Early-blocked sporulation mutations alter expression of enzymes under carbon control in Bacillus subtilis

Lysogeny and sporulation in Bacillus isolates from the Gulf of Mexico

Eleven Bacillus isolates from the surface and subsurface waters of the Gulf of Mexico were examined for their capacity to sporulate and harbor prophages. Occurrence of sporulation in each isolate was assessed through decoyinine induction, and putative lysogens were identified by prophage induction by mitomycin C treatment. No obvious correlation between ability to sporulate and prophage induction was found. Four strains that contained inducible virus-like particles (VLPs) were shown to sporulate. Four strains did not produce spores upon induction by decoyinine but contained inducible VLPs. Two of the strains did not produce virus-like particles or sporulate significantly upon induction. Isolate B14905 had a high level of virus-like particle production and a high occurrence of sporulation and was further examined by genomic sequencing in an attempt to shed light on the relationship between sporulation and lysogeny. In silico analysis of the B14905 genome revealed four prophage-like regions, one of which was independently sequenced from a mitomycin C-induced lysate. Based on PCR and transmission electron microscopy (TEM) analysis of an induced phage lysate, one is a noninducible phage remnant, one may be a defective phage-like bacteriocin, and two were inducible prophages. One of the inducible phages contained four putative transcriptional regulators, one of which was a SinR-like regulator that may be involved in the regulation of host sporulation. Isolates that both possess the capacity to sporulate and contain temperate phage may be well adapted for survival in the oligotrophic ocean.

General stress transcription factor sigmaB and sporulation transcription factor sigmaH each contribute to survival of Bacillus subtilis under extreme growth conditions

The general stress response of the bacterium Bacillus subtilis is controlled by the sigmaB transcription factor. Here we show that loss of sigmaB reduces stationary-phase viability 10-fold in either alkaline or acidic media and reduces cell yield in media containing ethanol. We further show that loss of the developmental transcription factor sigmaH also has a marked effect on stationary-phase viability under these conditions and that this effect is independent from the simple loss of sporulation ability.

Molecular cloning, expression, and characterization of dnaK in Streptococcus pneumoniae

DnaK is known to be highly conserved in all species and is a major immunogen in Streptococcus pneumoniae. To elucidate the role of dnaK in S. pneumoniae, dnaK was cloned in Escherichia coli using a homologous dnaK probe generated by PCR. The His-tagged DnaK was overexpressed in soluble form and purified from E. coli. Alignment of the deduced DnaK amino acid sequence from nucleotide sequences of the cloned dnaK revealed high homology with DnaK analogs in E. coli (53%) and Staphylococcus aureus (73%). However, anti-pneumococcal DnaK antiserum did not crossreact with DnaK analogs in E. coli, S. aureus and human cells suggesting that pneumococcal DnaK might be a good candidate as a vaccine.

General stress transcription factor sigmaB of Bacillus subtilis is a stable protein

The sigmaB subunit of Bacillus subtilis RNA polymerase governs the expression of a large general stress regulon. The results of pulse-chase and immunoprecipitation experiments showed that sigmaB is stable both in the presence and in the absence of the RsbW anti-sigma factor, the principal regulator of sigmaB in response to environmental signals.

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.

Catabolite repression of the Bacillus subtilis hut operon requires a cis-acting site located downstream of the transcription initiation site

Expression of the Bacillus subtilis hut operon is subject to regulation by catabolite repression. A set of hut-lacZ transcriptional fusions was constructed and used to identify two cis-acting sites involved in catabolite repression. The hutOCR1 operator site lies immediately downstream of the hut promoter and weakly regulates hut expression in response to catabolite repression. The downstream hutOCR2 operator site lies within the hutP gene, between positions +203 and +216, and is required for wild-type levels of catabolite repression. Both the hutOCR1 and hutOCR2 operators have sequence similarity to the sites which mediate catabolite repression of several other B. subtilis genes. Two mutations which relieve catabolite repression of hut expression were found to alter the nucleotide sequence of the hutOCR2 operator. Catabolite repression of hut expression was partially relieved in strains containing the ccpA mutation but not in strains containing either the pai or hpr mutation.

