Heterogeneity of RNA polymerase in Bacillus subtilis: evidence for an additional sigma factor in vegetative cells

Structural basis of promoter recognition by Staphylococcus aureus RNA polymerase

Bacterial RNAP needs to form holoenzyme with σ factors to initiate transcription. While Staphylococcus aureus σA controls housekeeping functions, S. aureus σB regulates virulence, biofilm formation, persistence, cell internalization, membrane transport, and antimicrobial resistance. Besides the sequence difference, the spacers between the -35 element and -10 element of σB regulated promoters are shorter than those of σA regulated promoters. Therefore, how σB recognizes and initiates transcription from target promoters can not be inferred from that of the well studied σ. Here, we report the cryo-EM structures of S. aureus RNAP-promoter open complexes comprising σA and σB, respectively. Structural analyses, in combination with biochemical experiments, reveal the structural basis for the promoter specificity of S. aureus transcription. Although the -10 element of σA regulated promoters is recognized by domain σA2 as single-stranded DNA, the -10 element of σB regulated promoters is co-recognized by domains σB2 and σB3 as double-stranded DNA, accounting for the short spacers of σB regulated promoters. S. aureus RNAP is a validated target of antibiotics, and our structures pave the way for rational drug design targeting S. aureus RNAP.

Diverse and unified mechanisms of transcription initiation in bacteria

Transcription of DNA is a fundamental process in all cellular organisms. The enzyme responsible for transcription, RNA polymerase, is conserved in general architecture and catalytic function across the three domains of life. Diverse mechanisms are used among and within the different branches to regulate transcription initiation. Mechanistic studies of transcription initiation in bacteria are especially amenable because the promoter recognition and melting steps are much less complicated than in eukaryotes or archaea. Also, bacteria have critical roles in human health as pathogens and commensals, and the bacterial RNA polymerase is a proven target for antibiotics. Recent biophysical studies of RNA polymerases and their inhibition, as well as transcription initiation and transcription factors, have detailed the mechanisms of transcription initiation in phylogenetically diverse bacteria, inspiring this Review to examine unifying and diverse themes in this process.

Where to begin? Sigma factors and the selectivity of transcription initiation in bacteria

Transcription is the fundamental process that enables the expression of genetic information. DNA-directed RNA polymerase (RNAP) uses one strand of the DNA duplex as template to produce complementary RNA molecules that serve in translation (rRNA, tRNA), protein synthesis (mRNA) and regulation (sRNA). Although the RNAP core is catalytically competent for RNA synthesis, the selectivity of transcription initiation requires a sigma (σ) factor for promoter recognition and opening. Expression of alternative σ factors provides a powerful mechanism to control the expression of discrete sets of genes (a σ regulon) in response to specific nutritional, developmental or stress-related signals. Here, I review the key insights that led to the original discovery of σ factor 50 years ago and the subsequent discovery of alternative σ factors as a ubiquitous mechanism of bacterial gene regulation. These studies form a prelude to the more recent, genomics-enabled insights into the vast diversity of σ factors in bacteria.

Phosphorylation of the beta' Subunit of RNA Polymerase and Other Host Proteins upon phiCd1 Infection of Caulobacter crescentus

A protein kinase activity is induced early after infection of Caulobacter crescentus by the DNA phage phiCd1. After phage infection at least 40 proteins are phosphorylated; these include DNA-binding proteins, a membrane-associated protein, and several ribosomal proteins. One of the phosphorylated DNA-binding proteins was identified as the beta' subunit of the host RNA polymerase.

Purification of RNA polymerase from mycobacteria for optimized promoter-polymerase interactions

In vitro transcription analysis is important to understand the mechanism of transcription. Various assays for the analysis of initiation, elongation and termination form the basis for better understanding of the process. Purified RNA polymerase (RNAP) with high specific activity is necessary to carry out variety of these specific reactions. The RNAP purified from Mycobacterium smegmatis from exponential phase showed low promoter specificity in promoter-polymerase interaction studies. This is due to the presence of a large number of sigma factors during exponential phase and under-representation of sigma(A) required for house-keeping transcription. We describe an in vivo reconstitution of RNAP holoenzyme with sigma(A) and its purification, which resulted in holoenzyme with stoichiometric sigma(A) content. The reconstituted holoenzyme showed enhanced promoter-specific binding and promoter-specific-transcription activity compared to the enzyme isolated using standard procedure. Such in vivo reconstitution of stoichiometric holoenzyme could facilitate promoter-specific transcription assays, especially in organisms which encode a large number of sigma factors.

Elution of proteins from gels

New protein biochemical technologies have been developed that allow one to learn more and more about a protein with less and less material (on the order of microg). Polyacrylamide gel electrophoresis, which was originally strictly an analytical method, has in some cases become a high-resolution preparative method. This chapter will focus on the elution of proteins from SDS gels, with an emphasis on recovering enzyme or biological activity of the resulting protein.

