Effect of the delta subunit of Bacillus subtilis RNA polymerase on initiation of RNA synthesis at two bacteriophage phi 29 promoters

Mechanism of δ Mediated Transcription Activation in Bacillus subtilis: Interaction with α CTD of RNA Polymerase Stabilizes δ and Successively Facilitates the Open Complex Formation

The α CTD (C-terminal domain of the α subunit) of RNA polymerase (RNAP) is a target for transcriptional regulators. In the transcription activation at Class I, Class II, and Class III promoters of bacteria, the transcriptional regulator, binds to DNA at different sites and interacts with the α CTD to stabilize the RNAP at the promoter or it binds to the α CTD to form a prerecruitment complex that searches for its cognate binding site. This 'simple recruitment mechanism' of the transcriptional machinery at the promoter is responsible for the activation of transcription. Strikingly, in B. subtilis the binding of RNAP at the promoter stabilizes the transcriptional regulator, δ at the -41 site of the promoter DNA through an interaction with its α CTD and successively facilitates the open complex formation. Two residues R293 and K294 of α CTD (equivalent to K297 and K298 of E. coli) are involved in the interactions with δ and essential for the activation of transcription. R293 is responsible for the stabilization of δ, while K294 is responsible for facilitating the open complex formation. Based on our data we propose a new model of transcription activation by δ of B. subtilis that is similar to (its binding location and interaction with α CTD), but distinct from (the recruitment of transcription factor by RNAP at the DNA, and enhancement of the open complex formation) the model Class II promoters in bacteria.

Loss of rpoE Encoding the δ-Factor of RNA Polymerase Impacts Pathophysiology of the Streptococcus pyogenes M1T1 Strain 5448

Streptococcus pyogenes, also known as the Group A Streptococcus (GAS), is a Gram-positive bacterial pathogen of major clinical significance. Despite remaining relatively susceptible to conventional antimicrobial therapeutics, GAS still causes millions of infections and hundreds of thousands of deaths each year worldwide. Thus, a need for prophylactic and therapeutic interventions for GAS is in great demand. In this study, we investigated the importance of the gene encoding the delta (δ) subunit of the GAS RNA polymerase, rpoE, for its impact on virulence during skin and soft-tissue infection. A defined 5448 mutant with an insertionally-inactivated rpoE gene was defective for survival in whole human blood and was attenuated for both disseminated lethality and lesion size upon mono-culture infection in mouse soft tissue. Furthermore, the mutant had reduced competitive fitness when co-infected with wild type (WT) 5448 in the mouse model. We were unable to attribute this attenuation to any observable growth defect, although colony size and the ability to grow at higher temperatures were both affected when grown with nutrient-rich THY media. RNA-seq of GAS grown in THY to late log phase found that mutation of rpoE significantly impacted (>2-fold) the expression of 429 total genes (205 upregulated, 224 downregulated), including multiple virulence and “housekeeping” genes. The arc operon encoding the arginine deiminase (ADI) pathway was the most upregulated in the rpoE mutant and this could be confirmed phenotypically. Taken together, these findings demonstrate that the delta (δ) subunit of RNA polymerase is vital in GAS gene expression and virulence.

Xenogeneic silencing strategies in bacteria are dictated by RNA polymerase promiscuity

Horizontal gene transfer facilitates dissemination of favourable traits among bacteria. However, foreign DNA can also reduce host fitness: incoming sequences with a higher AT content than the host genome can misdirect transcription. Xenogeneic silencing proteins counteract this by modulating RNA polymerase binding. In this work, we compare xenogeneic silencing strategies of two distantly related model organisms: Escherichia coli and Bacillus subtilis. In E. coli, silencing is mediated by the H-NS protein that binds extensively across horizontally acquired genes. This prevents spurious non-coding transcription, mostly intragenic in origin. By contrast, binding of the B. subtilis Rok protein is more targeted and mostly silences expression of functional mRNAs. The difference reflects contrasting transcriptional promiscuity in E. coli and B. subtilis, largely attributable to housekeeping RNA polymerase σ factors. Thus, whilst RNA polymerase specificity is key to the xenogeneic silencing strategy of B. subtilis, transcriptional promiscuity must be overcome to silence horizontally acquired DNA in E. coli.

Bacteria use specific silencing proteins to prevent spurious transcription of horizontally acquired DNA. Here, Forrest et al. describe differences in silencing strategies between E. coli and Bacillus subtilis, driven by the respective specificities of the silencing protein and the RNA polymerase in each organism.

In-Culture Cross-Linking of Bacterial Cells Reveals Large-Scale Dynamic Protein-Protein Interactions at the Peptide Level

Identification of dynamic protein–protein interactions at the peptide level on a proteomic scale is a challenging approach that is still in its infancy. We have developed a system to cross-link cells directly in culture with the special lysine cross-linker bis(succinimidyl)-3-azidomethyl-glutarate (BAMG). We used the Gram-positive model bacterium Bacillus subtilis as an exemplar system. Within 5 min extensive intracellular cross-linking was detected, while intracellular cross-linking in a Gram-negative species, Escherichia coli, was still undetectable after 30 min, in agreement with the low permeability in this organism for lipophilic compounds like BAMG. We were able to identify 82 unique interprotein cross-linked peptides with <1% false discovery rate by mass spectrometry and genome-wide database searching. Nearly 60% of the interprotein cross-links occur in assemblies involved in transcription and translation. Several of these interactions are new, and we identified a binding site between the δ and β′ subunit of RNA polymerase close to the downstream DNA channel, providing a clue into how δ might regulate promoter selectivity and promote RNA polymerase recycling. Our methodology opens new avenues to investigate the functional dynamic organization of complex protein assemblies involved in bacterial growth. Data are available via ProteomeXchange with identifier PXD006287.

