A gene at 333 degrees on the Bacillus subtilis chromosome encodes the newly identified sigma B-dependent general stress protein GspA

Growing Bacillus subtilis tendrils sense and avoid each other

Growing tendrils of aflagellate hag mutants of Bacillus subtilis were found to show an avoidance response when colonizing a semi-solid medium, suggesting a tip-to-tip communication mechanism between colonies. There may be a second sensing mechanism involved in shaping the morphology of tendrils. Tendril growth in B. subtilis was dependent on and possibly shaped by the release of surfactin, a biosurfactant. Transposon mutagenesis yielded two mutants with 'touching' tendrils, and each had a disrupted gspA gene that encodes a putative glycosyltransferase. Tendrils of gspA mutants, unlike the parental strain, were unresponsive to tendril tip growth by surfactin, suggesting disruption of intercellular signaling. Tendril sensing and avoidance could be physiologically relevant in habitats, such as plant roots, where some limiting nutrient might induce this type of multicellular behavior, promoting avoidance of previously explored areas by sibling colonies.

Transcriptional activity around bacterial cell death reveals molecular biomarkers for cell viability

Background

In bacteriology, the ability to grow in selective media and to form colonies on nutrient agar plates is routinely used as a retrospective criterion for the detection of living bacteria. However, the utilization of indicators for bacterial viability-such as the presence of specific transcripts or membrane integrity-would overcome bias introduced by cultivation and reduces the time span of analysis from initiation to read out. Therefore, we investigated the correlation between transcriptional activity, membrane integrity and cultivation-based viability in the Gram-positive model bacterium Bacillus subtilis.

Results

We present microbiological, cytological and molecular analyses of the physiological response to lethal heat stress under accurately defined conditions through systematic sampling of bacteria from a single culture exposed to gradually increasing temperatures. We identified a coherent transcriptional program including known heat shock responses as well as the rapid expression of a small number of sporulation and competence genes, the latter only known to be active in the stationary growth phase.

Conclusion

The observed coordinated gene expression continued even after cell death, in other words after all bacteria permanently lost their ability to reproduce. Transcription of a very limited number of genes correlated with cell viability under the applied killing regime. The transcripts of the expressed genes in living bacteria – but silent in dead bacteria-include those of essential genes encoding chaperones of the protein folding machinery and can serve as molecular biomarkers for bacterial cell viability.

Genome-wide transcriptional analysis of the phosphate starvation stimulon of Bacillus subtilis

Bacillus subtilis responds to phosphate starvation stress by inducing the PhoP and SigB regulons. While the PhoP regulon provides a specific response to phosphate starvation stress, maximizing the acquisition of phosphate (P(i)) from the environment and reducing the cellular requirement for this essential nutrient, the SigB regulon provides nonspecific resistance to stress by protecting essential cellular components, such as DNA and membranes. We have characterized the phosphate starvation stress response of B. subtilis at a genome-wide level using DNA macroarrays. A combination of outlier and cluster analyses identified putative new members of the PhoP regulon, namely, yfkN (2',3' cyclic nucleotide 2'-phosphodiesterase), yurI (RNase), yjdB (unknown), and vpr (extracellular serine protease). YurI is thought to be responsible for the nonspecific degradation of RNA, while the activity of YfkN on various nucleotide phosphates suggests that it could act on substrates liberated by YurI, which produces 3' or 5' phosphoribonucleotides. The putative new PhoP regulon members are either known or predicted to be secreted and are likely to be important for the recovery of inorganic phosphate from a variety of organic sources of phosphate in the environment.

Global expression profiling ofBacillus subtilis cells during industrial-close fed-batch fermentations with different nitrogen sources

