Multiple regions on the Escherichia coli heat shock transcription factor sigma32 determine core RNA polymerase binding specificity

Mutations compensating for the fitness cost of rifampicin resistance in Escherichia coli exert pleiotropic effect on RNA polymerase catalysis

The spread of drug-resistant bacteria represents one of the most significant medical problems of our time. Bacterial fitness loss associated with drug resistance can be counteracted by acquisition of secondary mutations, thereby enhancing the virulence of such bacteria. Antibiotic rifampicin (Rif) targets cellular RNA polymerase (RNAP). It is potent broad spectrum drug used for treatment of bacterial infections. We have investigated the compensatory mechanism of the secondary mutations alleviating Rif resistance (Rifr) on biochemical, structural and fitness indices. We find that substitutions in RNAP genes compensating for the growth defect caused by βQ513P and βT563P Rifr mutations significantly enhanced bacterial relative growth rate. By assaying RNAP purified from these strains, we show that compensatory mutations directly stimulated basal transcriptional machinery (2-9-fold) significantly improving promoter clearance step of the transcription pathway as well as elongation rate. Molecular modeling suggests that compensatory mutations affect transcript retention, substrate loading, and nucleotidyl transfer catalysis. Strikingly, one of the identified compensatory substitutions represents mutation conferring rifampicin resistance on its own. This finding reveals an evolutionary process that creates more virulent species by simultaneously improving the fitness and augmenting bacterial drug resistance.

Catalase Expression in Azospirillum brasilense Sp7 Is Regulated by a Network Consisting of OxyR and Two RpoH Paralogs and Including an RpoE1→RpoH5 Regulatory Cascade

The genome of Azospirillum brasilense encodes five RpoH sigma factors: two OxyR transcription regulators and three catalases. The aim of this study was to understand the role they play during oxidative stress and their regulatory interconnection. Out of the 5 paralogs of RpoH present in A. brasilense, inactivation of only rpoH1 renders A. brasilense heat sensitive. While transcript levels of rpoH1 were elevated by heat stress, those of rpoH3 and rpoH5 were upregulated by H₂O₂ Catalase activity was upregulated in A. brasilense and its rpoH::km mutants in response to H₂O₂ except in the case of the rpoH5::km mutant, suggesting a role for RpoH5 in regulating inducible catalase. Transcriptional analysis of the katN, katAI, and katAII genes revealed that the expression of katN and katAII was severely compromised in the rpoH3::km and rpoH5::km mutants, respectively. Regulation of katN and katAII by RpoH3 and RpoH5, respectively, was further confirmed in an Escherichia coli two-plasmid system. Regulation of katAII by OxyR2 was evident by a drastic reduction in growth, KatAII activity, and katAII::lacZ expression in an oxyR2::km mutant. This study reports the involvement of RpoH3 and RpoH5 sigma factors in regulating oxidative stress response in alphaproteobacteria. We also report the regulation of an inducible catalase by a cascade of alternative sigma factors and an OxyR. Out of the three catalases in A. brasilense, those corresponding to katN and katAII are regulated by RpoH3 and RpoH5, respectively. The expression of katAII is regulated by a cascade of RpoE1→RpoH5 and OxyR2.IMPORTANCE In silico analysis of the A. brasilense genome showed the presence of multiple paralogs of genes involved in oxidative stress response, which included 2 OxyR transcription regulators and 3 catalases. So far, Deinococcus radiodurans and Vibrio cholerae are known to harbor two paralogs of OxyR, and Sinorhizobium meliloti harbors three catalases. We do not yet know how the expression of multiple catalases is regulated in any bacterium. Here we show the role of multiple RpoH sigma factors and OxyR in regulating the expression of multiple catalases in A. brasilense Sp7. Our work gives a glimpse of systems biology of A. brasilense used for responding to oxidative stress.

When, how and why? Regulated proteolysis by the essential FtsH protease in Escherichia coli

Cellular proteomes are dynamic and adjusted to permanently changing conditions by ATP-fueled proteolytic machineries. Among the five AAA+ proteases in Escherichia coli FtsH is the only essential and membrane-anchored metalloprotease. FtsH is a homohexamer that uses its ATPase domain to unfold and translocate substrates that are subsequently degraded without the need of ATP in the proteolytic chamber of the protease domain. FtsH eliminates misfolded proteins in the context of general quality control and properly folded proteins for regulatory reasons. Recent trapping approaches have revealed a number of novel FtsH substrates. This review summarizes the substrate diversity of FtsH and presents details on the surprisingly diverse recognition principles of three well-characterized substrates: LpxC, the key enzyme of lipopolysaccharide biosynthesis; RpoH, the alternative heat-shock sigma factor and YfgM, a bifunctional membrane protein implicated in periplasmic chaperone functions and cytoplasmic stress adaptation.

Purification and biochemical characterization of DnaK and its transcriptional activator RpoH from Neisseria gonorrhoeae

DnaK plays a central role in stress response in the important human pathogen Neisseria gonorrhoeae. The genes encoding the DnaK chaperone machine (DnaK/DnaJ/GrpE) in N. gonorrhoeae are transcribed from RpoH (σ(32))-dependent promoters. In this study, we cloned, purified and biochemically characterised N. gonorrhoeae DnaK (NgDnaK) and RpoH. The NgDnaK and RpoH sequences are 73 and 50 % identical to the sequences of their respective E. coli counterparts. Similar to EcDnaK, nucleotide-free NgDnaK exists as a mix of monomers, dimers and higher oligomeric species in solution, and dissociates into monomers on addition of ATP. Like E. coli σ(32), RpoH of N. gonorrhoeae is monomeric in solution. Kinetic analysis of the basal ATPase activity of purified NgDnaK revealed a V max of 193 pmol phosphate released per minute per microgram DnaK (which is significantly higher than reported basal ATPase activity of EcDnaK), and the turnover number against ATP was 0.4 min(-1) under our assay conditions. Nucleotide-free NgDnaK bound a short model substrate, NR-peptide, with micromolar affinity close to that reported for EcDnaK. Our analysis showed that interaction between N. gonorrhoeae RpoH and DnaK appears to be ATP-dependent and non-specific, in stark contrast to the E. coli DnaK system where σ(32) and DnaK interact as monomers even in the absence of ATP. Sequence comparison showed that the DnaK-binding site of σ(32) is not conserved in RpoH. Our findings suggest that the mechanism of DnaK/RpoH recognition in N. gonorrhoeae is different from that in E. coli.