A Novel Function of δ Factor from Bacillus subtilis as a Transcriptional Repressor

δ, a small protein found in most Gram-positive bacteria was, for a long time, thought to be a subunit of RNA polymerase (RNAP) and was shown to be involved in recycling of RNAP at the end of each round of transcription. However, how δ participates in both up-regulation and down-regulation of genes in vivo remains unclear. We have recently shown, in addition to the recycling of RNAP, δ functions as a transcriptional activator by binding to an A-rich sequence located immediately upstream of the -35 element, consequently facilitating the open complex formation. The result had explained the mechanism of up-regulation of the genes by δ. Here, we show that Bacillus subtilis δ could also function as a transcriptional repressor. Our results demonstrate that δ binds to an A-rich sequence located near the -35 element of the spo0B promoter, the gene involved in the regulatory cascade of bacterial sporulation and inhibits the open complex formation due to steric clash with σ region 4.2. We observed a significant increase in the mRNA level of the spo0B gene in a δ-knock-out strain of B. subtilis compared with the wild-type. Thus, the results report a novel function of δ, and suggest the mechanism of down-regulation of genes in vivo by the protein.

Bacillus subtilis δ Factor Functions as a Transcriptional Regulator by Facilitating the Open Complex Formation

Most bacterial RNA polymerases (RNAP) contain five conserved subunits, viz. 2α, β, β', and ω. However, in many Gram-positive bacteria, especially in fermicutes, RNAP is associated with an additional factor, called δ. For over three decades since its identification, it had been thought that δ functioned as a subunit of RNAP to enhance the level of transcripts by recycling RNAP. In support of the previous observations, we also find that δ is involved in recycling of RNAP by releasing the RNA from the ternary complex. We further show that δ binds to RNA and is able to recycle RNAP when the length of the nascent RNA reaches a critical length. However, in this work we decipher a new function of δ. Performing biochemical and mutational analysis, we show that Bacillus subtilis δ binds to DNA immediately upstream of the promoter element at A-rich sequences on the abrB and rrnB1 promoters and facilitates open complex formation. As a result, δ facilitates RNAP to initiate transcription in the second scale, compared with minute scale in the absence of δ. Using transcription assay, we show that δ-mediated recycling of RNAP cannot be the sole reason for the enhancement of transcript yield. Our observation that δ does not bind to RNAP holo enzyme but is required to bind to DNA upstream of the -35 promoter element for transcription activation suggests that δ functions as a transcriptional regulator.

Small things considered: the small accessory subunits of RNA polymerase in Gram-positive bacteria

The DNA-dependent RNA polymerase core enzyme in Gram-positive bacteria consists of seven subunits. Whilst four of them (α2ββ(')) are essential, three smaller subunits, δ, ε and ω (∼9-21.5 kDa), are considered accessory. Both δ and ω have been viewed as integral components of RNAP for several decades; however, ε has only recently been described. Functionally these three small subunits carry out a variety of tasks, imparting important, supportive effects on the transcriptional process of Gram-positive bacteria. While ω is thought to have a wide range of roles, reaching from maintaining structural integrity of RNAP to σ factor recruitment, the only suggested function for ε thus far is in protecting cells from phage infection. The third subunit, δ, has been shown to have distinct influences in maintaining transcriptional specificity, and thus has a key role in cellular fitness. Collectively, all three accessory subunits, although dispensable under laboratory conditions, are often thought to be crucial for proper RNAP function. Herein we provide an overview of the available literature on each subunit, summarizing landmark findings that have deepened our understanding of these proteins and their function, and outline future challenges in understanding the role of these small subunits in the transcriptional process.

The δ subunit of RNA polymerase guides promoter selectivity and virulence in Staphylococcus aureus

In Gram-positive bacteria, and particularly the Firmicutes, the DNA-dependent RNA polymerase (RNAP) complex contains an additional subunit, termed the δ factor, or RpoE. This enigmatic protein has been studied for more than 30 years for various organisms, but its function is still not well understood. In this study, we investigated its role in the major human pathogen Staphylococcus aureus. We showed conservation of important structural regions of RpoE in S. aureus and other species and demonstrated binding to core RNAP that is mediated by the β and/or β' subunits. To identify the impact of the δ subunit on transcription, we performed transcriptome sequencing (RNA-seq) analysis and observed 191 differentially expressed genes in the rpoE mutant. Ontological analysis revealed, quite strikingly, that many of the downregulated genes were known virulence factors, while several mobile genetic elements (SaPI5 and prophage SA3usa) were strongly upregulated. Phenotypically, the rpoE mutant had decreased accumulation and/or activity of a number of key virulence factors, including alpha toxin, secreted proteases, and Panton-Valentine leukocidin (PVL). We further observed significantly decreased survival of the mutant in whole human blood, increased phagocytosis by human leukocytes, and impaired virulence in a murine model of infection. Collectively, our results demonstrate that the δ subunit of RNAP is a critical component of the S. aureus transcription machinery and plays an important role during infection.