Systematic analysis of SigD-regulated genes in Bacillus subtilis by DNA microarray and Northern blotting analyses

The SigD-regulated genes in Bacillus subtilis were systematically analyzed by comparing the pattern of transcripts derived from wild-type cells with those from sigD mutant cells using DNA microarray technology. One hundred and fifty-eight genes were found to be SigD-dependent candidates, 46 of which being known SigD-regulated genes. Northern blot analysis revealed that 18 of the remaining genes were SigD-dependent. The SigD consensus sequence was newly identified in the upstream regions of nine operons (11 genes): ybdO, yfmT-yfmS, hemAT, yjcP-yjcQ, yjfB, ylqB, yoaH, yscB and yxkC, and the other seven genes were assumed to be indirectly affected by a SigD mutation. Furthermore, yviE-yviF are likely to be SigD-dependent genes, because three independent sets of array data for yviE and yviF indicated they are SigD-dependent, and these genes are neighbors of flgL and hag transcribed by SigD RNA polymerase.

Affinity purification of DNA-binding proteins

The focus of this review is on DNA affinity chromatography, which is the most powerful tool for purification of DNA binding proteins. The use of nonspecific-, sequence specific- and single stranded-DNA affinity columns in purification of various DNA binding proteins is discussed. The purification strategies for transcription factors, restriction enzymes, telomerases, DNA and RNA polymerase and DNA binding antibodies are described. Different applications of DNA affinity chromatography are presented.

Expression, abundance, and RNA polymerase binding properties of the delta factor of Bacillus subtilis

The delta protein is a dispensable subunit of Bacillus subtilis RNA polymerase (RNAP) that has major effects on the biochemical properties of the purified enzyme. In the presence of delta, RNAP displays an increased specificity of transcription, a decreased affinity for nucleic acids, and an increased efficiency of RNA synthesis because of enhanced recycling. Despite these profound effects, a strain containing a deletion of the delta gene (rpoE) is viable and shows no major alterations in gene expression. Quantitative immunoblotting experiments demonstrate that delta is present in molar excess relative to RNAP in both vegetative cells and spores. Expression of rpoE initiates from a single, sigmaA-dependent promoter and is maximal in transition phase. A rpoE mutant strain has an altered morphology and is delayed in the exit from stationary phase. For biochemical analyses we have created derivatives of delta and sigmaA that can be radiolabeled with protein kinase A. Using electrophoretic mobility shift assays, we demonstrate that delta binds core RNAP with an apparent affinity of 2.5 x 10(6) M-1, but we are unable to demonstrate the formation of a ternary complex containing core enzyme, delta, and sigmaA.

The sigA gene encoding the major sigma factor of RNA polymerase from the marine cyanobacterium Synechococcus sp. strain PCC 7002: cloning and characterization

The gene encoding the principal sigma factor from Synechococcus sp. strain PCC 7002 was isolated and characterized. The Synechococcus sp. strain PCC 7002 sigA gene encodes a protein of 375 amino acids (43 center dot 7 kDa) that is required for viability under normal growth conditions. The SigA protein was overproduced in Escherichia coli and the purified protein was used to raise polyclonal antiserum in rabbits. This antiserum was used in immunoblot analyses of partially purified RNA polymerase from Synechococcus sp. strain PR6000. The probable in vivo translational start site was identified by a comparison of amino acid sequencing results obtained with SigA proteins overproduced in E. coli with immunoblot analyses of SigA protein in crude preparations of RNA polymerase from the cyanobacterium. The sigA gene is encoded on a transcript of 1700 bases that initiates 496 nucleotides upstream from the probable in vivo translational start site. The abundance of sigA transcripts decreases rapidly after the removal of combined nitrogen from the growth medium.

Promoter architecture in the flagellar regulon of Bacillus subtilis: high-level expression of flagellin by the sigma D RNA polymerase requires an upstream promoter element

Flagellin is one of the most abundant proteins in motile bacteria, yet its expression requires a low abundance sigma factor (sigma 28). We show that transcription from the Bacillus subtilis flagellin promoter is stimulated 20-fold by an upstream A+T-rich region [upstream promoter (UP) element] both in vivo and in vitro. This UP element is contacted by sigma 28 holoenzyme bound at the flagellin promoter and binds the isolated alpha 2 subassembly of RNA polymerase. The UP element increases the affinity of RNA polymerase for the flagellin promoter and stimulates transcription when initiation is limited by the rate of RNA polymerase binding. Comparison with other promoters in the flagellar regulon reveals a bipartite architecture: the -35 and -10 elements confer specificity for sigma 28, while promoter strength is determined largely by upstream DNA sequences.

The sigma factors of Bacillus subtilis

The specificity of DNA-dependent RNA polymerase for target promotes is largely due to the replaceable sigma subunit that it carries. Multiple sigma proteins, each conferring a unique promoter preference on RNA polymerase, are likely to be present in all bacteria; however, their abundance and diversity have been best characterized in Bacillus subtilis, the bacterium in which multiple sigma factors were first discovered. The 10 sigma factors thus far identified in B. subtilis directly contribute to the bacterium's ability to control gene expression. These proteins are not merely necessary for the expression of those operons whose promoters they recognize; in many instances, their appearance within the cell is sufficient to activate these operons. This review describes the discovery of each of the known B. subtilis sigma factors, their characteristics, the regulons they direct, and the complex restrictions placed on their synthesis and activities. These controls include the anticipated transcriptional regulation that modulates the expression of the sigma factor structural genes but, in the case of several of the B. subtilis sigma factors, go beyond this, adding novel posttranslational restraints on sigma factor activity. Two of the sigma factors (sigma E and sigma K) are, for example, synthesized as inactive precursor proteins. Their activities are kept in check by "pro-protein" sequences which are cleaved from the precursor molecules in response to intercellular cues. Other sigma factors (sigma B, sigma F, and sigma G) are inhibited by "anti-sigma factor" proteins that sequester them into complexes which block their ability to form RNA polymerase holoenzymes. The anti-sigma factors are, in turn, opposed by additional proteins which participate in the sigma factors' release. The devices used to control sigma factor activity in B, subtilis may prove to be as widespread as multiple sigma factors themselves, providing ways of coupling sigma factor activation to environmental or physiological signals that cannot be readily joined to other regulatory mechanisms.