Convergence of the transcriptional responses to heat shock and singlet oxygen stresses

Cells often mount transcriptional responses and activate specific sets of genes in response to stress-inducing signals such as heat or reactive oxygen species. Transcription factors in the RpoH family of bacterial alternative σ factors usually control gene expression during a heat shock response. Interestingly, several α-proteobacteria possess two or more paralogs of RpoH, suggesting some functional distinction. We investigated the target promoters of Rhodobacter sphaeroides RpoH_I and RpoH_II using genome-scale data derived from gene expression profiling and the direct interactions of each protein with DNA in vivo. We found that the RpoH_I and RpoH_II regulons have both distinct and overlapping gene sets. We predicted DNA sequence elements that dictate promoter recognition specificity by each RpoH paralog. We found that several bases in the highly conserved TTG in the −35 element are important for activity with both RpoH homologs; that the T-9 position, which is over-represented in the RpoH_I promoter sequence logo, is critical for RpoH_I–dependent transcription; and that several bases in the predicted −10 element were important for activity with either RpoH_II or both RpoH homologs. Genes that are transcribed by both RpoH_I and RpoH_II are predicted to encode for functions involved in general cell maintenance. The functions specific to the RpoH_I regulon are associated with a classic heat shock response, while those specific to RpoH_II are associated with the response to the reactive oxygen species, singlet oxygen. We propose that a gene duplication event followed by changes in promoter recognition by RpoH_I and RpoH_II allowed convergence of the transcriptional responses to heat and singlet oxygen stress in R. sphaeroides and possibly other bacteria.

An important property of living systems is their ability to survive under conditions of stress such as increased temperature or the presence of reactive oxygen species. Central to the function of these stress responses are transcription factors that activate specific sets of genes needed for this response. Despite the central role of stress responses across all forms of life, the processes driving their organization and evolution across organisms are poorly understood. This paper uses genomic, computational, and mutational analyses to dissect stress responses controlled by two proteins that are each members of the RpoH family of alternative σ factors. RpoH family members usually control gene expression during a heat shock response. However, the photosynthetic bacterium Rhodobacter sphaeroides and several other α-proteobacteria possess two or more paralogs of RpoH, suggesting some functional distinction. Our findings predict that a gene duplication event followed by changes in DNA recognition by RpoH_I and RpoH_II allowed convergence of the transcriptional responses to heat and singlet oxygen stress in R. sphaeroides and possibly other bacteria. Our approach and findings should interest those studying the evolution of transcription factors or the signal transduction pathways that control stress responses.

A two-subunit bacterial sigma-factor activates transcription in Bacillus subtilis

The sigma-like factor YvrI and coregulator YvrHa activate transcription from a small set of conserved promoters in Bacillus subtilis. We report here that these two proteins independently contribute sigma-region 2 and sigma-region 4 functions to a holoenzyme-promoter DNA complex. YvrI binds RNA polymerase (RNAP) through a region 4 interaction with the beta-subunit flap domain and mediates specific promoter recognition but cannot initiate DNA melting at the -10 promoter element. Conversely, YvrHa possesses sequence similarity to a conserved core-binding motif in sigma-region 2 and binds to the N-terminal coiled-coil element in the RNAP beta'-subunit previously implicated in interaction with region 2 of sigma-factors. YvrHa plays an essential role in stabilizing the open complex and interacts specifically with the N-terminus of YvrI. Based on these results, we propose that YvrHa is situated in the transcription complex proximal to the -10 element of the promoter, whereas YvrI is responsible for -35 region recognition. This system presents an unusual example of a two-subunit bacterial sigma-factor.

An extracytoplasmic function sigma factor controls beta-lactamase gene expression in Bacillus anthracis and other Bacillus cereus group species

The susceptibility of most Bacillus anthracis strains to beta-lactam antibiotics is intriguing considering that the closely related species Bacillus cereus and Bacillus thuringiensis typically produce beta-lactamases and the B. anthracis genome harbors two beta-lactamase genes, bla1 and bla2. We show that beta-lactamase activity associated with B. anthracis is affected by two genes, sigP (BA2502) and rsiP (BA2503), predicted to encode an extracytoplasmic function sigma factor and an anti-sigma factor, respectively. Deletion of the sigP-rsiP locus abolished beta-lactamase activity in a naturally occurring penicillin-resistant strain and had no effect on beta-lactamase activity in a prototypical penicillin-susceptible strain. Complementation with sigP and rsiP from the penicillin-resistant strain, but not with sigP and rsiP from the penicillin-susceptible strain, conferred constitutive beta-lactamase activity in both mutants. These results are attributed to a nucleotide deletion near the 5' end of rsiP in the penicillin-resistant strain that is predicted to result in a nonfunctional protein. B. cereus and B. thuringiensis sigP and rsiP homologues are required for inducible penicillin resistance in these species. Expression of the B. cereus or B. thuringiensis sigP and rsiP genes in a B. anthracis sigP-rsiP-null mutant confers inducible production of beta-lactamase activity, suggesting that while B. anthracis contains the genes necessary for sensing beta-lactam antibiotics, the B. anthracis sigP and rsiP gene products are not sufficient for bla induction.

Mutational analysis of Escherichia coli sigma28 and its target promoters reveals recognition of a composite -10 region, comprised of an 'extended -10' motif and a core -10 element

Sigma28 controls the expression of flagella-related genes and is the most widely distributed alternative sigma factor, present in motile Gram-positive and Gram-negative bacteria. The distinguishing feature of sigma28 promoters is a long -10 region (GCCGATAA). Despite the fact that the upstream GC is highly conserved, previous studies have not indicated a functional role for this motif. Here we examine the functional relevance of the GCCG motif and determine which residues in sigma28 participate in its recognition. We find that the GCCG motif is a functionally important composite element. The upstream GC constitutes an extended -10 motif and is recognized by R91, a residue in Domain 3 of sigma28. The downstream CG is the upstream edge of -10 region of the promoter; two residues in Region 2.4, D81 and R84, participate in its recognition. Consistent with their role in base-specific recognition of the promoter, R91, D81 and D84 are universally conserved in sigma28 orthologues. Sigma28 is the second Group 3 sigma shown to use an extended -10 region in promoter recognition, raising the possibility that other Group 3 sigmas will do so as well.

