Altering the level and regulation of the major sigma subunit of RNA polymerase affects gene expression and development in Bacillus subtilis

Artificial activation of both σH and Spo0A in Bacillus subtilis enforced initiation of spore development at the vegetatively growing phase

When Bacillus subtilis cells face environmental deterioration, such as exhaustion of nutrients and an increase in cell density, they form spores. It is known that phosphorylation of Spo0A and activation of σH are key events at the initiation of sporulation. However, the initiation of sporulation is an extremely complicated process, and the relationship between these two events remains to be elucidated. To determine the minimum requirements for triggering sporulation initiation, we attempted to induce cell sporulation at the log phase, regardless of nutrients and cell density. In rich media such as Luria-Bertani (LB) medium, the cells of B. subtilis do not sporulate efficiently, possibly because of excess nutrition. When the amount of xylose in the LB medium was limited, σH -dependent transcription of the strain, in which sigA was under the control of the xylose-inducible promoter, was induced, and the frequency of sporulation was elevated according to the decreased level of σA. We also employed a fusion of sad67, which codes for an active form of Spo0A, and the IPTG-inducible promoter. The combination of lowered σA expression and activated Spo0A allowed the cells in the log phase to stop growing and rush into spore development. This observation of enforced initiation of sporulation in the mutant strain was detected even in the presence of the wild-type strain, suggesting that only intracellular events initiate and fulfill spore development regardless of extracellular conditions. Under natural sporulation conditions, the amount of σA did not change drastically throughout growth. Mechanisms that sequester σA from the core RNA polymerase and help σH to become active exist, but this has not yet been elucidated.

Phage-Encoded Sigma Factors Alter Bacterial Dormancy

By entering a reversible state of reduced metabolic activity, dormant microorganisms are able to tolerate suboptimal conditions that would otherwise reduce their fitness. Dormancy may also benefit bacteria by serving as a refuge from parasitic infections. Here, we focus on dormancy in the Bacillota, where endospore development is transcriptionally regulated by the expression of sigma factors. A disruption of this process could influence the survivorship or reproduction of phages that infect spore-forming hosts with implications for coevolutionary dynamics. We characterized the distribution of sigma factors in over 4,000 genomes of diverse phages capable of infecting hosts that span the bacterial domain. From this, we identified homologs of sporulation-specific sigma factors in phages that infect spore-forming hosts. Unlike sigma factors required for phage reproduction, we provide evidence that sporulation-like sigma factors are nonessential for lytic infection. However, when expressed in the spore-forming Bacillus subtilis, some of these phage-derived sigma factors can activate the bacterial sporulation gene network and lead to a reduction in spore yield. Our findings suggest that the acquisition of host-like transcriptional regulators may allow phages to manipulate a complex and ancient trait in one of the most abundant cell types on Earth.

IMPORTANCE As obligate parasites, phages exert strong top-down pressure on host populations with eco-evolutionary implications for community dynamics and ecosystem functioning. The process of phage infection, however, is constrained by bottom-up processes that influence the energetic and nutritional status of susceptible hosts. Many phages have acquired auxiliary genes from bacteria, which can be used to exploit host metabolism with consequences for phage fitness. In this study, we demonstrate that phages infecting spore-forming bacteria carry homologs of sigma factors, which their hosts use to orchestrate gene expression during spore development. By tapping into regulatory gene networks, phages may manipulate the physiology and survival strategies of nongrowing bacteria in ways that influence host-parasite coevolution.

Evolutionary trade-offs between growth and survival: The delicate balance between reproductive success and longevity in bacteria

All living cells strive to allocate cellular resources in a way that promotes maximal evolutionary fitness. While there are many competing demands for resources the main decision making process centres on whether to proceed with growth and reproduction or to "hunker down" and invest in protection and survival (or to strike an optimal balance between these two processes). The transcriptional programme active at any given time largely determines which of these competing processes is dominant. At the top of the regulatory hierarchy are the sigma factors that commandeer the transcriptional machinery and determine which set of promoters are active at any given time. The regulatory inputs controlling their activity are therefore often highly complex, with multiple layers of regulation, allowing relevant environmental information to produce the most beneficial response. The tension between growth and survival is also evident in the developmental programme necessary to promote biofilm formation, which is typically associated with low growth rates and enhanced long-term survival. Nucleotide second messengers and energy pools (ATP/ADP levels) play critical roles in determining the fate of individual cells. Regulatory small RNAs frequently play important roles in the decision making processes too. In this review we discuss the trade-off that exists between reproduction and persistence in bacteria and discuss some of the recent advances in this fascinating field.

Bacterial Vivisection: How Fluorescence-Based Imaging Techniques Shed a Light on the Inner Workings of Bacteria

The rise in fluorescence-based imaging techniques over the past 3 decades has improved the ability of researchers to scrutinize live cell biology at increased spatial and temporal resolution. In microbiology, these real-time vivisections structurally changed the view on the bacterial cell away from the "watery bag of enzymes" paradigm toward the perspective that these organisms are as complex as their eukaryotic counterparts. Capitalizing on the enormous potential of (time-lapse) fluorescence microscopy and the ever-extending pallet of corresponding probes, initial breakthroughs were made in unraveling the localization of proteins and monitoring real-time gene expression. However, later it became clear that the potential of this technique extends much further, paving the way for a focus-shift from observing single events within bacterial cells or populations to obtaining a more global picture at the intra- and intercellular level. In this review, we outline the current state of the art in fluorescence-based vivisection of bacteria and provide an overview of important case studies to exemplify how to use or combine different strategies to gain detailed information on the cell's physiology. The manuscript therefore consists of two separate (but interconnected) parts that can be read and consulted individually. The first part focuses on the fluorescent probe pallet and provides a perspective on modern methodologies for microscopy using these tools. The second section of the review takes the reader on a tour through the bacterial cell from cytoplasm to outer shell, describing strategies and methods to highlight architectural features and overall dynamics within cells.

Proteases HtrA and HtrB for α-amylase secreted from Bacillus subtilis in secretion stress

HtrA and HtrB are two important proteases across species. In biotechnological industries, they are related to degradation of secreted heterologous proteins from bacteria, especially in the case of overproduction of α-amylases in Bacillus subtilis. Induction of HtrA and HtrB synthesis follows the overproduction of α-amylases in B. subtilis. This is different from the order usually observed in B. subtilis, i.e., the production of proteases is prior to the secretion of proteins. This discrepancy suggests three possibilities: (i) HtrA and HtrB are constantly synthesized from the end of the exponential phase, and then are synthesized more abundantly due to secretion stress; (ii) There is a hysteresis mechanism that holds HtrA and HtrB back from their large amount of secretion before the overproduction of α-amylases; (iii) Heterologous amylases could be a stress to B. subtilis leading to a general response to stress. In this review, we analyze the literature to explore these three possibilities. The first possibility is attributed to the regulatory pathway of CssR-CssS. The second possibility is because sigma factor σD plays a role in the overproduction of α-amylases and is subpopulation dependent with the switch between "ON" and "OFF" states that is fundamental for a bistable system and a hysteresis mechanism. Thus, sigma factor σD helps to hold HtrA and HtrB back from massive secretion before the overproduction of α-amylases. The third possibility is that several sigma factors promote the secretion of proteases at the end of the exponential phase of growth under the condition that heterologous amylases are considered as a stress.

