Genetic aspects of bacterial endospore formation

Temporal regulation and forespore-specific expression of the spore photoproduct lyase gene by sigma-G RNA polymerase during Bacillus subtilis sporulation

Bacterial spores are highly resistant to killing by UV radiation and exhibit unique DNA photochemistry. UV irradiation of spore DNA results in formation of spore photoproduct (SP), the thymine dimer 5-thyminyl-5,6-dihydrothymine. Repair of SP occurs during germination of Bacillus subtilis spores by two distinct routes, either by the general nucleotide excision repair (uvr) pathway or by a novel SP-specific monomerization reaction mediated by the enzyme SP lyase, which is encoded by the spl gene. Repair of SP occurs early in spore germination and is independent of de novo protein synthesis, suggesting that the SP repair enzymes are synthesized during sporulation and are packaged in the dormant spore. To test this hypothesis, the expression of a translational spl-lacZ fusion integrated at the spl locus was monitored during B. subtilis growth and sporulation. beta-Galactosidase expression from the spl-lacZ fusion was silent during vegetative growth and was not DNA damage inducible, but it was activated at morphological stage III of sporulation specifically in the forespore compartment, coincident with activation of expression of the stage III marker enzyme glucose dehydrogenase. Expression of the spl-lacZ fusion was shown to be dependent upon the sporulation-specific RNA polymerase containing the sigma-G factor (E sigma G), as spl-lacZ expression was abolished in a mutant harboring a deletion in the sigG gene and restored by expression of the sigG gene in trans. Primer extension analysis of spl mRNA revealed a major extension product initiating upstream from a small open reading frame of unknown function which precedes spl, and it revealed two other shorter minor extension products. All three extension products were present in higher quantities during sporulation and after sigG induction. The three putative transcripts are all preceded by sequences which share homology with the consensus sigma-G factor-type promoter sequence, but in vitro transcription by purified sigma-G RNA polymerase was detected only from the promoter corresponding to the major extension product. The open reading frame-spl operon therefore appears to be an additional member of the sigma-G regulon, which also includes as members the small, acid-soluble spore proteins which are in large part responsible for spore DNA photochemistry. Therefore, sporulating bacteria appear to coordinately regulate genes whose products not only alter spore DNA photochemistry but also repair the major spore-specific photoproduct during germination

Expression of the crystal protein gene under the control of the alpha-amylase promoter in Bacillus thuringiensis strains

The expression of an insecticidal crystal protein gene of Bacillus thuringiensis under the control of the alpha-amylase gene promoter was investigated. The cryIC gene, which encodes a protein known to have a unique activity against Spodoptera (armyworm) species, was used in this investigation. The cryIC gene was placed, along with the alpha-amylase promoter from B. subtilis, in a B. thuringiensis-derived cloning vector, generating a pair of recombinant plasmids, pSB744 and pSB745. The cloning vector that contains the minimal replicon of B. thuringiensis subsp. kurstaki HD73 is stably maintained in a variety of B. thuringiensis strains, as previously reported by Gamel and Piot (Gene 120:17-26, 1992). The present study confirmed that the recombinant plasmids are also stably maintained in B. thuringiensis subsp. kurstaki Cry-B and HD73 growing in media without selection pressure for at least 48 h. The cryIC gene on the recombinant plasmids were notably expressed at high levels in both recombinant strains. Expression of the introduced cryIC gene on the recombinant plasmid in B. thuringiensis subsp. kurstaki HD73 did not impair expression of the resident cryIA(c) gene. The CryIA(c) protein is known to have a high level of activity against loopers such as Trichoplusia ni (the cabbage looper). As a result of coexpression of the introduced cryIC gene and the resident cryIA(c) gene, recombinant strain HD73 acquired an additional insecticidal activity against Spodoptera exigua (the beet armyworm) whereas the original activity level against T. ni was maintained.

The dacF-spoIIA operon of Bacillus subtilis, encoding sigma F, is autoregulated

The spoIIA operon of Bacillus subtilis encodes sigma F and two proteins that may regulate sigma factor activity. High level induction of the tricistronic spoIIA operon occurs early during spore formation. At later times, the locus is cotranscribed with the upstream gene dacF, which encodes a putative DD-carboxypeptidase. In this study, the regulation of dacF-spoIIA transcription has been analyzed. Expression of a dacF-lacZ transcriptional fusion during sporulation required sigma F but not the later-expressed sporulation-associated sigma factors. Induction of sigma F synthesis during vegetative growth caused expression of dacF-lacZ fusions. The dacF-spoIIA promoter sequence is similar to sequences of previously identified sigma F promoters. It is concluded that dacF-spoIIA is transcribed by E sigma F. We present evidence that dacF-spoIIA is also transcribed by E sigma G, as is the case for the three other promoters known to be transcribed by E sigma F.

Analysis by fluorescence microscopy of the development of compartment-specific gene expression during sporulation of Bacillus subtilis

The use of a fluorogenic substrate, 5-octanoylaminofluorescein-di-beta-D-galactopyranoside, for beta-galactosidase has made it possible to visualize enzyme activity in individual cells of sporulating populations of Bacillus subtilis by fluorescence microscopy. lacZ fusions to different sporulation-associated genes have been used to investigate the cell compartmentalization of gene expression during sporulation. A strain with a lacZ fusion to sspA, a gene which is transcribed by E-sigma G at a late stage of sporulation, displayed predominantly compartment-specific fluorescence. Expression of the early-expressed spoIIA locus, which includes the structural gene for sigma F, was seen not to be compartmentalized. Populations of strains with lacZ fusions to gpr and dacF, genes which are transcribed by E-sigma F at intermediate stages of sporulation, included some organisms showing uncompartmentalized fluorescence and others showing compartment-specific fluorescence; the proportion showing compartment-specific fluorescence increased in samples taken later in sporulation. Several possible explanations of the results obtained with gpr and dacF are considered. A plausible interpretation is that sigma F activity is initially not compartmentalized and becomes compartmentalized as sporulation progresses. The progression to compartmentalization does not require the activities of the sporulation-specific factor sigma E or sigma G but may require some product of sigma F activity.