Initiating nucleotide identity determines efficiency of RNA synthesis from 6S RNA templates in Bacillus subtilis but not Escherichia coli

The 6S RNA is a non-coding small RNA that binds within the active site of housekeeping forms of RNA polymerases (e.g. Eσ⁷⁰ in Escherichia coli, Eσ^A in Bacillus subtilis) and regulates transcription. Efficient release of RNA polymerase from 6S RNA regulation during outgrowth from stationary phase is dependent on use of 6S RNA as a template to generate a product RNA (pRNA). Interestingly, B. subtilis has two 6S RNAs, 6S-1 and 6S-2, but only 6S-1 RNA appears to be used efficiently as a template for pRNA synthesis during outgrowth. Here, we demonstrate that the identity of the initiating nucleotide is particularly important for the B. subtilis RNA polymerase to use RNA templates. Specifically, initiation with guanosine triphosphate (GTP) is required for efficient pRNA synthesis, providing mechanistic insight into why 6S-2 RNA does not support robust pRNA synthesis as it initiates with adenosine triphosphate (ATP). Intriguingly, E. coli RNA polymerase does not have a strong preference for initiating nucleotide identity. These observations highlight an important difference in biochemical properties of B. subtilis and E. coli RNA polymerases, specifically in their ability to use RNA templates efficiently, which also may reflect the differences in GTP and ATP metabolism in these two organisms.

The δ subunit of RNA polymerase is required for rapid changes in gene expression and competitive fitness of the cell

RNA polymerase (RNAP) is an extensively studied multisubunit enzyme required for transcription of DNA into RNA, yet the δ subunit of RNAP remains an enigmatic protein whose physiological roles have not been fully elucidated. Here, we identify a novel, so far unrecognized function of δ from Bacillus subtilis. We demonstrate that δ affects the regulation of RNAP by the concentration of the initiating nucleoside triphosphate ([iNTP]), an important mechanism crucial for rapid changes in gene expression in response to environmental changes. Consequently, we demonstrate that δ is essential for cell survival when facing a competing strain in a changing environment. Hence, although δ is not essential per se, it is vital for the cell's ability to rapidly adapt and survive in nature. Finally, we show that two other proteins, GreA and YdeB, previously implicated to affect regulation of RNAP by [iNTP] in other organisms, do not have this function in B. subtilis.

Transcription activation by the siderophore sensor Btr is mediated by ligand-dependent stimulation of promoter clearance

Bacterial transcription factors often function as DNA-binding proteins that selectively activate or repress promoters, although the biochemical mechanisms vary. In most well-understood examples, activators function by either increasing the affinity of RNA polymerase (RNAP) for the target promoter, or by increasing the isomerization of the initial closed complex to the open complex. We report that Bacillus subtilis Btr, a member of the AraC family of activators, functions principally as a ligand-dependent activator of promoter clearance. In the presence of its co-activator, the siderophore bacillibactin (BB), the Btr:BB complex enhances productive transcription, while having only modest effects on either RNAP promoter association or the production of abortive transcripts. Btr binds to two direct repeat sequences adjacent to the −35 region; recognition of the downstream motif is most important for establishing a productive interaction between the Btr:BB complex and RNAP. The resulting Btr:BB dependent increase in transcription enables the production of the ferric-BB importer to be activated by the presence of its cognate substrate.

RNA polymerase trafficking in Bacillus subtilis cells

To obtain insight into the in vivo dynamics of RNA polymerase (RNAP) on the Bacillus subtilis genome, we analyzed the distribution of the σ(A) and β' subunits of RNAP and the NusA elongation factor on the genome in exponentially growing cells using chromatin affinity precipitation coupled with gene chip mapping (ChAP-chip). In contrast to Escherichia coli RNAP, which often accumulates at the promoter-proximal region, B. subtilis RΝΑP is evenly distributed from the promoter to the coding sequences. This finding suggests that, in general, B. subtilis RNAP recruited to the promoter promptly translocates away from the promoter to form the elongation complex and proceeds without intragenic transcription attenuation. We detected RNAP accumulation in the promoter-proximal regions of some genes, most of which can be identified as transcription attenuation systems in the leader region. Our findings suggest that the differences in RNAP behavior between E. coli and B. subtilis during initiation and elongation steps might result in distinct strategies for postinitiation control of transcription. The E. coli mechanism involves trapping at the promoter and promoter-proximal pausing of RNAP in addition to transcription attenuation, whereas transcription attenuation in leader sequences is mainly employed in B. subtilis.