Modulation of Bacillus subtilis catabolite repression by transition state regulatory protein AbrB

The first enzyme of the Bacillus subtilis histidine-degradative (hut) pathway, histidase, was expressed at higher levels during the onset of the stationary growth phase in nutrient sporulation medium in early-blocked sporulation mutants (spo0A) than in wild-type strains. Histidase expression was also elevated in spo0A mutant cultures compared with wild-type cultures during the logarithmic growth phase in minimal medium containing slowly metabolized carbon sources. Histidase expression was not derepressed in spo0A abrB mutant cultures under these growth conditions, suggesting that the AbrB protein is responsible for the derepression of histidase synthesis seen in spo0A mutant cultures. spo0A mutants contain higher levels of the AbrB protein than do wild-type strains because the Spo0A protein represses AbrB expression. A direct correlation between the levels of abrB transcription and histidase expression was found in spo0A mutant cultures. The hutOCR2 operator, which is required for wild-type regulation of hut expression by catabolite repression, was also required for AbrB-dependent derepression of hut expression in spo0A mutants. Purified AbrB protein bound to the hutOCR2 operator in vitro, suggesting that AbrB protein alters hut expression by competing with the hut catabolite repressor protein for binding to the hutOCR2 site. During the logarithmic growth phase in media containing slowly metabolized carbon sources, the expression of several other enzymes subject to catabolite repression was elevated in spo0A mutants but not in spo0A abrB mutants. This suggests that the AbrB protein acts as a global modulator of catabolite repression during carbon-limited growth.

Activation of the Bacillus subtilis hut operon at the onset of stationary growth phase in nutrient sporulation medium results primarily from the relief of amino acid repression of histidine transport

During growth of Bacillus subtilis in nutrient sporulation medium containing histidine (DSM-His medium), the expression of histidase, the first enzyme in the histidine-degradative pathway (hut), is derepressed 40- to 200-fold at the onset of stationary phase. To identify the gene products responsible for this regulation, histidase expression was examined in various hut regulatory mutants as well as in mutants defective in stationary-phase gene regulation. Histidase expression during growth in DSM-His medium was significantly altered only in a strain containing the hutC1 mutation. The hutC1 mutation allows the hut operon to be expressed in the absence of its inducer, histidine. During logarithmic growth in DSM-His medium, histidase levels were 25-fold higher in the HutC mutant than in wild-type cells. Moreover, histidase expression in the HutC mutant increased only four- to eightfold after the end of exponential growth in DSM-His medium. This suggests that histidine transport is reduced in wild-type cells during exponential growth in DSM-His medium and that this reduction is largely responsible for the repression of hut expression in cells growing logarithmically in this medium. Indeed, the rate of histidine uptake in DSM-His medium was fourfold lower in exponentially growing cells than in stationary-phase cells. The observation that the degradation of histidine is inhibited when B. subtilis is growing rapidly in medium containing a mixture of amino acids suggests that a hierarchy of amino acid utilization may be present in this bacterium.

An operator binding-negative mutation of Xyl repressor from Bacillus subtilis is trans dominant in Bacillus megaterium

We have selected a Bacillus subtilis 168-borne xylR Ser to Leu mutation at position 41 of the encoded amino acid sequence showing a constitutive expression phenotype for the xyl operon. When cloned on a multi-copy plasmid in a B. megaterium strain harbouring a single-copy xylA-lacZ fusion it leads to derepression of beta-galactosidase expression. Thus, it is trans dominant over the endogenous xylR, indicating that Xyl repressor functions as a multimer. This result also supports the assumption that the mutation is in a putative alpha-helix-turn-alpha-helix operator binding motif of Xyl repressor.