Sigma factors, asymmetry, and the determination of cell fate in Bacillus subtilis

Soon after the initiation of sporulation, Bacillus subtilis divides asymmetrically to produce sister cells that have very different developmental fates. Recently, it has been proposed that the differential gene expression which begins soon after this division is due to cell-specific activation of the transcription factors sigma F and sigma E in the prespore and the mother cell, respectively. We describe the use of a method for the localization of gene expression in individual sporulating cells that lends strong support to the cell-specific localization of sigma F and sigma E activities. The dependence of sigma E activity on integrity of the gene encoding sigma F has led to the suggestion that activation of sigma F in the prespore leads to a directional signal that triggers activation of sigma E only in the mother cell. Here we show that sigma E actually specifies the fate of the mother cell; in the absence of sigma E, two prespore-like cells are made. The appearance of sigma F activity at both poles of a sigma E-deficient mutant supports the idea that sigma F normally remains latent in the mother cell and that its activation depends on some morphological or physiological feature of the prespore. We present a model for the generation of asymmetry and the establishment of cell fate in B. subtilis.

Bacillus subtilis SpoIIIE protein required for DNA segregation during asymmetric cell division

Sporulation in Bacillus subtilis begins with an asymmetric cell division, producing a smaller prespore and a larger mother cell, both of which contain intact copies of the chromosome. The spoIIIE gene is required for chromosome segregation into the prespore compartment. The effects of the spoIIIE36 mutation on sigma F-dependent transcription are an indirect consequence of the failure of certain genes to enter the cellular compartment in which their transcription factor has become active. SpoIIIE may also be required to prevent sigma F from becoming active in the mother cell.

An adenosine nucleotide switch controlling the activity of a cell type-specific transcription factor in B. subtilis

The sigma F factor establishes cell type-specific gene transcription during sporulation in B. subtilis. sigma F is negatively regulated by SpollAB, which forms complexes with sigma F or SpollAA. ATP and its nonhydrolyzable analogs stimulate the formation of the SpollAB.sigma F complex, whereas ADP stimulates the formation of the SpollAB.SpollAA complex. Which protein SpollAB associates with is determined by the concentrations of the two nucleotides, on which basis we propose a partner-switching model for the regulation of sigma F: [formula: see text] Consistent with this model, SpollAA reverses SpollAB-mediated inhibition of sigma F-directed transcription in a manner that depends on ADP. Cell-specific activation of sigma F could be due to an alteration in adenosine nucleotide levels in one cell of the sporangium.

Cloning and characterization of spoVR, a gene from Bacillus subtilis involved in spore cortex formation

Screening for sigma E-dependent promoters led to the isolation of a gene from Bacillus subtilis, designated spoVR, which appears to be involved in spore cortex formation. Cultures of strains carrying mutations in spoVR had an increased proportion of phase-dark spores, which correlated with an increased proportion of cortexless spores seen by electron microscopy. The numbers of heat- and chloroform-resistant phase-bright spores produced by these mutants were decreased by about 3- to 10-fold, and accumulation of dipicolinate was decreased by more than 3-fold. The spoVR gene was located on the B. subtilis chromosome immediately upstream from, and in the opposite orientation of, the phoAIV gene. Expression of spoVR was initiated at the second hour of sporulation from a sigma E-dependent promoter, and this expression did not require any of the other known mother-cell-specific transcriptional regulators. The spoVR gene was predicted to encode a product of 468 residues.

Regulation of sigma D expression and activity by spo0, abrB, and sin gene products in Bacillus subtilis

Expression of sigma D protein and of the hag gene, which is transcribed by the sigma D holoenzyme, is not dependent on spo0, abrB, or sin gene products in Bacillus subtilis. Preliminary results, however, suggest that a signal mediated by the spo0K locus may be responsible for the inhibition of sigma D activity during the stationary phase.

Subcellular localization of proteins involved in the assembly of the spore coat of Bacillus subtilis

Spores of the bacterium Bacillus subtilis are encased in a two-layered protein shell, which consists of an electron-translucent, lamellar inner coat, and an electron-dense outer coat. The coat protein CotE is both a structural component of the coat and a morphogenetic protein that is required for the assembly of the outer coat. We now show that CotE is located in the outer coat of the mature spore and that at an intermediate stage of sporulation, when the developing spore (the forespore) is present as a free protoplast within the sporangium, CotE is localized in a ring that surrounds the forespore but is separated from it by a small gap. We propose that the ring is the site of assembly of the outer coat and that the gap is the site of formation of the inner coat. Assembly of the ring depends on the sporulation protein SpoIVA, which sits close to or on the surface of the outer membrane that encircles the forespore. We propose that SpoIVA creates a basement layer around the forespore on which coat assembly takes place. The subcellular localization and assembly of CotE and other coat proteins are therefore determined by the capacity of SpoIVA to recognize and adhere to a specific surface within the sporangium, the outer membrane of the forespore.

Cloning and sequencing of the cell division gene pbpB, which encodes penicillin-binding protein 2B in Bacillus subtilis

The pbpB gene, which encodes penicillin-binding protein (PBP) 2B of Bacillus subtilis, has been cloned, sequenced, mapped, and mutagenized. The sequence of PBP 2B places it among the class B high-molecular-weight PBPs. It appears to contain three functional domains: an N-terminal domain homologous to the corresponding domain of other class B PBPs, a penicillin-binding domain, and a lengthy carboxy extension. The PBP has a noncleaved signal sequence at its N terminus that presumably serves as its anchor in the cell membrane. Previous studies led to the hypothesis that PBP 2B is required for both vegetative cell division and sporulation septation. Its sequence, map site, and mutant phenotype support this hypothesis. PBP 2B is homologous to PBP 3, the cell division protein encoded by pbpB of Escherichia coli. Moreover, both pbpB genes are located in the same relative position within a cluster of cell division and cell wall genes on their respective chromosomes. However, immediately adjacent to the B. subtilis pbpB gene is spoVD, which appears to be a sporulation-specific homolog of pbpB. Inactivation of SpoVD blocked synthesis of the cortical peptidoglycan in the spore, whereas carboxy truncation of PBP 2B caused cells to grow as filaments. Thus, it appears that a gene duplication has occurred in B. subtilis and that one PBP has evolved to serve a common role in septation during both vegetative growth and sporulation, whereas the other PBP serves a specialized role in sporulation.

