Isolation and sequence of the spo0E gene: its role in initiation of sporulation in Bacillus subtilis

A conserved switch controls virulence, sporulation, and motility in C. difficile

Spore formation is required for environmental survival and transmission of the human enteropathogenic Clostridioides difficile. In all bacterial spore formers, sporulation is regulated through activation of the master response regulator, Spo0A. However, the factors and mechanisms that directly regulate C. difficile Spo0A activity are not defined. In the well-studied Bacillus species, Spo0A is directly inactivated by Spo0E, a small phosphatase. To understand Spo0E function in C. difficile, we created a null mutation of the spo0E ortholog and assessed sporulation and physiology. The spo0E mutant produced significantly more spores, demonstrating Spo0E represses C. difficile sporulation. Unexpectedly, the spo0E mutant also exhibited increased motility and toxin production, and enhanced virulence in animal infections. We uncovered that Spo0E interacts with both Spo0A and the toxin and motility regulator, RstA. Direct interactions between Spo0A, Spo0E, and RstA constitute a previously unknown molecular switch that coordinates sporulation with motility and toxin production. Reinvestigation of Spo0E function in B. subtilis revealed that Spo0E induced motility, demonstrating Spo0E regulation of motility and sporulation among divergent species. Further, 3D structural analyses of Spo0E revealed specific and exclusive interactions between Spo0E and binding partners in C. difficile and B. subtilis that provide insight into the conservation of this regulatory mechanism among different species.

A Conserved Switch Controls Virulence, Sporulation, and Motility in C. difficile

Spore formation is required for environmental survival and transmission of the human enteropathogenic Clostridioides difficile . In all bacterial spore formers, sporulation is regulated through activation of the master response regulator, Spo0A. However, the factors and mechanisms that directly regulate C. difficile Spo0A activity are not defined. In the well-studied Bacillus species, Spo0A is directly inactivated by Spo0E, a small phosphatase. To understand Spo0E function in C. difficile , we created a null mutation of the spo0E ortholog and assessed sporulation and physiology. The spo0E mutant produced significantly more spores, demonstrating Spo0E represses C. difficile sporulation. Unexpectedly, the spo0E mutant also exhibited increased motility and toxin production, and enhanced virulence in animal infections. We uncovered that Spo0E interacts with both Spo0A and the toxin and motility regulator, RstA. Direct interactions between Spo0A, Spo0E, and RstA constitute a previously unknown molecular switch that coordinates sporulation with motility and toxin production. Reinvestigation of Spo0E function in B. subtilis revealed that Spo0E induced motility, demonstrating Spo0E regulation of motility and sporulation among divergent species. Further, we found that Spo0E orthologs are widespread among prokaryotes, suggesting that Spo0E performs conserved regulatory functions in diverse bacteria.

A Life in Bacillus subtilis Signal Transduction

This is a tale of how technology drove the discovery of the molecular basis for signal transduction in the initiation of sporulation in Bacillus subtilis and in bacterial two-component systems. It progresses from genetics to cloning and sequencing to biochemistry to structural biology to an understanding of how proteins evolve interaction specificity and to identification of interaction surfaces by statistical physics. This is about how the people in my laboratory accomplished this feat; without them little would have been done.

Bactobolin resistance is conferred by mutations in the L2 ribosomal protein

Burkholderia thailandensis produces a family of polyketide-peptide molecules called bactobolins, some of which are potent antibiotics. We found that growth of B. thailandensis at 30°C versus that at 37°C resulted in increased production of bactobolins. We purified the three most abundant bactobolins and determined their activities against a battery of bacteria and mouse fibroblasts. Two of the three compounds showed strong activities against both bacteria and fibroblasts. The third analog was much less potent in both assays. These results suggested that the target of bactobolins might be conserved across bacteria and mammalian cells. To learn about the mechanism of bactobolin activity, we isolated four spontaneous bactobolin-resistant Bacillus subtilis mutants. We used genomic sequencing technology to show that each of the four resistant variants had mutations in rplB, which codes for the 50S ribosome-associated L2 protein. Ectopic expression of a mutant rplB gene in wild-type B. subtilis conferred bactobolin resistance. Finally, the L2 mutations did not confer resistance to other antibiotics known to interfere with ribosome function. Our data indicate that bactobolins target the L2 protein or a nearby site and that this is not the target of other antibiotics. We presume that the mammalian target of bactobolins involves the eukaryotic homolog of L2 (L8e).

Currently available antibiotics target surprisingly few cellular functions, and there is a need to identify novel antibiotic targets. We have been interested in the Burkholderia thailandensis bactobolins, and we sought to learn about the target of bactobolin activity by mapping spontaneous resistance mutations in the bactobolin-sensitive Bacillus subtilis. Our results indicate that the bactobolin target is the 50S ribosome-associated L2 protein or a region of the ribosome affected by L2. Bactobolin-resistant mutants are not resistant to other known ribosome inhibitors. Our evidence indicates that bactobolins interact with a novel antibiotic target.