A detailed gene expression analysis of industrial-close Bacillus subtilis fed-batch fermentation processes with casamino acids as the only nitrogen source and with a reduced casamino acid concentration but supplemented by ammonia was carried out. Although glutamine and arginine are supposed to be the preferred nitrogen sources of B. subtilis, we demonstrate that a combined feeding of ammonia and casamino acids supports cell growth under fed-batch fermentation conditions. The transcriptome and proteome analyses revealed that the additional feeding of ammonia in combination with a reduced amino acid concentration results in a significantly lower expression level of the glnAR or tnrA genes, coding for proteins, which are mainly involved in the nitrogen metabolism of B. subtilis. However, the mRNA levels of the genes of the ilvBHC-leuABD and hom-thrCB operons were significantly increased, indicating a valine, leucine, isoleucine, and threonine limitation under these fermentation conditions. In contrast, during the fermentation with casamino acids as the only nitrogen source, several genes, which play a crucial role in nitrogen metabolism of B. subtilis (e.g., glnAR, nasCDE, nrgAB, and ureABC), were up-regulated, indicating a nitrogen limitation under these conditions. Furthermore, increased expression of genes, which are involved in motility and chemotaxis (e.g., hag, fliT) and in acetoin metabolism (e.g., acoABCL), was determined during the fermentation with the mixed nitrogen source of casamino acids and ammonia, indicating a carbon limitation under these fermentation conditions. Under high cell density and slow growth rate conditions a weak up-regulation of autolysis genes could be observed as well as the induction of a number of genes involved in motility, chemotaxis and general stress response. Results of this study allowed the selection of marker genes, which could be used for the monitoring of B. subtilis fermentation processes. The data suggest for example acoA as a marker gene for glucose limitation or glnA as an indicator for nitrogen limitation.

Proteome analysis in the study of the bacterial heat-shock response

In recent years, it has become clear that, in addition to the regulation of the expression of specific genes, there are global regulatory systems that control the simultaneous expression of a large number of genes in response to a variety of environmental stresses. The first of these global control systems, and of substantial importance, is the heat-shock response. The heat-shock response is characterized by the induction of a large set of proteins (heat-shock proteins-HSPs) upon shifts to higher temperature and upon exposure to conditions in which proteins are denatured (i.e., alcohols, heavy metals). The heat-shock response is universal and many of the heat-shock proteins are highly conserved among species. In bacteria, the heat-shock response has been studied extensively in several Gram-positive bacteria (Bacillus subtilis) and in the Gram-negative bacteria (i.e., Escherichia coli, Agrobacterium tumefaciens). The first recognition of the molecular abundance of the bacterial heat-shock proteins took place with the introduction of high-resolution two-dimensional polyacrylamide gels (2D gels) to analyze complex mixtures of cellular proteins. Two-dimensional gels, followed by mass spectrometry, were used to define the heat-shock stimulons in several bacteria, and to study the regulatory elements that control the heat-shock response. Here, we review the heat-shock response and its regulation in bacteria. The review will emphasize the use of proteome analysis in the study of this response, and will point out those open questions that can be investigated with proteomics, including mass spectrometry techniques.

Bacillus subtilis functional genomics: global characterization of the stringent response by proteome and transcriptome analysis

The stringent response in Bacillus subtilis was characterized by using proteome and transcriptome approaches. Comparison of protein synthesis patterns of wild-type and relA mutant cells cultivated under conditions which provoke the stringent response revealed significant differences. According to their altered synthesis patterns in response to DL-norvaline, proteins were assigned to four distinct classes: (i) negative stringent control, i.e., strongly decreased protein synthesis in the wild type but not in the relA mutant (e.g., r-proteins); (ii) positive stringent control, i.e., induction of protein synthesis in the wild type only (e.g., YvyD and LeuD); (iii) proteins that were induced independently of RelA (e.g., YjcI); and (iv) proteins downregulated independently of RelA (e.g., glycolytic enzymes). Transcriptome studies based on DNA macroarray techniques were used to complement the proteome data, resulting in comparable induction and repression patterns of almost all corresponding genes. However, a comparison of both approaches revealed that only a subset of RelA-dependent genes or proteins was detectable by proteomics, demonstrating that the transcriptome approach allows a more comprehensive global gene expression profile analysis. The present study presents the first comprehensive description of the stringent response of a bacterial species and an almost complete map of protein-encoding genes affected by (p)ppGpp. The negative stringent control concerns reactions typical of growth and reproduction (ribosome synthesis, DNA synthesis, cell wall synthesis, etc.). Negatively controlled unknown y-genes may also code for proteins with a specific function during growth and reproduction (e.g., YlaG). On the other hand, many genes are induced in a RelA-dependent manner, including genes coding for already-known and as-yet-unknown proteins. A passive model is preferred to explain this positive control relying on the redistribution of the RNA polymerase under the influence of (p)ppGpp.