Characterization of a new sporulation factor in Bacillus subtilis

We report the existence and partial purification of sporulation factor, which stimulates sporulation of Bacillus subtilis at low cell density. Proline or arginine is required for stimulation under the conditions of our assay. Sporulation factor is a small heat-stable substance produced by the cells during exponential growth phase. It is required in small amounts and is resistant to various proteolytic agents. Several spo mutants were tested for the ability to produce functional sporulation factor. All of these mutants produce factor and do not sporulate in the presence of factor from wild-type cells. Sporulation factor is not involved in the induction of alpha-amylase synthesis at the initiation of sporulation.

Phosphorylation of Spo0A activates its stimulation of in vitro transcription from the Bacillus subtilis spoIIG operon

The spoIIG operon of Bacillus subtilis codes for a sporulation-specific sigma factor, sigma E. In vivo expression of the spoIIG promoter is activated shortly after the onset of sporulation and is dependent on kinA, spo0F, spo0B and spo0A genes. The products of these genes have been shown to participate in a phosphorelay reaction in vitro, culminating in phosphorylation of the transcription factor, Spo0A. The effect of Spo0A phosphorylation on in vitro transcription from the spoIIG promoter was determined. Aliquots from phosphorelay reactions enhanced spoIIG promoter activity 10-fold in transcription assays and stimulation of transcription was dependent on Spo0A phosphorylation. Our results provide biochemical evidence that Spo0A and the phosphorelay form a signal transduction pathway which activates spoII gene expression in development.

Bacillus subtilis spoVE gene is transcribed by sigma E-associated RNA polymerase

Expression of the Bacillus subtilis sporulation gene spoVE was examined by runoff transcription assay with an RNA polymerase preparation obtained from vegetative and sporulating cells. Transcripts from tandem promoters (P1 and P2 promoters) located just upstream of the spoVE structure gene were detected. The transcription of spoVE initiated within an hour after the onset of sporulation and coincided with the presence of RNA polymerase associated with a 33-kDa protein. Amino acid sequence analysis of the 33-kDa protein revealed that it is a sigma factor, sigma E. Reconstitution analysis of sigma E purified from the sporulating cell extracts and vegetative core RNA polymerase showed that sigma E recognizes the P2 promoter. SpoVE protein could not be synthesized in the transcription-translation coupled system prepared from vegetative cells (M. Okamoto, S. Fukui, and Y. Kobayashi, Agric. Biol. Chem. 49:1077-1082, 1985). However, addition of sigma E-associated RNA polymerase to the coupled system restored SpoVE protein synthesis. These results indicate that spoVE expression in sporulating cells is controlled essentially by sigma E-associated RNA polymerase.

In vivo expression of the Bacillus subtilis spoVE gene

In vivo expression of the Bacillus subtilis spoVE gene was studied by S1 nuclease mapping and spoVE gene fusion analysis. Transcription of spoVE is induced at about the second hour of sporulation from two closely spaced promoters designated P1 and P2. Examination of the precise transcription initiation site by high-resolution primer extension mapping indicated that the nucleotide sequences of the -10 and -35 regions of both P1 and P2 were similar to those of promoters recognized by E sigma E. Moreover, S1 nuclease mapping and translational spoVE-lacZ fusion studies with various spo mutants suggest that the expression of spoVE P2 requires the spoIIG gene product, sigma E. The sporulation of a wild-type strain was inhibited severely in the presence of a multicopy plasmid, pKBVE, carrying the spoVE promoter, indicating the possible titration of a transcriptional regulatory element(s).

Evidence that the spoIIM gene of Bacillus subtilis is transcribed by RNA polymerase associated with sigma E

We have investigated the temporal and spatial regulation of spoIIM, a gene of Bacillus subtilis whose product is required for complete septum migration and engulfment of the forespore compartment during sporulation. The spoIIM promoter was found to become active about 2 h after the initiation of sporulation. The effects of mutations on the expression of a spoIIM-lacZ fusion were most consistent with its utilization by sigma-E-associated RNA polymerase (E sigma E). A unique 5' end of the in vivo spoIIM transcript was detected by primer extension analysis and was determined to initiate at the appropriate distance from a sequence conforming very closely to the consensus for genes transcribed by E sigma E. A partially purified preparation of E sigma E produced a transcript in vitro that initiated at the same nucleotide as the primer extension product generated from in vivo RNA. Ectopic induction of sigma E synthesis during growth resulted in the immediate and strong expression of a spoIIM-lacZ fusion, but an identical fusion was completely unresponsive to induced synthesis of either sigma F or sigma G under similar conditions. The results of plasmid integration-excision experiments in which the spoIIM gene was reversibly disrupted by a temperature-sensitive integrational vector suggested that spoIIM expression is required in the forespore compartment, but direct examination of subcellular fractions enriched for mother cell or forespore material indicated that spoIIM expression cannot be confined to the forespore. We conclude that spoIIM is a member of the sigma E regulon and that it may be transcribed exclusively by E sigma E. We discuss the implications of this conclusion for models in which activation of sigma E in the mother cell is proposed to be a part of the mechanism responsible for initiating separate programs of gene activity in the two sporangium compartments.

Physical and functional characterization of the Bacillus subtilis spoIIM gene

The spoIIM locus of Bacillus subtilis is the most recently discovered of six genetic loci in which mutations can prevent the synthesis of a normal asymmetric septum or prevent migration of the septal structure to engulf the forespore compartment of the sporangium. Ultrastructure studies of a spoIIM mutant confirmed a block prior to the completion of engulfment. Introduction of a spoIIM mutation into a panel of strains containing lacZ fusions belonging to different regulatory classes allowed us to determine that the spoIIM gene product is required for the efficient expression of genes transcribed by sigma G-associated RNA polymerase but is not required for the expression of sigma F-controlled genes, including spoIIIG, which encodes sigma G. The results of complementation studies, gene disruption analysis, and DNA sequencing revealed that the spoIIM locus contains a single sporulation-essential gene encoding a polypeptide with a predicted molecular mass of 24,850 Da. The predicted spoIIM gene product is highly hydrophobic and very basic, and it does not exhibit significant homology to sequence files in several major data bases.