Identification of flagellar synthesis regulatory and structural genes in a sigma D-dependent operon of Bacillus subtilis

The sigma D form of RNA polymerase from Bacillus subtilis has been shown previously to direct the synthesis of several transcription units bearing genes for flagellin, motility proteins, and autolysins. In this report, we describe an operon of genes transcribed from the sigma D-dependent promoter PD-1. We have identified three complete open reading frames and one partial one downstream of this promoter; immediately upstream is the previously identified comF locus. The PD-1 operon encodes the presumptive B. subtilis homologs of two Salmonella typhimurium late flagellar genes, flgM and flgK. Also present in this operon are two genes of unknown function, orf139 and orf160, whose products show similarities to the eukaryotic cytoskeletal proteins myosin and vimentin, respectively. orf139 and orf160 may encode proteins that form extended alpha-helical secondary structures and coiled-coil quaternary structures which may be filamentous components of the gram-positive bacterial flagellum. We have characterized the B. subtilis flgM gene further by constructing an in-frame deletion mutation, flgM delta 80, and creating strains of B. subtilis in which this allele has replaced the wild-type copy. By primer extension analysis of cellular RNA, we have shown that the flgM delta 80 mutation relieves the block to transcription of two other sigma D-dependent operons imposed by an unlinked mutation in a gene directing early flagellar synthesis. We conclude that, as in the case of S. typhimurium, early flagellar synthesis in B. subtilis is coupled to late flagellar synthesis through repression of sigma D-dependent transcription by the flgM gene product.

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.

An operon of Bacillus subtilis motility genes transcribed by the sigma D form of RNA polymerase

Two genes controlling motility functions in Bacillus subtilis were identified by DNA sequence analysis of a chromosomal fragment containing a strong promoter for sigma D RNA polymerase. Previous studies had shown that this sigma D-dependent promoter controls synthesis of a 1.6-kb transcript in vivo and in vitro. Sequence analysis revealed that the 1.6-kb transcript contains two open reading frames coding for protein sequences homologous to the Escherichia coli motA and motB gene products, respectively, and ends in a rho-independent termination site. Direct evidence linking these genes to motility functions in B. subtilis was obtained by precise localization by polymerase chain reaction of Tn917 transposon insertion mutations of Mot- strains, isolated by Zuberi et al. (A. R. Zuberi, C. Ying, H. M. Parker, and G. W. Ordal, J. Bacteriol. 172:6841-6848, 1990), to within this mot. operon. Replacement of each wild-type gene by in-frame deletion mutations yielded strains possessing paralyzed flagella and confirmed that both motA and motB are required for the motility of B. subtilis. These current findings support our earlier suggestions that sigma D in B. subtilis plays a central role in the control of gene expression for flagellar assembly, chemotaxis, and motility functions. Sigma F, the enteric homolog of sigma D, controls similar functions in E. coli and Salmonella typhimurium, and these factors appear to be representative of a family of factors implicated in flagellar synthesis in many bacterial species, which we propose to designate the sigma 28 family.

Alternative sigma factors and the regulation of flagellar gene expression

Synthesis of bacterial flagella and the accompanying array of chemotaxis receptors and transducers represents a major commitment of energy and resources for a growing bacterial cell and is subject to numerous levels of regulation. Genes for flagellar and chemotaxis proteins are expressed in a complex transcriptional cascade. This regulatory hierarchy acts to ensure that the highly expressed filament structural protein, flagellin, is synthesized only after a prerequisite set of structural proteins has been expressed and properly assembled. Recent evidence suggests that many bacteria utilize an alternative sigma (sigma) subunit, similar in specificity to the Bacillus subtilis sigma 28 protein, to direct transcription of flagellin, chemotaxis and motility genes. In Caulobacter crescentus and Campylobacter spp., both a sigma 54-like factor and a sigma 28-like factor participate in the transcription of flagellar and chemotaxis genes. Conversely, a sigma 28-like factor controls non-motility functions in at least one non-flagellated organism.

The Bacillus subtilis flagellin gene (hag) is transcribed by the sigma 28 form of RNA polymerase

The Bacillus subtilis gene hag, which codes for the flagellin structural protein, was identified by DNA sequence analysis in a collection of DNA fragments bearing in vitro promoters for the sigma 28 form of RNA polymerase. The hag gene and adjacent regions of the B. subtilis chromosome were restriction mapped, and the nucleotide sequence was determined. The hag gene was transcribed at all stages of growth from a single promoter that had sequences in the promoter recognition region characteristic of the consensus sequence for the sigma 28 holoenzyme. Transcription of hag was eliminated by insertion mutations that blocked synthesis of the sigma 28 protein. These findings provide strong support for the previous proposal that the sigma 28 form of RNA polymerase controls transcription of a regulon specifying flagellar, chemotaxis, and motility functions in B. subtilis (J. D. Helmann and M. J. Chamberlin, Proc. Natl. Acad. Sci. USA 84:6422-6424, 1987). The steady-state levels of hag mRNA increased during exponential growth and peaked as the B. subtilis cells entered the stationary phase. The transcript levels then decreased to zero within 4 h after the onset of sporulation. Hence, sigma 28 RNA polymerase function is temporally regulated.