Bacillus subtilis tolerance of moderate concentrations of rifampin involves the sigma(B)-dependent general and multiple stress response

Low concentrations of the RNA polymerase inhibitor rifampin added to an exponentially growing culture of Bacillus subtilis led to an instant inhibition of growth. Survival experiments revealed that during the growth arrest the cells became tolerant to the antibiotic and the culture was able to resume growth some time after rifampin treatment. L-[(35)S]methionine pulse-labeled protein extracts were separated by two-dimensional polyacrylamide gel electrophoresis to investigate the change in the protein synthesis pattern in response to rifampin. The sigma(B)-dependent general stress proteins were found to be induced after treatment with the antibiotic. Part of the oxidative stress signature was induced as indicated by the catalase KatA and MrgA. The target protein of rifampin, the beta subunit (RpoB) of the DNA-dependent RNA polymerase, and the flagellin protein Hag belonging to the sigma(D) regulon were also induced. The rifampin-triggered growth arrest was extended in a sigB mutant in comparison to the wild-type strain, and the higher the concentration, the more pronounced this effect was. Activity of the RsbP energy-signaling phosphatase in the sigma(B) signal transduction network was also important for this protection against rifampin, but the RsbU environmental signaling phosphatase was not required. The sigB mutant strain was less capable of growing on rifampin-containing agar plates. When plated from a culture that had already reached stationary phase without previous exposure to the antibiotic during growth, the survival rate of the wild type exceeded that of the sigB mutant by a factor of 100. We conclude that the general stress response of B. subtilis is induced by rifampin depending on RsbP activity and that loss of SigB function causes increased sensitivity to the antibiotic.

Global transcriptional response of Bacillus subtilis to heat shock

In response to heat stress, Bacillus subtilis activates the transcription of well over 100 different genes. Many of these genes are members of a general stress response regulon controlled by the secondary sigma factor, sigma(B), while others are under control of the HrcA or CtsR heat shock regulators. We have used DNA microarrays to monitor the global transcriptional response to heat shock. We find strong induction of known sigma(B)-dependent genes with a characteristic rapid induction followed by a return to near prestimulus levels. The HrcA and CtsR regulons are also induced, but with somewhat slower kinetics. Analysis of DNA sequences proximal to newly identified heat-induced genes leads us to propose ~70 additional members of the sigma(B) regulon. We have also identified numerous heat-induced genes that are not members of known heat shock regulons. Notably, we observe very strong induction of arginine biosynthesis and transport operons. Induction of several genes was confirmed by quantitative reverse transcriptase PCR. In addition, the transcriptional responses measured by microarray hybridization compare favorably with the numerous previous studies of heat shock in this organism. Since many different conditions elicit both specific and general stress responses, knowledge of the heat-induced general stress response reported here will be helpful for interpreting future microarray studies of other stress responses.

Induction of sigma(B)-dependent general stress genes by amino acid starvation in a spo0H mutant of Bacillus subtilis

Solely sigma(B)-dependent genes like gsiB and gspA are not significantly induced in amino acid-starved wild-type cells, since amino acid starvation does not trigger activation of sigma(B). The general stress gene yvyD is subject to the control of both sigma(B) and sigma(H) therefore displaying induction in response to amino acid starvation at the sigma(H)-dependent promoter. Surprisingly, the proteins YvyD, GsiB and GspA were significantly induced in amino acid-starved cells of a strain lacking sigma(H) activity. Transcriptional studies provided evidence that sigma(B)-dependent transcription is indeed induced in a spo0H mutant during amino acid starvation and depends on RsbP but not on RsbU indicating that the stress signal transduction is not required for this induction. A similar phenomenon of sigma(B) activation was observed in amino acid-starved cells of a spo0A deletion mutant. The sigma(B)-dependent transcription in a spo0H mutant further needs an active RelA protein which is responsible for strong repression of house-keeping genes after amino acid starvation (stringent response). Our data indicate that in the absence of sigma(H) and under conditions which provoke the stringent response, RsbP-dependent levels of active sigma(B) can more effectively compete for increased levels of free RNA polymerase core enzyme leading to the induction of the probably strongest sigma(B)-dependent genes.