Bacillus subtilis RapA phosphatase domain interaction with its substrate, phosphorylated Spo0F, and its inhibitor, the PhrA peptide

Rap proteins in Bacillus subtilis regulate the phosphorylation level or the DNA-binding activity of response regulators such as Spo0F, involved in sporulation initiation, or ComA, regulating competence development. Rap proteins can be inhibited by specific peptides generated by the export-import processing pathway of the Phr proteins. Rap proteins have a modular organization comprising an amino-terminal alpha-helical domain connected to a domain formed by six tetratricopeptide repeats (TPR). In this study, the molecular basis for the specificity of the RapA phosphatase for its substrate, phosphorylated Spo0F (Spo0F∼P), and its inhibitor pentapeptide, PhrA, was analyzed in part by generating chimeric proteins with RapC, which targets the DNA-binding domain of ComA, rather than Spo0F∼P, and is inhibited by the PhrC pentapeptide. In vivo analysis of sporulation efficiency or competence-induced gene expression, as well as in vitro biochemical assays, allowed the identification of the amino-terminal 60 amino acids as sufficient to determine Rap specificity for its substrate and the central TPR3 to TPR5 (TPR3-5) repeats as providing binding specificity toward the Phr peptide inhibitor. The results allowed the prediction and testing of key residues in RapA that are essential for PhrA binding and specificity, thus demonstrating how the widespread structural fold of the TPR is highly versatile, using a common interaction mechanism for a variety of functions in eukaryotic and prokaryotic organisms.

Dynamical consequences of bandpass feedback loops in a bacterial phosphorelay

Under conditions of nutrient limitation, Bacillus subtilis cells terminally differentiate into a dormant spore state. Progression to sporulation is controlled by a genetic circuit consisting of a phosphorelay embedded in multiple transcriptional feedback loops, which is used to activate the master regulator Spo0A by phosphorylation. These transcriptional regulatory interactions are "bandpass"-like, in the sense that activation occurs within a limited band of Spo0A∼P concentrations. Additionally, recent results show that the phosphorelay activation occurs in pulses, in a cell-cycle dependent fashion. However, the impact of these pulsed bandpass interactions on the circuit dynamics preceding sporulation remains unclear. In order to address this question, we measured key features of the bandpass interactions at the single-cell level and analyzed them in the context of a simple mathematical model. The model predicted the emergence of a delayed phase shift between the pulsing activity of the different sporulation genes, as well as the existence of a stable state, with elevated Spo0A activity but no sporulation, embedded within the dynamical structure of the system. To test the model, we used time-lapse fluorescence microscopy to measure dynamics of single cells initiating sporulation. We observed the delayed phase shift emerging during the progression to sporulation, while a re-engineering of the sporulation circuit revealed behavior resembling the predicted additional state. These results show that periodically-driven bandpass feedback loops can give rise to complex dynamics in the progression towards sporulation.

Mathematical modelling of the sporulation-initiation network in Bacillus subtilis revealing the dual role of the putative quorum-sensing signal molecule PhrA

Bacillus subtilis cells may opt to forgo normal cell division and instead form spores if subjected to certain environmental stimuli, for example nutrient deficiency or extreme temperature. The resulting spores are extremely resilient and can survive for extensive periods of time, importantly under particularly harsh conditions such as those mentioned above. The sporulation process is highly time and energy consuming and essentially irreversible. The bacteria must therefore ensure that this route is only undertaken under appropriate circumstances. The gene regulation network governing sporulation initiation accordingly incorporates a variety of signals and is of significant complexity. We present a model of this network that includes four of these signals: nutrient levels, DNA damage, the products of the competence genes, and cell population size. Our results can be summarised as follows: (i) the model displays the correct phenotypic behaviour in response to these signals; (ii) a basal level of sda expression may prevent sporulation in the presence of nutrients; (iii) sporulation is more likely to occur in a large population of cells than in a small one; (iv) finally, and of most interest, PhrA can act simultaneously as a quorum-sensing signal and as a timing mechanism, delaying sporulation when the cell has damaged DNA, possibly thereby allowing the cell time to repair its DNA before forming a spore.

The Spo0E phosphatase of Bacillus subtilis is a substrate of the FtsH metalloprotease

In the absence of the ATP-dependent metalloprotease FtsH, the sporulation frequency of Bacillus subtilis cells is reduced by several orders of magnitude. This indicates that FtsH has to degrade or to regulate the steady-state level of one or more proteins that interfere with successful sporulation. Here, we show that the amount of the master regulator protein Spo0A is reduced in an ftsH knockout and the small amounts of Spo0A protein present are inactive. Phosphorylation of Spo0A occurs through a phosphorelay. Four negative regulators have been identified here which directly interfere with the phosphorelay through ftsH, namely the phosphatases RapA, RapB, RapE and Spo0E. If a null allele in any one of them was combined with an ftsH knockout, the sporulation frequency was increased by two to three orders of magnitude, but remained below 1 %. When purified Spo0E was incubated with FtsH, partial degradation of the phosphatase was observed. In contrast, two mutant versions of Spo0E with truncated C-termini remained stable. Transfer of the C-terminal 25 aa of Spo0E to a shorter homologue of Spo0E, YnzD, which is not a substrate of FtsH, conferred instability. When a mutant Spo0A was produced that was active in the absence of phosphorylation, spores were formed at a normal rate in an ftsH knockout, indicating that ftsH is needed only during phase 0.

Negative regulation of Bacillus anthracis sporulation by the Spo0E family of phosphatases

The initiation of sporulation in Bacillus species is controlled by the phosphorelay signal transduction system. Multiple regulatory elements act on the phosphorelay to modulate the level of protein phosphorylation in response to cellular, environmental, and metabolic signals. In Bacillus anthracis nine possible histidine sensor kinases can positively activate the system, while two response regulator aspartyl phosphate phosphatases of the Rap family negatively impact the pathway by dephosphorylating the Spo0F intermediate response regulator. In this study, we have characterized the B. anthracis members of the Spo0E family of phosphatases that specifically dephosphorylate the Spo0A response regulator of the phosphorelay and master regulator of sporulation. The products of four genes were able to promote the dephosphorylation of Spo0A approximately P in vitro. The overexpression of two of these B. anthracis Spo0E-like proteins from a multicopy vector consistently resulted in a sporulation-deficient phenotype. A third gene was found to be not transcribed in vivo. A fourth gene encoded a prematurely truncated protein due to a base pair deletion that nevertheless was subject to translational frameshift repair in an Escherichia coli protein expression system. A fifth Spo0E-like protein has been structurally and functionally characterized as a phosphatase of Spo0A approximately P by R. N. Grenha et al. (J. Biol. Chem. 281:37993-38003, 2006). We propose that these proteins may contribute to maintain B. anthracis in the transition phase of growth during an active infection and therefore contribute to the virulence of this organism.