Dissection of recognition determinants of Escherichia coli sigma32 suggests a composite -10 region with an 'extended -10' motif and a core -10 element

Sigma32 controls expression of heat shock genes in Escherichia coli and is widely distributed in proteobacteria. The distinguishing feature of sigma32 promoters is a long -10 region (CCCCATNT) whose tetra-C motif is important for promoter activity. Using alanine-scanning mutagenesis of sigma32 and in vivo and in vitro assays, we identified promoter recognition determinants of this motif. The most downstream C (-13) is part of the -10 motif; our work confirms and extends recognition determinants of -13C. Most importantly, our work suggests that the two upstream Cs (-16, -15) constitute an 'extended -10' recognition motif that is recognized by K130, a residue universally conserved in beta- and gamma-proteobacteria. This residue is located in the alpha-helix of sigmaDomain 3 that mediates recognition of the extended -10 promoter motif in other sigmas. K130 is not conserved in alpha- and delta-/epsilon-proteobacteria and we found that sigma32 from the alpha-proteobacterium Caulobacter crescentus does not need the extended -10 motif for high promoter activity. This result supports the idea that K130 mediates extended -10 recognition. Sigma32 is the first Group 3 sigma shown to use the 'extended -10' recognition motif.

Convergence of molecular, modeling, and systems approaches for an understanding of the Escherichia coli heat shock response

The heat shock response (HSR) is a homeostatic response that maintains the proper protein-folding environment in the cell. This response is universal, and many of its components are well conserved from bacteria to humans. In this review, we focus on the regulation of one of the most well-characterized HSRs, that of Escherichia coli. We show that even for this simple model organism, we still do not fully understand the central component of heat shock regulation, a chaperone-mediated negative feedback loop. In addition, we review other components that contribute to the regulation of the HSR in E. coli and discuss how these additional components contribute to regulation. Finally, we discuss recent genomic experiments that reveal additional functional aspects of the HSR.

Bacterial growth and cell division: a mycobacterial perspective

The genus Mycobacterium is best known for its two major pathogenic species, M. tuberculosis and M. leprae, the causative agents of two of the world's oldest diseases, tuberculosis and leprosy, respectively. M. tuberculosis kills approximately two million people each year and is thought to latently infect one-third of the world's population. One of the most remarkable features of the nonsporulating M. tuberculosis is its ability to remain dormant within an individual for decades before reactivating into active tuberculosis. Thus, control of cell division is a critical part of the disease. The mycobacterial cell wall has unique characteristics and is impermeable to a number of compounds, a feature in part responsible for inherent resistance to numerous drugs. The complexity of the cell wall represents a challenge to the organism, requiring specialized mechanisms to allow cell division to occur. Besides these mycobacterial specializations, all bacteria face some common challenges when they divide. First, they must maintain their normal architecture during and after cell division. In the case of mycobacteria, that means synthesizing the many layers of complex cell wall and maintaining their rod shape. Second, they need to coordinate synthesis and breakdown of cell wall components to maintain integrity throughout division. Finally, they need to regulate cell division in response to environmental stimuli. Here we discuss these challenges and the mechanisms that mycobacteria employ to meet them. Because these organisms are difficult to study, in many cases we extrapolate from information known for gram-negative bacteria or more closely related GC-rich gram-positive organisms.

Activity of Rhodobacter sphaeroides RpoHII, a second member of the heat shock sigma factor family

We have identified a second RpoH homolog, RpoH(II), in the alpha-proteobacterium Rhodobacter sphaeroides. Primary amino acid sequence comparisons demonstrate that R. sphaeroides RpoH(II) belongs to a phylogenetically distinct group with RpoH orthologs from alpha-proteobacteria that contain two rpoH genes. Like its previously identified paralog, RpoH(I), RpoH(II) is able to complement the temperature-sensitive phenotype of an Escherichia coli sigma(32) (rpoH) mutant. In addition, we show that recombinant RpoH(I) and RpoH(II) each transcribe two E. coli sigma(32)-dependent promoters (rpoD P(HS) and dnaK P1) when reconstituted with E. coli core RNA polymerase. We observed differences, however, in the ability of each sigma factor to recognize six R. sphaeroides promoters (cycA P1, groESL(1), rpoD P(HS), dnaK P1, hslO, and ecfE), all of which resemble the E. coli sigma(32) promoter consensus. While RpoH(I) reconstituted with R. sphaeroides core RNA polymerase transcribed all six promoters, RpoH(II) produced detectable transcripts from only four promoters (cycA P1, groESL(1), hslO, and ecfE). These results, in combination with previous work demonstrating that an RpoH(I) mutant mounts a typical heat shock response, suggest that while RpoH(I) and RpoH(II) have redundant roles in response to heat, they may also have roles in response to other environmental stresses.

The alternative sigma factor RpoH2 is required for salt tolerance in Sinorhizobium sp. strain BL3

The objectives of this investigation were to isolate the rpoH2 gene encoding an alternative sigma factor from Sinorhizobium sp. BL3 and to determine its role in exopolysaccharide (EPS) synthesis, salt tolerance and symbiosis with Phaseolus lathyroides. The rpoH2 gene of Rhizobium sp. strain TAL1145 is known to be required for EPS synthesis and effective nodulation of Leucaena leucocephala. Three overlapping cosmid clones containing the rpoH2 gene of BL3 were isolated by complementing an rpoH2 mutant of TAL1145 for EPS production. From one of these cosmids, rpoH2 of BL3 was identified within a 3.0-kb fragment by subcloning and sequencing. The cloned rpoH2 gene of BL3 restored both EPS production and nodulation defects of the TAL1145 rpoH2 mutants. Three rpoH2 mutants of BL3 were constructed by transposon-insertion mutagenesis. These mutants of BL3 grew normally in complete or minimal medium and were not defective in EPS synthesis, nodulation and nitrogen fixation, but they failed to grow in salt stress conditions. The mutants complemented with cloned rpoH2 from either BL3 or TAL1145 showed higher levels of salt tolerance than BL3. The expression of rpoH2 in BL3 started increasing during the exponential phase and reached the highest level in the mid-stationary phase. These results indicate that RpoH2 is required for salt tolerance in Sinorhizobium sp. BL3, and it may have additional roles during the stationary phase.