Molecular Time Sharing through Dynamic Pulsing in Single Cells

In cells, specific regulators often compete for limited amounts of a core enzymatic resource. It is typically assumed that competition leads to partitioning of core enzyme molecules among regulators at constant levels. Alternatively, however, different regulatory species could time share, or take turns utilizing, the core resource. Using quantitative time-lapse microscopy, we analyzed sigma factor activity dynamics, and their competition for RNA polymerase, in individual Bacillus subtilis cells under energy stress. Multiple alternative sigma factors were activated in ~1-hr pulses in stochastic and repetitive fashion. Pairwise analysis revealed that two sigma factors rarely pulse simultaneously and that some pairs are anti-correlated, indicating that RNAP utilization alternates among different sigma factors. Mathematical modeling revealed how stochastic time-sharing dynamics can emerge from pulse-generating sigma factor regulatory circuits actively competing for RNAP. Time sharing provides a mechanism for cells to dynamically control the distribution of cell states within a population. Since core molecular components are limiting in many other systems, time sharing may represent a general mode of regulation.

A model for sigma factor competition in bacterial cells

Sigma factors control global switches of the genetic expression program in bacteria. Different sigma factors compete for binding to a limited pool of RNA polymerase (RNAP) core enzymes, providing a mechanism for cross-talk between genes or gene classes via the sharing of expression machinery. To analyze the contribution of sigma factor competition to global changes in gene expression, we develop a theoretical model that describes binding between sigma factors and core RNAP, transcription, non-specific binding to DNA and the modulation of the availability of the molecular components. The model is validated by comparison with in vitro competition experiments, with which excellent agreement is found. Transcription is affected via the modulation of the concentrations of the different types of holoenzymes, so saturated promoters are only weakly affected by sigma factor competition. However, in case of overlapping promoters or promoters recognized by two types of sigma factors, we find that even saturated promoters are strongly affected. Active transcription effectively lowers the affinity between the sigma factor driving it and the core RNAP, resulting in complex cross-talk effects. Sigma factor competition is not strongly affected by non-specific binding of core RNAPs, sigma factors and holoenzymes to DNA. Finally, we analyze the role of increased core RNAP availability upon the shut-down of ribosomal RNA transcription during the stringent response. We find that passive up-regulation of alternative sigma-dependent transcription is not only possible, but also displays hypersensitivity based on the sigma factor competition. Our theoretical analysis thus provides support for a significant role of passive control during that global switch of the gene expression program.

Bacteria respond to changing environmental conditions by switching the global pattern of expressed genes. A key mechanism for global switches of the transcriptional program depends on alternative sigma factors that bind the RNA polymerase core enzyme and direct it towards the appropriate stress response genes. Competition of different sigma factors for a limited amount of RNA polymerase is believed to play a central role in this global switch. Here, a theoretical approach is used towards a quantitative understanding of sigma factor competition and its effects on gene expression. The model is used to quantitatively describe in vitro competition assays and to address the question of indirect or passive control in the stringent response upon amino acids starvation. We show that sigma factor competition provides a mechanism for a passive up-regulation of the stress specific sigma-driven genes due to the increased availability of RNA polymerase in the stringent response. Moreover, we find that active separation of sigma factor from the RNA polymerase during early transcript elongation weakens the sigma factor-RNA polymerase equilibrium constant, raising the question of how their in vitro measure is relevant in the cell.

The key sigma factor of transition phase, SigH, controls sporulation, metabolism, and virulence factor expression in Clostridium difficile

Toxin synthesis in Clostridium difficile increases as cells enter into stationary phase. We first compared the expression profiles of strain 630E during exponential growth and at the onset of stationary phase and showed that genes involved in sporulation, cellular division, and motility, as well as carbon and amino acid metabolism, were differentially expressed under these conditions. We inactivated the sigH gene, which encodes an alternative sigma factor involved in the transition to post-exponential phase in Bacillus subtilis. Then, we compared the expression profiles of strain 630E and the sigH mutant after 10 h of growth. About 60% of the genes that were differentially expressed between exponential and stationary phases, including genes involved in motility, sporulation, and metabolism, were regulated by SigH, which thus appears to be a key regulator of the transition phase in C. difficile. SigH positively controls several genes required for sporulation. Accordingly, sigH inactivation results in an asporogeneous phenotype. The spo0A and CD2492 genes, encoding the master regulator of sporulation and one of its associated kinases, and the spoIIA operon were transcribed from a SigH-dependent promoter. The expression of tcdA and tcdB, encoding the toxins, and of tcdR, encoding the sigma factor required for toxin production, increased in a sigH mutant. Finally, SigH regulates the expression of genes encoding surface-associated proteins, such as the Cwp66 adhesin, the S-layer precursor, and the flagellum components. Among the 286 genes positively regulated by SigH, about 40 transcriptional units presenting a SigH consensus in their promoter regions are good candidates for direct SigH targets.

Transcriptional switching in Escherichia coli during stress and starvation by modulation of sigma activity

During active growth of Escherichia coli, majority of the transcriptional activity is carried out by the housekeeping sigma factor (sigma(70)), whose association with core RNAP is generally favoured because of its higher intracellular level and higher affinity to core RNAP. In order to facilitate transcription by alternative sigma factors during nutrient starvation, the bacterial cell uses multiple strategies by which the transcriptional ability of sigma(70) is diminished in a reversible manner. The facilitators of shifting the balance in favour of alternative sigma factors happen to be as diverse as a small molecule (p)ppGpp (represents ppGpp or pppGpp), proteins (DksA, Rsd) and a species of RNA (6S RNA). Although 6S RNA and (p)ppGpp were known in literature for a long time, their role in transcriptional switching has been understood only in recent years. With the elucidation of function of DksA, a new dimension has been added to the phenomenon of stringent response. As the final outcome of actions of (p)ppGpp, DksA, 6S RNA and Rsd is similar, there is a need to analyse these mechanisms in a collective manner. We review the recent trends in understanding the regulation of sigma(70) by (p)ppGpp, DksA, Rsd and 6S RNA and present a case for evolving a unified model of RNAP redistribution during starvation by modulation of sigma(70) activity in E. coli.

