Interaction of a Putative Repressor Protein with an Extended Control Region of the Bacillus subtilis pur Operon

The nucleotide messenger (p)ppGpp is an anti-inducer of the purine synthesis transcription regulator PurR in Bacillus

The nucleotide messenger (p)ppGpp allows bacteria to adapt to fluctuating environments by reprogramming the transcriptome. Despite its well-recognized role in gene regulation, (p)ppGpp is only known to directly affect transcription in Proteobacteria by binding to the RNA polymerase. Here, we reveal a different mechanism of gene regulation by (p)ppGpp in Firmicutes: (p)ppGpp directly binds to the transcription factor PurR to downregulate purine biosynthesis gene expression upon amino acid starvation. We first identified PurR as a receptor of (p)ppGpp in Bacillus anthracis. A co-structure with Bacillus subtilis PurR reveals that (p)ppGpp binds to a PurR pocket reminiscent of the active site of phosphoribosyltransferase enzymes that has been repurposed to serve a purely regulatory role, where the effectors (p)ppGpp and PRPP compete to allosterically control transcription. PRPP inhibits PurR DNA binding to induce transcription of purine synthesis genes, whereas (p)ppGpp antagonizes PRPP to enhance PurR DNA binding and repress transcription. A (p)ppGpp-refractory purR mutant in B. subtilis fails to downregulate purine synthesis genes upon amino acid starvation. Our work establishes the precedent of (p)ppGpp as an effector of a classical transcription repressor and reveals the key function of (p)ppGpp in regulating nucleotide synthesis through gene regulation, from soil bacteria to pathogens.

Rational engineering of transcriptional riboswitches leads to enhanced metabolite levels in Bacillus subtilis

Many metabolic pathways in bacteria are regulated by metabolite sensing riboswitches that exert their control at the level of transcription employing a termination-antitermination mechanism. These riboswitches represent engineering targets to modulate expression of genes and operons relevant for the biotechnological production of commercially relevant compounds. We show that removal of the transcriptional riboswitches that control purine biosynthesis and riboflavin biosynthesis in Bacillus subtilis leads to auxotrophic strains. As an alternative, we report a rational approach for engineering transcriptional riboswitches independently from the availability of structural data. This approach consists in the identification and deletion of a key nucleotide sequence exclusively involved in transcription termination without affecting formation of other secondary and tertiary structures, which can be involved in other functions. To demonstrate the efficacy of our approach, we tested it with regard to deregulation of the purine and the riboflavin biosynthetic pathways in B. subtilis. Following validation of the engineered transcriptional riboswitches using specialized reporter strains, our approach was implemented into a B. subtilis wild-type strain employing CRISPR-Cas9 genome editing. The resulting purine and riboflavin production strains were characterized at the level of gene expression, metabolite synthesis and growth, and a substantial enhancement was measured at each level. Moreover, applying our approach to deregulate the purine pathway of an industrial riboflavin overproducing strain with impaired growth led to an increase in biomass by 53%, which resulted in an enhanced total production of riboflavin in the culture.

Postgenomic analysis of streptococcus thermophilus cocultivated in milk with Lactobacillus delbrueckii subsp. bulgaricus: involvement of nitrogen, purine, and iron metabolism

Streptococcus thermophilus is one of the most widely used lactic acid bacteria in the dairy industry, in particular in yoghurt manufacture, where it is associated with Lactobacillus delbrueckii subsp. bulgaricus. This bacterial association, known as a proto-cooperation, is poorly documented at the molecular and regulatory levels. We thus investigate the kinetics of the transcriptomic and proteomic modifications of S. thermophilus LMG 18311 in response to the presence of L. delbrueckii subsp. bulgaricus ATCC 11842 during growth in milk at two growth stages. Seventy-seven different genes or proteins (4.1% of total coding sequences), implicated mainly in the metabolism of nitrogen (24%), nucleotide base (21%), and iron (20%), varied specifically in coculture. One of the most unpredicted results was a significant decrease of most of the transcripts and enzymes involved in purine biosynthesis. Interestingly, the expression of nearly all genes potentially encoding iron transporters of S. thermophilus decreased, whereas that of iron-chelating dpr as well as that of the fur (perR) regulator genes increased, suggesting a reduction in the intracellular iron concentration, probably in response to H(2)O(2) production by L. bulgaricus. The present study reveals undocumented nutritional exchanges and regulatory relationships between the two yoghurt bacteria, which provide new molecular clues for the understanding of their associative behavior.