Mutational analysis of Escherichia coli heat shock transcription factor sigma 32 reveals similarities with sigma 70 in recognition of the -35 promoter element and differences in promoter DNA melting and -10 recognition

Upon the exposure of Escherichia coli to high temperature (heat shock), cellular levels of the transcription factor sigma32 rise greatly, resulting in the increased formation of the sigma32 holoenzyme, which is capable of transcription initiation at heat shock promoters. Higher levels of heat shock proteins render the cell better able to cope with the effects of higher temperatures. To conduct structure-function studies on sigma32 in vivo, we have carried out site-directed mutagenesis and employed a previously developed system involving sigma32 expression from one plasmid and a beta-galactosidase reporter gene driven by the sigma32-dependent groE promoter on another in order to monitor the effects of single amino acid substitutions on sigma32 activity. It was found that the recognition of the -35 region involves similar amino acid residues in regions 4.2 of E. coli sigma32 and sigma70. Three conserved amino acids in region 2.3 of sigma32 were found to be only marginally important in determining activity in vivo. Differences between sigma32 and sigma70 in the effects of mutation in region 2.4 on the activities of the two sigma factors are consistent with the pronounced differences between both the amino acid sequences in this region and the recognized promoter DNA sequences.

Structure-function studies of Escherichia coli RpoH (sigma32) by in vitro linker insertion mutagenesis

The sigma factor RpoH (sigma(32)) is the key regulator of the heat shock response in Escherichia coli. Many structural and functional properties of the sigma factor are poorly understood. To gain further insight into RpoH regions that are either important or dispensable for its cellular activity, we generated a collection of tetrapeptide insertion variants by a recently established in vitro linker insertion mutagenesis technique. Thirty-one distinct insertions were obtained, and their sigma factor activity was analyzed by using a groE-lacZ reporter fusion in an rpoH-negative background. Our study provides a map of permissive sites which tolerate linker insertions and of functionally important regions at which a linker insertion impairs sigma factor activity. Selected linker insertion mutants will be discussed in the light of known sigma factor properties and in relation to a modeled structure of an RpoH fragment containing region 2.

RNA polymerase holoenzyme: structure, function and biological implications

The past three years have marked the breakthrough in our understanding of the structural and functional organization of RNA polymerase. The latest major advance was the high-resolution structures of bacterial RNA polymerase holoenzyme and the holoenzyme in complex with promoter DNA. Together with an array of genetic, biochemical and biophysical data accumulated to date, the structures provide a comprehensive view of dynamic interactions between the major components of transcription machinery during the early stages of the transcription cycle. They include the binding of sigma factor to the core enzyme, and the recognition of promoter sequences and DNA melting by holoenzyme, transcription initiation and promoter clearance.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Kinetic studies and structural models of the association of E. coli sigma(70) RNA polymerase with the lambdaP(R) promoter: large scale conformational changes in forming the kinetically significant intermediates

The kinetics of interaction of Esigma(70) RNA polymerase (R) with the lambdaP(R) promoter (P) were investigated by filter binding over a broad range of temperatures (7.3-42 degrees C) and concentrations of RNA polymerase (1-123 nM) in large excess over promoter DNA. Under all conditions examined, the kinetics of formation of competitor-resistant complexes (I(2), RP(o)) are single-exponential with first order rate constant beta(CR). Interpretation of the polymerase concentration dependence of beta(CR) in terms of the three step mechanism of open complex formation yields the equilibrium constant K(1) for formation of the first kinetically significant intermediate (I(1)) and the forward rate constant (k(2)) for the conformational change converting I(1) to the second kinetically significant intermediate I(2): R + P-->(K(1))<--I(1)(k(2))-->I(2). Use of rapid quench mixing allows K(1) and k(2) to be individually determined over the entire temperature range investigated, previously not possible at this promoter using manual mixing. Given the large (>60 bp) interface formed in I(1), its relatively small binding constant K(1) at 37 degrees C at this [salt] (approximately 6 x 10(6) M(-1)) strongly argues that binding free energy is used to drive large-scale structural changes in polymerase and/or promoter DNA or other coupled processes. Evidence for coupling of protein folding is provided by the large and negative activation heat capacity of k(a)[DeltaC(o,++)(a)= -1.5(+/-0.2)kcal K(-1)], now shown to originate directly from formation of I(1) [DeltaC(o)(1)= -1.4(+/-0.3)kcal K(-1)] rather than from the formation of I(2) as previously proposed. The isomerization I(1)-->I(2) exhibits relatively slow kinetics and has a very large temperature-independent Arrhenius activation energy [E(act)(2)= 34(+/-2)kcal]. This kinetic signature suggests that formation of the transition state (I(1)-I(2)++ involves large conformational changes dominated by changes in the exposure of polar and/or charged surface to water. Structural and biochemical data lead to the following hypotheses to interpret these results. We propose that formation of I(1) involves coupled folding of unstructured regions of polymerase (beta, beta' and sigma(70)) and bending of promoter DNA (in the -10 region). We propose that interactions with region 2 of sigma(70) and possibly domain 1 of beta induce a kink at the -11/-12 base pairs of the lambdaP(R) promoter which places the downstream DNA (-5 to +20) in the jaws of the beta and beta' subunits of polymerase in I(1). These early interactions of beta and beta' with the DNA downstream of position -5 trigger jaw closing (with coupled folding) and subsequent steps of DNA opening.

Crystal structure of the Bacillus stearothermophilus anti-sigma factor SpoIIAB with the sporulation sigma factor sigmaF

Cell type-specific transcription during Bacillus sporulation is established by sigmaF. SpoIIAB is an anti-sigma that binds and negatively regulates sigmaF, as well as a serine kinase that phosphorylates and inactivates the anti-anti-sigma SpoIIAA. The crystal structure of sigmaF bound to the SpoIIAB dimer in the low-affinity, ADP form has been determined at 2.9 A resolution. SpoIIAB adopts the GHKL superfamily fold of ATPases and histidine kinases. A domain of sigmaF contacts both SpoIIAB monomers, while 80% of the sigma factor is disordered. The interaction occludes an RNA polymerase binding surface of sigmaF, explaining the SpoIIAB anti-sigma activity. The structure also explains the specificity of SpoIIAB for its target sigma factors and, in combination with genetic and biochemical data, provides insight into the mechanism of SpoIIAA anti-anti-sigma activity.