The minCD locus of Bacillus subtilis lacks the minE determinant that provides topological specificity to cell division

A key event of the sporulation process in Bacillus subtilis is the asymmetric cell division that divides the developing cell into two unequal compartments. To examine the function of vegetative cell division genes in this developmental division, we isolated and characterized the B. subtilis counterpart to the Escherichia coli minicell operon minB, which governs correct placement of the division septum. Starting from the closely linked spoIVF locus, we used walking methods to isolate the region of the B. subtilis chromosome proximate to the divIVB minicell locus. DNA sequence analysis found two open reading frames whose predicted products had significant identity to the E. coli MinC cell division inhibitor and the MinD ATPase activator of MinC, and disruption of minCD function generated a minicell phenotype in B. subtilis. Notably, no homologue to the E. coli MinE topological specificity element was found in the B. subtilis minCD region. The B. subtilis min genes were part of an operon transcribed from a major promoter more than 2.5 kb upstream from minC. An internal promoter immediately upstream from minC was dependent on RNA polymerase containing sigma-H and was active at the onset of sporulation. However, neither minC nor minD function was absolutely required for sporulation and, by implication, for asymmetric septum formation.

Activation of Bacillus subtilis transcription factor sigma B by a regulatory pathway responsive to stationary-phase signals

Alternative transcription factor sigma B of Bacillus subtilis controls a stationary-phase regulon induced under growth conditions that do not favor sporulation. Little is known about the metabolic signals and protein factors regulating the activity of sigma B. The operon containing the sigma B structural gene has the gene order orfV-orfW-sigB-rsbX, and operon expression is autoregulated positively by sigma B and negatively by the rsbX product (rsbX = regulator of sigma B). To establish the roles of the orfV and orfW products, orfV and orfW null and missense mutations were constructed and tested for their effects on expression of the sigma B-dependent genes ctc and csbA. These mutations were tested in two contexts: in the first, the sigB operon was under control of its wild-type, sigma B-dependent promoter, and in the second, the sigB operon promoter was replaced by the inducible Pspac promoter. The principal findings are that (i) the orfV (now called rsbV) product is a positive regulator of sigma B-dependent gene expression; (ii) the orfW (now called rsbW) product is a negative regultor of such expression; (iii) sigma B is inactive during logarithmic growth unless the rsbW product is absent; (iv) the rsbX, rsbV, and rsbW products have a hierarchical order of action; and (v) both the rsbV and rsbW products appear to regulate sigma B activity posttranslationally. There are likely to be at least two routes by which information can enter the system to regulate sigma B: via the rsbX product, and via the rsbV and rsbW products.

Catabolite repression of the xyl operon in Bacillus megaterium

We characterized catabolite repression of the genes encoding xylose utilization in Bacillus megaterium. A transcriptional fusion of xylA encoding xylose isomerase to the spoVG-lacZ indicator gene on a plasmid with a temperature-sensitive origin of replication was constructed and efficiently used for single-copy replacement cloning in the B. megaterium chromosome starting from a single transformant. In the resulting strain, beta-galactosidase expression is 150-fold inducible by xylose and 14-fold repressed by glucose, showing that both regulatory effects occur at the level of transcription. Insertion of a kanamycin resistance gene into xylR encoding the xylose-dependent repressor leads to the loss of xylose-dependent regulation and to a small drop in the efficiency of glucose repression to eightfold. Deletion of 184 bp from the 5' part of the xylA reading frame reduces glucose repression to only twofold. A potential glucose-responsive element in this region is discussed on the basis of sequence similarities to other glucose-repressed genes in Bacillus subtilis. The sequence including the glucose-responsive element is also necessary for repression exerted by the carbon sources fructose and mannitol. Their efficiencies of repression correlate to the growth rate of B. megaterium, as is typical for catabolite repression. Glycerol, ribose, and arabinose exert only a basal twofold repression of the xyl operon, which is independent of the presence of the cis-active glucose-responsive element within the xylA reading frame.