Sensor domains encoded in Bacillus anthracis virulence plasmids prevent sporulation by hijacking a sporulation sensor histidine kinase

Anthrax toxin and capsule, determinants for successful infection by Bacillus anthracis, are encoded on the virulence plasmids pXO1 and pXO2, respectively. Each of these plasmids also encodes proteins that are highly homologous to the signal sensor domain of a chromosomally encoded major sporulation sensor histidine kinase (BA2291) in this organism. B. anthracis Sterne overexpressing the plasmid pXO2-61-encoded signal sensor domain exhibited a significant decrease in sporulation that was suppressed by the deletion of the BA2291 gene. Expression of the sensor domains from the pXO1-118 and pXO2-61 genes in Bacillus subtilis strains carrying the B. anthracis sporulation sensor kinase BA2291 gene resulted in BA2291-dependent inhibition of sporulation. These results indicate that sporulation sensor kinase BA2291 is converted from an activator to an inhibitor of sporulation in its native host by the virulence plasmid-encoded signal sensor domains. We speculate that activation of these signal sensor domains contributes to the initiation of B. anthracis sporulation in the bloodstream of its infected host, a salient characteristic in the virulence of this organism, and provides an additional role for the virulence plasmids in anthrax pathogenesis.

Interaction surface of the Spo0A response regulator with the Spo0E phosphatase

Spo0A~P is the essential response regulator and transcription factor for sporulation initiation in Bacillus subtilis. The phosphorylation level of Spo0A in the cell is determined by the sensor kinase activity of the phosphorelay, donating phosphoryl groups, and the antagonistic effects of dephosphorylation mediated by the Rap and Spo0E families of phosphatases. In this study, spo0A mutations were generated that encoded proteins less sensitive to the activity of Spo0E than the wild-type protein. The Spo0A substitutions N12K, P60S, L62P and F88L are surface exposed and localize to the same face of the molecule as the active site and in its close proximity on the beta1-alpha1, beta3-alpha3 and beta4-alpha4 loops. The corresponding surface in the Spo0F response regulator was shown previously to be involved in the interaction with the RapB phosphatase, as well as the KinA histidine kinase and the Spo0B phosphotransferase. Thus, residues occupying the same position (N12:Q12, F88:Y84) and the same loops in Spo0A or Spo0F are involved in the interaction with the structurally unrelated Spo0E and RapB phosphatases, respectively, in addition to kinases and phosphotransferase. The specificity in phosphatase target recognition must be the result of side-chain variability within the response regulators and the interactions they promote. The residues involved in Spo0E interaction are identical in all Spo0A orthologues from spore-forming Bacilli encoding Spo0E phosphatases.

Characterization of the parB-like yyaA gene of Bacillus subtilis

We have characterized the yyaA gene of Bacillus subtilis, located near the origin of chromosome replication (oriC). Its protein product is similar to the Spo0J protein, which belongs to the ParB family of chromosome- and plasmid-partitioning proteins. Insertional inactivation of the yyaA gene had no apparent effect on chromosome organization and partitioning during vegetative growth or sporulation. Subcellular localization of YyaA by immunofluorescence microscopy indicated that it colocalizes with the nucleoid, and gel retardation studies confirmed that YyaA binds relatively nonspecifically to DNA. Overexpression of yyaA caused a sporulation defect characterized by the formation of multiple septa within the cell. This phenotype indicates that YyaA may have a regulatory role at the onset of sporulation.

A new family of aspartyl phosphate phosphatases targeting the sporulation transcription factor Spo0A of Bacillus subtilis

The initiation of the sporulation developmental pathway in Bacillus subtilis is controlled by the phospho-relay, a multicomponent signal transduction system. Multiple positive and negative signals are integrated by the phosphorelay through the opposing activities of histidine protein kinases and aspartyl phosphate phosphatases. Three members of the Rap family of phosphatases (RapA, RapB and RapE) specifically dephosphorylate the Spo0F approximately P response regulator intermediate, while the Spo0A approximately P transcription factor is specifically dephosphorylated by the Spo0E phosphatase and, as shown here, the newly identified YnzD and YisI proteins. The products of the YnzD and YisI genes are highly homologous to Spo0E and define a new family of phosphatases with a distinct signature motif in their amino acid sequence. As negative regulators of the developmental pathway, YnzD and YisI inhibit spore formation if over-expressed, while a chromosomal deletion of their coding sequences results in increased sporulation frequency. Transcription of the ynzD, yisI and spo0E genes is differentially regulated and generally induced by growth conditions antithetical to sporulation. Negative signals interpreted by aspartyl phosphate phosphatases appear to be a common mechanism in Gram-positive spore-forming microorganisms.