Structure of the bacterial RNA polymerase promoter specificity sigma subunit

The sigma subunit is the key regulator of bacterial transcription. Proteolysis of Thermus aquaticus sigma(A), which occurred in situ during crystallization, reveals three domains, sigma(2), sigma(3), and sigma(4), connected by flexible linkers. Crystal structures of each domain were determined, as well as of sigma(4) complexed with -35 element DNA. Exposed surfaces of each domain are important for RNA polymerase binding. Universally conserved residues important for -10 element recognition and melting lie on one face of sigma(2), while residues important for extended -10 recognition lie on sigma(3). Genetic studies correctly predicted that a helix-turn-helix motif in sigma(4) recognizes the -35 element but not the details of the protein-DNA interactions. Positive control mutants in sigma(4) cluster in two regions, positioned to interact with activators bound just upstream or downstream of the -35 element.

Low concentrations of free hydrophobic amino acids disrupt the Escherichia coli RNA polymerase core-sigma(70) protein-protein interaction

Studies of the Escherichia coli RNA polymerase subunit sigma-70 employing limited proteolytic digestion and binding by monoclonal antibodies indicate that conserved region 3 is solvent accessible in the free protein and in the RNA polymerase holoenzyme. Conversely, when sigma-70 binds to core RNA polymerase, proteolytic cleavage of region 3 is dramatically reduced. The former set of results seems to indicate the physical presence of region 3 on or near the surface of the holoenzyme while the latter of these results suggest that region 3 is sequestered in a direct protein-protein contact within the RNA holoenzyme which alters its protease sensitivity. To further investigate these possibilities we inserted an internal histidine-tag within region 3 of sigma(70) (sigma(70)-R3-His6) between amino acids 508 and 509. Confirmation that the internal His-tag insertion does not disrupt normal sigma(70) function was verified by genetic complementation. His-tagged protein was immobilized on nickel-agarose and core RNAP was tethered via the sigma-core interaction. Our results are consistent with the localization of region 3 on or near the surface both of free sigma(70) and of RNA polymerase holoenzyme. Furthermore, we find that the sigma(70)-core interaction is resistant to high ionic conditions but is completely disrupted by the presence of the low-molecular-weight hydrophobic amino acids phenylalanine and leucine free in solution. These results demonstrate the general usefulness of this approach to the disruption of protein-protein interactions and its potential application for protein purification.

Characterization of monoclonal antibodies against Escherichia coli core RNA polymerase

Multiple interactions with DNA, RNA and transcription factors occur in a transcription cycle. To survey the proximity of some of these factors to the Escherichia coli RNA polymerase surface, we produced a set of nine monoclonal antibodies (mAbs) against the enzyme. These mAbs, located at different places on the surface of the enzyme, were used in a co-immunopurification assay to investigate interference with the binding of NusA, sigma70, GreB and HepA to core RNA polymerase. One of these mAbs turned out to be the first antibody inhibitor of the binding of NusA and sigma70; it did not affect GreB and HepA interactions. Its epitope was located on the beta' subunit at the C-terminus of region G. The properties of this mAb reinforce the idea that the mutually exclusive binding of NusA and sigma70 to core RNA polymerase is due to, at least partially, overlapping binding sites, rather than allosteric interaction between two distant binding sites. This mAb is also useful to understand the occupancy of sigma70, NusA and Gre proteins on core RNA polymerase.

The C terminus of sigma(32) is not essential for degradation by FtsH

A key step in the regulation of heat shock genes in Escherichia coli is the stress-dependent degradation of the heat shock promoter-specific sigma(32) subunit of RNA polymerase by the AAA protease, FtsH. Previous studies implicated the C termini of protein substrates, including sigma(32), as degradation signals for AAA proteases. We investigated the role of the C terminus of sigma(32) in FtsH-dependent degradation by analysis of C-terminally truncated sigma(32) mutant proteins. Deletion of the 5, 11, 15, and 21 C-terminal residues of sigma(32) did not affect degradation in vivo or in vitro. Furthermore, a peptide comprising the C-terminal 21 residues of sigma(32) was not degraded by FtsH in vitro and thus did not serve as a recognition sequence for the protease, while an unrelated peptide of similar length was efficiently degraded. The truncated sigma(32) mutant proteins remained capable of associating with DnaK and DnaJ in vitro but showed intermediate (5-amino-acid deletion) and strong (11-, 15-, and 21-amino-acid deletions) defects in association with RNA polymerase in vitro and biological activity in vivo. These results indicate an important role for the C terminus of sigma(32) in RNA polymerase binding but no essential role for FtsH-dependent degradation and association of chaperones.

Identification of the heat-shock sigma factor RpoH and a second RpoH-like protein in Sinorhizobium meliloti

Hybridization to a PCR product derived from conserved sigma-factor sequences led to the identification of two Sinorhizobium meliloti DNA segments that display significant sequence similarity to the family of rpoH genes encoding the sigma(32) (RpoH) heat-shock transcription factors. The first gene, rpoH1, complements an Escherichia coli rpoH mutation. Cells containing an rpoH1 mutation are impaired in growth at 37 degrees C under free-living conditions and are defective in nitrogen fixation during symbiosis with alfalfa. A plasmid-borne rpoH1-gusA fusion increases in expression upon entry of the culture into the stationary phase of growth. The second gene, designated rpoH2, is 42% identical to the S. meliloti rpoH1 gene. Cells containing an rpoH2 mutation have no apparent phenotype under free-living conditions or during symbiosis with the host plant alfalfa. An rpoH2-gusA fusion increases in expression during the stationary phase of growth. The presence of two rpoH-like sequences in S. meliloti is reminiscent of the situation in Bradyrhizobium japonicum, which has three rpoH genes.

Mapping of the Rsd contact site on the sigma 70 subunit of Escherichia coli RNA polymerase

Rsd (regulator of sigma D) is an anti-sigma factor for the Escherichia coli RNA polymerase sigma(70) subunit. The contact site of Rsd on sigma(70) was analyzed after mapping of the contact-dependent cleavage sites by Rsd-tethered iron-p-bromoacetamidobenzyl EDTA and by analysis of the complex formation between Ala-substituted sigma(70) and Rsd. Results indicate that the Rsd contact site is located downstream of the promoter -35 recognition helix-turn-helix motif within region 4, overlapping with the regions involved in interaction with both core enzyme and sigma(70) contact transcription factors.