SpoIIAB is an anti-sigma factor that binds to and inhibits transcription by regulatory protein sigma F from Bacillus subtilis

The sigma F factor is a regulatory protein that is responsible for directing gene expression in the forespore compartment of developing cells of the spore-forming soil bacterium Bacillus subtilis. The sigma F factor is encoded by the promoter-distal member of sporulation operon spoIIA, which consists of cistrons called spoIIAA, spoIIAB, and spoIIAC. Genetic evidence indicates that the activity of sigma F is negatively regulated by the product (SpoIIAB) of the spoIIAB cistron. We now report that SpoIIAB is capable of binding to sigma F and inhibiting its capacity to direct transcription by core RNA polymerase from the promoter for a forespore-expressed gene. SpoIIAB is an anti-sigma factor that may be directly involved in the compartmentalization of sigma F-directed gene expression.

Cloning and characterization of a gene required for assembly of the Bacillus subtilis spore coat

During endospore formation in Bacillus subtilis, approximately a dozen proteins are synthesized and assembled around the prespore to form a protective coat. Little is known about the assembly process, but several of the genes encoding these coat proteins are expressed in the mother cell compartment, where the proteins accumulate on the outer side of the developing endospore. Transcription of these genes is directed by the mother cell-specific sigma factor, sigma K, during the later stages of endospore development. sigma E may direct expression of the genes that encode proteins that function in the earliest stages of coat assembly. By screening for sigma E-dependent promoters, we cloned a gene, designated spoVID, required for assembly of a normal spore coat. Expression of spoVID was initiated at about the second hour of sporulation and continued throughout development from a sigma E-dependent promoter. The spoVID gene was located on the B. subtilis chromosome just downstream of the previously characterized hemAXCDBL operon and is predicted to encode an extremely acidic protein with 575 residues. Insertion mutants of spoVID produced refractile spores that were resistant to heat and to chloroform but were sensitive to lysozyme. Electron microscopic examination of sporulating spoVID mutant cells revealed normal morphological development up to about the third hour of sporulation. However, during the later stages of development the coat proteins assembled into aberrant structures that occurred freely in the mother cell cytoplasm and that consisted of reiterations of the single inner and outer layers that normally make up the spore coat.

Bacillus subtilis sporulation: regulation of gene expression and control of morphogenesis

Bacillus subtilis sporulation is an adaptive response to nutritional stress and involves the differential development of two cells. In the last 10 years or so, virtually all of the regulatory genes controlling sporulation, and many genes directing the structural and morphological changes that accompany sporulation, have been cloned and characterized. This review describes our current knowledge of the program of gene expression during sporulation and summarizes what is known about the functions of the genes that determine the specialized biochemical and morphological properties of sporulating cells. Most steps in the genetic program are controlled by transcription factors that have been characterized in vitro. Two sporulation-specific sigma factors, sigma E and sigma F, appear to segregate at septation, effectively determining the differential development of the mother cell and prespore. Later, each sigma is replaced by a second cell-specific sigma factor, sigma K in the mother cell and sigma G in the prespore. The synthesis of each sigma factor is tightly regulated at both the transcriptional and posttranslational levels. Usually this regulation involves an intercellular interaction that coordinates the developmental programmes of the two cells. At least two other transcription factors fine tune the timing and levels of expression of genes in the sigma E and sigma K regulons. The controlled synthesis of the sigma factors and other transcription factors leads to a spatially and temporally ordered program of gene expression. The gene products made during each successive stage of sporulation help to bring about a sequence of gross morphological changes and biochemical adaptations. The formation of the asymmetric spore septum, engulfment of the prespore by the mother cell, and formation of the spore core, cortex, and coat are described. The importance of these structures in the development of the resistance, dormancy, and germination properties of the spore is assessed.

Sporulation gene spoIIB from Bacillus subtilis

We have cloned and characterized the sporulation gene spoIIB from Bacillus subtilis. In extension of previous nucleotide sequence analysis, our results show that the order of genes in the vicinity of spoIIB is valS folC comC spoIIB orfA orfB mreB mreC mreD minC minD spoIVFA spoIVFB L20 orfX L24 spoOB obg pheB pheA. All 20 genes have the same orientation; the direction of transcription is from valS to pheA. We show that spoIIB is a 332-codon-long open reading frame whose transcription is under sporulation control. The deduced amino acid sequence of the spoIIB gene product, a 36-kDa polypeptide, is highly charged and contains a stretch of uncharged amino acids that could correspond to a transmembrane segment. Surprisingly, mutations in spoIIB, including an in vitro-constructed null mutation, cause only a mild impairment of spore formation in certain otherwise wild-type bacteria. However, when combined with mutations in another sporulation gene, spoVG, mutations in spoIIB cause a severe block in spore formation at the stage (stage II) of septum formation. (As with spoIIB mutations, mutations in spoVG cause little impairment in sporulation on their own.) The nature of the spoIIB spoVG mutant phenotype is discussed in terms of the events involved in the maturation of the sporulation septum and in the activation of sporulation transcription factors sigma F and sigma E.

Properties of purified sporlets produced by spoII mutants of Bacillus subtilis

A number of abortively disporic spoII mutants of Bacillus subtilis released their forespore compartments (termed stage II sporlets) after mother cell lysis during sporulation in nutrient exhaustion or resuspension media. Stage II sporlets were viable and contained levels of ATP and a number of enzymes similar to those in cells 2 to 3 h after sporulation. However, stage II sporlets carried out essentially no macromolecular synthesis, a result suggesting that they were in a quiescent state. The nucleoid of these quiescent stage II sporlets was significantly condensed relative to that in the original vegetative cells, as was previously found to take place 1 to 2 h after initiation of sporulation (B. Setlow, N. Magill, P. Febbroriello, L. Nakhimousky, D. E. Koppel, and P. Setlow, J. Bacteriol. 173:6270-6278, 1991). Stage II sporlets may be a useful model system for analysis of forespore properties early in stage II of sporulation.