Secondary sigma factor controls transcription of flagellar and chemotaxis genes in Escherichia coli

The genes specifying chemotaxis, motility, and flagellar function in Escherichia coli are coordinately regulated and form a large and complex regulon. Despite the importance of these genes in controlling bacterial behavior, little is known of the molecular mechanisms that regulate their expression. We have identified a minor form of E. coli RNA polymerase that specifically transcribes several E. coli chemotaxis/flagellar genes in vitro and is likely to carry out transcription of these genes in vivo. The enzyme was purified to near homogeneity based on its ability to initiate transcription of the E. coli tar chemotaxis gene at start sites that are used in vivo. Specific tar transcription activity is associated with a polypeptide of apparent 28-kDa molecular mass that remains bound to the E. coli RNA polymerase throughout purification. This peptide behaves as a secondary sigma factor--designated sigma F--because it restores specific tar transcription activity when added to core RNA polymerase. The sigma F holoenzyme also transcribes the E. coli tsr and flaAI genes in vitro as well as several Bacillus subtilis genes that are transcribed specifically by the sigma 28 form of B. subtilis RNA polymerase. The latter holoenzyme is implicated in transcription of flagellar and chemotaxis genes in B. subtilis. Hence E. coli sigma F holoenzyme appears to be analogous to the B. subtilis sigma 28 RNA polymerase, both in its promoter specificity and in the nature of the regulon it controls.

Characteristics of an RNA polymerase population isolated from Bacillus subtilis late in sporulation

The sigma-factor composition of Bacillus subtilis RNA polymerase alters during endospore formation. The best-documented change is the appearance of a major sporulation-specific sigma factor (sigma epsilon), which is an RNA polymerase subunit readily detected at 2 to 4 h into the 8-h sporulation process. To determine the nature of the RNA polymerase in differentiating cells after the period of sigma epsilon abundance, we isolated RNA polymerase from cells that were harvested at 6 h after the onset of sporulation. Highly purified fractions of RNA polymerase from these cells contained at least six proteins which cosedimented with core RNA polymerase (beta beta' alpha 2) during glycerol gradient centrifugation. Most of these proteins were in the size range of 20,000 to 29,000 daltons, although one 90,000-dalton protein was also evident. None of the putative RNA polymerase subunits were present in quantities similar to that observed for sigma epsilon during its period of prominence in the cell but instead resembled the minor vegetative-cell sigma factors in abundance. In vitro transcriptions using cloned B. subtilis DNAs as templates revealed at least two novel transcriptional activities in the enzyme that was isolated from cells at 6 h after the onset of sporulation but absent in an RNA polymerase preparation extracted from cells at 4 h after the onset of sporulation. One of these activities was reconstituted by the addition of a 25,000 to 27,000-dalton protein fraction to core RNA polymerase.

Isolation and characterization of the Bacillus subtilis sigma 28 factor

RNA polymerase preparations isolated from vegetatively growing Bacillus subtilis cells contain the core subunits beta, beta', and alpha, together with multiple sigma factors and other core-associated polypeptides such as delta, omega 1, and omega 2. We have developed an improved, large-scale purification procedure that yields RNA polymerase fractions enriched in both the sigma 28 and delta proteins. These fractions have been used to isolate sigma 28 protein for biochemical characterization and for preparation of highly specific anti-sigma 28 antisera. The amino acid composition of purified sigma 28 protein and the amino acid sequences of tryptic peptide fragments have been determined. Anti-sigma 28 antisera specifically inhibit transcription by the purified sigma 28 -dependent RNA polymerase, yet do not affect transcription by sigma 43 -dependent RNA polymerase. Immunochemical analysis confirms that the sigma 28 protein copurifies with total RNA polymerase activity through the majority of the purification procedure and allows the steps when sigma 28 protein is lost to be identified and optimized. Immunochemical techniques have also been used to monitor the structure and abundance of the sigma 28 protein in vivo. A single form of antibody-reactive protein was detected by two-dimensional gel electrophoresis-isoelectric focusing. Its abundance corresponds to a maximal content of 220 molecules of sigma 28 per B. subtilis cell during late-logarithmic-phase growth.

Two separable functional domains in the sigma-subunit of RNA polymerase in Bacillus subtilis?

The sigma-subunit of RNA polymerase is responsible for promoter recognition in prokaryotes [(1969) Nature 221, 43-46]. Alterations in the sigma-subunit are thought to be involved in controlling 'global' changes in gene expression, such as those involved in differentiation in the spore-forming bacterium Bacillus subtilis [(1981) Cell 25, 582-584]. Stragier et al. [(1985) FEBS Lett. 195, 3-11] have proposed that sigma-factors are composed of two domains: a C-terminal domain involved in promoter recognition and an N-terminal domain involved in interactions with RNA polymerase. We have sequenced another developmental gene from B. subtilis, spoIIIC, and the strong homology of its predicted product suggests that it too may be a sigma-factor. However, the spoIIIC product is small and lacks completely the conserved N-terminal domain of the sigma-subunits. I propose that the product of the spoIIIC gene may carry out the DNA-recognition functions of a sigma-factor but that it probably requires an auxiliary factor to interact with core RNA polymerase.