Lipase expression in Pseudomonas alcaligenes is under the control of a two-component regulatory system

Preliminary observations in a large-scale fermentation process suggested that the lipase expression of Pseudomonas alcaligenes can be switched on by the addition of certain medium components, such as soybean oil. In an attempt to elucidate the mechanism of induction of lipase expression, we have set up a search method for genes controlling lipase expression by use of a cosmid library containing fragments of P. alcaligenes genomic DNA. A screen for lipase hyperproduction resulted in the selection of multiple transformants, of which the best-producing strains comprised cosmids that shared an overlapping genomic fragment. Within this fragment, two previously unidentified genes were found and named lipQ and lipR. Their encoded proteins belong to the NtrBC family of regulators that regulate gene expression via binding to a specific upstream activator sequence (UAS). Such an NtrC-like UAS was identified in a previous study in the P. alcaligenes lipase promoter, strongly suggesting that LipR acts as a positive regulator of lipase expression. The regulating role could be confirmed by down-regulated lipase expression in a strain with an inactivated lipR gene and a threefold increase in lipase yield in a large-scale fermentation when expressing the lipQR operon from the multicopy plasmid pLAFR3. Finally, cell extracts of a LipR-overexpressing strain caused a retardation of the lipase promoter fragment in a band shift assay. Our results indicate that lipase expression in Pseudomonas alcaligenes is under the control of the LipQR two-component system.

Mutations in PurBox1 of the Bacillus subtilis pur operon control site affect adenine-regulated expression in vivo

Transcription of the Bacillus subtilis pur operon is regulated by a purine repressor (PurR)-DNA control site interaction. The pur operon control site has two PurBoxes that are required for high-affinity PurR binding. An upstream, strong-binding PurBox1 is at position -81 to -68 relative to the transcription start site and a downstream weak-binding PurBox2 is at position -49 to -36. We constructed three PurBox1 mutations and the effects on binding of PurR to the control region in vitro and on regulation of pur operon expression in vivo were investigated. The mutations significantly reduced the binding of PurR to control region DNA. In strains with G-75A, G-75T and a five bp deletion (delta5) pur operon repression was defective in vivo. In addition in vivo PurR titration was used to confirm that sequences flanking PurBox1 and PurBox2 are required for PurR binding to the puroperon control site.

Interaction between ArgR and AhrC controls regulation of arginine metabolism in Lactococcus lactis

The expression of arginine metabolism in Lactococcus lactis is controlled by the two homologous transcriptional regulators ArgR and AhrC. Genome sequence analyses have shown that the occurrence of multiple homologues of the ArgR family of transcriptional regulators is a common feature of many low-G + C Gram-positive bacteria. Detailed studies of ArgR type regulators have previously only been carried out in bacteria containing single regulators. Here, we present a first characterization of the two L. lactis arginine regulators by means of gel retardation and DNase I footprinting. ArgR of L. lactis was shown to bind to the promoter regions of both the arginine biosynthetic argCJDBF operon and the arginine catabolic arcABD1C1C2TD2yvaD operon, but in an arginine-independent manner. Surprisingly, AhrC alone was unable to bind to DNA. Arginine-dependent DNA binding was obtained by mixing the two regulators in gel retardation assays. With both regulators present, the addition of arginine led to increased binding of ArgR-AhrC to the biosynthetic argC promoter but also to diminished binding to the catabolic arcA promoter. Footprinting showed ArgR-AhrC protection of regions containing ARG box operator sequences preceding argC. In the absence of AhrC, ArgR protected sites in the arcA promoter region with similarity to ARG box half-sites, here called ARC boxes. We propose a model for repression of arginine biosynthesis and activation of catabolism by anti-repression, involving arginine-dependent interaction between the two L. lactis regulator proteins, ArgR and AhrC.