Genome-wide analysis of the general stress response in Bacillus subtilis

Bacteria respond to diverse growth-limiting stresses by producing a large set of general stress proteins. In Bacillus subtilis and related Gram-positive pathogens, this response is governed by the sigma(B) transcription factor. To establish the range of cellular functions associated with the general stress response, we compared the transcriptional profiles of wild and mutant strains under conditions that induce sigma(B) activity. Macroarrays representing more than 3900 annotated reading frames of the B. subtilis genome were hybridized to (33)P-labelled cDNA populations derived from (i) wild-type and sigB mutant strains that had been subjected to ethanol stress; and (ii) a strain in which sigma(B) expression was controlled by an inducible promoter. On the basis of their significant sigma(B)-dependent expression in three independent experiments, we identified 127 genes as prime candidates for members of the sigma(B) regulon. Of these genes, 30 were known previously or inferred to be sigma(B) dependent by other means. To assist in the analysis of the 97 new genes, we constructed hidden Markov models (HMM) that identified possible sigma(B) recognition sequences preceding 21 of them. To test the HMM and to provide an independent validation of the hybridization experiments, we mapped the sigma(B)-dependent messages for seven representative genes. For all seven, the 5' end of the message lay near typical sigma(B) recognition sequences, and these had been predicted correctly by the HMM for five of the seven examples. Lastly, all 127 gene products were assigned to functional groups by considering their similarity to known proteins. Notably, products with a direct protective function were in the minority. Instead, the general stress response increased relative message levels for known or predicted regulatory proteins, for transporters controlling solute influx and efflux, including potential drug efflux pumps, and for products implicated in carbon metabolism, envelope function and macromolecular turnover.

Isolation and characterization of two hydrocarbon-degrading Bacillus subtilis strains from oil contaminated soil of Kuwait

Two strains of hydrocarbon-utilizing bacteria were isolated from soil samples of the Kuwait Burqan oil field at a temperature of 37 degrees C. The bacteria were motile endospore-forming rods with slight differences in their metabolic patterns and 16S rRNA sequence. Vegetative cells of the strains designated as AHI and AHII had an ultrastructure typical of gram-positive bacteria and showed gram-positive staining. The bacteria did not show pigmentation. Best growth was observed at 37 degrees C at neutral pH and NaCl concentrations in the range of 5-10 g per l. Both strains were obligatory aerobic and developed on synthetic media with either Diesel fuel, n-decan or naphthalene as the sole carbon and energy source. No specific growth factors were required. On the basis of their morphological, physiological and biochemical features, as well as their 16S rRNA analysis and electron microscope study, both strains were assigned to the species of Bacillus subtilis.

Identification of sigma(B)-dependent genes in Bacillus subtilis using a promoter consensus-directed search and oligonucleotide hybridization

A consensus-directed search for sigma(B) promoters was used to locate potential candidates for new sigma(B)-dependent genes in Bacillus subtilis. Screening of those candidates by oligonucleotide hybridizations with total RNA from exponentially growing or ethanol-stressed cells of the wild type as well as a sigB mutant revealed 22 genes that required sigma(B) for induction by ethanol. Although almost 50% of the proteins encoded by the newly discovered sigma(B)-dependent stress genes seem to be membrane localized, biochemical functions have so far not been defined for any of the gene products. Allocation of the genes to the sigma(B)-dependent stress regulon may indicate a potential function in the establishment of a multiple stress resistance. AldY and YhdF show similarities to NAD(P)-dependent dehydrogenases and YdbP to thioredoxins, supporting our suggestion that sigma(B)-dependent proteins may be involved in the maintenance of the intracellular redox balance after stress.

Identification and characterization of a stress-responsive promoter in the macromolecular synthesis operon of Bacillus subtilis

Bacillus subtilis DB1005 is a temperature-sensitive (Ts) sigA mutant. Induction of sigmaA has been observed exclusively in this mutant harbouring extra copies of the plasmid-borne Ts sigA gene transcriptionally controlled by the P1P2 promoters of the B. subtilis macromolecular synthesis (MMS; rpoD or sigA) operon. Investigation of the mechanisms leading to the induction has allowed us to identify a sigmaB-type promoter, P7, in the MMS operon for the first time. Therefore, at least seven promoters in total are responsible for the regulation of the B. subtilis MMS operon, including the four known sigmaA- and sigmaH-type promoters, as well as two incompletely defined promoters. The P7 promoter was activated in B. subtilis after the imposition of heat, ethanol and salt stresses, indicating that the MMS operon of B. subtilis is subjected to the control of general stress. The significant heat induction of P7 in B. subtilis DB1005 harbouring a plasmid-borne Ts sigA gene can be explained by a model of competition between sigmaA and sigmaB for core binding; very probably, the sigmaB factor binds more efficiently to core RNA polymerase under heat shock. This mechanism may provide a means for the expression of the B. subtilis MMS operon when sigmaA becomes defective in core binding.