DNA sequence analysis suggests that expression of flagellar and chemotaxis genes in Escherichia coli and Salmonella typhimurium is controlled by an alternative sigma factor

Biosynthesis of bacterial flagella involves the coordinated expression of 30 or more genes in several separate operons. We have recently shown that in Bacillus subtilis, the sigma 28 factor is essential for flagellar synthesis, suggesting that transcription of these genes is directly under the control of this alternative sigma factor. In enteric bacteria structural genes for flagellar, chemotaxis, and motility operons appear to be under coordinate control, however, the nature of the regulatory factors has not been determined. Sequence analysis of many such genes has failed to reveal plausible promoter sequences for the predominant bacterial RNA polymerase, and several such genes are not transcribed effectively in vitro by the Escherichia coli sigma 70 RNA polymerase. However, all of the sequenced flagellar, chemotaxis, and motility operons from the enteric bacteria are preceded by DNA sequences highly homologous to B. subtilis sigma 28 promoters. We propose that an alternative sigma factor controls expression of the flagellar regulon in both B. subtilis and in the enteric bacteria.

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

The pleiotropic stage 0 sporulation locus spo0E was isolated and sequenced. The spo0E gene was found to code for a protein of 9791 molecular weight. Two spo0E mutations were identified by sequence analysis and were found to give rise to nonsense codons within the gene. The results indicated that it is the lack of the spo0E gene product that is responsible for the sporulation-defective phenotype. The DNA fragment containing the spo0E locus was inhibitory to sporulation when present on a multicopy plasmid. Since DNA fragments containing only the upstream region of the gene were also inhibitory, this effect was not due to over-production of the spo0E gene product. Coupling the transcription of the spo0E gene to beta-galactosidase in an integrative plasmid vector revealed that active transcription of this gene begins at the end of exponential growth and continues through the early part of sporulation. Studies of the regulation of this gene have allowed the generation of a hypothesis to explain the interactions of those five stage 0 genes involved in the activation of sporulation-specific transcription.

Nucleotide sequence of the outB locus of Bacillus subtilis and regulation of its expression

The outB gene is one of the genes involved in the process of spore outgrowth in Bacillus subtilis. The gene has been cloned in bacteriophage lambda and subcloned in plasmids. We have determined the sequence of 2,553 base pairs around the outB locus. The locus was found to code for a protein of about 30,000 daltons. Analysis of the in vivo transcripts from this region by RNase protection experiments revealed the presence of two start sites for transcription. Two potential promoters for these transcripts can be tentatively assigned from the sequence data. The amount of one transcript is highest during outgrowth and vegetative growth and absent during the stationary phase. The second transcript is present at a low level throughout the cell cycle.

Gene encoding the 37,000-dalton minor sigma factor of Bacillus subtilis RNA polymerase: isolation, nucleotide sequence, chromosomal locus, and cryptic function

We began an analysis of rpoF, the gene encoding the cryptic, 37,000-dalton minor sigma factor (sigma-37) of Bacillus subtilis RNA polymerase. Using antibody raised against sigma-37 holoenzyme to probe a lambda gt11 expression vector library, we isolated a 901-base-pair EcoRI fragment that expressed the COOH-terminal half of sigma-37 fused to lacZ. We used this fragment as a hybridization probe to isolate the entire rpoF gene and additional flanking sequences. Identity of the cloned gene was confirmed by the size and immunological reaction of its product expressed in Escherichia coli and, after DNA sequencing, by the homology of its predicted product (264 residues; 30,143 daltons) with other sigma factors. The DNA sequence also suggested that rpoF may lie in a gene cluster. Upstream of rpoF was an open reading frame that would encode a protein of 17,992 daltons; this frame overlapped the rpoF-coding sequence by 41 base pairs. Immediately following rpoF was a reading frame that would encode a protein of at least 20,000 daltons; expression of this region may be translationally coupled to that of rpoF. By plasmid integration and PBS1 transduction, we found the chromosomal locus of rpoF linked to ddl and dal at 40 degrees on the B. subtilis map and near no known lesions affecting growth regulation or development. Further, an rpoF null mutation resulting from gene disruption had no effect on cell growth or sporulation in rich medium, suggesting that sigma-37 may partly control a regulon not directly involved in the sporulation process.

New RNA polymerase sigma factor under spo0 control in Bacillus subtilis

In Bacillus subtilis transcription of spoVG is activated within minutes after the initiation of sporulation. Mutations in several spo0 genes prevent the activation of spoVG transcription. We have found a sigma-like protein that is capable of directing core RNA polymerase to use the spoVG promoter in an in vitro run-off transcription assay. This sigma-like protein was not found to be associated with RNA polymerase in a spo0A or spo0B mutant but was present in a spo0H mutant. We suggest that one role of the spo0A gene product in transcription of spoVG is the modulation of RNA polymerase activity by this sigma-like protein.