How sigma docks to RNA polymerase and what sigma does

It is clear that multiple sites of interaction exist between sigmas and core subunits, likely reflecting the changing pattern of interactions that occur sequentially during the complex process of holoenzyme formation, open promoter formation, and initiation of transcription. Recent studies have revealed that a major site of interaction of Escherichia coli sigma factors is the amino acid 260-309 coiled-coil region of the beta' subunit of core RNA polymerase. This region of beta' interacts with region 2.1-2.2 of sigma(70). Binding of this region of beta' to sigma(70) triggers a conformational change in sigma that allows it to bind to a -10 nontemplate promoter DNA strand oligonucleotide.

A multipartite interaction between Salmonella transcription factor sigma28 and its anti-sigma factor FlgM: implications for sigma28 holoenzyme destabilization through stepwise binding

Transcription of the late (Class 3) flagellar promoters in Salmonella typhimurium is dependent upon the flagellar specific sigma factor, sigma28, encoded by the fliA gene. sigma28-dependent transcription is inhibited by an anti-sigma factor, FlgM, through a direct interaction. FlgM can bind both to free sigma28 to prevent it from forming a complex with core RNA polymerase, and to sigma28 holoenzyme to destabilize the complex. A collection of fliA mutants defective for negative regulation by FlgM (fliA* mutants) were isolated. This collection included 27 substitution mutations that conferred insensitivity to FlgM in vivo. The distribution of mutations defined three potential FlgM binding domains in conserved sigma factor regions 2.1, 3.1 and 4 of sigma28. A subset of mutants from each region was assayed for FlgM binding and transcriptional activity in vitro. The results strongly support a multipartite interaction between sigma28 and FlgM. Region 4 mutations, but not region 2.1 or 3.1 mutations, interfered with the ability of FlgM to destabilize sigma28 from core RNA polymerase. We present refined models for FlgM inhibition of sigma28, and for FlgM destabilization of sigma28 holoenzyme.

Structural and functional properties of a Bacillus subtilis temperature-sensitive sigma(A) factor

Bacillus subtilis DB1005 is a temperature-sensitive (Ts) sigA mutant containing double-amino-acid substitutions (I198A and I202A) on the hydrophobic face of the promoter -10 binding helix of sigma(A) factor. We have analyzed the structural and functional properties of this mutant sigma(A) factor both in vivo and in vitro. Our data revealed that the Ts sigma(A) factor possessed predominantly a multimeric structure which was prone to aggregation at restrictive temperature. The extensive aggregation of the Ts sigma(A) resulted in a very low core-binding activity of the Ts sigma(A) factor and a markedly reduced sigma(A)-RNA polymerase activity in B. subtilis DB1005, suggesting that extensive aggregation of the Ts sigma(A) is the main trigger for the temperature sensitivity of B. subtilis DB1005. Partial proteolysis, tryptophan fluorescence and 1-anilinonaphthalene-8-sulfonate-binding analyses revealed that the hydrophobic face of the promoter -10 binding helix and also the hydrophobic core region of the Ts sigma(A) factor were readily exposed on the protein surface. This hydrophobic exposure provides an important cue for mutual interaction between molecules of the Ts sigma(A) and allows the formation of multimeric Ts sigma(A). Our results also indicate that Ile-198 and Ile-202 on the hydrophobic face of the promoter -10 binding helix are essential to ensure the correct folding and stabilization of the functional structure of sigma(A) factor.

Identifying a core RNA polymerase surface critical for interactions with a sigma-like specificity factor

Cyclic interactions occurring between a core RNA polymerase (RNAP) and its initiation factors are critical for transcription initiation, but little is known about subunit interaction. In this work we have identified regions of the single-subunit yeast mitochondrial RNAP (Rpo41p) important for interaction with its sigma-like specificity factor (Mtf1p). Previously we found that the whole folded structure of both polypeptides as well as specific amino acids in at least three regions of Mtf1p are required for interaction. In this work we started with an interaction-defective point mutant in Mtf1p (V135A) and used a two-hybrid selection to isolate suppressing mutations in the core polymerase. We identified suppressors in three separate regions of the RNAP which, when modeled on the structure of the closely related phage T7 RNAP, appear to lie on one surface of the protein. Additional point mutations and biochemical assays were used to confirm the importance of each region for Rpo41p-Mtf1p interactions. Remarkably, two of the three suppressors are found in regions required by T7 RNAP for DNA sequence recognition and promoter melting. Although these essential regions of the phage RNAP are poorly conserved with the mitochondrial RNAPs, they are conserved among the mitochondrial enzymes. The organellar RNAPs appear to use this surface in an alternative way for interactions with their separate sigma-like specificity factor, which, like its bacterial counterpart, provides promoter recognition and DNA melting functions to the holoenzyme.

Evidence for an active role of the DnaK chaperone system in the degradation of sigma(32)

Under non-stressed conditions in Escherichia coli, the heat shock transcription factor sigma(32) is rapidly degraded by the AAA protease FtsH. The DnaK chaperone system is also required for the rapid turnover of sigma(32) in the cell. It has been hypothesized that the DnaK chaperone system facilitates the degradation of sigma(32) by sequestering it from RNA polymerase core. This hypothesis predicts that mutant sigma(32) proteins, which are deficient in binding to RNA polymerase core, will be degraded independently of the DnaK chaperone system. We examined the in vivo stability of such mutant sigma(32) proteins. Results indicated that the mutant sigma(32) proteins as similar as authentic sigma(32) were stabilized in DeltadnaK and DeltadnaJ/DeltacbpA cells. The interaction between sigma(32) and DnaK/DnaJ/GrpE was not affected by these mutations. These results strongly suggest that the degradation of sigma(32) requires an unidentified active role of the DnaK chaperone system.