Probing direct interactions between CodY and the oppD promoter of Lactococcus lactis

CodY of Lactococcus lactis MG1363 is a transcriptional regulator that represses the expression of several genes encoding proteins of the proteolytic system. These genes include pepN, pepC, opp-pepO1, and probably prtPM, pepX, and pepDA2, since the expression of the latter three genes relative to nitrogen availability is similar to that of the former. By means of in vitro DNA binding assays and DNase I footprinting techniques, we demonstrate that L. lactis CodY interacts directly with a region upstream of the promoter of its major target known so far, the opp system. Our results indicate that multiple molecules of CodY interact with this promoter and that the amount of bound CodY molecules is affected by the presence of branched-chain amino acids and not by GTP. Addition of these amino acids strongly affects the extent of the region protected by CodY in DNase I footprints. Random and site-directed mutagenesis of the upstream region of oppD yielded variants that were derepressed in a medium with an excess of nitrogen sources. Binding studies revealed the importance of specific bases in the promoter region required for recognition by CodY.

Functional dissection of the Bacillus subtilis pur operator site

Bacillus subtilis PurR represses transcription of several genes involved in purine synthesis, metabolism, and transport and cofactor synthesis. PurR binds specifically to DNAs containing an inverted repeat of a 14-nucleotide "PurBox" located in the upstream control regions of genes in the PurR regulon. Further biochemical investigation of the interaction of PurR with a series of shortened upstream DNA fragments of the pur operon determined the minimum length and specificity elements of the operator. The relative affinities of the two PurBoxes differ significantly, such that upstream PurBox1 (-81 to -68 relative to the transcription start site) is designated "strong" and downstream PurBox2 (-49 to -36) is designated "weak." Two PurBoxes are required for high-affinity PurR binding, and one of these must be strong. The shortest DNA construct with high affinity for PurR is a 74-bp perfect palindrome in which weak PurBox2 and its flanking sequences are replaced by strong PurBox1 and flanking sequences. Two PurR dimers bind to this symmetric construct. Phosphoribosylpyrophosphate (PRPP), the effector molecule that reduces affinity of PurR for DNA, requires one weak PurBox in the DNA construct to inhibit PurR binding. PRPP binds, as expected, to a PRPP-motif in PurR. A tracks outside the central conserved CGAA sequence of the PurBox may facilitate DNA bending, leading to a proposal for strong and weak designations of PurBoxes in the control regions of other genes regulated by PurR.

The purine repressor of Bacillus subtilis: a novel combination of domains adapted for transcription regulation

The purine repressor from Bacillus subtilis, PurR, represses transcription from a number of genes with functions in the synthesis, transport, and metabolism of purines. The 2.2-A crystal structure of PurR reveals a two-domain protein organized as a dimer. The larger C-terminal domain belongs to the PRT structural family, in accord with a sequence motif for binding the inducer phosphoribosylpyrophosphate (PRPP). The PRT domain is fused to a smaller N-terminal domain that belongs to the winged-helix family of DNA binding proteins. A positively charged surface on the winged-helix domain likely binds specific DNA sequences in the recognition site. A second positively charged surface surrounds the PRPP site at the opposite end of the PurR dimer. Conserved amino acids in the sequences of PurR homologs in 21 gram-positive bacteria cluster on the proposed recognition surface of the winged-helix domain and around the PRPP binding site at the opposite end of the molecule, supporting a common function of DNA and PRPP binding for all of the proteins. The structure supports a binding mechanism in which extended regions of DNA interact with extensive protein surface. Unlike most PRT proteins, which are phosphoribosyltransferases (PRTases), PurR lacks catalytic activity. This is explained by a tyrosine side chain that blocks the site for a nucleophile cosubstrate in PRTases. Thus, B. subtilis has adapted an enzyme fold to serve as an effector-binding domain and has used it in a novel combination with the DNA-binding winged-helix domain as a repressor of purine genes.