Cloning and overexpression of glycosyltransferases that generate the lipopolysaccharide core of Rhizobium leguminosarum

The lipopolysaccharide (LPS) core of the Gram-negative bacterium Rhizobium leguminosarum is more amenable to enzymatic study than that of Escherichia coli because much of it is synthesized from readily available sugar nucleotides. The inner portion of the R. leguminosarum core contains mannose, galactose, and three 3-deoxy-D-manno-octulosonate (Kdo) residues, arranged in the order: lipid A-(Kdo)2-Man-Gal-Kdo-[O antigen]. A mannosyltransferase that uses GDP-mannose and the conserved precursor Kdo2-[4'-32P]lipid IVA (Kadrmas, J. L., Brozek, K. A., and Raetz, C. R. H. (1996) J. Biol. Chem. 271, 32119-32125) is proposed to represent a key early enzyme in R. leguminosarum core assembly. Conditions for demonstrating efficient galactosyl- and distal Kdo-transferase activities are now described using a coupled assay system that starts with GDP-mannose and Kdo2-[4'-32P]lipid IVA. As predicted, mannose incorporation precedes galactose addition, which in turn precedes distal Kdo transfer. LPS core mutants with Tn5 insertions in the genes encoding the putative galactosyltransferase (lpcA) and the distal Kdo-transferase (lpcB) are shown to be defective in the corresponding in vitro glycosylation of Kdo2-[4'-32P]lipid IVA. We have also discovered the new gene (lpcC) that encodes the mannosyltransferase. The gene is separated by several kilobase pairs from the lpcAB cluster. All three glycosyltransferases are carried on cosmid pIJ1848, which contains at least 20 kilobase pairs of R. leguminosarum DNA. Transfer of pIJ1848 into R. meliloti 1021 results in heterologous expression of all three enzymes, which are not normally present in strain 1021. Expression of the lpc genes individually behind the T7 promoter results in the production of each R. leguminosarum glycosyltransferase in E. coli membranes in a catalytically active form, demonstrating that lpcA, lpcB, and lpcC are structural genes.

Identification of the gene encoding the alternative sigma factor sigmaB from Listeria monocytogenes and its role in osmotolerance

Listeria monocytogenes is well known for its robust physiology, which permits growth at low temperatures under conditions of high osmolarity and low pH. Although studies have provided insight into the mechanisms used by L. monocytogenes to allay the physiological consequences of these adverse environments, little is known about how these responses are coordinated. In the studies presented here, we have cloned the sigB gene and several rsb genes from L. monocytogenes, encoding homologs of the alternative sigma factor sigmaB and the RsbUVWX proteins, which govern transcription of a general stress regulon in the related bacterium Bacillus subtilis. The L. monocytogenes and B. subtilis sigB and rsb genes are similar in sequence and physical organization; however, we observed that the activity of sigmaB in L. monocytogenes was uniquely responsive to osmotic upshifting, temperature downshifting, and the presence of EDTA in the growth medium. The magnitude of the response was greatest after an osmotic upshift, suggesting a role for sigmaB in coordinating osmotic responses in L. monocytogenes. A null mutation in the sigB gene led to substantial defects in the ability of L. monocytogenes to use betaine and carnitine as osmoprotectants. Subsequent measurements of betaine transport confirmed that the absence of sigmaB reduced the ability of the cells to accumulate betaine. Thus, sigmaB coordinates responses to a variety of physical and chemical signals, and its function facilitates the growth of L. monocytogenes under conditions of high osmotic strength.

Non-specific, general and multiple stress resistance of growth-restricted Bacillus subtilis cells by the expression of the sigmaB regulon

Bacillus subtilis cells respond almost immediately to different stress conditions by increasing the production of general stress proteins (GSPs). The genes encoding the majority of the GSPs that are induced by heat, ethanol, salt stress or by starvation for glucose, oxygen or phosphate belong to the sigmaB-dependent general stress regulon. Despite a good understanding of the complex regulation of the activity of sigmaB and knowledge of a very large number of general stress genes controlled by sigmaB, first insights into the physiological role of this nonspecific stress response have been obtained only very recently. To explore the physiological role of this reguIon, we and others identified sigmaB-dependent general stress genes and compared the stress tolerance of wild-type cells with mutants lacking sigmaB or general stress proteins. The proteins encoded by sigmaB-dependent general stress genes can be divided into at least five functional groups that most probably provide growth-restricted B. subtilis cells with a multiple stress resistance in anticipation of future stress. In particular, sigB mutants are impaired in non-specific resistance to oxidative stress, which requires the sigmaB-dependent dps gene encoding a DNA-protecting protein. Protection against oxidative damage of membranes, proteins or DNA could be the most essential component of sigmaB mediated general stress resistance in growth-arrested aerobic gram-positive bacteria. Other general stress genes have both a sigmaB-dependent induction pathway and a second sigmaB-independent mechanism of stress induction, thereby partially compensating for a sigmaB deficiency in a sigB mutant. In contrast to sigB mutants, null mutations in genes encoding those proteins, such as cIpP or cIpC, cause extreme sensitivity to salt or heat.