Bacillus subtilis RNA Polymerase Recruits the Transcription Factor Spo0A∼P to Stabilize a Closed Complex during Transcription Initiation

The Bacillus subtilis response regulator Spo0A approximately P activates transcription from the spoIIG promoter by stimulating a rate-limiting transition between the initial interaction of RNA polymerase with the promoter and initiation of RNA synthesis. Previous work showed that Spo0A exerts its effect on RNA polymerase prior to the formation of an open complex in which the DNA strands at the initiation site have been separated. To isolate the effect of Spo0A approximately P on events prior to DNA strand separation at spoIIG we studied RNA polymerase binding to DNA fragments that were truncated to contain only promoter sequences 5' to the -10 element by electrophoretic mobility shift assays. RNA polymerase bound to these fragments readily though highly reversibly, and polymerase-promoter complexes recruited Spo0A approximately P. Sequence-independent interactions between the RNA polymerase and the DNA upstream of the core promoter were important for RNA polymerase binding and essential for Spo0A approximately P recruitment, while sequence-specific Spo0A approximately P-DNA interactions positioned and stabilized RNA polymerase binding to the DNA. Spo0A approximately P decreased the dissociation rate of the complexes formed with truncated promoter templates which could contribute to the means by which Spo0A approximately P stimulates spoIIG expression.

Differences in contacts of RNA polymerases from Escherichia coli and Thermus aquaticus with lacUV5 promoter are determined by core-enzyme of RNA polymerase

The interaction of RNA polymerases from Escherichia coli and Thermus aquaticus with lacUV5 promoter was studied at various temperatures. Using DNA-protein cross-linking induced by formaldehyde, it was demonstrated that each RNA polymerase formed a unique pattern of contacts with DNA in the open promoter complex. In the case of E. coli RNA polymerase, beta and sigma subunits were involved into formation of cross-links with the promoter, whereas in the case of T. aquaticus RNA polymerase its beta subunit formed the cross-links with the promoter. A cross-linking pattern in promoter complexes of a hybrid holoenzyme comprised of the core-enzyme of E. coli and sigma subunit of T. aquaticus was similar to that of the E. coli holoenzyme. This suggests that DNA-protein contacts in the promoter complex are primarily determined by the core-enzyme of RNA polymerase. However, temperature-dependent behavior of contact formation is determined by the sigma subunit. Results of the present study indicate that the method of formaldehyde cross-linking can be employed for elucidation of differences in the structure of promoter complexes of RNA polymerases from various bacteria.

Structural properties of promoters: similarities and differences between prokaryotes and eukaryotes

During the process of transcription, RNA polymerase can exactly locate a promoter sequence in the complex maze of a genome. Several experimental studies and computational analyses have shown that the promoter sequences apparently possess some special properties, such as unusual DNA structures and low stability, which make them distinct from the rest of the genome. But most of these studies have been carried out on a particular set of promoter sequences or on promoter sequences from similar organisms. To examine whether the promoters from a wide variety of organisms share these special properties, we have carried out an analysis of sets of promoters from bacteria, vertebrates and plants. These promoters were analyzed with respect to the prediction of three different properties, such as DNA curvature, bendability and stability, which are relevant to transcription. All the promoter sequences are predicted to share certain features, such as stability and bendability profiles, but there are significant differences in DNA curvature profiles and nucleotide composition between the different organisms. These similarities and differences are correlated with some of the known facts about transcription process in the promoters from the three groups of organisms.

The Bacillus subtilis response regulator Spo0A stimulates sigmaA-dependent transcription prior to the major energetic barrier

At the spoIIG promoter phosphorylated Spo0A (Spo0A approximately P) binds 0A boxes overlapping the -35 element, interacting with RNA polymerase to facilitate open complex formation. We have compared in vitro transcription from a series of heteroduplex templates containing denatured regions within the promoters. Transcription from heteroduplex templates with 12, 8, or 6 base pairs denatured was independent of Spo0A approximately P, but heteroduplexes with 4 or 2 base pairs denatured required Spo0A approximately P for maximal levels of transcription. Investigation of the thermal dependence of transcription suggested that strand separation was the primary thermodynamic barrier to transcription initiation but indicated that Spo0A approximately P does not reduce this energetic barrier. Kinetic assays revealed that Spo0A approximately P stimulated both the rate of formation of initiated complexes as well as increasing the number of complexes capable of initiating transcription. These results imply that Spo0A approximately P stimulates transcription at least in part by stabilizing the RNA polymerase-spoIIG complex until contacts between RNA polymerase and the -10 element induce strand separation.

The TRTGn motif stabilizes the transcription initiation open complex

The effect on transcription initiation by the extended -10 motif (5'-TRTG(n)-3'), positioned upstream of the -10 region, was investigated using a series of base substitution mutations in the alpha-amylase promoter (amyP). The extended -10 motif, previously referred to as the -16 region, is found frequently in Gram-positive bacterial promoters and several extended -10 promoters from Escherichia coli. The inhibitory effects of the non-productive promoter site (amyP2), which overlaps the upstream region of amyP, were eliminated by mutagenesis of the -35 region and the TRTG motif of amyP2. Removal by mutagenesis of the competitive effects of amyP2 resulted in a reduced dependence of amyP on the TRTG motif. In the absence of the second promoter, mutations in the TRTG motif of amyP destabilized the open complex and prevented the maintenance of open complexes at low temperatures. The open complex half-life was up to 26-fold shorter in the mutant TRTG motif promoters than in the wild-type promoter. We demonstrate that the amyP TRTG motif dramatically stabilizes the open complex intermediate during transcription initiation. Even though the open complex is less stable in the mutant promoters, the region of melted DNA is the same in the wild-type and mutant promoters. However, upon addition of the first three nucleotides, which trap RNAP (RNA polymerase) in a stable initiating complex, the melted DNA region contracts at the 5'-end in a TRTG motif promoter mutant but not at the wild-type promoter, indicating that the motif contributes to maintaining DNA-strand separation.