Transcriptional regulation and signature patterns revealed by microarray analyses of Streptococcus pneumoniae R6 challenged with sublethal concentrations of translation inhibitors

The effects of sublethal concentrations of four different classes of translation inhibitors (puromycin, tetracycline, chloramphenicol, and erythromycin) on global transcription patterns of Streptococcus pneumoniae R6 were determined by microarray analyses. Consistent with the general mode of action of these inhibitors, relative transcript levels of genes that encode ribosomal proteins and translation factors or that mediate tRNA charging and amino acid biosynthesis increased or decreased, respectively. Transcription of the heat shock regulon was induced only by puromycin or streptomycin treatment, which lead to truncation or mistranslation, respectively, but not by other antibiotics that block translation, transcription, or amino acid charging of tRNA. In contrast, relative transcript amounts of certain genes involved in transport, cellular processes, energy metabolism, and purine nucleotide (pur) biosynthesis were changed by different translation inhibitors. In particular, transcript amounts from a pur gene cluster and from purine uptake and salvage genes were significantly elevated by several translation inhibitors, but not by antibiotics that target other cellular processes. Northern blotting confirmed increased transcript amounts from part of the pur gene cluster in cells challenged by translation inhibitors and revealed the presence of a 10-kb transcript. Purine metabolism genes were negatively regulated by a homologue of the PurR regulatory protein, and full derepression in a DeltapurR mutant depended on optimal translation. Unexpectedly, hierarchical clustering of the microarray data distinguished among the global transcription patterns caused by antibiotics that inhibit different steps in the translation cycle. Together, these results show that there is extensive control of transcript amounts by translation in S. pneumoniae, especially for de novo purine nucleotide biosynthesis. In addition, these global transcription patterns form a signature that can be used to classify the mode of action and potential mechanism of new translation inhibitors.

Regulation of production of the antifungal metabolite 2,4-diacetylphloroglucinol in Pseudomonas fluorescens F113: genetic analysis of phlF as a transcriptional repressor

The antifungal metabolite 2,4-diacetylphloroglucinol plays a major role in the biocontrol capabilities of Pseudomonas fluorescens. The phloroglucinol biosynthetic locus of P. fluorescens F113 has been isolated previously. From nucleotide sequence data, a putative regulator gene (phlF) was identified upstream and divergently transcribed from the phlACBD phloroglucinol biosynthetic genes. PhlF shows similarity to various transcriptional repressors in the EMBL database and exhibits a helix-turn-helix motif in its amino acid sequence. phlF was cloned into an expression vector and the PhlF protein product was purified. Gel retardation experiments demonstrated PhlF to be a DNA-binding protein and showed that it binds to the phlA-phlF intergenic region. Introduction of phlF into P. fluorescens F113 in multiple copies resulted in repression of phloroglucinol production in this strain. This effect was mediated at the transcription level since the expression of a phloroglucinol biosynthetic gene fusion in this background was equally repressed. Furthermore, the inactivation of phlF results in derepression of phloroglucinol production in this strain.