Heterochronic phosphorelay gene expression as a source of heterogeneity in Bacillus subtilis spore formation

In response to limiting nutrient sources and cell density signals, Bacillus subtilis can differentiate and form highly resistant endospores. Initiation of spore development is governed by the master regulator Spo0A, which is activated by phosphorylation via a multicomponent phosphorelay. Interestingly, only part of a clonal population will enter this developmental pathway, a phenomenon known as sporulation bistability or sporulation heterogeneity. How sporulation heterogeneity is established is largely unknown. To investigate the origins of sporulation heterogeneity, we constructed promoter-green fluorescent protein (GFP) fusions to the main phosphorelay genes and perturbed their expression levels. Using time-lapse fluorescence microscopy and flow cytometry, we showed that expression of the phosphorelay genes is distributed in a unimodal manner. However, single-cell trajectories revealed that phosphorelay gene expression is highly dynamic or "heterochronic" between individual cells and that stochasticity of phosphorelay gene transcription might be an important regulatory mechanism for sporulation heterogeneity. Furthermore, we showed that artificial induction or depletion of the phosphorelay phosphate flow results in loss of sporulation heterogeneity. Our data suggest that sporulation heterogeneity originates from highly dynamic and variable gene activity of the phosphorelay components, resulting in large cell-to-cell variability with regard to phosphate input into the system. These transcriptional and posttranslational differences in phosphorelay activity appear to be sufficient to generate a heterogeneous sporulation signal without the need of the positive-feedback loop established by the sigma factor SigH.

Transient heterogeneity in extracellular protease production by Bacillus subtilis

The most sophisticated survival strategy Bacillus subtilis employs is the differentiation of a subpopulation of cells into highly resistant endospores. To examine the expression patterns of non-sporulating cells within heterogeneous populations, we used buoyant density centrifugation to separate vegetative cells from endospore-containing cells and compared the transcriptome profiles of both subpopulations. This demonstrated the differential expression of various regulons. Subsequent single-cell analyses using promoter-gfp fusions confirmed our microarray results. Surprisingly, only part of the vegetative subpopulation highly and transiently expresses genes encoding the extracellular proteases Bpr (bacillopeptidase) and AprE (subtilisin), both of which are under the control of the DegU transcriptional regulator. As these proteases and their degradation products freely diffuse within the liquid growth medium, all cells within the clonal population are expected to benefit from their activities, suggesting that B. subtilis employs cooperative or even altruistic behavior. To unravel the mechanisms by which protease production heterogeneity within the non-sporulating subpopulation is established, we performed a series of genetic experiments combined with mathematical modeling. Simulations with our model yield valuable insights into how population heterogeneity may arise by the relatively long and variable response times within the DegU autoactivating pathway.

Intracellular levels and activity of PvdS, the major iron starvation sigma factor of Pseudomonas aeruginosa

In Pseudomonas aeruginosa the iron starvation sigma factor PvdS directs the transcription of pyoverdine and virulence genes under iron limitation. PvdS activity is modulated by pyoverdine through the surface signalling cascade involving the FpvA receptor and the inner membrane-spanning sensor FpvR. To gain insight into the molecular mechanisms enabling PvdS to compete with the major sigma RpoD for RNA polymerase (RNAP) binding, we determined the intracellular levels of RNAP, RpoD and PvdS in P. aeruginosa PAO1, and the effect of pyoverdine signalling on PvdS activity. Under iron limitation, P. aeruginosa contains 2221 and 933 molecules of RNAP and RpoD per cell respectively. PvdS attains 62% of RpoD levels. The high PvdS content is partly offset by retention of 30% of PvdS on the membrane, lowering the concentration of cytosolic PvdS to 45% of RpoD levels. RNAP purification from iron-starved P. aeruginosa cells demonstrated that PvdS-RNAP is poorly represented compared with RpoD-RNAP (1 and 27% of total RNAP respectively). Pyoverdine signalling does not affect the PvdS cellular content but facilitates PvdS release from the membrane, increasing its cytosolic concentration from 35% in both pvdF and fpvA signalling mutants to 70% in the wild type and 83% in the fpvR mutant.

Production and secretion stress caused by overexpression of heterologous alpha-amylase leads to inhibition of sporulation and a prolonged motile phase in Bacillus subtilis

Transcriptome analysis was used to investigate the global stress response of the gram-positive bacterium Bacillus subtilis caused by overproduction of the well-secreted AmyQ alpha-amylase from Bacillus amyloliquefaciens. Analyses of the control and overproducing strains were carried out at the end of exponential growth and in stationary phase, when protein secretion from B. subtilis is optimal. Among the genes that showed increased expression were htrA and htrB, which are part of the CssRS regulon, which responds to high-level protein secretion and heat stress. The analysis of the transcriptome profiles of a cssS mutant compared to the wild type, under identical secretion stress conditions, revealed several genes with altered transcription in a CssRS-dependent manner, for example, citM, ylxF, yloA, ykoJ, and several genes of the flgB operon. However, high-affinity CssR binding was observed only for htrA, htrB, and, possibly, citM. In addition, the DNA macroarray approach revealed that several genes of the sporulation pathway are downregulated by AmyQ overexpression and that a group of motility-specific (sigmaD-dependent) transcripts were clearly upregulated. Subsequent flow-cytometric analyses demonstrate that, upon overproduction of AmyQ as well as of a nonsecretable variant of the alpha-amylase, the process of sporulation is severely inhibited. Similar experiments were performed to investigate the expression levels of the hag promoter, a well-established reporter for sigmaD-dependent gene expression. This approach confirmed the observations based on our DNA macroarray analyses and led us to conclude that expression levels of several genes involved in motility are maintained at high levels under all conditions of alpha-amylase overproduction.

The alternative sigma factor SigB of Corynebacterium glutamicum modulates global gene expression during transition from exponential growth to stationary phase

Background

Corynebacterium glutamicum is a gram-positive soil bacterium widely used for the industrial production of amino acids. There is great interest in the examination of the molecular mechanism of transcription control. One of these control mechanisms are sigma factors. C. glutamicum ATCC 13032 has seven putative sigma factor-encoding genes, including sigA and sigB. The sigA gene encodes the essential primary sigma factor of C. glutamicum and is responsible for promoter recognition of house-keeping genes. The sigB gene codes for the non-essential sigma factor SigB that has a proposed role in stress reponse.

Results

The sigB gene expression was highest at transition between exponential growth and stationary phase, when the amount of sigA mRNA was already decreasing. Genome-wide transcription profiles of the wild-type and the sigB mutant were recorded by comparative DNA microarray hybridizations. The data indicated that the mRNA levels of 111 genes are significantly changed in the sigB-proficient strain during the transition phase, whereas the expression profile of the sigB-deficient strain showed only minor changes (26 genes). The genes that are higher expressed during transition phase only in the sigB-proficient strain mainly belong to the functional categories amino acid metabolism, carbon metabolism, stress defense, membrane processes, and phosphorus metabolism. The transcription start points of six of these genes were determined and the deduced promoter sequences turned out to be indistinguishable from that of the consensus promoter recognized by SigA. Real-time reverse transcription PCR assays revealed that the expression profiles of these genes during growth were similar to that of the sigB gene itself. In the sigB mutant, however, the transcription profiles resembled that of the sigA gene encoding the house-keeping sigma factor.