Forespore-specific transcription of the lonB gene during sporulation in Bacillus subtilis

The Bacillus subtilis genome encodes two members of the Lon family of prokaryotic ATP-dependent proteases. One, LonA, is produced in response to temperature, osmotic, and oxidative stress and has also been implicated in preventing sigma(G) activity under nonsporulation conditions. The second is encoded by the lonB gene, which resides immediately upstream from lonA. Here we report that transcription of lonB occurs during sporulation under sigma(F) control and thus is restricted to the prespore compartment of sporulating cells. First, expression of a lonB-lacZ transcriptional fusion was abolished in strains unable to produce sigma(F) but remained unaffected upon disruption of the genes encoding the early and late mother cell regulators sigma(E) and sigma(K) or the late forespore regulator sigma(G). Second, the fluorescence of strains harboring a lonB-gfp fusion was confined to the prespore compartment and depended on sigma(F) production. Last, primer extension analysis of the lonB transcript revealed -10 and -35 sequences resembling the consensus sequence recognized by sigma(F)-containing RNA polymerase. We further show that the lonB message accumulated as a single monocistronic transcript during sporulation, synthesis of which required sigma(F) activity. Disruption of the lonB gene did not confer any discernible sporulation phenotype to otherwise wild-type cells, nor did expression of lonB from a multicopy plasmid. In contrast, expression of a fusion of the lonB promoter to the lonA gene severely reduced expression of the sigma(G)-dependent sspE gene and the frequency of sporulation. In confirmation of earlier observations, we found elevated levels of sigma(F)-dependent activity in a spoIIIE47 mutant, in which the lonB region of the chromosome is not translocated into the prespore. Expression of either lonB or the P(lonB)-lonA fusion from a plasmid in the spoIIIE47 mutant reduced sigma(F) -dependent activity to wild-type levels. The results suggest that both LonA and LonB can prevent abnormally high sigma(F) activity but that only LonA can negatively regulate sigma(G).

A Bacillus subtilis secreted protein with a role in endospore coat assembly and function

Bacterial endospores are encased in a complex protein coat, which confers protection against noxious chemicals and influences the germination response. In Bacillus subtilis, over 20 polypeptides are organized into an amorphous undercoat, a lamellar lightly staining inner structure, and an electron-dense outer coat. Here we report on the identification of a polypeptide of about 30 kDa required for proper coat assembly, which was extracted from spores of a gerE mutant. The N-terminal sequence of this polypeptide matched the deduced product of the tasA gene, after removal of a putative 27-residue signal peptide, and TasA was immunologically detected in material extracted from purified spores. Remarkably, deletion of tasA results in the production of asymmetric spores that accumulate misassembled material in one pole and have a greatly expanded undercoat and an altered outer coat structure. Moreover, we found that tasA and gerE mutations act synergistically to decrease the efficiency of spore germination. We show that tasA is the most distal member of a three-gene operon, which also encodes the type I signal peptidase SipW. Expression of the tasA operon is enhanced 2 h after the onset of sporulation, under the control of sigmaH. When tasA transcription is uncoupled from sipW expression, a presumptive TasA precursor accumulates, suggesting that its maturation depends on SipW. Mature TasA is found in supernatants of sporulating cultures and intracellularly from 2 h of sporulation onward. We suggest that, at an early stage of sporulation, TasA is secreted to the septal compartment. Later, after engulfment of the prespore by the mother cell, TasA acts from the septal-proximal pole of the spore membranes to nucleate the organization of the undercoat region. TasA is the first example of a polypeptide involved in coat assembly whose production is not mother cell specific but rather precedes its formation. Our results implicate secretion as a mechanism to target individual proteins to specific cellular locations during the assembly of the bacterial endospore coat.

Kinase-phosphatase competition regulates Bacillus subtilis development

The major regulator of sporulation initiation in Bacillus subtilis is the phosphorelay, a multicomponent signal transduction system. A myriad of signals, both positive and negative, from the environment, cell cycle and metabolism is received and interpreted by the phosphorelay and integrated through the opposing activity of protein kinases and protein aspartate phosphatases to create an extremely sophisticated regulatory network.

A negative regulator linking chromosome segregation to developmental transcription in Bacillus subtilis

The SpoOJA and SpoOJB proteins of Bacillus subtilis are similar to the ParA and ParB plasmid-partitioning proteins, respectively, and mutation of spoOJB prevents the expression of stage II genes of sporulation. This phenotype is a consequence of SpoOJA activity in the absence of SpoOJB, and its basis was unknown. In the studies reported here, SpoOJA was found specifically to dissociate transcription initiation complexes formed in vitro by the phosphorylated sporulation transcription factor SpoOA and RNA polymerase with the spollG promoter. This repressor-like activity is likely to be the basis for preventing the onset of differentiation in vivo. SpoOJB is known to neutralize SpoOJA activity in vivo and also to interact with a mitotic-like apparatus responsible for chromosome partitioning. These data suggest that SpoOJA and SpoOJB form a regulatory link between chromosome partition and development gene expression.