Gene encoding the sigma 37 species of RNA polymerase sigma factor from Bacillus subtilis

sigma 37 is a minor species of RNA polymerase sigma factor found in the Gram-positive bacterium Bacillus subtilis. sigma 37 governs the transcription in vitro of genes that are turned on at an early stage in spore formation, as well as other genes that are switched on at the end of the exponential phase of growth but that are not under sporulation control. To study the role of sigma 37 in B. subtilis gene expression, we have cloned the gene for this minor species of sigma factor in Escherichia coli by using as a hybridization probe a synthetic oligonucleotide that was designed on the basis of the NH2-terminal amino acid sequence of sigma 37 protein. We determined the nucleotide sequence of the entire sigma 37 gene, which was found to encode a 262-amino acid residue polypeptide of 29.9 kDa. The predicted amino acid sequence of sigma 37 showed significant homology to that of other sigma proteins in a region that has been proposed to be the site of binding of these factors to core RNA polymerase. Genetic mapping experiments placed the gene for sigma 37, herein designated sigB, at 40 degrees on the genetic map of Piggot and Hoch [Piggot, P. & Hoch, J. A. (1985) Microbiol. Rev. 49, 158-179]. An insertion mutation was constructed in sigB and found not to impair growth or sporulation.

Isolation of Bacillus subtilis genes transcribed in vitro and in vivo by a major sporulation-induced, DNA-dependent RNA polymerase

As a means of determining the function of sigma 29, a sporulation-essential sigma factor, we have isolated and begun to characterize genes that require sigma 29 for their expression. RNA transcribed in vitro from total Bacillus subtilis DNA by using sigma 29-containing RNA polymerase (E-sigma-29) was hybridized to a bank of B. subtilis DNA fragments that had been cloned into bacteriophage lambda. Approximately 0.25% of the cloned B. subtilis DNA fragments displayed detectable hybridization with our RNA probe. Five DNA fragments that had strong in vitro template activity for E-sigma-29 were selected for further study. The DNA fragments which contained in vitro sigma 29 promoter activity encoded RNAs that were synthesized by B. subtilis during sporulation. Mutant B. subtilis that failed to synthesize sigma 29 (spoIIA, spoIIE) made less RNA that could hybridize to these cloned DNAs than did a mutant (spoIIC) which did synthesize sigma 29 but was blocked at a similar stage in development. A detailed analysis of several of the cloned DNAs demonstrated that they encoded RNAs that were transcribed from approximately the same start site in vivo that E-sigma-29 initiated transcription in vitro. These particular transcripts were present only during the period of sigma-29 abundance (2 to 4 h after the onset of sporulation) in sporulating cells which carried a wild-type allele of the sigma-29 structural gene (spoIIG). We conclude that the isolation procedure used in this study identified genes that are transcribed by E-sigma 29, not only in vitro but also in vivo. Preliminary characterization of the cloned genes indicate that they encoded multiple overlapping RNAs which were each synthesized at unique times during growth or sporulation. This result implies that sigma 29 does not activate a unique population of genes with a novel function in sporulation but rather that it has a temporal role in spore gene control, transcribing those genes required to be active during its period of abundance regardless of their specific function.

Sigma 29-like protein is a common sporulation-specific element in bacteria of the genus Bacillus

A monoclonal antibody specific for an antigenic determinant on the Bacillus subtilis sporulation-induced sigma factor sigma 29 reacted with proteins similar in size to sigma 29 in extracts of sporulating Bacillus licheniformis, Bacillus amyloliquifaciens, Bacillus cereus, Bacillus natto, and Bacillus pumilus but not in extracts prepared from vegetatively growing cultures of these bacteria. These results indicate that RNA polymerase modifications, initially described for B. subtilis, are likely to be common among sporulating Bacillus spp. and that at least some of the specific modifications that are observed in sporulating B. subtilis are conserved among members of this genus.

Bacillus subtilis citB gene is regulated synergistically by glucose and glutamine

The activity of aconitase in Bacillus subtilis is greatly reduced in cells cultured in media containing rapidly metabolized carbon sources (e.g., glucose). Thus, expression of this enzyme appears to be subject to a form of catabolite repression. Since the product of the citB gene of B. subtilis is required for aconitase activity, we cloned the wild-type allele of this gene and used this DNA as a probe for transcription of citB in cells grown in various media. The steady-state level of RNA that hybridized to this probe was about 10-fold higher in B. subtilis cells grown in citrate-glutamine medium than in cells grown in glucose-glutamine medium. This result correlates well with the steady-state levels of aconitase activity. Two transcripts were shown to initiate within the cloned DNA; the steady-state level of one of these transcripts varied in the same way as did aconitase activity when cells were grown in media containing different carbon sources. This is the first demonstration of regulation by the carbon source of the level of a vegatative-cell transcript in B. subtilis.

Genetic mapping of rpoD implicates the major sigma factor of Bacillus subtilis RNA polymerase in sporulation initiation

We have mapped the chromosomal locus of rpoD, which encodes the major sigma factor of Bacillus subtilis RNA polymerase. The rpoD locus lay between aroD and lys, tightly linked to dnaE and inseparable from crsA. Marker order in this region was acf-aroD-dnaE-rpoD(crsA)-spoOG-lys. By transformation using cloned donor DNA from the rpoD region, we identified the gene immediately upstream of rpoD as dnaE, which coded for a 62,000 dalton protein essential for DNA replication. Both dnaE and rpoD were transcribed in the same direction, counterclockwise on the chromosome. The gene functions and organization in the rpoD region are thus similar to those of the E. coli sigma operon. We also used transformation to identify crsA47 as a mutation within the sigma coding region itself. The crsA alteration of sigma renders the sporulation process insensitive to glucose catabolite repression, and also restores sporulation ability to strains carrying early-blocked spoOE, spoOF, and spoOK mutations. Thus the major sigma factor and these spoO gene products directly or indirectly affect the same cellular function.