Conclusion

During transition phase, the sigB gene showed an enhanced expression, while simultaneously the sigA mRNA decreased in abundance. This might cause a replacement of SigA by SigB at the RNA polymerase core enzyme and in turn results in increased expression of genes relevant for the transition and the stationary phase, either to cope with nutrient limitation or with the accompanying oxidative stress. The increased expression of genes encoding anti-oxidative or protection functions also prepares the cell for upcoming limitations and environmental stresses.

Insights into transcriptional regulation and sigma competition from an equilibrium model of RNA polymerase binding to DNA

To explore scenarios that permit transcription regulation by activator recruitment of RNA polymerase and sigma competition in vivo, we used an equilibrium model of RNA polymerase binding to DNA constrained by the values of total RNA polymerase (E) and sigma(70) per cell measured in this work. Our numbers of E and sigma(70) per cell, which are consistent with most of the primary data in the literature, suggest that in vivo (i) only a minor fraction of RNA polymerase (<20%) is involved in elongation and (ii) sigma(70) is in excess of total E. Modeling the partitioning of RNA polymerase between promoters, nonspecific DNA binding sites, and the cytoplasm suggested that even weak promoters will be saturated with Esigma(70) in vivo unless nonspecific DNA binding by Esigma(70) is rather significant. In addition, the model predicted that sigmas compete for binding to E only when their total number exceeds the total amount of RNA polymerase (excluding that involved in elongation) and that weak promoters will be preferentially subjected to sigma competition.

Growth versus maintenance: a trade-off dictated by RNA polymerase availability and sigma factor competition?

The regulatory design of higher organisms is proposed to comprise a trade-off between activities devoted to reproduction and those devoted to cellular maintenance and repair. Excessive reproduction will inevitably limit the organism's ability to resist stress whereas excessively devoted stress defence systems may increase lifespan but reduce Darwinian fitness. The trade-off is arguably a consequence of limited resources in any one organism but the nature and identity of such limiting resources are ambiguous. Analysis of global control of gene expression in Escherichia coli suggests that reproduction and maintenance activities are also at odds in bacteria and that this antagonism may be a consequence of a battle between transcription factors for limiting RNA polymerase. The outcome of this battle is regulated and depends on the nutritional status of the environment, the levels of the alarmone ppGpp, and RNA polymerase availability. This paper reviews how the concentration of RNA polymerase available for transcription initiation may vary upon shifts between growth and growth-arrest conditions and how this adjustment may differentially affect genes whose functions relate to reproduction and maintenance.

Controlled induction of the RpoS regulon in Escherichia coli, using an RpoS-expressing plasmid

RpoS, an alternative sigma factor produced by many gram-negative bacteria, primarily controls genes that are expressed in stationary phase in response to nutrient deprivation. To test the idea that induction of RpoS in the exponential phase, when RpoS is not normally expressed, increases RpoS-dependent gene expression, we constructed a plasmid carrying the rpoS gene under the control of an IPTG (isopropyl-beta-D-thiogalactopyranoside)-inducible T7lac promoter. Northern and Western analyses revealed that levels of RpoS mRNA and protein, respectively, increased in response to the inducer IPTG. Assays of changes in RpoS-dependent functions (catalase activity and glycogen accumulation), confirmed that induced RpoS was functional in exponential phase and was sufficient for the expression of RpoS-dependent functions. Controlled expression of RpoS and RpoS-dependent genes by plasmid-encoded rpoS may thus offer a useful tool for the study of RpoS-dependent gene expression.

Transcriptional regulation of the phoPR operon in Bacillus subtilis

When Bacillus subtilis is subjected to phosphate starvation, the Pho regulon is activated by the PhoP-PhoR two-component signal transduction system to elicit specific responses to this nutrient limitation. The response regulator, PhoP, and its cognate histidine sensor kinase, PhoR, are encoded by the phoPR operon that is transcribed as a 2.7-kb bicistronic mRNA. The phoPR operon is transcribed from two sigma(A)-dependent promoters, P(1) and P(2). Under conditions where the Pho regulon was not induced (i.e., phosphate-replete conditions or phoR-null mutant), a low level of phoPR transcription was detected only from promoter P(1). During phosphate starvation-induced transition from exponential to stationary phase, the expression of the phoPR operon was up-regulated in a phosphorylated PhoP (PhoP approximately P)-dependent manner; in addition to P(1), the P(2) promoter becomes active. In vitro gel shift assays and DNase I footprinting experiments showed that both PhoP and PhoP approximately P could bind to the control region of the phoPR operon. The data indicate that while low-level constitutive expression of phoPR is required under phosphate-replete conditions for signal perception and transduction, autoinduction is required to provide sufficient PhoP approximately P to induce other members of the Pho regulon. The extent to which promoters P(1) and P(2) are activated appears to be influenced by the presence of other sigma factors, possibly the result of sigma factor competition. For example, phoPR is hyperinduced in a sigB mutant and, later in stationary phase, in sigH, sigF, and sigE mutants. The data point to a complex regulatory network in which other stress responses and post-exponential-phase processes influence the expression of phoPR and, thereby, the magnitude of the Pho regulon response.

Tethering sigma70 to RNA polymerase reveals high in vivo activity of sigma factors and sigma70-dependent pausing at promoter-distal locations

Bacterial sigma factors compete for binding to RNA polymerase (RNAP) to control promoter selection, and in some cases interact with RNAP to regulate at least the early stages of transcript elongation. However, the effective concentration of sigmas in vivo, and the extent to which sigma can regulate transcript elongation generally, are unknown. We report that tethering sigma70 to all RNAP molecules via genetic fusion of rpoD to rpoC (encoding sigma70 and RNAP's beta' subunit, respectively) yields viable Escherichia coli strains in which alternative sigma-factor function is not impaired. beta'::sigma70 RNAP transcribed DNA normally in vitro, but allowed sigma70-dependent pausing at extended -10-like sequences anywhere in a transcriptional unit. Based on measurement of the effective concentration of tethered sigma70, we conclude that the effective concentration of sigma70 in E. coli (i.e., its thermodynamic activity) is close to its bulk concentration. At this level, sigma70 would be a bona fide elongation factor able to direct transcriptional pausing even after its release from RNAP during promoter escape.