Developmental gene expression in Bacillus subtilis crsA47 mutants reveals glucose-activated control of the gene for the minor sigma factor sigma(H)

The presence of excess glucose in growth media prevents normal sporulation of Bacillus subtilis. The crsA47 mutation, located in the gene for the vegetative phase sigma factor (sigma(A)) results in a glucose-resistant sporulation phenotype. As part of a study of the mechanisms whereby the mutation in sigma(A) overcomes glucose repression of sporulation, we examined the expression of genes involved in sporulation initiation in the crsA47 background. The crsA47 mutation had a significant impact on a variety of genes. Changes to stage II gene expression could be linked to alterations in the expression of the sinI and sinR genes. In addition, there was a dramatic increase in the expression of genes dependent on the minor sigma factor sigma(H). This latter change was paralleled by the pattern of spo0H gene transcription in cells with the crsA47 mutation. In vitro analysis of RNA polymerase containing sigma(A47) indicated that it did not have unusually high affinity for the spo0H gene promoter. The in vivo pattern of spo0H expression is not predicted by the known regulatory constraints on spo0H and suggests novel regulation mechanisms that are revealed in the crsA47 background.

RNA polymerases from Bacillus subtilis and Escherichia coli differ in recognition of regulatory signals in vitro

Adaptation of bacterial cells to diverse habitats relies on the ability of RNA polymerase to respond to various regulatory signals. Some of these signals are conserved throughout evolution, whereas others are species specific. In this study we present a comprehensive comparative analysis of RNA polymerases from two distantly related bacterial species, Escherichia coli and Bacillus subtilis, using a panel of in vitro transcription assays. We found substantial species-specific differences in the ability of these enzymes to escape from the promoter and to recognize certain types of elongation signals. Both enzymes responded similarly to other pause and termination signals and to the general E. coli elongation factors NusA and GreA. We also demonstrate that, although promoter recognition depends largely on the sigma subunit, promoter discrimination exhibited in species-specific fashion by both RNA polymerases resides in the core enzyme. We hypothesize that differences in signal recognition are due to the changes in contacts made between the beta and beta' subunits and the downstream DNA duplex.

A role for Asp75 in domain interactions in the Bacillus subtilis response regulator Spo0A

Spo0A is a two-domain response regulator required for sporulation initiation in Bacillus subtilis. Studies on response regulators have focused on the activity of each domain, but very little is known about the mechanism by which the regulatory domain inhibits the activator domain. In this study, we created a single amino acid substitution in the regulatory domain, D75S, which resulted in a dramatic decrease in sporulation in vivo. In vitro studies with the purified Spo0AD75S protein demonstrated that phosphorylation and DNA binding were comparable with wild type Spo0A. However, the mutant was unable to stimulate transcription by final sigma(A)-RNA polymerase from the Spo0A-dependent spoIIG operon promoter. We suggest that the amino acid Asp(75) and/or the region within which it resides, the alpha3-beta4 loop, are involved in the inhibitory interaction between the regulatory and activator domains of Spo0A.

Identification of new sigma K-dependent promoters using an in vitro transcription system derived from Bacillus subtilis

In Bacillus subtilis, the genes that depend on sigma K-RNA polymerase for their transcription are expressed in the mother cell compartment at later stages of sporulation. More than a dozen genes belonging to the sigma K regulon have been identified. Here I describe the identification of two additional promoters under the control of sigma K-RNA polymerase. Using a set of histidine-tagged RNA polymerases prepared from cells harvested at various times during the course of growth and sporulation (Fujita, M., Sadaie, Y., 1998. Gene 221, 185-190), transcription initiated from putative promoter sequences on a number of DNA fragments, as inferred from genome sequencing, was examined in vitro. One of these showed sigma K-dependent transcription. For further characterization of transcription initiated from this site, in vitro transcription analysis was performed using RNA polymerase holoenzyme reconstituted from purified sigma K and core RNA polymerase. Two sigma K-dependent promoters, yfhP P1 and yfhP P2, separated by a distance of about 15 bp, were thereby identified. These promoters are located immediately upstream of the yfhP gene that encodes a protein of unknown function consisting of 327 amino acids residues. The promoter strength, the rate of open complex formation and the RNA polymerase binding affinity were examined for these two promoters in comparison with other known sigma K-dependent promoters, gerE and cotD. The promoter strength displayed was in the order of gerE > cotD > yfhP P2 > yfhP P1.