Coupling between gene expression and DNA synthesis early during development in Bacillus subtilis

Endospore formation in the bacterium Bacillus subtilis involves generation of two cell types, each with different developmental fates. Each cell type contains an active chromosome, and treatments that inhibit DNA synthesis at the beginning of development inhibit spore formation. We describe experiments demonstrating that gene expression early during sporulation is coupled to DNA synthesis. Expression of several genes that are induced early during sporulation, before the formation of two cell types, is inhibited when DNA synthesis is inhibited. Genes that are affected require the transcription factor encoded by spo0A for normal induction. Spo0A protein is normally activated early in development by a multicomponent phosphorylation pathway, or phospho-relay. Altered function mutations in spo0A that bypass the need for the phospho-relay allow early sporulation gene expression, even when DNA synthesis is inhibited. These results indicate that inhibition of DNA synthesis prevents activation of the Spo0A transcription factor by inhibiting a step in the phospho-relay. It seems likely that coupling early developmental gene expression to DNA synthesis is a general mechanism to prevent inappropriate or unnecessary gene expression.

Sin, a stage-specific repressor of cellular differentiation

Sin is a Bacillus subtilis DNA-binding protein which is essential for competence, motility, and autolysin production but also, if expressed on a multicopy plasmid, is inhibitory to sporulation and alkaline protease synthesis. We have now examined the physiological role of Sin in sporulation and found that this protein specifically represses three stage II sporulation genes (spoIIA, spoIIE, and spoIIG) but not the earlier-acting stage 0 sporulation genes. sin loss-of-function mutations cause higher expression of stage II genes and result in a higher frequency of sporulation, in general. Sin binds to the upstream promoter region of spoIIA in vitro and may thus gate entry into sporulation by directly repressing the transcription of stage II genes. In vivo levels of Sin increase rather than decrease at the time of stage II gene induction, suggesting that posttranslational modification may play a role in downregulation of negative Sin function.

Characterization of bofA, a gene involved in intercompartmental regulation of pro-sigma K processing during sporulation in Bacillus subtilis

Sporulating cells of the gram-positive bacterium Bacillus subtilis are partitioned into two cellular compartments called the mother cell and the forespore. Gene expression in the mother cell and the forespore is regulated differentially by the compartment-specific transcription factors sigma K and sigma G, respectively. Gene expression between the two compartments is also coordinated by a signal transduction pathway that couples the activation of sigma K (by processing of its inactive precursor pro-sigma K) in the mother cell to sigma G-directed gene expression in the forespore. To dissect the signal transduction pathway genetically, we previously isolated bypass of forespore mutations at loci called bofA and bofB that relieve the dependence of pro-sigma K processing on the action of sigma G. bofB mutations were previously shown to be allelic to the two-cistron sporulation operon spoIVF, which encodes the pro-sigma K-processing enzyme or its regulator. We now report that bofA mutations are located in a small open reading frame of 87 codons that encodes a putative integral membrane protein with three potential membrane-spanning domains. The possibility is discussed that BofA and the SpoIVF proteins form a heteromeric complex in the mother cell membrane that surrounds the forespore and that this complex mediates the intercompartmental coupling of pro-sigma K processing to events in the forespore.

Molecular cloning of a subtilisin J gene from Bacillus stearothermophilus and its expression in Bacillus subtilis

The structural gene for a subtilisin J from Bacillus stearothermophilus NCIMB10278 was cloned in Bacillus subtilis using pZ124 as a vector, and its nucleotide sequence was determined. The nucleotide sequence revealed only one large open reading frame, composed of 1,143 base pairs and 381 amino acid residues. A Shine-Dalgarno sequence was found 8 bp upstream from the translation start site (GTG). The deduced amino acid sequence revealed an N-terminal signal peptide and pro-peptide of 106 residues followed by the mature protein comprised of 275 residues. The productivity of subtilisin in the culture broth of the Bacillus subtilis was about 46-fold higher than that of the Bacillus stearothermophilus. The amino acid sequence of the extracellular alkaline protease subtilisin J is highly homologous to that of subtilisin E and it shows 69% identity with subtilisin Carlsberg, 89% with subtilisin BPN' and 70% with subtilisin DY. Some properties of the subtilisin J that had been purified from the Bacillus subtilis were examined. The subtilisin J has alkaline pH characteristics and a molecular weight of 27,500. It retains about 50% of its activity even after treatment at 60 degrees C for 30 min in the presence of 2 mM calcium chloride.

Crisscross regulation of cell-type-specific gene expression during development in B. subtilis

Sporulation in Bacillus subtilis is a model for how cells of one type generate other differentiated cell types. During sporulation two cellular compartments arise that differ from each other and from the progenitor cell. Differential gene expression between the two is governed by the successive appearance of four transcription factors whose activities are coordinated in crisscross fashion between the two cells.

Characterization of the Bacillus subtilis sporulation gene spoVK

The sporulation gene spoVK of Bacillus subtilis was cloned by use of the insertional mutation spoVK::Tn917 omega HU8. The spoVK gene was shown to be the site of an incorrectly mapped mutation called spoVJ517. Thus, a separate spoVJ gene as defined by the 517 mutation does not exist and is instead identical with spoVK.

Characterization of spoIVA, a sporulation gene involved in coat morphogenesis in Bacillus subtilis

We report the cloning and characterization of the Bacillus subtilis sporulation locus spoIVA, mutations at which cause an unusual defect in spore formation in which the coat misassembles as swirls within the mother cell. We show that spoIVA is a single gene of 492 codons that is capable of encoding a polypeptide of 55 kDa. Transcription of spoIVA is induced at about the second hour of sporulation by the regulatory protein sigma E from two closely spaced promoters designated P1 and P2. Experiments in which the upstream promoter P1 was removed show that transcription of spoIVA from P2 is sufficient for efficient spore formation. Based on these and other findings, we infer that the spoIVA gene product is a morphogenetic protein; we discuss its role in the deposition of coat polypeptides around the developing forespore.

Characterization of a sporulation gene, spoIVA, involved in spore coat morphogenesis in Bacillus subtilis

Mutations in the spoIVA locus of Bacillus subtilis abolish cortex synthesis and interfere with the synthesis and assembly of the spore coat. We have characterized the cloned spoIVA locus in terms of its physical structure and regulation during sporulation. The locus contains a single gene capable of encoding an acidic protein of 492 amino acids (molecular weight, 55,174). The gene is transcribed from a sigma E-dependent promoter soon after the formation of the spore septum. A genetic test indicated that expression of spoIVA is only necessary in the mother cell compartment for the formation of a mature spore. This, together with the phenotypic properties of spoIVA mutations, would be in accord with the hypothesis that sigma E is only active after septation and in the mother cell compartment.