Underproduction of sigma 70 mimics a stringent response. A proteome approach

When Escherichia coli cells enter stationary phase due to carbon starvation the synthesis of ribosomal proteins is rapidly repressed. In a DeltarelA DeltaspoT mutant, defective in the production of the alarmone guanosine tetraphosphate (ppGpp), this regulation of the levels of the protein synthesizing system is abolished. Using a proteomic approach we demonstrate that the production of the vast majority of detected E. coli proteins are decontrolled during carbon starvation in the DeltarelA DeltaspoT strain and that the starved cells behave as if they were growing exponentially. In addition we show that the inhibition of ribosome synthesis by the stringent response can be qualitatively mimicked by artificially lowering the levels of the housekeeping sigma factor, sigma(70). In other words, genes encoding the protein-synthesizing system are especially sensitive to reduced availability of sigma(70) programmed RNA polymerase. This effect is not dependent on ppGpp since lowering the levels of sigma(70) gives a similar but less pronounced effect in a ppGpp(0) strain. The data is discussed in view of the models advocating for a passive control of gene expression during stringency based on alterations in RNA polymerase availability.

Transient association of an alternative sigma factor, ComX, with RNA polymerase during the period of competence for genetic transformation in Streptococcus pneumoniae

Natural transformation in Streptococcus pneumoniae is regulated by a quorum-sensing system that acts through accumulation and sensing of a peptide pheromone (competence-stimulating peptide [CSP]) to control many competence-specific genes acting in DNA uptake, processing, and integration. The period of competence induced by CSP lasts only 15 min (quarter-height peak width). The recently identified regulator ComX is required for the CSP-dependent expression of many competence-specific genes that share an unusual consensus sequence (TACGAATA) at their promoter regions. To test the hypothesis that this regulator acts as a transient alternative sigma factor, ComX was purified from an Escherichia coli overexpression strain and core RNA polymerase was purified from a comX-deficient S. pneumoniae strain. The reconstituted ComX-polymerase holoenzyme produced transcripts for the competence-specific genes ssbB, cinA, cglA, celA, and dalA and was inhibited by anti-ComX antibody, but not by anti-sigma(70) antibody. Western blotting using antibodies specific for ComX, sigma(70), and poly-His revealed a transient presence of ComX for a period of 15 to 20 min after CSP treatment, while RNA polymerase remained at a constant level and sigma(A) remained between 60 and 125% of its normal level. ComX reached a molar ratio to RNA polymerase of at least 1.5. We conclude that ComX is unstable and acts as a competence-specific sigma factor.

Binding of sigma(A) and sigma(B) to core RNA polymerase after environmental stress in Bacillus subtilis

In Bacillus subtilis, the alternative sigma factor sigma(B) is activated in response to environmental stress or energy depletion. The general stress regulon under the control of sigma(B) provides the cell with multiple stress resistance. Experiments were designed to determine how activated sigma(B) replaces sigma(A) as a constituent of the RNA polymerase holoenzyme. Studies of the transcription of the sigma(A)-dependent stress gene clpE under sigma(B)-inducing conditions showed that expression was higher in a sigB mutant background than in the wild type. The relative affinities of sigma(A) and sigma(B) for binding to the core RNA polymerase (E) were determined by means of indirect surface plasmon resonance. The results showed that the affinity of sigma(B) for E was 60-fold lower than that of sigma(A). Western blot analyses with antibodies against sigma(A), sigma(B), and E showed that, after exposure to ethanol stress, the concentration of sigma(B) was only twofold higher than those of sigma(A) and E. Thus, the concentration of sigma(B) after stress is not high enough to compensate for its relatively low affinity for E, and it seems that additional mechanisms must be invoked to account for the binding of sigma(B) to E after stress.

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.

Transcriptional responses during outgrowth of Bacillus subtilis endospores

The Bacillus subtilis 168 genome contains an array of alternative sigma factors, many of which play important roles in reprogramming expression during stress and sporulation. The role of the different sigma factors during outgrowth, when the germinated endospore is converted back to a vegetative cell, is less well characterized. The activity of the alternative sigma factors sigmaB, sigmaD and sigmaH during endospore outgrowth was analysed by Northern blotting and lacZ reporter assays. While sigmaD and sigmaH were transcriptionally active during outgrowth, sigmaB-dependent transcription was not observed until after the first cell division, when growth slowed. Using an IPTG-controllable copy of sigA, an optimal level of expression was required to maintain growth rate at the end of outgrowth. The genes encoding the putative extracytoplasmic function (ECF) sigma factors sigmaI, sigmaV, sigmaW, sigmaZ and YlaC were insertionally inactivated using pMUTIN4. These strains, together with sigM and sigX mutants, were tested to determine their role and measure their expression during endospore outgrowth. Transcripts or beta-galactosidase activity were observed for each of the ECF sigma factors early after germination. With the exception of MJH003 (sigM), which showed an exacerbated salt stress defect, inactivation of the ECF sigma factor genes did not affect outgrowth in the conditions tested.

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.

Mutational analysis of RsrA, a zinc-binding anti-sigma factor with a thiol-disulphide redox switch

In the Gram-positive bacterium, Streptomyces coelicolor A3(2), expression of the thioredoxin system is modulated by a sigma factor called sigmaR in response to changes in the cytoplasmic thiol-disulphide status, and the activity of sigmaR is controlled post-translationally by an anti-sigma factor, RsrA. In vitro, the anti-sigma factor activity of RsrA, which contains seven cysteines, correlates with its thiol-disulphide redox status. Here, we investigate the function of RsrA in vivo. A constructed rsrA null mutant had very high constitutive levels of disulphide reductase activity and sigmaR-dependent transcription, confirming that RsrA is a negative regulator of sigmaR and a key sensor of thiol-disulphide status. Targeted mutagenesis revealed that three of the seven cysteines in RsrA (C11, C41 and C44) were essential for anti-sigma factor activity and that a mutant RsrA protein containing only these three cysteines was active and still redox sensitive in vivo. We also show that RsrA is a metalloprotein, containing near-stoichiometric amounts of zinc. On the basis of these data, we propose that a thiol-disulphide redox switch is formed between two of C11, C41 and C44, and that all three residues play an essential role in anti-sigma factor activity in their reduced state, perhaps by acting as ligands for zinc. Unexpectedly, rsrA null mutants were blocked in sporulation, probably as a consequence of an increase in the level of free sigmaR.

Regulation of sigma factor activity during Bacillus subtilis development

Progression of Bacillus subtilis through a series of morphological changes is driven by a cascade of sigma (sigma) factors and results in formation of a spore. Recent work has provided new insights into the location and function of proteins that control sigma factor activity, and has suggested that multiple mechanisms allow one sigma factor to replace another in the cascade.

Suppression of temperature-sensitive sporulation mutation in the Bacillus subtilis sigA gene by rpoB mutation

We isolated a temperature-sensitive sporulation defective mutant of the sigA gene, encoding a major sigma factor, sigma(A) protein, in Bacillus subtilis, and designated it as sigA21. The sigA21 mutation caused a single-amino acid substitution, E314K, in region 4 of the sigma(A) protein. In this mutant, expression of the spoIIG gene, whose transcription depends on both sigma(A) and the phosphorylated Spo0A protein, Spo0A approximately P, a major transcription factor during early stages of sporulation, was greatly reduced at 43 degrees C. To obtain further information on the mechanism of sigma(A) function during the early spore development, we isolated a spontaneous sporulation-proficient suppressor mutant at 43 degrees C. This extragenic suppressor mutation was mapped within the rpoB gene, encoding the beta subunit of RNA polymerase, and was found to have a single-amino acid substitution, A863G. In this mutant, the expression of the spoIIG is partially restored at 43 degrees C.