Methylation of Iron-Sulfur Complexes by Trimethyl Phosphate

Reaction of [(C(4)H(9))(4)N](2)[Fe(4)S(4)(SR)(4)] (R = C(6)H(5), C(2)H(5)) with (CH(3)O)(3)PO in DMSO-d(6) afforded [(C(4)H(9))N](2){Fe(4)S(4)(SR)(3)[(CH(3)O)(2)PO(2)]} and CH(3)SR as revealed by (1)H and (31)P{(1)H} NMR spectroscopy. The more reduced species [(C(2)H(5))(4)N](3)[Fe(4)S(4)(SC(2)H(5))(4)] gave uncoordinated (CH(3)O)(2)PO(2)(-) and CH(3)SC(2)H(5) in addition to an unidentified iron thiolate species. Stoichiometric methylation of mononuclear [(C(2)H(5))(4)N](2)[Fe(SC(2)H(5))(4)] by (CH(3)O)(3)PO afforded [Fe(2)(SC(2)H(5))(6)](2)(-) as well as free (CH(3)O)(2)PO(2)(-) and CH(3)SC(2)H(5). Kinetic studies revealed the rate constant for methylation of [(C(2)H(5))(4)N](3)[Fe(4)S(4)(SC(2)H(5))(4)] to be more than 200-fold higher than that of the oxidized analogues [(C(4)H(9))(4)N](2)[Fe(4)S(4)(SR)(4)] (R = C(6)H(5), C(2)H(5)). The compound [(C(2)H(5))(4)N](2)[Fe(SC(2)H(5))(4)] had the highest rate constant, >/=5 x 10(-)(3) s(-)(1) at concentrations of 5.0 mM in complex and 1.0 mM in (CH(3)O)(3)PO. Attempts to prepare site-differentiated tetranuclear iron-sulfur complexes by removing one thiolate via methylation and addition of second, capping ligands are described. These results are discussed in the context of protein metal thiolate moieties that transfer methyl cations for substrate synthesis, such as carbon monoxide dehydrogenase/acetyl coenzyme A synthase, and repair of DNA alkylation damage.

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

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

The Spo0A sof mutations reveal regions of the regulatory domain that interact with a sensor kinase and RNA polymerase

Spo0A is a two-domain response regulator required for the initiation of sporulation in Bacillus subtilis. Spo0A is activated by phosphorylation of its regulatory domain by a multicomponent phosphorelay. To define the role of the regulatory domain in the activation of Spo0A, we have characterized four of the sof mutations in vitro. The sof mutations were identified previously as suppressors of the sporulation-negative phenotype resulting from a deletion of the gene for one of the phosphorelay components, spo0F. Like wild-type Spo0A, the transcription stimulation properties of all of the Sof proteins were dependent upon phosphorylation. Sof mutants from two classes were improved substrates for direct phosphorylation by the KinA sensor kinase, providing an explanation for their suppression properties. Two other Sof proteins showed a phosphorylation-dependent enhancement of the stability of the Sof approximately P-RNA polymerase-DNA complex. One of these mutants, Sof114, increased the stability of the Sof114 approximately P-RNAP-DNA complex without increasing its own affinity for the spoIIG promoter. A comparison of the location of the sof mutations with mutations in CheY suggests that phosphorylation of Spo0A results in the exposure of a region in the regulatory domain that interacts with RNA polymerase, thereby contributing to the signal transduction mechanism.

Contributions of the domains of the Bacillus subtilis response regulator Spo0A to transcription stimulation of the spoIIG operon

Spo0A is a response regulator that controls entry into sporulation by specifically stimulating or repressing transcription of critical developmental genes. Response regulators have at least two domains: an output transcription regulation domain and a receiver domain that inhibits the output domain. Phosphorylation of the receiver domain relieves the inhibition. We examined the in vitro transcription activation mechanism for Spo0A, phosphorylated Spo0A (Spo0A approximately P), and a deletion mutant that consists solely of the C-terminal output domain (Spo0ABD). Both Spo0A approximately P and Spo0ABD stimulated transcription from the spoIIG promoter 10-fold more efficiently than Spo0A. Spo0A approximately P and Spo0ABD induced DNA denaturation by RNA polymerase in the -10 recognition region, whereas Spo0A did not. DNase I footprint assays revealed that phosphorylation enhanced binding of intact Spo0A to the 0A boxes, while the binding of Spo0ABD was similar to that of Spo0A. Thus, activation of Spo0A by phosphorylation is not primarily due to enhanced DNA binding. The presence of a phosphorylated N terminus increased the stability of the ternary complex at the spoIIG promoter. We propose that the primary effect of phosphorylation is to expose an RNA polymerase interaction domain to promote transcription from PspoIIG.

The Bacillus subtilis regulator SinR inhibits spoIIG promoter transcription in vitro without displacing RNA polymerase

Initiation of sporulation in Bacillus subtilis is controlled by several regulators which affect activation by phosphorylation of the key response regulator Spo0A or transcription of Spo0A-P-dependent genes. In vivo overexpression of one of these regulators, sinR , results in suppression of transcription from the Spo0A-P-dependent promoters of spo0A , spoIIA , spoIIE and spoIIG and in vitro SinR binds to the promoters of the spoIIA operon and the spo0A gene. In this study we have demonstrated that in vitro SinR directly repressed Spo0A- P-dependent transcription by B.subtilis RNA polymerase from the spoIIG operon promoter. SinR inhibited transcription prior to formation of heparin-resistant complexes but did not displace RNA polymerase from the spoIIG promoter. DNase I protection studies demonstrated that SinR protected a large region of the spoIIG promoter and induced DNase I hypersensitive sites, particularly around the 0A boxes, at the same positions as those induced by zinc. Since binding of zinc induces bends in the DNA, we concluded that SinR binding also altered the conformation of the spoIIG promoter. We propose that SinR-induced conformational changes in Spo0A-dependent promoters prevent activation of trans-cription by Spo0A-P.