Characterization of a phosphoprotein phosphatase for the phosphorylated form of nucleoside-diphosphate kinase from Pseudomonas aeruginosa

Nucleoside-diphosphate kinase (ATP:nucleoside-diphosphate phosphotransferase, EC 2.7.4.6; NDP kinase) is an important enzyme for the maintenance of the correct cellular levels of nucleoside triphosphates (NTPs) and their deoxy derivatives (dNTPs) and is involved in the regulation of cellular development. The enzyme is under the dual control of algR2 and algH in Pseudomonas aeruginosa. We report here the purification and characterization of a protein that dephosphorylates the phosphorylated intermediate form of the P. aeruginosa NDP kinase (Ndk). Dephosphorylation of Ndk phosphate leads to loss of its enzymatic activity. The 10.1-kDa polypeptide shows 77% homology at the N terminus with the Spo0E phosphatase, identified as a negative regulator of sporulation in Bacillus subtilis and 66% with the human Bax protein, identified as an effector of programmed cell death. The phosphatase termed Npp showed varied specificity toward phosphorylated Ndks from different sources including human erythrocyte Ndk phosphate. Its activity toward other histidine phosphates such as CheA or the alpha-subunit of succinyl-CoA synthetase or phosphoesters such as p-nitrophenyl phosphate was quite limited. Npp was stable at room temperature up to 2 h and required Mg2+ for activity. The presence of a phosphatase capable of dephosphorylating the phosphorylated form of P. aeruginosa Ndk represents an interesting and efficient mode of post-translational modification of an enzyme crucial to cellular development.

In vitro binding affinity of the Bacillus subtilis AbrB protein to six different DNA target regions

AbrB is a transcriptional regulator of many Bacillus subtilis genes. A number of AbrB-binding sites have previously been delimited by DNase I footprinting studies, but the heterogeneity of the protected sequences and sizes has not led to a determination of a possible consensus motif for recognition. We have examined the affinity of AbrB for binding to six known target regions when the regions were placed in DNA fragments of various sizes. The sites are shown to vary dramatically in AbrB-binding affinity when they are present in smaller fragments, but the differences are smaller when the affinities of larger fragments are compared. Additional observations that indicate that AbrB binding may be a multistep cooperative process are reported.

Isolation and characterization of kinC, a gene that encodes a sensor kinase homologous to the sporulation sensor kinases KinA and KinB in Bacillus subtilis

Phosphorylation of the transcription factor encoded by spo0A is required for the initiation of sporulation in Bacillus subtilis. Production and accumulation of Spo0A-P is controlled by histidine protein kinases and the spo0 gene products. To identify additional genes that might be involved in the initiation of sporulation and production of Spo0A-P, we isolated genes which when present on a multicopy plasmid could suppress the sporulation defect of a spo0K mutant. kinC was one gene isolated in this way. A multicopy plasmid containing kinC completely or partially suppressed the sporulation defect caused by mutations in spo0K, kinA, spo0F, and spo0B, indicating that at least when overexpressed, KinC is capable of stimulating phosphorylation of Spo0A independently of the normal phosphorylation pathway. The predicted product of kinC is 428 amino acids long and is most similar to KinA and KinB, the histidine protein kinases involved in the initiation of sporulation. In otherwise wild-type strains, kinC null mutations caused little or no defect in sporulation under the conditions tested. However, in the absence of a functional phosphorelay (spo0F or spo0B), KinC appears to be the kinase responsible for phosphorylation of the sof-1 and rvtA11 forms of Spo0A.

spo0J is required for normal chromosome segregation as well as the initiation of sporulation in Bacillus subtilis

The spo0J gene of Bacillus subtilis is required for the initiation of sporulation. We show that the sporulation defect caused by null mutations in spo0J is suppressed by a null mutation in the gene located directly upstream from spo0J, soj (suppressor of spo0J). These results indicate that Soj inhibits the initiation of sporulation and that Spo0J antagonizes that inhibition. Further genetic experiments indicated that Soj ultimately affects sporulation by inhibiting the activation (phosphorylation) of the developmental transcription factor encoded by spo0A. In addition, the temperature-sensitive sporulation phenotype caused by the ftsA279 (spoIIN279) mutation was partly suppressed by the soj null mutation, indicating that FtsA might also affect the activity of Soj. Soj and Spo0J are known to be similar in sequence to a family of proteins involved in plasmid partitioning, including ParA and ParB of prophage P1, SopA and SopB of F, and IncC and KorB of RK2, spo0J was found to be required for normal chromosome partitioning as well as for sporulation. spo0J null mutants produced a significant proportion of anucleate cells during vegetative growth. The dual functions of Spo0J could provide a mechanism for regulating the initiation of sporulation in response to activity of the chromosome partition machinery.

Gene expression in single cells of Bacillus subtilis: evidence that a threshold mechanism controls the initiation of sporulation

Early during endospore formation in the bacterium Bacillus subtilis, two distinct cell types are formed. The initiation of this developmental pathway requires several physiological conditions (e.g., nutrient deprivation) and is controlled by the Spo0A transcription factor. We have found that in a culture of sporulating cells, there are two subpopulations, one that has initiated the developmental program and activated the expression of early developmental genes and one in which early developmental gene expression remains uninduced. We measured the expression of developmental (spo) genes in single cells of B. subtilis by using spo-lacZ fusions. Cells containing a spo-lacZ fusion were stained with a dye that fluoresces upon hydrolysis by beta-galactosidase, and the fluorescence in individual cells was measured with a flow cytometer. For Spo+ cells, we found that the proportion of the population expressing early developmental genes correlates well with the fraction of the population that eventually produces spores. In addition, mutations that cause a decrease in the amount of activated (phosphorylated) Spo0A transcription factor cause a decrease in the size of the subpopulation expressing early developmental genes that are directly activated by Spo0A approximately P. Again, the size of the subpopulation correlates well with the fraction of cells that produce spores. These results indicate that a threshold level of activated Spo0A (Spo0A approximately P) or of a component of the phosphorylation pathway must accumulate to induce sporulation gene expression and that most of the cells that are able to induce the expression of early genes that are directly activated by Spo0A approximately P go on to produce mature spores.(ABSTRACT TRUNCATED AT 250 WORDS)

Deactivation of the sporulation transcription factor Spo0A by the Spo0E protein phosphatase