The ClpX protein of Bacillus subtilis indirectly influences RNA polymerase holoenzyme composition and directly stimulates sigma-dependent transcription

In Bacillus subtilis, several processes associated with the onset of stationary phase, including the initiation of sporulation, require the activity of the minor sigmaH form of RNA polymerase (RNAP). The induction of sigmaH-dependent gene transcription requires the regulatory ATPase, ClpX. The ClpX-dependent post-exponential increase in sigmaH activity is not dependent on the activator of sporulation gene expression, Spo0A. By determining the level of sigmaH and sigmaA in whole-cell extracts and RNAP preparations, evidence is presented that clpX does not influence the concentration of sigma subunits, but is required for the stationary phase reduction in sigmaA-RNAP holoenzyme. This is probably an indirect consequence of ClpX activity, because the ClpX-dependent decrease in sigmaA-RNAP concentration does not occur in a spo0A abrB mutant. The addition of ClpX to in vitro transcription reactions resulted in the stimulation of RNAP holoenzyme activity, but sigmaH-RNAP was observed to be more sensitive to ClpX-dependent stimulation than sigmaA-RNAP. No difference in transcriptional activity was observed in single-cycle in vitro transcription reactions, suggesting that ClpX acted at a step in transcription initiation after closed- and open-promoter complex formation. ClpX is proposed to function indirectly in the displacement of sigmaA from core RNAP and to act directly in the stimulation of sigmaH-dependent transcription in sporulating B. subtilis cells.

Temporal and selective association of multiple sigma factors with RNA polymerase during sporulation in Bacillus subtilis

BACKGROUND

During sporulation in Bacillus subtilis, an asymmetric division produces two cells, a forespore and mother cell, with which follow different developmental paths. The highly ordered programme of temporal and spatial gene activation during sporulation is governed by the principal RNA polymerase holoenzyme (EsigmaA) and alternative holoenzyme forms containing the developmental sigma factors sigmaH, sigmaF, sigmaE, sigmaG and sigmaK, which appear successively during development. The control mechanism(s) of temporal and selective association of multiple sigma factors with core RNA polymerase is unclear. As a first step to addressing these issues, this report quantifies the amount of each subunit of RNA polymerase that is present in the sporangium during sporulation, and analyses in vitro the relative affinities of each sigma subunit for core RNA polymerase.

RESULTS

Using quantitative immunoblot analysis, the amounts of EsigmaA, EsigmaH, EsigmaE and EsigmaK in relation to the total amount of RNA polymerase at appropriate time-points were found to be 15%, 1%, 6% and 2%, respectively. Therefore, the core RNA polymerase is predicted to be in excess. The level of core RNA polymerase and sigmaA remained constant during the transition from vegetative growth to sporulation, whereas the sporulation-specific sigma factors appeared successively, in the order sigmaH, sigmaE and sigmaK. Competition experiments between sigma factors in an in vitro transcription system revealed the dominance of sigmaA over sigmaH and sigmaE for open promoter complex formation. These results are inconsistent with the idea that late appearing sigma factors can displace earlier appearing sigmas from the core enzyme.

CONCLUSIONS

As the core RNA polymerase is in excess, the results suggest that successive sigma factors can bind to core RNA polymerase without having to displace earlier appearing sigma factors. Thus, the programme of gene expression during sporulation might not require mechanisms for the substitution of one sigma factor by another on the core RNA polymerase.

Sigma factor displacement from RNA polymerase during Bacillus subtilis sporulation

As Bacillus subtilis proceeds through sporulation, the principal vegetative cell sigma subunit (sigma(A)) persists in the cell but is replaced in the extractable RNA polymerase (RNAP) by sporulation-specific sigma factors. To explore how this holoenzyme changeover might occur, velocity centrifugation techniques were used in conjunction with Western blot analyses to monitor the associations of RNAP with sigma(A) and two mother cell sigma factors, sigma(E) and sigma(K), which successively replace sigma(A) on RNAP. Although the relative abundance of sigma(A) with respect to RNAP remained virtually unchanged during sporulation, the percentage of the detectable sigma(A) which cosedimented with RNAP fell from approximately 50% at the onset of sporulation (T(0)) to 2 to 8% by 3 h into the process (T(3)). In a strain that failed to synthesize sigma(E), the first of the mother cell-specific sigma factors, approximately 40% of the sigma(A) remained associated with RNAP at T(3). The level of sigma(A)-RNAP cosedimentation dropped to less than 10% in a strain which synthesized a sigma(E) variant (sigma(ECR119)) that could bind to RNAP but was unable to direct sigma(E)-dependent transcription. The E-sigma(E)-to-E-sigma(K) changeover was characterized by both the displacement of sigma(E) from RNAP and the disappearance of sigma(E) from the cell. Analyses of extracts from wild-type and mutant B. subtilis showed that the sigma(K) protein is required for the displacement of sigma(E) from RNAP and also confirmed that sigma(K) is needed for the loss of the sigma(E) protein. The results indicate that the successive appearance of mother cell sigma factors, but not necessarily their activities, is an important element in the displacement of preexisting sigma factors from RNAP. It suggests that competition for RNAP by consecutive sporulation sigma factors may be an important feature of the holoenzyme changeovers that occur during sporulation.

sigmaK can negatively regulate sigE expression by two different mechanisms during sporulation of Bacillus subtilis

Temporal and spatial gene regulation during Bacillus subtilis sporulation involves the activation and inactivation of multiple sigma subunits of RNA polymerase in a cascade. In the mother cell compartment of sporulating cells, expression of the sigE gene, encoding the earlier-acting sigma factor, sigmaE, is negatively regulated by the later-acting sigma factor, sigmaK. Here, it is shown that the negative feedback loop does not require SinR, an inhibitor of sigE transcription. Production of sigmaK about 1 h earlier than normal does affect Spo0A, which when phosphorylated is an activator of sigE transcription. A mutation in the spo0A gene, which bypasses the phosphorelay leading to the phosphorylation of Spo0A, diminished the negative effect of early sigmaK production on sigE expression early in sporulation. Also, early production of sigmaK reduced expression of other Spo0A-dependent genes but not expression of the Spo0A-independent ald gene. In contrast, both sigE and ald were overexpressed late in development of cells that fail to make sigmaK. The ald promoter, like the sigE promoter, is believed to be recognized by sigmaA RNA polymerase, suggesting that sigmaK may inhibit sigmaA activity late in sporulation. To exert this negative effect, sigmaK must be transcriptionally active. A mutant form of sigmaK that associates with core RNA polymerase, but does not direct transcription of a sigmaK-dependent gene, failed to negatively regulate expression of sigE or ald late in development. On the other hand, the negative effect of early sigmaK production on sigE expression early in sporulation did not require transcriptional activity of sigmaK RNA polymerase. These results demonstrate that sigmaK can negatively regulate sigE expression by two different mechanisms, one observed when sigmaK is produced earlier than normal, which does not require sigmaK to be transcriptionally active and affects Spo0A, and the other observed when sigmaK is produced at the normal time, which requires sigmaK RNA polymerase transcriptional activity. The latter mechanism facilitates the switch from sigmaE to sigmaK in the cascade controlling mother cell gene expression.