A negative regulator linking chromosome segregation to developmental transcription in Bacillus subtilis

The SpoOJA and SpoOJB proteins of Bacillus subtilis are similar to the ParA and ParB plasmid-partitioning proteins, respectively, and mutation of spoOJB prevents the expression of stage II genes of sporulation. This phenotype is a consequence of SpoOJA activity in the absence of SpoOJB, and its basis was unknown. In the studies reported here, SpoOJA was found specifically to dissociate transcription initiation complexes formed in vitro by the phosphorylated sporulation transcription factor SpoOA and RNA polymerase with the spollG promoter. This repressor-like activity is likely to be the basis for preventing the onset of differentiation in vivo. SpoOJB is known to neutralize SpoOJA activity in vivo and also to interact with a mitotic-like apparatus responsible for chromosome partitioning. These data suggest that SpoOJA and SpoOJB form a regulatory link between chromosome partition and development gene expression.

DNA strand separation during activation of a developmental promoter by the Bacillus subtilis response regulator Spo0A

Spo0A is the central regulator of commitment to sporulation in Bacillus subtilis. Spo0A is a member of the response regulator family of proteins and both represses and stimulates transcription from promoters when activated. In vivo Spo0A activation takes place by phosphorylation and in vitro activation can be accomplished by phosphorylation or removal of the N-terminal domain of the protein. We have examined the mechanism of Spo0A stimulation of transcription from the promoter of the spoIIG operon. This operon encodes one of the first compartment specific sigma factors whose appearance regulates sporulation development. When activated Spo0A was incubated with RNA polymerase and a DNA fragment containing the spoIIG promoter, bases between -13 and -3, relative to the start site of transcription, were denatured. Addition of activated Spo0A or RNA polymerase alone did not induce denaturation. Heteroduplex templates that contained the nontemplate sequence of the wild-type promoter on both strands between positions -3 and -13 were efficiently transcribed without activated Spo0A. These data suggest that DNA strand separation is a two-step process and that the activation of Spo0A creates a form that interacts with the polymerase to induce the first of the two steps.

DNA-melting at the Bacillus subtilis flagellin promoter nucleates near -10 and expands unidirectionally

A central step in promoter activation by RNA polymerase (RNAP) is the localized separation of the DNA strands to form the transcription bubble. We have used potassium permanganate footprinting to monitor DNA strand-separation by the Bacillus subtilis sigmaD RNAP at the strong promoter, Phag, directing transcription of flagellin. The susceptibility of individual thymine bases to permanganate oxidation is influenced by temperature, Mg2+, nucleotides, and the RNAP delta subunit. In the absence of delta, sigmaD RNAP establishes a partially opened complex even at 0 degrees C with permanganate reactivity localized between -11 and -4 (RP(-4)). The region of strand separation expands to near -1 at 20 degrees C (RP(-1)) and to +3 at 40 degrees C (RP(+3)). The delta subunit inhibits the downstream propagation of the transcription bubble and thereby increases the concentration of early intermediates in the melting pathway. Indeed, E delta sigmaD forms a distinct nucleated complex (RPn) at 0 degrees C with a structural distortion localized to an AT base step within the -10 element. We propose a model for promoter melting in which strand separation nucleates within the conserved -10 consensus and subsequently propagates downstream. Mg2+ and nucleoside triphosphates (NTPs) favor the downstream propagation of the transcription bubble and strongly stimulate the RP(-1) to RP(+3) conversion. The NTP effects are apparently mediated by binding of substrate to the initiating NTP site: purines are more effective than pyrimidines and GMP alone can greatly increase the level of DNA-melting. The binding of substrates, but not Mg2+ alone, can effectively overcome the anti-melting effect of delta.

Compilation and analysis of Bacillus subtilis sigma A-dependent promoter sequences: evidence for extended contact between RNA polymerase and upstream promoter DNA

Sequence analysis of 236 promoters recognized by the Bacillus subtilis sigma A-RNA polymerase reveals an extended promoter structure. The most highly conserved bases include the -35 and -10 hexanucleotide core elements and a TG dinucleotide at position -15, -14. In addition, several weakly conserved A and T residues are present upstream of the -35 region. Analysis of dinucleotide composition reveals A2- and T2-rich sequences in the upstream promoter region (-36 to -70) which are phased with the DNA helix: An tracts are common near -43, -54 and -65; Tn tracts predominate at the intervening positions. When compared with larger regions of the genome, upstream promoter regions have an excess of An and Tn sequences for n > 4. These data indicate that an RNA polymerase binding site affects DNA sequence as far upstream as -70. This sequence conservation is discussed in light of recent evidence that the alpha subunits of the polymerase core bind DNA and that the promoter may wrap around RNA polymerase.