Interactions among mutations that cause altered timing of gene expression during sporulation in Bacillus subtilis

The ski4::Tn917lac insertion mutation in Bacillus subtilis was isolated in a screen for mutations that cause a defect in sporulation but that are suppressed by the presence or overexpression of the histidine protein kinase encoded by kinA (spoIIJ). ski4::Tn917lac caused a small defect in sporulation, but in combination with a null mutation in kinA, it caused a much more severe defect. The insertion mutation was in an 87-amino-acid open reading frame (orf87 bofA) that controls the activation of a sigma factor, sigma K, at intermediate times during sporulation. The ski4 mutation caused the premature expression of cotA, a gene controlled by sigma K. An independent mutation that causes the premature activation of sigma K also caused a synthetic (synergistic) sporulation phenotype in combination with a null mutation in kinA, indicating that the defect was due to altered timing of gene expression directed by sigma K. Expression of ski4 was shown to be controlled by the sporulation-specific sigma factor sigma E.

Regulation of Staphylococcus xylosus xylose utilization genes at the molecular level

We have investigated the regulation of the operon encoding xylose utilization in Staphylococcus xylosus C2a and Staphylococcus carnosus TM300. For in vivo studies, transcriptional fusions of the xylAB regulatory region to the lipase gene from Staphylococcus hyicus were constructed. Repression of lipase activity depended on a functional xylR gene and an xyl operator palindrome downstream of the promoter, while induction was obtained in the presence of xylose. Inactivation of either xylR or the xyl operator led to constitutive expression in the absence of xylose. Crude protein extracts from xylR+ staphylococci led to gel mobility shifts of the xyl regulatory DNA in the absence but not in the presence of xylose. A copper-phenanthroline footprint of the shifted band revealed protection of 28 phosphodiesters from cleavage in each strand of the xyl operator. Thus, the Xyl repressor covers the DNA over more than 2.5 helical turns. Glucose repression of the xyl operon occurs at the level of transcription and is independent of a functional xylR gene. A potential cis-active sequence element for glucose repression is discussed on the basis of sequence similarities to respective elements from bacilli.

Catabolite repression of the operon for xylose utilization from Bacillus subtilis W23 is mediated at the level of transcription and depends on a cis site in the xylA reading frame

The Bacillus subtilis xyl operon encoding enzymes for xylose utilization is repressed in the absence of xylose and in the presence of glucose. Transcriptional fusions of spoVG-lacZ to this operon show regulation of beta-galactosidase expression by glucose, indicating that glucose repression operates at the level of transcription. A similar result is obtained when glucose is replaced by glycerol, thus defining a general catabolite repression mechanism. A deletion of xylR, which encodes the xylose-sensitive repressor of the operon, does not affect glucose repression. The cis element mediating glucose repression was identified by Bal31 deletion analysis. It is confined to a 34 bp segment located at position +125 downstream of the xyl promoter in the coding sequence for xylose isomerase. Cloning of this segment in the opposite orientation leads to reduced catabolite repression. The homology of this element to various proposed consensus sequences for catabolite repression in B. subtilis is discussed.

Organization, promoter analysis and transcriptional regulation of the Staphylococcus xylosus xylose utilization operon

The Staphylococcus xylosus xyl genes were cloned in Staphylococcus carnosus by complementation to xylose utilization. Xylose isomerase assays under inducing (xylose present) and non-inducing (xylose absent) conditions indicated the presence of a regulated xylA gene on the recombinant plasmid. The nucleotide sequence (4520 bases) revealed three open reading frames with the same polarity. They were identified by sequence homologies as xylR, encoding the Xyl repressor, xylA, encoding xylose isomerase and xylB, encoding xylulokinase. Primer extension analyses indicated constitutive transcription of xylR and xylose-inducible transcription of xylA. Promoter consensus sequences were found upstream of both transcriptional start sites. A transcriptional terminator between xylR and xylA separates the different transcriptional units. Potential regulatory elements were identified by sequence analysis and suggest a repressor-operator mechanism for the regulation of xylAB expression.