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.

Role of lon and ClpX in the post-translational regulation of a sigma subunit of RNA polymerase required for cellular differentiation in Bacillus subtilis

The RNA polymerase sigma subunit, sigmaH (Spo0H) of Bacillus subtilis, is essential for the transcription of genes that function in sporulation and genetic competence. Although spo0H is transcriptionally regulated by the key regulatory device that controls sporulation initiation, the Spo0 phosphorelay, there is considerable evidence implicating a mechanism of post-translational control that governs the activity and concentration of sigmaH. Post-translational control of spo0H is responsible for the reduced expression of genes requiring sigmaH under conditions of low environmental pH. It is also responsible for heightened sigmaH activity upon relief of acid stress and during nutritional depletion. In this study, the ATP-dependent proteases LonA and B and the regulatory ATPase ClpX were found to function in the post-translational control of sigmaH. Mutations in lonA and lonB result in elevated sigmaH protein concentrations in low-pH cultures. However, this is not sufficient to increase sigmaH-dependent transcription. Activation of sigmaH-dependent transcription upon raising medium pH and in cells undergoing sporulation requires clpX, as shown by measuring the expression of lacZ fusions that require sigmaH for transcription and by complementation of a clpX null mutation. A hypothesis is presented that low environmental pH results in the Lon-dependent degradation of sigmaH, but the activity of sigmaH in sporulating cells and in cultures at neutral pH is stimulated by a ClpX-dependent mechanism in response to nutritional stress.

Replacement of vegetative sigmaA by sporulation-specific sigmaF as a component of the RNA polymerase holoenzyme in sporulating Bacillus subtilis

Soon after asymmetric septation in sporulating Bacillus subtilis cells, sigmaF is liberated in the prespore from inhibition by SpoIIAB. To initiate transcription from its cognate promoters, sigmaF must compete with sigmaA, the housekeeping sigma factor in the predivisional cell, for binding to core RNA polymerase (E). To estimate the relative affinity of E for sigmaA and sigmaF, we made separate mixtures of E with each of the two sigma factors, allowed reconstitution of the holoenzyme, and measured the concentration of free E remaining in each mixture. The affinity of E for sigmaF was found to be about 25-fold lower than that for sigmaA. We used quantitative Western blotting to estimate the concentrations of E, sigmaA, and sigmaF in sporulating cells. The cellular concentrations of E and sigmaA were both about 7.5 microM, and neither changed significantly during the first 3 h of sporulation. The concentration of sigmaF was extremely low at the beginning of sporulation, but it rose rapidly to a peak after about 2 h. At its peak, the concentration of sigmaF was some twofold higher than that of sigmaA. This difference in concentration cannot adequately account for the replacement of sigmaA holoenzyme by sigmaF holoenzyme in the prespore, and it seems that some further mechanism-perhaps the synthesis or activation of an anti-sigmaA factor-must be responsible for this replacement.

Control of sigma factor activity during Bacillus subtilis sporulation

When starved, Bacillus subtilis undergoes asymmetric division to produce two cell types with different fates. The larger mother cell engulfs the smaller forespore, then nurtures it and, eventually, lyses to release a dormant, environmentally resistant spore. Driving these changes is a programme of transcriptional gene regulation. At the heart of the programme are sigma factors, which become active at different times, some only in one cell type or the other, and each directing RNA polymerase to transcribe a different set of genes. The activity of each sigma factor in the cascade is carefully regulated by multiple mechanisms. In some cases, novel proteins control both sigma factor activity and morphogenesis, co-ordinating the programme of gene expression with morphological change. These bifunctional proteins, as well as other proteins involved in sigma factor activation, and even precursors of sigma factors themselves, are targeted to critical locations, allowing the mother cell and forespore to communicate with each other and to co-ordinate their programmes of gene expression. This signalling can result in proteolytic sigma factor activation. Other mechanisms, such as an anti-sigma factor and, perhaps, proteolytic degradation, prevent sigma factors from becoming active in the wrong cell type. Accessory transcription factors modulate RNA polymerase activity at specific promoters. Negative feedback loops limit sigma factor production and facilitate the transition from one sigma factor to the next. Together, the mechanisms controlling sigma factor activity ensure that genes are expressed at the proper time and level in each cell type.

Rapid isolation of RNA polymerase from sporulating cells of Bacillus subtilis

A highly ordered program of temporal and spatial gene activation during sporulation in Bacillus subtilis is governed by the principal RNA polymerase, and RNA polymerases containing at least five developmental sigma factors appearing successively during sporulation. This report describes a rapid procedure for extracting RNA polymerase from sporulating B. subtilis cells, which involves the construction of hexahistidine tagged beta' subunit of RNA polymerase and the isolation of RNA polymerase holoenzyme with Ni2+-NTA resin. In in vitro transcription of various promoters with the RNA polymerase thus purified, we observed the temporal change of each RNA polymerase activity during sporulation. This procedure enables isolation of RNA polymerase within 4h, starting with cell pellets. Our results indicated that a principal sigma factor, sigmaA, could be detected in a holoenzyme form during all the stages of growth and sporulation, while the other sigma factors sigmaH, sigmaE, sigmaF, sigmaG, and sigmaK involved in sporulation could be detected sequentially during sporulation. Moreover, Spo0A, the central transcription factor of commitment to sporulation, was also co-purified with RNA polymerase at early stages of sporulation.

Negative regulation by RpoS: a case of sigma factor competition

A mutation in the Escherichia coli gene encoding the stationary phase-inducible sigma factor (sigmaS, RpoS) not only abolishes transcription of some genes in stationary phase, but also causes superinduction of other stationary phase-induced genes. We have examined this phenomenon of repression by sigmaS using as a model system the divergently transcribed stationary phase-inducible genes, uspA and uspB. uspA is transcribed by sigma70-programmed RNA polymerase and is superinduced in an rpoS mutant, while uspB induction is sigmaS dependent. The data suggest that the superinduction of uspA is caused by an increased amount of sigma70 bound to RNA polymerase in the absence of the competing sigmaS. Increasing the ability of sigma70 to compete against sigmaS by overproducing sigma70 mimics the effect of an rpoS mutation by causing superinduction of sigma70-dependent stationary phase-inducible genes (uspA and fadD), silencing of sigmaS-dependent genes (uspB, bolAp1 and fadL) and inhibiting the development of sigmaS-dependent phenotypes, such as hydrogen peroxide resistance in stationary phase. In addition, overproduction of sigmaS markedly reduced stationary phase expression of a sigma70-dependent promoter. Thus, we conclude that sigma factors compete for a limiting amount of RNA polymerase during stationary phase. The implications of this competition in the passive control of promoter activity is discussed.