Analysis of the upstream activating sequence and site of carbon and nitrogen source repression in the promoter of an early-induced sporulation gene of Bacillus subtilis

The transcription from the spoVG promoter of Bacillus subtilis is induced at the start of the stationary phase of growth and is dependent on the expression of the spoOA, spoOB, and spoOH genes. It is repressed in cells grown in the presence of excess glucose and glutamine and is under the negative control of the abrB gene. The spoOA and spoOB gene products function to suppress the negative control exerted by abrB. Transcription initiation requires the form of RNA polymerase holoenzyme that contains the spoOH gene product, sigma H. Optimal transcription also requires an upstream A-T-rich region termed the upstream activating sequence (UAS). The mechanism of UAS function was examined through mutational analysis of the spoVG promoter region. Deletion of the UAS or positioning the UAS one half turn or one full turn of the DNA helix upstream of its location in wild-type spoVG resulted in a severe reduction in promoter activity. Deletion of most of the UAS abolished the abrB-dependent repression of spoVG transcription. Higher activity was observed when the UAS was inserted 10 bp (one turn of the helix) upstream than when the sequence was repositioned either 5 or 13 bp upstream. Sequences upstream of the UAS were found not to be involved with the position-dependent function of the UAS. Positioning the UAS 42 or 116 bp upstream eliminated the stimulatory effect of the sequence on spoVG transcription. These data indicate that the UAS functions effectively when it is in close proximity to the -35 region. In vitro transcription analysis indicated that the deletion and insertion mutation affecting the UAS impair RNA polymerase-spoVG promoter interaction. Deletion of the UAS showed that the negative effect of exogenous glucose and glutamine is not dependent on the UAS but is exerted at a site within or near the -35 and -10 regions.

Cloning, characterization, and expression of the spoVB gene of Bacillus subtilis

Mutation of the spoVB gene in Bacillus subtilis causes the production of spores containing a defective cortex and unable to acquire heat resistance. The spoVB locus is highly linked to another spo locus, spoIIIF, characterized by a single mutation (I. L. Lamont and J. Mandelstam, J. Gen. Microbiol. 130:1253-1261, 1984). A 18-kb DNA region overlapping the spoIIIF-spoVB region was cloned in successive steps starting from a Tn917 insertion in the nic locus. The exact location of the spoIIIF and spoVB loci was defined with various integrative plasmids carrying subfragments of that region. DNA sequencing established that spoIIIF and spoVB are a single monocistronic locus encoding a 518-amino-acid polypeptide with features of an integral membrane protein. The precise location of the spoIIIF590 and spoVB91 mutations in that unique open reading frame was determined, and both mutations were sequenced. A null mutation was engineered in the spoIIIF-spoVB locus and led to a typical spoVB phenotype, identical to the phenotype created by either spoIIIF590 or spoVB91, suggesting that the original spoIIIF mutant contained a secondary mutation arresting sporulation at an earlier stage. A transcriptional spoVB-lacZ fusion was constructed, and its expression was found to be directly dependent on RNA polymerase containing sigma E. A null mutation of spoVB had no effect on expression of sspB and cotA, members of the sigma G- and sigma K-controlled regulons respectively, while expression of cotC, a member of the latest known mother cell regulon, was delayed and strongly reduced. These results are consistent with SpoVB being involved in cortex biosynthesis and affecting only indirectly expression of late sporulation genes.

Establishment of cell type by compartmentalized activation of a transcription factor

Early in the process of spore formation in Bacillus subtilis a septum is formed that partitions the sporangium into daughter cells called the forespore and the mother cell. The daughter cells each have their own chromosome but follow dissimilar programs of gene expression. Differential gene expression in the forespore is now shown to be established by the compartmentalized activity of the transcription factor sigma F. The sigma F factor is produced prior to septation, but is active only in the forespore compartment of the post-septation sporangium. The sigma F factor is controlled by the products of sporulation operons spoIIA and spoIIE, which may be responsible for confining its activity to one of the daughter cells.

Condensation of the forespore nucleoid early in sporulation of Bacillus species

Fluorescence microscopic examination coupled with digital videoimage analysis of 4',6-diamidino-2-phenylindole-stained sporulating cells of Bacillus megaterium or Bacillus subtilis revealed a striking condensation of the forespore nucleoid. While both mother cell and forespore compartments had equal amounts of DNA, the forespore nucleoid became greater than 2-fold more condensed than the mother cell nucleoid. The condensation of the forespore nucleoid began after only the first hour of sporulation, 2 to 3 h before expression of most forespore-specific genes including those for small, acid-soluble spore proteins, and was abolished in spo0 mutants but not in spoII or spoIII mutants. It is possible that this striking condensation of forespore DNA plays some role in modulating gene expression during sporulation.

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.

Suppression of defective-sporulation phenotypes by mutations in transcription factor genes of Bacillus subtilis

Mutations in the Bacillus subtilis major RNA polymerase sigma factor gene (rpoD/crsA47) and a sensory receiver gene (spoOA/rvtA11) are potent intergenic suppressors of several stage 0 sporulation mutations (spoOB, OE, OF & OK). We show here that these suppressors also rescue temperature-sensitive sporulation phenotypes (Spots) caused by mutations in RNA polymerase, ribosomal protein, and protein synthesis elongation factor EF-G genes. The effects of the crsA and rvtA suppressors on RNA polymerase and ribosomal protein spots mutations are similar to those previously described for mutations in another intergenic suppressor gene rev. We have examined the effects of rvtA and crsA mutations on the expression of sporulation-associated membrane proteins, including flagellin and penicillin binding protein 5* (PBP 5*). Both suppressors restored sporulation and synthesis of PBP 5* in several spoO mutants. However, only rvtA restored flagellin synthesis in spoO suppressed backgrounds. The membrane protein phenotypes resulting from the presence of crsA or rvtA suppressors in spoO strains suggests that these suppressors function via distinct molecular mechanisms. The rvtA and crsA mutations are also able to block the ability of ethanol to induce spoO phenocopies at concentrations of ethanol which prevent sporulation in wild type cells. The effects of ethanol on sporulation-associated membrane protein synthesis in wild type and suppressor containing strains have been examined.