Molecular cloning, structure, promoters and regulatory elements for transcription of the Bacillus megaterium encoded regulon for xylose utilization

The xylA and xylB genes of Bacillus subtilis BR151 encoding xylose isomerase and xylulokinase, respectively, were disrupted by gene replacement rendering the constructed mutant strain unable to grow on xylose as the sole carbon source. The Bacillus megaterium encoded xyl genes were cloned by complementation of this strain to xylose utilization. The nucleotide sequence of about 4 kbp of the insertion indicates the presence of the xylA and xylB genes on the complementing plasmid. Furthermore, a regulatory gene, xylR, is located upstream of xylA and has opposite polarity to it. The intergenic region between the divergently oriented reading frames of xylR and xylA contains palindromic sequences of 24 bp spaced by five central bp and 29 bp spaced by 11 bp, respectively, and two promoters with opposite orientation as determined by primer extension analysis. They overlap with one nucleotide of their--35 consensus boxes. Transcriptional fusions of lacZ to xylA, xylB and xylR were constructed and revealed that xylA and xylB are repressed in the absence and can be 200-fold induced in the presence of xylose. The increased level of xylAB mRNA in induced and its absence in repressed cells confirms that this regulation occurs on the level of transcription. Deletion of the xylR gene encoding the Xyl repressor results in constitutive expression of xylAB. The transcription of xylR is autoregulated and can be induced 9-fold by xylose. The mechanism of this regulation is not clear. While the apparent xyl operator palindrome is upstream of the xylR promoter, the potential recognition of another palindrome downstream of this promoter by Xyl repressor is discussed.

Molecular cloning, structure, promoters and regulatory elements for transcription of the Bacillus licheniformis encoded regulon for xylose utilization

In this article we describe the cloning of the xyl regulon encoding xylose utilization from Bacillus licheniformis by complementation of a xyl mutant of B. subtilis. The xylose isomerase encoding gene, xylA, was sequenced and identified by its extensive homology to other xylose isomerases. The expression of xylA is regulated on the level of transcription by a repressor protein encoded by xylR. Its gene has the opposite orientation of xylA and the start codons are 181 bp apart. A deletion of xylR renders xylA expression constitutive. The xylR sequence was determined and is discussed with respect to its homology to other xylR structures. Primer extension analyses of the xylA and xylR transcripts under repressing and including conditions define their promoters and confirm the regulation of xylA transcription. Furthermore, some induction of the xylR transcript by xylose is also observed. The regulatory sequence of both genes consists of a bipolar promoter system and contains three palindromic sequence elements. Their potential functions with respect to xylA and xylR regulation are discussed. The primary structures of the genes, promoters and regulatory sequences are compared to the xyl regulons encoded by B. subtilis, B. megaterium, Staphylococcus xylosus and E. coli. Homology is greatest between the B. subtilis and B. megaterium encoded xyl genes while the B. licheniformis borne genes are clearly more distant. The next greater differences are found to the S. xylosus and the greatest to the E. coli encoded genes. These results are discussed with respect to the taxonomic relations of these bacteria.

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

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

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

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

Regulation of histidine and proline degradation enzymes by amino acid availability in Bacillus subtilis

The first enzymes of the histidine (hut) and proline degradative pathways, histidase and proline oxidase, could not be induced in Bacillus subtilis cells growing in glucose minimal medium containing a mixture of 16 amino acids. Addition of the 16-amino-acid mixture to induced wild-type cells growing in citrate minimal medium repressed histidase synthesis 25- to 250-fold and proline oxidase synthesis 16-fold. A strain containing a transcriptional fusion of the hut promoter to the beta-galactosidase gene was isolated from a library of Tn917-lacZ transpositions. Examination of histidase and beta-galactosidase expression in extracts of a hut-lacZ fusion strain grown in various media showed that induction, catabolite repression, and amino acid repression of the hut operon were mediated at the level of transcription. This result was confirmed by measurement of the steady-state level of hut RNA in cells grown in various media. Since amino acid repression was not defective in B. subtilis mutants deficient in nitrogen regulation of glutamine synthetase and catabolite repression, amino acid repression appears to be mediated by a system that functions independently of these regulatory systems.