Simulation of prokaryotic genetic circuits

Biochemical and genetic approaches have identified the molecular mechanisms of many genetic reactions, particularly in bacteria. Now a comparably detailed understanding is needed of how groupings of genes and related protein reactions interact to orchestrate cellular functions over the cell cycle, to implement preprogrammed cellular development, or to dynamically change a cell's processes and structures in response to environmental signals. Simulations using realistic, molecular-level models of genetic mechanisms and of signal transduction networks are needed to analyze dynamic behavior of multigene systems, to predict behavior of mutant circuits, and to identify the design principles applicable to design of genetic regulatory circuits. When the underlying design rules for regulatory circuits are understood, it will be far easier to recognize common circuit motifs, to identify functions of individual proteins in regulation, and to redesign circuits for altered functions.

Differential expression of the OmpF and OmpC porin proteins in Escherichia coli K-12 depends upon the level of active OmpR

We have generated a mutant form of the OmpR regulatory protein, OmpRD55E, that is active independent of the EnvZ kinase. Notably, the pattern of OmpF and OmpC expression can be altered simply by changing the level of this mutant protein in the cell. This result supports a key prediction of the current model of porin regulation, which states that the differential regulation of OmpF and OmpC is a direct consequence of the cellular level of the active form of OmpR.

Regulation of Bacillus subtilis sigmaH (spo0H) and AbrB in response to changes in external pH

The RNA polymerase sigma subunit, sigmaH, of Bacillus subtilis is required for the transcription of genes that are induced in late-growth cultures at high cell density, including genes that function in sporulation. The expression of sigmaH-controlled genes is repressed when nutrient broth sporulation medium (Difco sporulation medium [DSM]) is supplemented with high concentrations of glucose and glutamine (DSM-GG), preferred carbon and nitrogen sources of B. subtilis. Under these conditions, the pH of the DSM-GG medium decreases to approximately 5. Raising the pH by the addition of morpholinepropanesulfonic acid (MOPS) or Tris-HCl (pH 7.5) results in a dramatic increase in the expression of lacZ fusions to sigmaH-dependent promoters. Correspondingly, the level of sigmaH protein was higher in cells of late-growth DSM-GG cultures treated with a pH stabilizer. When sigmaH-dependent gene expression was examined in cells bearing a mutation in abrB, encoding the transition state regulator that negatively controls genes transcribed by the sigmaH form of RNA polymerase, derepression was observed as well as an increase in medium pH. Reducing the pH with acetic acid resulted in repression, suggesting that AbrB was not functioning directly in pH-dependent repression but was required to maintain the low medium pH in DSM-GG. AbrB protein levels were high in late-growth, DSM-GG cultures but significantly lower when the pH was raised by Tris-HCl addition. An active tricarboxylic acid (TCA) cycle was required to obtain maximum derepression of sigmaH-dependent transcription, and transcription of the TCA cycle enzyme gene citB was repressed in DSM-GG but derepressed when the pH was artificially raised. The negative effect of low pH on sigmaH-dependent lacZ expression was also observed in unbuffered minimal medium and appeared to be exerted posttranslationally with respect to spo0H expression. However, the addition of amino acids to the medium caused pH-independent repression of both sigmaH-dependent transcription and spo0H-lacZ expression. These results suggest that spo0H transcription or translation is repressed by a mechanism responding to the availability of amino acids whereas spo0H is posttranslationally regulated in response to external pH.

A feedback loop regulates the switch from one sigma factor to the next in the cascade controlling Bacillus subtilis mother cell gene expression

Regulation of gene expression in the mother cell compartment of sporulating Bacillus subtilis involves sequential activation and inactivation of several transcription factors. Among them are two sigma factors, sigmaE and sigmaK, and a DNA-binding protein, SpoIIID. A decrease in the level of SpoIIID is thought to relieve its repressive effect on transcription by sigmaK RNA polymerase of certain spore coat genes. Previous studies showed that sigmaK negatively regulates the level of spoIIID mRNA. Here, it is shown that sigmaK does not affect the stability of spoIIID mRNA. Rather, sigmaK appears to negatively regulate the synthesis of spoIIID mRNA by accelerating the disappearance of sigmaE RNA polymerase, which transcribes spoIIID. As sigmaK begins to accumulate by 4 h into sporulation, the sigmaE level drops rapidly in wild-type cells but remains twofold to fivefold higher in sigK mutant cells during the subsequent 4 h. In a strain engineered to produce sigmaK 1 h earlier than normal, twofold less sigmaE than that in wild-type cells accumulates. SigmaK did not detectably alter the stability of sigmaE in pulse-chase experiments. However, beta-galactosidase expression from a sigE-lacZ transcriptional fusion showed a pattern similar to the level of sigmaE protein in sigK mutant cells and cells prematurely expressing sigmaK. These results suggest that the appearance of sigmaK initiates a negative feedback loop controlling not only transcription of spoIIID, but the entire sigmaE regulon, by directly or indirectly inhibiting the transcription of sigE.

Expression of the Bacillus subtilis ureABC operon is controlled by multiple regulatory factors including CodY, GlnR, TnrA, and Spo0H

Expression of urease, which is encoded by the ureABC operon, is regulated in response to nitrogen availability in Bacillus subtilis. Three ureABC promoters were identified in primer extension experiments and by examination of beta-galactosidase expression from ure-lacZ fusions. P1, a low-level constitutive promoter, lies immediately upstream of ureA. The P2 promoter is transcribed by the E sigmaH form of RNA polymerase and initiates transcription 270 bp upstream of the ureA start codon. The transcriptional start site for the sigmaA-dependent P3 promoter is located 839 bp upstream of the ureA start codon. To identify transcription factors that control ureABC expression, regulation of the P2 and P3 promoters was examined in wild-type and mutant strains. During rapid growth in minimal medium containing glucose and amino acids, CodY represses expression of the P2 and P3 promoters 30- and 60-fold, respectively. TnrA activates expression of the P3 promoter 10-fold in nitrogen-limited cells, while GlnR represses transcription from the P3 promoter 55-fold during growth on excess nitrogen. Expression of the ureABC operon increases 10-fold at the end of exponential growth in nutrient sporulation medium. This elevation in expression results from the relief of CodY-mediated repression during exponential growth and increased sigmaH-dependent transcription during stationary phase.