The spo0E locus of Bacillus subtilis codes for a negative regulator of sporulation that, when overproduced, represses sporulation and, if deleted, results in inappropriate timing of sporulation. The product of this locus, Spo0E, was purified and found to be a protein phosphatase, which specifically dephosphorylated the sporulation transcription factor Spo0A-P, converting it to an inactive form. Spo0E was not significantly active as a phosphatase on other components of the phosphorelay signal-transduction pathway producing Spo0A-P. A mutant Spo0E protein that results in sporulation deficiency was purified and found to be hyperactive as a phosphatase. The Spo0E phosphatase may provide an additional control point for environmental, metabolic, or cell-cycle regulation of phosphate flow in the phosphorelay. These results reinforce the concept that the phosphorelay is subject to a host of positive and negative signals for sporulation that are recognized and interpreted as signal integration circuit that has the role of regulating the cellular level of active phosphorylated Spo0A sporulation transcription factor.

Cloning, nucleotide sequence, and regulation of the Bacillus subtilis pbpF gene, which codes for a putative class A high-molecular-weight penicillin-binding protein

The partial nucleotide sequence of a gene encoding a Bacillus subtilis homolog to the Escherichia coli ponA gene, encoding penicillin-binding protein 1A, was previously reported. The remaining part of this gene, termed pbpF, was isolated, and its nucleotide sequence was completed. Deletion of this gene did not alter the profile of B. subtilis penicillin-binding proteins observed after gel electrophoresis and resulted in no observable phenotype. A transcriptional pbpF-lacZ fusion was weakly expressed during vegetative growth. Expression diminished during the first hours of sporulation but was slightly induced in the forespore compartment during late sporulation. This sporulation expression was dependent on spoIIIG, which encodes the forespore-specific transcription factor sigma G. A single transcription start site which was apparently directly dependent on E sigma A was detected in vegetative cells.

Signal transduction in Bacillus subtilis sporulation

The initiation of sporulation in Bacillus subtilis is regulated by a signal transduction system leading to activation (by phosphorylation) of the Spo0A transcription factor. Activated Spo0A controls the expression of genes encoding different RNA polymerase sigma factors, whose synthesis and activities are related to morphological events and intercompartmental communication between the developing forespore and the mother cell.

The phosphorelay signal transduction pathway in the initiation of Bacillus subtilis sporulation

The formation of spores in Bacillus subtilis is a developmental process under genetic control. The decision to either divide or sporulate is regulated by the state of phosphorylation of the SpoOA transcription factor. Phosphorylated SpoOA (SpoOA approximately P) is both a repressor and an activator of transcription depending on the promoter it is affecting. SpoOA approximately P is the end product of the phosphorelay, a signal transduction system linking environmental information to the activation of sporulation. Activation or deinhibition of two ATP-dependent kinases, KinA and KinB, to phosphorylate the SpoOF secondary messenger initiates the phosphorelay. SpoOF approximately P is the substrate for the SpoOB protein, a phosphoprotein phosphotransferase which transfers the phosphate group to SpoOA. The SpoOA approximately P formed from this pathway orchestrates transcription events during the initial stage of spore development through direct effects on a variety of promoters and through the use of other transcription factors, termed transition state regulators, whose activity it controls. Because commitment to sporulation has serious cellular programming consequences and is not undertaken capriciously, the phosphorelay is subject to a variety of complex controls on the flow of phosphate through its components.

Bacillus subtilis CheN, a homolog of CheA, the central regulator of chemotaxis in Escherichia coli

The Bacillus subtilis cheN gene was isolated, sequenced, and expressed. It encodes a large negatively charged protein with a molecular weight of approximately 74,000. The predicted protein sequence has 33 to 34% identity with the Escherichia coli and Salmonella typhimurium CheA and Myxococcus xanthus FrzE sequences. These proteins are found to autophosphorylate and are members of the same histidine kinase signal modulating family. CheN has several conserved regions (including the histidine that is phosphorylated in CheA) that coincide with other autophosphorylated signal transducers. A null mutant is defective in attractant-induced methanol formation and shows no behavioral response to chemoeffectors. These results imply that in B. subtilis the mechanism of chemotaxis involves phosphoryl transfer similar to that in E. coli. However, the CheN null mutant mostly tumbles, whereas CheA mutants swim smoothly, and only in B. subtilis does excitation lead to methyl transfer and methanol formation. Thus, the overall mechanism of chemotaxis is different in the two organisms.

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.

Transcriptional regulation of a Bacillus subtilis dipeptide transport operon

The Bacillus subtilis dciA operon, which encodes a dipeptide transport system, was induced rapidly by several conditions that caused the cells to enter stationary phase and initiate sporulation. The in vivo start point of transcription was mapped precisely and shown to correspond to a site of transcription initiation in vitro by the major vegetative form of RNA polymerase. Post-exponential expression was prevented by a mutation in the spo0A gene (whose product is a known regulator of early sporulation genes) but was restored in a spo0A abrB double mutant. This implicated AbrB, another known regulator, as a repressor of dciA. In fact, purified AbrB protein bound to a portion of the dciA promoter region, protecting it against DNase I digestion. Expression of dciA in growing cells was also repressed independently by glucose and by a mixture of amino acids; neither of these effects was mediated by AbrB.