Interaction of a repressor and its binding sites for regulation of the Bacillus subtilis iol divergon

Transcription of the Bacillus subtilis iol divergon is negatively regulated by a repressor encoded by iolR, which belongs to the DeoR family of bacterial regulators. Gel retardation analysis involving the IolR protein synthesized in Escherichia coli revealed that IolR bound specifically and independently to each of the iol and iolRS promoter regions, with higher affinity to iol. DNase I footprinting revealed that IolR affected DNase I sensitivity either in the iol promoter region between nucleotides -46 and +51 or in iolRS between -79 and -2 (+1 is the transcription initiation nucleotide of both iol and iolRS), indicating its interaction with the extended regions of the iol and iolRS promoters. Deletion analysis indicated that the iol region between -23 and +21 is involved mainly in IolR binding and negative regulation, while the iolRS region between -70 and -44 comprises at least part of the cis-acting sequences for IolR binding and negative regulation. Sequence examination of the extended regions revealed that a tandem direct repeat consisting of two relatively conserved 11-mer sequences, WRAYCAADARD (where D is A, G or T; R is A or G; W is A or T; and Y is C or T), found in each of the iol and iolRS regions might be a determinant sequence for the IolR-DNA interaction. Actual involvement of the direct repeats in the IolR-DNA interaction was shown by the deficiency of IolR-binding and negative regulation that was caused by substitution of the conserved bases within the conserved sequences. These results imply a unique mode of interaction of IolR with the target DNA.

Cloning and expression of the Lactococcus lactis purDEK genes, required for growth in milk

An operon containing the genes purD and purE and part of the purK gene was cloned from the facultative anaerobic gram-positive bacterium Lactococcus lactis by complementation of the purD mutation in Escherichia coli SO609. The genes encode enzymes in the de novo pathway of purine nucleotides. The expression of the genes was regulated approximately 35-fold at the transcription level by the availability of purines in the growth medium. Deletion analysis of the nucleotide region upstream of purD indicated that a region of 145 bp is enough to give regulated expression of the reporter lacLM genes, which encode beta-galactosidase. Deletion of a region 79 bp upstream of the transcription start point reduced the promoter activity 33-fold when incubated in a purine-free medium and to values below the detection limit when incubated in a purine-containing medium. No secondary transcription start points were mapped in or close to this region, indicating that a putative activator site and not a promoter was deleted or partly destroyed.

A transcriptional activator, homologous to the Bacillus subtilis PurR repressor, is required for expression of purine biosynthetic genes in Lactococcus lactis

A purR::pGh9:ISS1 mutant of Lactococcus lactis was obtained following transposon mutagenesis of strain MG1363 and selection for purine auxotrophs. After determination of the nucleotide sequence and deduction of the purR reading frame, the PurR product was found to be highly similar to the purR-encoded repressor from Bacillus subtilis. The wild-type purR gene complemented the purine auxotrophy of a purR::ISS1 mutant, and it was shown that the purR::ISS1 mutation lowered the level of transcription from the purine-regulated L. lactis purD promoter. In a parallel study on the regulation of purC and purD expression in L. lactis (M. Kilstrup, S. G. Jessing, S. B. Wichmand-Jorgensen, M. Madsen, and D. Nilsson, J. Bacteriol. 180:3900-3906, 1998), we identified regions (PurBox sequences: AWWWCCGAACWWT) upstream of the promoters with a central G residue at exactly position -76 relative to the transcriptional start site. The PurBox sequences were found to be required for high-level promoter activity and purine regulation. We identified a PurBox sequence overlapping the -35 region of the L. lactis purR promoter and found, by studies of a purR-lacLM fusion plasmid, that purR is autoregulated. Because of the high degree of similarity of the PurR proteins from B. subtilis and L. lactis, we looked for PurBox sequences in the promoter regions of the PurR-regulated genes in B. subtilis and identified a perfectly matching PurBox sequence in the purA promoter region and slightly degenerate PurBox-like sequences in the promoter regions for the pur operon and the purR gene. Interestingly, the PurBox in the pur operon of B. subtilis is located almost identically, with respect to the promoter, to the PurBox sequences located in front of purC and purD in L. lactis. We present a hypothesis to explain how an ancestral PurR protein in B. subtilis could have evolved from an activator of the pur operon into a repressor which regulates transcription initiation from the same pur promoter by using the same PurR binding site and a similar response toward its effectors.