Differential degradation of Escherichia coli sigma32 and Bradyrhizobium japonicum RpoH factors by the FtsH protease

The Escherichia coli heat shock sigma factor sigma32 (RpoH) is rapidly degraded under non-stress conditions. The integrity of the DnaK chaperone machinery and the ATP-dependent FtsH protease are required for sigma32 proteolysis in vivo. Bradyrhizobium japonicum expresses three sigma32-type transcription factors, RpoH1, RpoH2, and RpoH3, which are functional in E. coli. We compared the stability of these sigma factors with E. coli sigma32 stability. In E. coli C600 (wild-type), the half-lives of sigma32, RpoH1, RpoH2 and RpoH3 were 30 s, 7 min, 4 min and 4 min, respectively. The first three proteins were stabilized in ftsH mutant backgrounds, indicating that they are degraded by FtsH in the wild-type. Proteolysis of RpoH3 was FtsH-independent because this sigma factor was not stabilized in ftsH mutants. Interestingly, in a purified in vitro system, all four RpoH proteins were degraded by FtsH, indicating that in vivo protein degradation depends on additional cellular factors. Rationally designed point mutations of sigma32 and RpoH1 suggested that the highly conserved RpoH box does not play a major role in conferring stability to RpoH factors. Presumably, several regions distributed along the primary sequence of the sigma factor are important for FtsH-mediated proteolysis. Finally, we provide evidence that proteolysis of RpoH factors in vivo depends on the DnaK machinery, irrespective of the protease involved.

Mutational analysis of beta '260-309, a sigma 70 binding site located on Escherichia coli core RNA polymerase

In eubacteria, the final sigma subunit binds to the core RNA polymerase and directs transcription initiation from any of its cognate set of promoters. Previously, our laboratory defined a region of the beta' subunit that interacts with final sigma(70) in vitro. This region of beta' contained heptad repeat motifs indicative of coiled coils. In this work, we used 10 single point mutations of the predicted coiled coils, located within residues 260-309 of beta', to look at disruption of the final sigma(70)-core interaction. Several of the mutants were defective for binding final sigma(70) in vitro. Of these mutants, three (R275Q, E295K, and A302D) caused cells to be inviable in an in vivo assay in which the mutant beta' is the sole source of beta' subunit for the cell. All of the mutants were able to assemble into the core enzyme; however, R275Q, E295K, A302D were defective for Efinal sigma(70) holoenzyme formation. Several of the mutants were also defective for holoenzyme assembly with various minor final sigma factors. In the recently published crystal structure of Thermus aquaticus core RNA polymerase (Zhang, G., Campbell, E. A., Minakhin, L., Richter, C., Severinov, K. , and Darst, S. A. (1999) Cell 98, 811-824), the region homologous to beta'(260-309) of Escherichia coli forms a coiled coil. Modeling of our mutations onto that coiled coil places the most defective mutations on one face of the coiled coil.

Dynamic interplay between antagonistic pathways controlling the sigma 32 level in Escherichia coli

The heat-shock response in Escherichia coli depends primarily on the transient increase in the cellular level of heat-shock sigma factor final sigma(32) encoded by the rpoH gene, which results from both enhanced synthesis and transient stabilization of normally unstable final sigma(32). Heat-induced synthesis of final sigma(32) was previously shown to occur at the translation level by melting the mRNA secondary structure formed within the 5' coding sequence of rpoH including the translation initiation region. The subsequent decrease in the final sigma(32) level during the adaptation phase has been thought to involve both shutoff of synthesis (translation) and destabilization of final sigma(32)-mediated by the DnaK-DnaJ chaperones, although direct evidence for translational repression was lacking. We now show that the heat-induced synthesis of final sigma(32) does not shut off at the translation level by using a reporter system involving translational coupling. Furthermore, the apparent shutoff was not observed when the synthesis rate was determined by a very short pulse labeling (15 s). Examination of final sigma(32) stability at 10 min after shift from 30 to 42 degrees C revealed more extreme instability (t(1/2)=20 s) than had previously been thought. Thus, the dynamic change in final sigma(32) stability during the heat-shock response largely accounts for the apparent shutoff of final sigma(32) synthesis observed with a longer pulse. These results suggest a mechanism for maintaining the intricate balance between the antagonistic pathways: the rpoH translation as determined primarily by ambient temperature and the turnover of final sigma(32) as modulated by the chaperone (and presumably protease)-mediated autogenous control.

The heat shock response of Escherichia coli

A large variety of stress conditions including physicochemical factors induce the synthesis of more than 20 heat shock proteins (HSPs). In E. coli, the heat shock response to temperature upshift from 30 to 42 degrees C consists of the rapid induction of these HSPs, followed by an adaptation period where the rate of HSP synthesis decreases to reach a new steady-state level. Major HSPs are molecular chaperones, including DnaK, DnaJ and GrpE, and GroEL and GroES, and proteases. They constitute the two major chaperone systems of E. coli (15-20% of total protein at 46 degrees C). They are important for cell survival, since they play a role in preventing aggregation and refolding proteins. The E. coli heat shock response is positively controlled at the transcriptional level by the product of the rpoH gene, the heat shock promoter-specific sigma32 subunit of RNA polymerase. Because of its rapid turn-over, the cellular concentration of sigma32 is very low under steady-state conditions (10-30 copies/cell at 30 degrees C) and is limiting for heat shock gene transcription. The heat shock response is induced as a consequence of a rapid increase in sigma32 levels and stimulation of sigma32 activity. The shut off of the response occurs as a consequence of declining sigma32 levels and inhibition of sigma32 activity. Stress-dependent changes in heat shock gene expression are mediated by the antagonistic action of sigma32 and negative modulators which act upon sigma32. These modulators are the DnaK chaperone system which inactivate sigma32 by direct association and mediate its degradation by proteases. Degradation of sigma32 is mediated mainly by FtsH (HflB), an ATP-dependent metallo-protease associated with the inner membrane. There is increasing evidence that the sequestration of the DnaK chaperone system through binding to misfolded proteins is a direct determinant of the modulation of the heat shock genes expression. A central open question is the identity of the binding sites within sigma32 for DnaK, DnaJ, FtsH and the RNA polymerase, and the functional interplay between these sites. We have studied the role of two distinct regions of sigma32 in its activity and stability control: region C and the C-terminal part. Both regions are involved in RNA polymerase binding.