Negative regulation of Bacillus subtilis sporulation by the spo0E gene product

Transcription of the Bacillus subtilis spo0E gene is controlled by the AbrB transition state regulator. In AbrB+ strains, a single transcript, P1, was observed for the spo0E gene. In an abrB4 mutant strain, a second transcription start site 3 bases upstream from P1 was found to be used for the predominant transcript. P1 transcription was insensitive to the state of the abrB gene. Mutants carrying deletion or antibiotic cassette insertion mutations in the spo0E gene were Spo+. Multiple copies of the spo0E gene, not just the promoter region, were found to render strains incapable of sporulation. Spo+ strains that arose spontaneously from such Spo- strains were found to have deletions in the spo0E coding sequence on the plasmid. Strains carrying a deletion of the spo0E gene segregated Spo- colonies. These colonies were found to have secondary mutations in or near the spo0A, spo0B, or spo0F gene, suggesting that deletion of the spo0E gene results in increased pressure to sporulate that is compensated for by inactivation of one or more of the components of the signal transduction system leading to the initiation of sporulation. spo0E deletions were suppressors of the spo0F221 missense mutation but had no effect on the regulation of the spo0F, kinA, spo0A, or spo0B genes. The results suggest that the spo0E gene product is a negative regulator of the signal transduction pathway leading to sporulation.

The Bacillus subtilis spo0J gene: evidence for involvement in catabolite repression of sporulation

Previous observations concerning the ability of the Bacillus subtilis bacteriophages SP10 and PMB12 to suppress mutations in spo0J and to make wild-type sporulation catabolite resistant suggested that spo0J had a role in catabolite repression of sporulation. This suggestion was supported in the present report by the ability of the catabolite-resistant sporulation mutation crsF4 to suppress a Tn917 insertion mutation of the B. subtilis spo0J locus (spo0J::Tn917 omega HU261) in medium without glucose. Although crsF4 and SP10 made wild-type B. subtilis sporulation catabolite resistant, neither crsF4 nor SP10 caused a mutant with spo0J::Tn917 omega HU261 to sporulate in medium with glucose. Sequencing the spo0J locus revealed an open reading frame that was 179 codons in length. Disruption of the open reading frame resulted in a sporulation-negative (Spo-) phenotype that was similar to those of other spo0J mutations. Analysis of the deduced amino acid sequence of the spo0J locus indicated that the spo0J gene product contains an alpha-helix-turn-alpha-helix unit similar to the motif found in lambda Cro-like DNA-binding proteins.

Initiation of sporulation in B. subtilis is controlled by a multicomponent phosphorelay

Stage 0 sporulation (spo0) mutants of Bacillus subtilis are defective in the signal transduction system initiating sporulation. Two of the products of these genes, Spo0A and Spo0F, are related to response regulator components of two-component regulatory systems used to control environmental responses in bacteria. The Spo0F response regulator was found to be the primary substrate for phosphorylation by the sporulation-specific protein kinase, KinA. Phosphorylated Spo0F was the phosphodonor for a phosphotransferase, Spo0B, which transferred the phosphate group to the second response regulator, the transcription regulatory protein Spo0A. This phosphorelay provides a mechanism for signal gathering from several protein kinases using Spo0F as a secondary messenger. These divergent signals are integrated through Spo0B phosphotransferase to activate the Spo0A transcription factor. This system provides for many levels of control to prevent capricious induction of sporulation.

Regulation of spo0H, a gene coding for the Bacillus subtilis sigma H factor

The Bacillus spo0H gene codes for sigma H, which, as part of the RNA polymerase holoenzyme E sigma H, is responsible for the transcription of several genes which are expressed at the beginning of the sporulation process. In this communication, we examined the regulation of the spo0H gene of Bacillus subtilis by using lacZ reporter gene assays, quantitative RNA determinations, and Western immunoassay. The expression of the spo0H gene increases as the culture enters the mid-logarithmic stage of growth. This increased expression requires the genes spo0A, spo0B, spo0E, and spo0F, and the requirement for at least spo0A and spo0B can be bypassed when the abrB gene is mutated. The expression of the spo0H gene is constitutive in the presence of the abrB mutation, being expressed at higher levels during vegetative growth. In addition, the sof-1 mutation, in the spo0A structural gene, can bypass the need for spo0F in spo0H expression. The transcriptional start site of spo0H was determined by using RNA made in vivo as well as in vitro. These studies indicate that spo0H is transcribed by the major vegetative RNA polymerase, E sigma A. spo0H RNA and sigma H levels during growth are not identical to each other or to the pattern of expression of spoVG, a gene transcribed by E sigma H. This suggests that spo0H is regulated posttranscriptionally and also that factors in addition to sigma H levels are involved in the expression of genes of the E sigma H regulon.

The oligopeptide transport system of Bacillus subtilis plays a role in the initiation of sporulation

Bacillus subtilis spo0K mutants are blocked at the first step in sporulation. The spo0K strain was found to contain two mutations: one was linked to the trpS locus, and the other was elsewhere on the chromosome. The mutation linked to trpS was responsible for the sporulation defect (spo-). The unlinked mutation enhanced this sporulation deficiency but had no phenotype on its own. The spo- mutation was located in an operon of five genes highly homologous to the oligopeptide transport (Opp) system of Gram-negative species. Studies with toxic peptide analogues showed that this operon does indeed encode a peptide-transport system. However, unlike the Opp system of Salmonella typhimurium, one of the two ATP-binding proteins, OppF, was not required for peptide transport or for sporulation. The OppA peptide-binding protein, which is periplasmically located in Gram-negative species, has a signal sequence characteristic of lipoproteins with an amino-terminal lipo-amino acid anchor. Cellular location studies revealed that OppA was associated with the cell during exponential growth, but was released into the medium in stationary phase. A major role of the Opp system in Gram-negative bacteria is the recycling of cell-wall peptides as they are released from the growing peptidoglycan. We postulate that the accumulation of such peptides may play a signalling role in the initiation of sporulation, and that the sporulation defect in opp mutants results from an inability to transport these peptides.