Genetic regulation of morphogenesis in Bacillus subtilis: roles of sigma E and sigma F in prespore engulfment

Electron microscopic examination of sporulating cultures of wild-type Bacillus subtilis revealed that the morphological events previously characterized as stages II and III can be divided into four substages, namely, stages IIi, IIii, IIiii, and III. The ultrastructural phenotypes of several stage II mutant strains indicate that each of the four substages has a biochemical and genetic basis. Two of the genes needed for the transition from stage II to stage III encode transcription factors sigma E and sigma F. Their roles during spore morphogenesis have been the subject of much speculation. We now show that sigma E controls genes involved in the morphological transition from stage IIi to stage IIii and then stage IIiii, while the transition to stage III may be determined by genes controlled by sigma F. The results also indicate the existence of at least two undiscovered sporulation genes involved in B. subtilis spore morphogenesis.

A model for asymmetric septum formation during sporulation in Bacillus subtilis

Many differentiation processes in both prokaryotes and eukaryotes begin with an asymmetric division, producing 'daughter' cells that differ in size and developmental fate. This is particularly obvious in the well-studied prokaryotic life cycles of Caulobacter and Bacillus. In no system, however, is the mechanism of asymmetric division understood. Here I propose a model for the mechanism of asymmetric division during sporulation in Bacillus subtilis. The model explains both the timing and asymmetric localization of spore-septum formation. It also explains the morphological phenotypes of various asporogenous (spo) mutants.

Differential regulation of spo0A transcription in Bacillus subtilis: glucose represses promoter switching at the initiation of sporulation

We have shown by S1 nuclease mapping with in vivo transcripts that the differential expression of a sporulation-regulatory gene, spo0A, is regulated by switching of two discrete promoters during the initiation of sporulation in Bacillus subtilis; vegetative mRNA was transcribed from an upstream promoter (Pv, vegetative promoter), and sporulation-specific mRNA was transcribed from the other promoter (Ps, sporulation-specific promoter) about 150 bp downstream of the Pv promoter. Transcription from the Pv promoter was at a low level and shut off at T0.5. On the other hand, transcription from the Ps promoter was strongly induced at T0.5 and increased until T2.5. In the presence of 2% glucose, Pv-directed transcription was not shut off and was observed even at T1.5, whereas the induction of Ps-directed transcription was completely repressed. A mutant in which the spo0A gene was transcribed only from the Ps promoter could sporulate normally in the presence of 0.1% glucose but could not sporulate at all in the presence of 2% glucose. In a catabolite-resistant sporulation mutant carrying crsA47 (sigA47), a mutation within the gene encoding sigma A, normal promoter switching from Pv to Ps was observed in the presence of 2% glucose.

FtsZ in Bacillus subtilis is required for vegetative septation and for asymmetric septation during sporulation

A Bacillus subtilis strain was constructed in which the cell division gene, ftsZ, was placed under control of the isopropyl-beta-D-thiogalactoside (IPTG)-inducible spac promoter. This strain was dependent upon the presence of IPTG for cell division and colony formation indicating that ftsZ is an essential cell division gene in this organism. In sporulation medium this strain increased in mass and reached stationary phase in the presence or absence of IPTG, but only sporulated in the presence of IPTG. The expression of the sporulation genes spoIIG, spoIIA, and spoIIE occurred normally in the absence of IPTG as monitored by spo-lacZ fusions. However, expression of lacZ fusions to genes normally induced later in the developmental pathway, and that required processed pro-sigma E for expression, was inhibited. Immunoblot analysis revealed that pro-sigma E was not processed to its active form (sigma E) under these experimental conditions. Electron microscopy revealed that these FtsZ-depleted cells did not initiate asymmetric septation, suggesting that FtsZ has a common role in the initiation of both the vegetative and sporulation septa.

Forespore-specific transcription of a gene in the signal transduction pathway that governs Pro-sigma K processing in Bacillus subtilis

We present studies on the regulation of a developmental gene (spoIVB) whose product is required at a late stage of morphogenesis during the process of sporulation in Bacillus subtilis. Earlier work implicated the spoIVB gene product in a signal-transduction pathway that governs the conversion of pro-sigma K to the mature and active form of the mother cell sigma factor, sigma K, in response to a signal generated within the forespore chamber of the sporangium. We now show that (1) spoIVB is induced at the engulfment stage of sporulation, (2) this transcription is restricted to the forespore, and (3) spoIVB is under the direct control of the forespore sigma factor sigma G. The discovery that spoIVB is a forespore-expressed gene suggests that the spoIVB gene product, or a developmental event under its control, triggers the processing of pro-sigma K and thereby mediates the coupling of sigma K-directed gene expression in the mother cell to sigma G-directed gene expression in the forespore. We also show that spoIVB transcription is partially dependent on the action of the mother cell regulatory gene spoIIID, a finding that suggests that the transcription of certain forespore-expressed genes is influenced by events in the mother cell.

The spo0K locus of Bacillus subtilis is homologous to the oligopeptide permease locus and is required for sporulation and competence

Spore formation in Bacillus subtilis is a dramatic response to environmental signals that is controlled in part by a two-component regulatory system composed of a histidine protein kinase (SpoIIJ) and a transcriptional regulator (Spo0A). The spo0K locus plays an important but undefined role in the initiation of sporulation and in the development of genetic competence. spoIIJ spo0K double mutants had a more severe defect in sporulation than either single mutant. Overproduction of the spoIIJ gene product resulted in the suppression of the sporulation defect, but not the competence defect, caused by mutations in the spo0K locus. On the basis of the phenotype of the spoIIJ spo0K double mutant and the effect of overproduction of the spoIIJ gene product, a transposon insertion in the spo0K locus was isolated. The spo0K locus was cloned and sequenced. spo0K proved to be an operon of five genes that is homologous to the oligopeptide permease (opp) operon of Salmonella typhimurium and related to a large family of membrane transport systems. The requirement for the transport system encoded by spo0K in the development of competence was somewhat different than its requirement in the system encoded by spo0K in the development of competence was somewhat different than its requirement in the initiation of sporulation. Disruption of the last open reading frame in the spo0K operon caused a defect in competence but had little or no effect on sporulation. We hypothesize that the transport system encoded by spo0K may have a role in sensing extracellular peptide factors that we have shown are required for efficient sporulation and perhaps in sensing similar factors that may be necessary for genetic competence.