Expression of a stress- and starvation-induced dps/pexB-homologous gene is controlled by the alternative sigma factor sigmaB in Bacillus subtilis

SigmaB-dependent general stress proteins (Gsps) of Bacillus subtilis are essential for the development of glucose-starvation-induced cross-resistance to oxidative challenge. However, the proteins directly involved in this nonspecific resistance to oxidative stress have to be identified. We found that one prominent Gsp displayed strong sequence similarity to the previously characterized oxidative-stress-inducible MrgA protein of B. subtilis and to the starvation-induced Dps/PexB protein of Escherichia coli. We therefore designated this prominent Gsp Dps. While MrgA belongs to the peroxide-stress-inducible proteins needed for the H2O2-inducible adaptive response to oxidative stress, Dps belongs to the proteins induced by heat, salt, or ethanol stress and after starvation for glucose but not by a sublethal oxidative challenge. Primer extension experiments identified two overlapping promoters upstream of the coding region of dps, one being sigmaB dependent (PB) and the other being sigmaB independent (P1). Both promoters contribute to the basal level of dps during growth. After stress or during entry into the stationary phase, transcription from PB strongly increased whereas transcription from P1 decreased. Mutant strains lacking Dps completely failed to develop glucose-starvation-induced resistance to oxidative stress. These results confirm our suggestion that sigmaB-dependent general stress proteins of B. subtilis are absolutely required for the development of nonspecific resistance to oxidative stress.

Identification of vegetative proteins for a two-dimensional protein index of Bacillus subtilis

Twenty-three of the most prominent spots which are visible on two-dimensional (2-D) protein gels of Bacillus subtilis crude extracts were selected as marker spots for the construction of a 2-D protein index. N-terminal sequencing of the corresponding proteins resulted in the identification of enzymes involved in glycolysis, TCA cycle, pentose phosphate cycle, amino acid metabolism, nucleotide biosynthesis and translation. Using computer analysis of the 2-D protein gels, most of these metabolic enzymes were found to be synthesized at a reduced rate after different stresses and glucose starvation. Such an approach permits a rapid and global evaluation of the regulation of different branches of metabolism in response to various physiological conditions.

Specific and general stress proteins in Bacillus subtilis--a two-deimensional protein electrophoresis study

A computer-aided analysis of high resolution two-dimensional polyacrylamide gels was used to investigate the changes in the protein synthesis profile in B. subtilis wild-type strains and sigB mutants in response to heat shock, salt and ethanol stress, and glucose of phosphate starvation. The data provided evidence that the induction of a least 42 general stress proteins absolutely required the alternative sigma factor sigmaB. However, at least seven stress proteins, among them ClpC, ClpP, Sod, AhpC and AhpF, remained stress-inducible in a sigB mutant. Such a detailed analysis also premitted the description of subgroups of general stress proteins which are subject to additional regulatory circuits, indicating a very thorough fine-tuning of this complex response. The relative synthesis rate of the general stress proteins constituted up to 40% of the total protein synthesis of stressed cells and thereby emphasizes the importance of the stress regulon. Besides the induction of these general or rather unspecific stress proteins, the induction of stress-specific proteins is shown and discussed.

General and oxidative stress responses in Bacillus subtilis: cloning, expression, and mutation of the alkyl hydroperoxide reductase operon