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).

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

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

Characterization of the gene for a protein kinase which phosphorylates the sporulation-regulatory proteins Spo0A and Spo0F of Bacillus subtilis

The kinA (spoIIJ) locus contains a single gene which codes for a protein of 69,170 daltons showing strong homology to the transmitter kinases of two component regulatory systems. The purified kinase autophosphorylates in the presence of ATP and mediates the transfer of phosphate to the Spo0A and Spo0F sporulation regulatory proteins. Spo0F protein was a much better phosphoreceptor for this kinase than Spo0A protein in vitro. Mutants with deletion mutations in the kinA gene were delayed in their sporulation. They produced about a third as many spores as the wild type in 24 h, but after 72 h on solid medium, the level of spores approximated that found for the wild-type strain. Such mutations had no effect on the regulation of the abrB gene or on the timing of subtilisin expression and therefore did not impair the repression function of the Spo0A protein. Placement of the kinA locus on a multicopy vector suppressed the sporulation-defective phenotype of spo0B, spo0E, and spo0F mutations but not of spo0A mutations. The results suggest that the spo0B-, spo0E-, and spo0F-dependent pathway of activation (phosphorylation) of the Spo0A regulator may be by-passed through the kinA gene product if it is present at sufficiently high intracellular concentration. The results suggest that multiple kinases exist for the Spo0A protein.

The transition state transcription regulator AbrB of Bacillus subtilis is autoregulated during vegetative growth

The DNA-binding AbrB protein of Bacillus subtilis is an ambiactive transcriptional regulator of genes expressed during the transition state between vegetative growth and the onset of stationary phase and sporulation. Studies on the transcriptional control of AbrB synthesis using abrB-lacZ fusions indicated that the abrB gene was autoregulated. This was consistent with the observation that purified AbrB protein bound specifically to the promoter region of its own gene in DNase I protection experiments. The structural gene mutation abrB4 abolished the autoregulation and purified AbrB4 protein did not have the promoter binding properties associated with the wild-type protein. Both AbrB and AbrB4 proteins were shown to be hexamers of 10,500 Dalton subunits and subunit exchange occurred between the proteins in vitro. However, the presence of only one or two mutant subunits dramaticaly altered the DNA-binding ability of the multimeric protein. The results support a model in which autoregulation of the abrB gene is an important factor in preventing sporulation-associated genes from being expressed during vegetative growth.

Identification of Bacillus subtilis genes expressed early during sporulation

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

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

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

Use of a versatile lacZ vector to analyze the upstream region of the Bacillus subtilis spoOF gene

We have constructed a versatile vector, pIS112, in which lacZ translational fusions can be made in Escherichia coli and then analyzed in Bacillus subtilis in three contexts, without recloning: in multicopy during propagation of the plasmid, in single copy integrated via a Campbell-type mechanism into the wild-type locus of the cloned fragment, or in single copy integrated into a heterologous locus. Upstream regions are reconstituted in the integration into the wild-type locus, but not into the heterologous locus, allowing the identification of upstream regulatory sequences. We have used this vector to analyze the expression of the early sporulation gene, spoOF, which, during early stationary phase, is induced 10-fold from a basal vegetative level. When a region, -50 to -150 bp relative to the transcriptional start site, is removed in the spoOF-lacZ gene, stationary phase induction of beta-galactosidase is lost. The same deletion in the upstream region of the functional spoOF gene results in cells which sporulate very poorly, although they are not blocked at the onset of sporulation, as in an spoOF null mutant. This suggests induction of spoOF expression during the beginning of stationary phase is necessary for wild-type sporulation.

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

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

Processing of a sporulation sigma factor in Bacillus subtilis: how morphological structure could control gene expression

Sporulation of Bacillus subtilis is a primitive example of coupling between morphological changes and timing of gene expression during development. A major early control of transcriptional activity is dependent on a new sigma factor, sigma E, which is encoded by the sigE gene and synthesized as an inactive precursor, pro-sigma E. We show that mutations in the spoIIGA gene block the processing of pro-sigma E. Moreover, synthesis of both spoIIGA and sigE products in vegetative cells leads to expression of a sigma E-controlled promoter during growth, suggesting that SpoIIGA has pro-sigma E processing activity. The SpoIIGA polypeptide, which contains five potential transmembrane domains, is synthesized during sporulation 1 hr before processing activity can be detected. We propose that SpoIIGA processing activity is triggered by the presence of the sporulation septum, which is itself dependent on the spoIIAA and spoIIE products. These proteins are normally needed for pro-sigma E processing during sporulation but can be bypassed in vegetative cells. According to this model, a morphological structure would directly control the synthesis of a developmental sigma factor and would modify gene expression.

Bacillus sporulation gene spo0H codes for sigma 30 (sigma H)

The DNA sequences of the spo0H genes from Bacillus licheniformis and B. subtilis are described, and the predicted open reading frames code for proteins of 26,097 and 25,447 daltons, respectively. The two spo0H gene products are 91% identical to one another and about 25% identical to most of the procaryotic sigma factors. The predicted proteins have a conserved 14-amino-acid sequence at their amino terminal end, typical of sigma factors. Antibodies raised against the spo0H gene product of B. licheniformis specifically react with RNA polymerase sigma factor protein, sigma 30, purified from B. subtilis. We conclude that the spo0H genes of B. licheniformis and B. subtilis code for sigma 30, now known as sigma H.