New Ways to Study Developmental Genes in Spore-Forming Bacteria

The regulated activation of numerous sets of genes in multiple chromosomal locations is a hallmark of cellular differentiation in both eukaryotes and prokaryotes. Certain species of bacteria that experience complex developmental cycles are especially attractive as systems in which to study the mechanisms of this kind of gene regulation because they are highly amenable to both biochemical and genetic approaches. Bacillus subtilis, which undergoes extensive cellular differentiation when it sporulates, is one such system. Many new methods are now available in this Gram-positive species for identifying, manipulating, and studying the regulation of genes involved in spore formation, including the use of transposable genetic elements that create gene fusions in vivo as an automatic consequence of insertions into genes.

Isolation of Bacillus subtilis mutants altered in expression of a gene transcribed in vitro by a minor form of RNA polymerase (E-sigma 37)

To develop a technique for identifying Bacillus subtilis genes whose products affect transcription from promoters recognized by sigma 37-containing RNA polymerase (E-sigma 37), we cloned the promoter region of a gene (ctc) that is actively transcribed in vitro by E-sigma 37 into a plasmid (pPL603B) so that a transcriptional fusion was created between ctc and a plasmid-borne chloramphenicol acetyltransferase (CAT) gene. CAT levels in B. subtilis carrying the ctc/CAT fusion plasmid varied in a manner that was consistent with the known pattern of ctc RNA synthesis. Mutagenesis of cells harboring the ctc/CAT plasmid led to the isolation of bacterial clones which displayed altered chloramphenicol resistance. Analysis of the mutants demonstrated that CAT activity was substantially changed in the mutant cells. Several of the B. subtilis mutants, both CAT overproducers and underproducers, also had acquired a sporulation-deficient phenotype. The mutations responsible for altered CAT expression were not carried on the plasmid. Analysis of RNA synthesized by mutant cells indicates that at least a portion of the mutants may be altered in the level of transcription from the ctc promoter and, hence, are likely to define B. subtilis genes which influence this process.

Synthesis of sigma 29, an RNA polymerase specificity determinant, is a developmentally regulated event in Bacillus subtilis

Using an immunological probe, we have determined that the synthesis of the Bacillus subtilis RNA polymerase promoter specificity determinant sigma 29 is a developmentally regulated event. sigma 29 is absent from vegetatively growing cells but is abundant in sporulating cells for a restricted (2-h) period during differentiation (hour 2 to hour 4 into the sporeforming process). The narrowness of this period suggests that sigma 29 is a regulatory factor that directs the transcription of a subpopulation of genes at a precise, intermediate stage of spore formation. This view predicts that sigma 29 should be dispensable for early sporulation events. We verified this prediction by an analysis of sigma 29 accumulation in mutants that are blocked at different stages of sporulation in which we show that cells can advance to at least an intermediate point in development (stage III) in the absence of detectable sigma 29. Lastly, our anti-sigma 29 antibody probe detected a second, previously unrecognized protein in Bacillus cell extracts that may be a precursor to sigma 29. This protein, P31 (molecular weight, 31,000) is synthesized earlier in sporulation than is sigma 29. It has a peptide profile that is similar to sigma 29 and is present in all Bacillus subtilis Spo- mutants that were tested and found to still be able to accumulate sigma 29.

Selective expression of a plasmid cat gene at a late stage of Bacillus subtilis sporulation

The cat-86 gene in plasmid pPL603 specifies chloramphenicol acetyltransferase (CAT) and is selectively expressed in Bacillus subtilis at a stage in sporulation in which internal spores are first observed (approximately T8). The gene is unexpressed in vegetatively growing cells. cat-86 expression and spore formation are both blocked when cells are grown in excess glucose. cat-86 expression at T8 is due to selective transcription of the gene, since cat-86 mRNA is undetectable in vegetatively growing cells but is readily demonstrated in sporulating cells. The transcription start site for cat-86 mRNA from sporulating cells is within a 203-base-pair restriction fragment designated P1, which is located upstream from the cat coding region on pPL603 . Deletion of P1 from pPL603 eliminates the sporulation -associated expression of cat-86. Host sporulation genes, whose function is absolutely required for cat-86 expression at T8, include six early sporulation, spo0 , genes and spoIIE . Therefore, pPL603 provides a novel system in which the in vivo expression of a known, plasmid-linked gene is dependent on sporulation-specific changes in B. subtilis.

In vitro transcription of the Bacillus subtilis phage phi 29 DNA by Bacillus subtilis and Escherichia coli RNA polymerases

The Escherichia coli RNA polymerase bound to phage phi 29 DNA has been visualized by electron microscopy. Thirteen specific binding sites have been observed at 1.7,2.6,5.5,10.4,13.7,25.2,25.7,26.3,33.5,59.5,69.2,91.7 and 99.6 DNA length units and they have been named A1,A1I,A1II,A1III,A1IV,A2,A2I, A3, A4,B1,B1I,C1 and C2, respectively. The binding sites A1,A2,A3,B1,C1 and C2 coincide with those found with Bacillus subtilis RNA polymerase. The transcription of phage phi 29 DNA with B. subtilis or E. coli RNA polymerases has been studied. With the B. subtilis RNA polymerase eight transcripts were found, starting at positions corresponding to the binding sites A1, A1III, A2,A3,B1I,B2,C1 and C2, respectively. With the E. coli RNA polymerase the same transcripts were found and a new one starting at position corresponding to the A4 binding site. The RNAs starting at binding sites A1,A1III,A2,B1I, B2,C1 and C2 are transcribed from right to left, as expected for early RNA. The RNAs which initiate at positions A3 and A4 are transcribed from left to right and probably correspond to late RNAs.