Interaction of Bacillus subtilis purine repressor with DNA

A purine repressor (PurR) mediates adenine nucleotide-dependent regulation of transcription initiation of the Bacillus subtilis pur operon. This repressor has been purified for the first time, and binding to control site DNA was characterized. PurR binds in vitro to four operons. Apparent Kd values for binding were 7 nM for the pur operon, 8 nM for purA, 13 nM for purR, and 44 nM for the pyr operon. In each case, DNase I footprints exhibited a pattern of protected and hypersensitive sites that extended over more than 60 bp. A GAAC-N24-GTTC sequence in the pur operon was necessary but not sufficient for the PurR-DNA interaction. However, this motif, which is conserved in the four binding sites, was not required for binding of PurR to purA. Thus, the common DNA recognition element for binding of PurR to the four operons is not known. Multiple PurR-pur operon DNA complexes having a binding stoichiometry that was either approximately two or six repressor molecules per DNA fragment were detected. The results of a torsional constraint experiment suggest that control site DNA forms one right-handed turn around PurR.

Regulated expression of the dinR and recA genes during competence development and SOS induction in Bacillus subtilis

It has been hypothesized that the dinR gene product of Bacillus subtilis acts as a repressor of the SOS regulon by binding to DNA sequences located upstream of SOS genes, including dinR and recA. Following activation as a result of DNA damage, RecA is believed to catalyse DinR-autocleavage, thus derepressing the SOS regulon. The present results support this hypothesis: a dinR insertion mutation caused a high, constitutive expression of both dinR and recA, which could not be further elevated by SOS-induction. In addition, gel-retardation assays demonstrated a direct interaction between the dinR gene product and the recA and dinR promoter regions. Epistatic interactions and gel-retardation assays demonstrated that the previously reported competence-specific expression of recA directly depended upon the gene product of comK, the competence transcription factor. These data demonstrate the existence of a direct regulatory link between the competence signal-transduction pathway and the SOS reguion.

comK encodes the competence transcription factor, the key regulatory protein for competence development in Bacillus subtilis

comK is a positive autoregulatory gene occupying a central position in the competence-signal-transduction network. All regulatory routes identified in this network converge at the level of comK expression. The ComK protein is required for the transcriptional induction of comK and the late competence genes, which specify morphogenetic and structural proteins necessary for construction of the DNA-binding and uptake apparatus. In this report we demonstrate that ComK specifically binds to DNA fragments containing promoter and upstream sequences of the genes it affects (comC, comE, comF, comG and comK). Using portions of the region upstream of comC we show that the ComK-binding sequences are essential for the expression of competence. Moreover, we demonstrate that the presence of ComK stimulates the expression of comF-lacZ and comG-lacZ translational fusions in vivo in Escherichia coli. These results indicate that the gene product of comK is identical to the previously inferred competence transcription factor (CTF).

Differential expression of two closely related deoxyribonuclease genes, nucA and nucB, in Bacillus subtilis

Despite the lack of involvement of the competence-specific, membrane-associated deoxyribonuclease (DNase) in competence development, the expression of the gene encoding this protein, nucA, was shown to be dependent on the competence signal transduction pathway, and in particular on ComK, the competence transcription factor, which was shown to bind to the DNA region upstream of nucA. The expression of nucB, specifying an extracellular DNase, which was cloned on the basis of its homology to nucA, was shown to be sporulation-specific and dependent on the gene products of spo0A and spoIIG, the latter constituting an operon responsible for the synthesis of the mother-cell-specific sigma factor sigma E. The observed differential expression of nucA and nucB demarcates the appearance of DNase activities which are either associated with the cytoplasmic membrane or secreted into the medium during different post-exponential growth-phase processes.