The AhpC subunit of the Bacillus subtilis alkyl hydroperoxide reductase was identified as a general stress protein induced in response to heat or salt stress or after entry of the organism into the stationary phase. The ahp operon, encoding the two subunits AhpC and AhpF, was cloned and localized between the gntRKPZ operon and the bglA locus. Two-dimensional gel analyses revealed an especially strong induction of AhpC and AhpF in cells subjected to oxidative stress. Transcriptional studies showed a 3- to 4-fold induction of ahp mRNA after heat or salt stress or starvation for glucose and a 20-fold induction by oxidative stress, thus confirming the protein induction data for AhpC and AhpF. Stress induction occurred at a sigmaA-dependent promoter that overlaps with operator sites similar to the per box. Compared with the wild type, the ahpC mutant was resistant to hydrogen peroxide because of the derepression of the peroxide regulon (N. Bsat, L. Chen, and J. D. Helmann, J. Bacteriol. 178:6579-6586, 1996) but more sensitive to cumene hydroperoxide (CHP) during exponential growth. In contrast, stationary-phase wild-type and ahpC mutant cells displayed complete resistance to treatment with 1 mM CHP. Moreover, a sigmaB mutant was found to be extremely sensitive to CHP during vegetative growth and in stationary phase, which indicates that sigmaB-dependent general stress proteins are involved in the protection of cells against oxidative stress.

Isolation and characterization of csbB, a gene controlled by Bacillus subtilis general stress transcription factor sigma B

In the bacterium Bacillus subtilis (Bs), the alternative transcription factor sigma B is activated by environmental stresses to control the expression of a large set of unlinked genes. However, the range of physiological functions mediated by these sigma B-controlled genes is presently unknown. We report here that the newly identified gene csbB is under the dual control of a sigma B-dependent and a sigma B-independent promoter. The predicted product of csbB is a 329 residue protein containing two potential membrane-spanning segments in its C-terminal region, leading us to speculate that one class of sigma B-controlled genes acts to modify the cell envelope as part of the general stress response.

Global changes in protein composition of N2-fixing-Azoarcus sp. strain BH72 upon diazosome formation

The strictly respiratory, diazotrophic bacterium Azoarcus sp. strain BH72 fixes nitrogen under microaerobic conditions. In empirically optimized batch cultures at nanomolar O2 concentrations in the presence of proline, cells can shift into a state of higher activity and respiratory efficiency of N2 fixation in which intracytoplasmic membrane stacks (diazosomes) related to N2 fixation are formed. Induction of intracytoplasmic membranes is most pronounced in coculture of Azoarcus sp. strain BH72 with an ascomycete originating from the same host plant, Kallar grass. To initiate studies on function of diazosomes and regulation of their formation, diazosome-containing bacteria were compared with respect to composition or total cellular and membrane proteins with diazosome-free cells fixing nitrogen under standard conditions. In two-dimensional protein gels, we detected striking differences in protein patterns upon diazosome formation: (i) 7.3% of major proteins disappeared, and only 73% of the total proteins of control cells were detectable, indicating that diazosome-containing cells have a more specialized metabolism; (ii) nine new proteins appeared and five proteins increased in concentration, designated DP1 to DP 15; and (iii) five new major membrane proteins (MP1 to MP6) were detected, indicating that membranes might have specialized functions. N-terminal amino acid sequence analysis of DP1 to DP4 allowed us to preliminarily identify DP4 as the glnB gene product P(II), an intracellular signal transmitter known to be involved in the regulation of nitrogen metabolism. According to its electrophoretic mobility, it might be uridylylated in diazosome-free cells but not in diazosome-containing cells, or it may represent a second, not identical P(II) protein. Oligonucleotides deduced from N-terminal sequences of DP1 and DP4 specifically hybridized to chromosomal DNA of Azoarcus sp. strain BH72 in Southern hybridizations.

Cold shock stress-induced proteins in Bacillus subtilis

Bacteria respond to a decrease in temperature with the induction of proteins that are classified as cold-induced proteins (CIPs). Using two-dimensional gel electrophoresis, we analyzed the cold shock response in Bacillus subtilis. After a shift from 37 to 15 degrees C the synthesis of a majority of proteins was repressed; in contrast, 37 proteins were synthesized at rates higher than preshift rates. One hour after cold shock, the induction of CIPs decreased, and after 2 h, general protein synthesis resumed. The identified main CIPs were excised from two-dimensional gels and were subjected to microsequencing. Three small acidic proteins that showed the highest relative induction after cold shock were highly homologous and belonged to a protein family of which one member, the major cold shock protein, CspB, has previously been characterized. Two-dimensional gel analyses of a cspB null mutant revealed that CspB affects the level of induction of several CIPs. Other identified CIPs function at various levels of cellular physiology, such as chemotaxis (CheY), sugar uptake (Hpr), translation (ribosomal proteins S6 and L7/L12), protein folding (PPiB), and general metabolism (CysK, Ilvc, Gap, and triosephosphate isomerase).