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.

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.

Control of developmental transcription factor sigma F by sporulation regulatory proteins SpoIIAA and SpoIIAB in Bacillus subtilis

The sporulation operon spoIIA of Bacillus subtilis consists of three cistrons called spoIIAA, spoIIAB, and spoIIAC. Little is known about the function of spoIIAA and spoIIAB, but spoIIAC encodes a sigma factor called sigma F, which is capable of directing the transcription in vitro of genes that are expressed in the forespore chamber of the developing sporangium. We now report that the products of the spoIIA operon constitute a regulatory system in which SpoIIAA is an antagonist of SpoIIAB (or otherwise counteracts the effect of SpoIIAB) and SpoIIAB is, in turn, an antagonist of SpoIIAC (sigma F). This conclusion is based on the observations that (i) overexpression of spoIIAB inhibits sigma F-directed gene expression, (ii) a mutation in spoIIAB stimulates sigma F-directed gene expression, (iii) a mutation in spoIIAA blocks sigma F-directed gene expression, and (iv) a mutation in spoIIAB relieves the block in sigma F-directed gene expression caused by a mutation in spoIIAA. The SpoIIAA/SpoIIAB/SpoIIAC regulatory system could play a role in controlling the timing of sigma F-directed gene expression and/or could be responsible for restricting sigma F-directed gene expression to the forespore chamber of the sporangium.

Similar organization of the sigB and spoIIA operons encoding alternate sigma factors of Bacillus subtilis RNA polymerase

Bacillus subtilis sigma-B is an alternate sigma factor implicated in controlling stationary-phase gene expression. We characterized the genetic organization and regulation of the region containing the sigma-B structural gene (sigB) to learn which metabolic signals and protein factors govern sigma-B function. sigB lay in an operon with four open reading frames (orfs) in the order orfV-orfW-sigB-orfX, and lacZ gene fusions showed that all four frames were translated in vivo. Experiments with primer extension, S1 nuclease mapping, and lacZ transcriptional fusions found that sigB operon transcription initiated early in stationary phase from a site 32 nucleotides upstream of orfV and terminated 34 nucleotides downstream of orfX. Fusion expression was abolished in a strain carrying an in-frame deletion in sigB, suggesting that sigma-B positively regulated its own synthesis, and deletions in the sigB promoter region showed that sequences identical to the sigma-B-dependent ctc promoter were essential for promoter activity. Fusion expression was greatly enhanced in a strain carrying an insertion mutation in orfX, suggesting that the 22-kilodalton (kDa) orfX product was a negative effector of sigma-B expression or activity. Notably, the genetic organization of the sigB operon was strikingly similar to that of the B. subtilis spoIIA operon, which has the gene order spoIIAA-spoIIAB-spoIIAC, with spoIIAC encoding the sporulation-essential sigma-F. The predicted sequence of the 12-kDa orfV product was 32% identical to that of the 13-kDa SpoIIAA protein, and the 18-kDa orfW product was 27% identical to the 16-kDa SpoIIAB protein. On the basis of this clear evolutionary conservation, we speculate these protein pairs regulate their respective sigma factors by a similar molecular mechanism and that the spoIIA and sigB operons might control divergent branches of stationary-phase gene expression.

Temporal regulation of the Bacillus subtilis early sporulation gene spo0F

The initiation of sporulation in Bacillus subtilis depends on seven genes of the spo0 class. One of these, spo0F, codes for a protein of 14,000 daltons. We studied the regulation of spo0F by using spo0F-lacZ translational fusions and also measured Spo0F protein levels by immunoassays. spo0F-lacZ and Spo0F levels increased as the cells entered the stationary phase, and this effect was repressed by glucose and glutamine. Decoyinine, which lowers GTP levels and allows sporulation in the presence of normally repressing levels of glucose, induced spo0F-lacZ expression and raised Spo0F levels. The expression of spo0F-lacZ was dependent on spo0A, -0B, -0E, -0F, and -0H genes, a spo0H deletion causing the strongest effect. In most respects, the spo0F gene was regulated in a manner similar to that of spoVG. However, the presence of an abrB mutation did not relieve the dependence of spo0F gene expression on spo0A, as it does with spoVG (P. Zuber and R. Losick, J. Bacteriol. 169:2223-2230, 1987).

Structural alterations in the Bacillus subtilis Spo0A regulatory protein which suppress mutations at several spo0 loci

Secondary site mutations that restore sporulation to sporulation-defective spo0F or spo0B deletion mutants were found to reside in the spo0A gene. Sequence analysis of 23 such sof mutants showed that the sof mutations fell into six classes of missense codon changes, primarily in the conserved amino-terminal domain of the response regulator Spo0A protein. Changes were observed in codons 12, 14, 60, 92, and 121. The residues affected were predominantly located in the potential turn regions at one end of the amino-terminal conserved domain on the same topological face as the active site aspartate residues. The ability of sof mutations to suppress deficiencies in the transmitter kinases, KinA and KinB, of two-component regulatory systems was tested. All of the sof mutations suppressed the sporulation deficiency of kinA mutants but only two classes among five tested suppressed kinB mutations. sof mutants segregated Spo- colonies at high frequency. Five of these Spo- mutants were found to result from mutations in the spo0A locus that reversed the effect of the sof mutatation. One of these was sequenced and found to have the original sof mutation and a new mutation, sos, at codon 105. The accumulation of sos mutations in sof strains suggested that the sof mutations have a subtle, yet deleterious, effect on the growth of the cell. The results suggested that the sof mutations increase the avidity for or reactivity with transmitter kinases in an allele-specific manner, although in some cases it is possible that the sof mutations obviate the need for phosphorylation to activate the Spo0A protein. An alternative hypothesis is presented in which the sof mutations play the role of bypass mutations for kinases.