Expression of the ATP-dependent deoxyribonuclease of Bacillus subtilis is under competence-mediated control

Transcription of the ATP-dependent deoxynuclease operon (addAB), as monitored by means of an addAB-lacZ transcriptional fusion, has a low, constitutive level and is initiated from a sigma A type promoter. Transcription of addAB is independent of DNA-damaging agents known to induce the SOS response in Bacillus subtilis. However, addAB transcription increased significantly during competence development. This competence-specific induction was dependent on the gene products of srfA, degU and comK, but not on that of recA. Deletion analysis of the addAB promoter region demonstrated that the competence-specific transcription induction requires DNA sequences located upstream of the addAB promoter that associated with ComK, the competence transcription factor. The latter finding indicates that a direct regulatory link exists between the establishment of the competent state and the synthesis of AddAB, required for recombination of internalized donor DNA.

Functional organization of the riboflavin biosynthesis operon from Bacillus subtilis SHgw

We have sequenced 6006 bp DNA of a region from the Bacillus subtilis SHgw chromosome known to contain riboflavin biosynthesis genes (rib gene cluster, 210 degrees on the B. subtilis genetic map). Five of the seven open reading frames found within the sequence are shown to represent the genes ribG, ribB, ribA, ribH and ribTD. The calculated molecular masses for the putative translation products are 39,305, 23,481, 44,121, 16,287 and 14,574 daltons respectively. The five rib genes are transcribed as a polycistronic 4277 nucleotide messenger RNA. The steady-state level of the transcript is negatively regulated by riboflavin. A cis-acting element necessary for regulation was mapped by analysis of constitutive mutations within the 5' untranslated region of the operon. The element is at least 48 bp in length and does not bear obvious similarity to well defined prokaryotic regulatory elements. The molecular mechanism of regulation remains unknown, but the data presented argue against regulation by attenuation.

Riboflavin operon of Bacillus subtilis: unusual symmetric arrangement of the regulatory region

Seventeen cis-dominant mutations leading to riboflavin overproduction in Bacillus subtilis were localized to the region between nucleotides +37 and +159 relative to the transcription initiation site of the riboflavin operon. This region displays an unusual structure for regulatory sequences. The main part of it represents clusters of A/T and G/C-rich sequences that symmetrically blank a short inverted repeat.

Cloning and sequence of Bacillus subtilis purA and guaA, involved in the conversion of IMP to AMP and GMP

Bacillus subtilis genes purA, encoding adenylosuccinate synthetase, and guaA, coding for GMP synthetase, appear to be lethal when cloned in multicopy plasmids in Escherichia coli. The nucleotide sequences of purA and guaA were determined from a series of gene fragments isolated by polymerase chain reaction amplification, library screening, and plasmid rescue techniques. Identifications were based on amino acid sequence alignments with enzymes from other organisms. Comparison of the 5'-flanking regions of purA and guaA with the pur operon suggests similarities in mechanisms for gene regulation. Nucleotide sequences are now available for all genes involved in the 14-step pathway for de novo purine nucleotide synthesis in B. subtilis.

Purification and initial characterization of AhrC: the regulator of arginine metabolism genes in Bacillus subtilis

The arginine-dependent repressor-activator from Bacillus subtilis, AhrC, has been overexpressed in Escherichia coli and purified to homogeneity. AhrC, expressed in E. coli, is able to repress a Bacillus promoter (argCp), which lies upstream of the argC gene. The purified protein is a hexamer with a subunit molecular mass of 16.7 kDa. Its ability to recognize DNA has been examined in vitro using argCp in both DNase I and hydroxyl radical protection assays. AhrC binds at two distinct sites within the argCp fragment. One site, argCo1, with the highest affinity for protein, is located within the 5' promoter sequences, whilst the other, argCo2, is within the coding region of argC. The data are consistent with the binding of a single hexamer of AhrC to argCo1 via four of its subunits, possibly allowing the remaining two subunits to bind at argCo2 in vivo forming a repression loop similar to those observed for the E. coli Lac repressor.

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

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