late competence gene of Bacillus subtilis

comC is a Bacillus subtilis gene required for the development of genetic competence. We have cloned a fragment from the B. subtilis chromosome that carries comC and contains all the information required to complement a Tn917lac insertion in comC. Genetic tests further localized comC to a 2.0-kilobase HindIII fragment. Northern (RNA) blotting experiments revealed that an 800-base-pair comC-specific transcript appeared at the time of transition from exponential to stationary phase during growth through the competence regimen. The DNA sequence of the comC region revealed two open reading frames (ORFs), transcribed in the same direction. The upstream ORF encoded a protein with apparent sequence similarity to the folC gene of Escherichia coli. Insertion of a chloramphenicol resistance determinant into this ORF and integration of the disrupted construct into the bacterial chromosome by replacement did not result in competence deficiency. The downstream ORF, which contained the Tn917lac insertion that resulted in a lack of competence, is therefore the comC gene. The predicted protein product of comC consisted of 248 amino acid residues and was quite hydrophobic. The comC gene product was not required for the expression of any other com genes tested, and this fact, together with the marked hydrophobicity of ComC, suggests that it may be a component of the DNA-processing apparatus of competent cells.

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.

Cloning and characterization of the regulatory Bacillus subtilis competence genes comA and comB

comA and comB are Bacillus subtilis competence genes that are identified by insertions of Tn917lac. They are classified as early genes because of their expression throughout growth; the expression of late com genes increases sharply during the transition to the stationary phase. The comA and comB determinants were cloned, and the 5' and 3' termini of their transcripts were localized by low-resolution S1 nuclease protection experiments. comA and comB were found by Southern blotting to be localized near one another, but they were nevertheless apparently transcribed independently. Epistatic relationships among the com genes were explored by using the beta-galactosidase expressed from transcriptional fusions as a marker. Late com genes were found to be dependent on the products of comA, comB, and sin for their expression. The sin gene is a transcriptional regulator that is required for the development of competence (N. K. Gaur, E. Dubnau, and I. Smith, J. Bacteriol. 168:860-869, 1986).

Nucleotide sequence and genetic organization of the Bacillus subtilis comG operon

A series of Tn917lac insertions define the comG region of the Bacillus subtilis chromosome. comG mutants are deficient in competence and specifically in the binding of exogenous DNA. The genes included in the comG region are first expressed during the transition from the exponential to the stationary growth phase. From nucleotide sequence information, it was concluded that the comG locus contains seven open reading frames (ORFs), several of which overlap at their termini. High-resolution S1 nuclease mapping and primer extension were used to identify the 5' terminus of the comG mRNA. The sequence upstream from the comG start site closely resembled the consensus recognition sequence for the major B. subtilis vegetative RNA polymerase holoenzyme. Complementation analysis confirmed that the comG ORF1 protein is required for the ability of competent cultures to resolve into two populations with different cell densities on Renografin (E. R. Squibb & Sons, Princeton, N.J.) gradients, as well as for full expression of comE, another late competence locus. The predicted comG ORF1 protein showed significant similarity to the virB ORF11 protein from Agrobacterium tumefaciens, which is probably involved in T-DNA transfer. The N-terminal sequences of comG ORF3 and, to a lesser extent, the comG ORF4 and ORF5 proteins were similar to a class of pilin proteins from members of the genera Bacteroides, Pseudomonas, Neisseria, and Moraxella. All of the comG proteins except comG ORF1 possessed hydrophobic domains that were potentially capable of spanning the bacterial membrane. It is likely that these proteins are membrane associated, and they may comprise part of the DNA transport machinery. When present in multiple copies, a DNA fragment carrying the comG promoter was capable of inhibiting the development of competence as well as the expression of several late com genes, suggesting a role for a transcriptional activator in the expression of those genes.