Pathway of promoter melting by Bacillus subtilis RNA polymerase at a stable RNA promoter: effects of temperature, delta protein, and sigma factor mutations

Bacillus subtilis RNA polymerase (RNAP) contains a catalytic core (beta beta' alpha 2; or E) associated with one of several sigma factors, which determine promoter recognition, and delta protein, which enhances promoter selectivity. We have shown previously that specific mutations in sigma A region 2.3, or addition of delta, decrease the ability of RNAP to melt the ilv-leu promoter. Here we extend these studies to a stable RNA promoter, PtmS, which controls transcription of seven tRNA genes. KMnO4 footprinting was used to visualize DNA melting at PtmS as a function of both temperature and the protein composition of the RNAP holoenzyme. We propose that the pathway leading to productive initiation includes several intermediates: a closed complex (RPc), a complex in which DNA melting has nucleated within the conserved TATA element (RPn), and an open complex in which DNA-melting extends to at least -4 (RPo1). RNAP reconstituted with either of two mutant sigma A proteins, Y189A and W192A, was defective for both the nucleation and propagation of the transcription bubble while a third sigma A mutant, W193A, allows normal nucleation of DNA-melting, but does not efficiently propagate the melted region downstream.

Phosphorylation of Spo0A activates its stimulation of in vitro transcription from the Bacillus subtilis spoIIG operon

The spoIIG operon of Bacillus subtilis codes for a sporulation-specific sigma factor, sigma E. In vivo expression of the spoIIG promoter is activated shortly after the onset of sporulation and is dependent on kinA, spo0F, spo0B and spo0A genes. The products of these genes have been shown to participate in a phosphorelay reaction in vitro, culminating in phosphorylation of the transcription factor, Spo0A. The effect of Spo0A phosphorylation on in vitro transcription from the spoIIG promoter was determined. Aliquots from phosphorelay reactions enhanced spoIIG promoter activity 10-fold in transcription assays and stimulation of transcription was dependent on Spo0A phosphorylation. Our results provide biochemical evidence that Spo0A and the phosphorelay form a signal transduction pathway which activates spoII gene expression in development.

The main early and late promoters of Bacillus subtilis phage phi 29 form unstable open complexes with sigma A-RNA polymerase that are stabilized by DNA supercoiling

Most Escherichia coli promoters studied so far form stable open complexes with sigma 70-RNA polymerase which have relatively long half-lives and, therefore, are resistant to a competitor challenge. A few exceptions are nevertheless known. The analysis of a number of promoters in Bacillus subtilis has suggested that the instability of open complexes formed by the vegetative sigma A-RNA polymerase may be a more general phenomenon than in Escherichia coli. We show that the main early and late promoters from the Bacillus subtilis phage phi 29 form unstable open complexes that are stabilized either by the formation of the first phosphodiester bond between the initiating nucleoside triphosphates or by DNA supercoiling. The functional characteristics of these two strong promoters suggest that they are not optimized for a tight and stable RNA polymerase binding. Their high activity is probably the consequence of the efficiency of further steps leading to the formation of an elongation complex.

Mechanism of initiation of transcription by Bacillus subtilis RNA polymerase at several promoters

The behavior of the major vegetative cell RNA polymerase of Bacillus subtilis, E sigma A, during initiation of transcription was compared to that of its Escherichia coli counterpart, E sigma 70, at several promoters known to be actively transcribed by both RNA polymerases. Challenge experiments using heparin, restriction endonucleases, and competing promoter DNA under various conditions showed that, at several promoters, complexes with B. subtilis RNA polymerase formed in the absence of nucleoside triphosphates were unstable. These complexes produced DNase I footprints that were less extended than those produced by the E. coli enzyme at the same promoters. Further, in the presence of certain combinations of nucleoside triphosphates, conditions that allow production of abortive oligonucleotides, these B. subtilis RNA polymerase complexes remained dissociable. Thus, at these promoters, the B. subtilis enzyme interacted with the DNA and reached a catalytically active initial transcribing complex without becoming committed to the template. At these same promoters, E. coli RNA polymerase formed stable open complexes before forming any phosphodiester bonds. B. subtilis initial transcribing complexes also remained sensitive to the drug rifampicin until a later stage in the initiation process than did the corresponding E. coli complexes. At one promoter, B. subtilis E sigma A and E. coli E sigma 70 behaved similarly, forming stable open complexes in the absence of any nucleoside triphosphates.

Separation of Escherichia coli RNA polymerase sigma-70 holoenzyme from core enzyme on heparin-Sepharose columns

A method is described for the rapid purification of DNA-dependent RNA polymerase sigma-70 holoenzyme from Escherichia coli. The essential step in this protocol involves the differential elution of sigma-70 holoenzyme from core polymerase on a heparin-Sepharose column. Using a linear gradient of KCl, holoenzyme was found to elute at 0.25 M whereas core polymerase eluted at 0.35 M. From 20 g of cells, up to 1 mg of RNA polymerase holoenzyme could be isolated in two days. The preparations were greater than 95% pure with respect to protein, and saturated with the sigma subunit.