The subtilisin E gene of Bacillus subtilis is transcribed from a sigma 37 promoter in vivo

A cloned Bacillus subtilis gene (sprE) expressed only during the stationary growth phase is shown to encode the subtilisin E protease, an enzyme associated with sporulation. We have determined the DNA sequence of the sprE promoter region and the promoter-proximal half of the structural gene. The sprE gene codes for a putative 29-residue signal peptide and a 77-residue leader peptide preceding the mature subtilisin sequence. By plasmid integration and phage PBS1 transduction, we have mapped the sprE locus between glyB and metD on the B. subtilis chromosome, a region also containing the hyperprotease-producing hpr gene. In vitro the sprE gene is transcribed by the minor form of RNA polymerase containing a 37,000-dalton sigma factor (sigma 37). We show by S1 nuclease mapping that sprE transcription initiates at dual start sites both in vitro and in vivo and that the promoter for the downstream site has a characteristic sigma 37 recognition sequence. We propose that the physiological role of the sigma 37 RNA polymerase is to transcribe a class of genes that are catabolite repressed, that encode extracellular enzymes, or that are expressed only during the stationary phase of growth.

Restriction fragments that exert promoter activity during postexponential growth of Bacillus subtilis

Two restriction fragments of Bacillus subtilis DNA were identified which caused the cat-86 gene present on the promoter cloning plasmid pPL703 to be activated predominantly during postexponential growth of host cells. The postexponential increase was observed in both sporulation-positive strains and in a spoOA mutant of B. subtilis. However, the postexponential increase in the cat-86 gene product, chloramphenicol acetyltransferase, was diminished or not observed when the plasmid-containing cells were grown in the presence of excess glucose. The promoter-containing fragment, designated as 33, was mapped to a site on the B. subtilis chromosome adjacent to hisA. The other fragment, 14, mapped to a site adjacent to ctrA. When present on a high-copy vector, both fragments caused a reduction in the sporulation frequency of host cells. Fragment 33 in high copy number conferred on B. subtilis cells three additional phenotypic changes: brown colony color, intracellular inclusions, and, in a protease-deficient mutant, the production of extracellular protease activity. These activities were observed only in postexponential-phase cultures.

A temporally regulated promoter from Bacillus subtilis is transcribed only by an RNA polymerase with a 37,000 dalton sigma factor

A 1,250 base pair Bacillus subtilis chromosomal HindIII restriction fragment (S fragment) has been cloned into the B. subtilis expression-probe plasmid pGR71. The S fragment induces the expression of the pGR71 chloramphenicol resistance gene shortly after the initiation of sporulation. The transcriptional promoter responsible for the expression of this temporally regulated genetic element has been identified and mapped in vitro. This promoter is recognized exclusively by the minor B. subtilis RNA polymerase that contains the 37,000 dalton sigma factor.

Isolation and physical mapping of the gene encoding the major sigma factor of Bacillus subtilis RNA polymerase

At least four sigma factors separately bind the Bacillus subtilis RNA polymerase core (beta beta' alpha 2), each conferring a different promoter specificity on the holoenzyme in vitro. Using the Broome-Gilbert immunological screening, we isolated recombinant lambda phages that carry rpoD, the gene for the most abundant sigma factor, sigma 55. These phages encode a 55,000-dalton protein whose size, immunological properties, and peptide map identify it as sigma 55. All the phages have in common two adjacent 3.5-kilobase EcoRI fragments from the B. subtilis chromosome; most carry additional genomic DNA. Deletion analysis localized rpoD to a 1.6-kilobase region, suggested the direction of its transcription, and found two additional genes near rpoD, which code for proteins of 62,000 and 17,000 daltons.

Early sporulation gene spo0F: nucleotide sequence and analysis of gene product

We have determined the sequence of a 1,162-base-pair DNA fragment containing a spo0F gene which is required for an early stage of sporulation in Bacillus subtilis. The sequence has only one long open reading frame consisting of 173 codons, which has been confirmed to be the spo0F cistron by DNA-mediated transformation and in vitro transcription. In UV-irradiated "maxicells" containing pUBSF13, the plasmid that carries cloned spo0F gene, we have observed the synthesis of a 20-kilodalton polypeptide that is absent from cells carrying a vector plasmid pUB110. The molecular weight of this protein is in agreement with the calculated molecular weight of the spo0F gene product (Mr, 19,065). The putative promoter sequences of spo0F gene were 5' T-A-T-A-A-T 3' at -10 and 5' T-T-G-A-T-T 3' at -35. An octamer sequence, 5' A-A-A-G-G-A-G-G 3', situated 8 base pairs prior to the initiation codon was found to be perfectly complementary with the 3' end of 16S ribosomal RNA. This result offers additional evidence for the proposal by Rabinowitz's group that an extensive mRNA-rRNA interaction is a requirement for efficient translation by B. subtilis ribosomes.