Homologous pairs of regulatory proteins control activity of Bacillus subtilis transcription factor sigma(b) in response to environmental stress

In Bacillus subtilis, activity of the general stress transcription factor sigma B is controlled posttranslationally by a regulatory network that transmits signals of environmental and metabolic stress. These signals include heat, ethanol, or osmotic challenge, or a sharp decrease in cellular energy levels, and all ultimately control sigma B activity by influencing the binding decision of the RsbW anti-sigma factor. In the absence of stress, RsbW binds to sigma B and prevents its association with RNA polymerase core enzyme. However, following stress, RsbW binds instead to the RsbV anti-anti-sigma factor, thereby releasing sigma B to direct transcription of its target genes. These two principal regulators of sigmaB activity are encoded in the eight-gene sigB operon, which has the gene order rsbR-rsbS-rsbT-rsbU-rsbV-rsbW-sig B-rsbX (where rsb stands for regulator of sigma B). Notably, the predicted rsbS product has significant amino acid identity to the RsbV anti-anti-sigma factor and the predicted rsbT product resembles the RsbW anti-sigma factor. To determine the roles of rsbS and rsbT, null or missense mutations were constructed in the chromosomal copies or each and tested for their effects on expression of a sigma B-dependent reporter fusion. On the basis of this genetic analysis, our principal conclusions are that (i) the rsbS product is a negative regulator of or" activity, (ii) the rsbT product is a positive regulator, (iii) RsbS requires RsbT for function, and (iv) the RsbS-RsbT and RsbV-RsbW pairs act hierarchically by a common mechanism in which key protein-protein interactions are controlled by phosphorylation events.

Bacillus subtilis operon under the dual control of the general stress transcription factor sigma B and the sporulation transcription factor sigma H

The sigma B transcription factor of Bacillus subtilis is activated in response to a variety of environmental stresses, including those imposed by entry into the stationary-growth phase, and by heat, salt or ethanol challenge to logarithmically growing cells. Although sigma B is thought to control a general stress regulon, the range of cellular functions it directs remains largely unknown. Our approach to understand the physiological role of sigma B is to characterize genes that require this factor for all or part of their expression, i.e. the csb genes. In this study, we report that the transposon insertion csb40::Tn917lac identifies an operon with three open reading frames, the second of which resembles plant proteins induced by desiccation stress. Primer-extension and operon-fusion experiments showed that the csb40 operon has a sigma B-dependent promoter which is strongly induced by the addition of salt to logarithmically growing cells. The csb40 operon also has a second, sigma H-dependent promoter that is unaffected by salt addition. These results provide support for the hypothesis that sigma B controls a general stress regulon, and indicate that the sigma B and sigma H regulons partly overlap. We suggest that in addition to its acknowledged role in the sporulation process, sigma H is also involved in controlling a subclass of genes that are broadly involved in a general stress response.

Tricistronic operon expression of the genes gcaD (tms), which encodes N-acetylglucosamine 1-phosphate uridyltransferase, prs, which encodes phosphoribosyl diphosphate synthetase, and ctc in vegetative cells of Bacillus subtilis

The gcaD, prs, and ctc genes were shown to be organized as a tricistronic operon. The transcription of the prs gene, measured as phosphoribosyl diphosphate synthetase activity, and of the ctc gene, measured as beta-galactosidase activity specified by a ctc-lacZ protein fusion, were dependent on the promoter in front of the gcaD gene. Analysis of cDNA molecules prepared with gcaD-prs-ctc-specified mRNA as the template revealed an RNA transcript that encompassed all three cistrons.

Cloning, nucleotide sequence, and regulation of katE encoding a sigma B-dependent catalase in Bacillus subtilis

A sigma B-dependent stress gene of Bacillus subtilis was localized downstream of the licS gene. The predicted amino acid sequence exhibited a significant similarity to the sequence of the katE-encoded catalase HPII of Escherichia coli, and we designated it the open reading frame katE. In a B. subtilis katE mutant, catalase 2 could not be detected. The amount of katE-specific mRNA was increased after heat, salt, or ethanol stress or after glucose starvation in a sigma B-dependent manner. As in E. coli, the transcription of the katE gene in B. subtilis was unaffected by the addition of H2O2 to exponentially growing cells. In contrast, the katA gene encoding catalase 1 of B. subtilis showed an induction pattern different from that of katE; katA expression was strongly increased by oxidative stress. The similarity between E. coli sigma S-dependent genes and B. subtilis sigma B-dependent genes suggests that both may confer multiple stress resistance to stationary-phase cells.