The interface of sigma with core RNA polymerase is extensive, conserved, and functionally specialized

The sigma subunit of eubacterial RNA polymerase is required throughout initiation, but how it communicates with core polymerase (alpha(2)betabeta') is poorly understood. The present work addresses the location and function of the interface of sigma with core. Our studies suggest that this interface is extensive as mutations in six conserved regions of sigma(70) hinder the ability of sigma to bind core. Direct binding of one of these regions to core can be demonstrated using a peptide-based approach. The same regions, and even equivalent residues, in sigma(32) and sigma(70) alter core interaction, suggesting that sigma(70) family members use homologous residues, at least in part, to interact with core. Finally, the regions of sigma that we identify perform specialized functions, suggesting that different portions of the interface perform discrete roles during transcription initiation.

Role of region C in regulation of the heat shock gene-specific sigma factor of Escherichia coli, sigma32

Expression of heat shock genes is controlled in Escherichia coli by the antagonistic action of the sigma32 subunit of RNA polymerase and the DnaK chaperone system, which inactivates sigma32 by stress-dependent association and mediates sigma32 degradation by the FtsH protease. A stretch of 23 residues (R122 to Q144) conserved among sigma32 homologs, termed region C, was proposed to play a role in sigma32 degradation, and peptide analysis identified two potential DnaK binding sites central and peripheral to region C. Region C is thus a prime candidate for mediating stress control of sigma32, a hypothesis that we tested in the present study. A peptide comprising the central DnaK binding site was an excellent substrate for FtsH, while a peptide comprising the peripheral DnaK binding site was a poor substrate. Replacement of a single hydrophobic residue in each DnaK binding site by negatively charged residues (I123D and F137E) strongly decreased the binding of the peptides to DnaK and the degradation by FtsH. However, introduction of these and additional region C alterations into the sigma32 protein did not affect sigma32 degradation in vivo and in vitro or DnaK binding in vitro. These findings do not support a role for region C in sigma32 control by DnaK and FtsH. Instead, the sigma32 mutants had reduced affinities for RNA polymerase and decreased transcriptional activities in vitro and in vivo. Furthermore, cysteines inserted into region C allowed cysteine-specific cross-linking of sigma32 to RNA polymerase. Region C thus confers on sigma32 a competitive advantage over other sigma factors to bind RNA polymerase and thereby contributes to the rapidity of the heat shock response.

Regulation of the heat-shock response

Current models of both heat induction and the chaperone-mediated feedback control of the sigma32 regulon in Escherichia coli have been further substantiated, and the extent of conservation among Gram-negative bacteria has been assessed. Analyses of the 'CIRCE' and other regulons or operons in Gram-positive and Gram-negative bacteria have provided new insights into their significance and regulatory mechanisms.

On the mechanism of FtsH-dependent degradation of the sigma 32 transcriptional regulator of Escherichia coli and the role of the Dnak chaperone machine

The Escherichia coli sigma 32 transcriptional regulator has been shown to be degraded both in vivo and in vitro by the FtsH (HflB) protease, a member of the AAA protein family. In our attempts to study this process in detail, we found that two sigma 32 mutants lacking 15-20 C-terminal amino acids had substantially increased half-lives in vivo or in vitro, compared with wild-type sigma 32. A truncated version of sigma 32, sigma 32 C delta, was purified to homogeneity and shown to be resistant to FtsH-dependent degradation in vitro, suggesting that FtsH initiates sigma 32 degradation from its extreme C-terminal region. Purified sigma 32 C delta interacted with the DnaK and DnaJ chaperone proteins in a fashion similar to that of wild-type sigma 32. However, in contrast to wild-type sigma 32, sigma 32 C delta was largely deficient in its in vivo and in vitro interaction with core RNA polymerase. As a consequence, the truncated sigma 32 protein was completely non-functional in vivo, even when overproduced. Furthermore, it is shown that wild-type sigma 32 is protected from degradation by FtsH when complexed to the RNA polymerase core, but sensitive to proteolysis when in complex with the DnaK chaperone machine. Our results are in agreement with the proposal that the capacity of the DnaK chaperone machine to autoregulate its own synthesis negatively is simply the result of its ability to sequester sigma 32 from RNA polymerase, thus making it accessible to degradation by the FtsH protease.

Several new bacteriophage T4 genes, mapped by sequencing deletion endpoints between genes 56 (dCTPase) and dda (a DNA-dependent ATPase-helicase) modulate transcription

We have analyzed DNA of wild-type T4 and of 13 independent large viable deletions isolated by Homyk and Weil (Virology 61 (1974) 505-523) and by Little (Virology 53 (1973) 47-59), by sequencing, cloning, and expression studies. The deletions can be explained by illegitimate recombination between short (4- to 15-bp) ectopic repeats. In four deletions, adjacent regions are partially homologous, and in at least one of them, the base adjacent to the overlap was deleted during recombination. The sequence 5'-GGGC, which has not been associated with T4 deletions in other map regions, occurs within three repeats, and near the repeats in four more of the 13 deletions. Five previously named genes, 69, soc, mrh, modA, and dda were mapped relative to the deletion endpoints. Nine additional ORFs were found interspersed between them. One of these shares some similarities with mrh (modulates rpoH; Frazier and Mosig, Gene 88 (1990) 7-14), and another one resembles modA (coding for an ADP-ribosyl-transferase that modifies RNA polymerase alpha subunits, Skórko et al., Eur. J. Biochem. 79 (1977) 55-66) respectively. We found that the host's heat shock sigma factor, sigma32, is phosphorylated, and that Mrh protein modulates this phosphorylation. The ORF dda.9 downstream of mrh has a patchy similarity with conserved C-terminal segments (motifs) of sigma32; therefore, we call it srh. Another ORF, dda.2 located between modA and dda, shares sequence similarity with sigma70, and we call it srd. We consider the possibility that Srh and Srd act as decoys for sigma32, or sigma70, respectively. Expression of several of the ORFs from cloned DNA appears to be toxic to the host bacteria. Mutant clones only could be constructed from gene 69 and from modA. Moreover, dda.2 (srd)-containing bacteria grow extremely slowly, and they form filaments in liquid cultures. Clones carrying mrh and srh show less severe filamentation. Our results highlight the importance of 'non-essential' genes for phage development and evolution.

Localization of a sigma70 binding site on the N terminus of the Escherichia coli RNA polymerase beta' subunit

The Escherichia coli genome encodes genes for seven different sigma subunit species while only having single genes for the alpha, beta, and beta' subunits that make up the RNA polymerase core enzyme. The various sigma factors compete for binding to the core enzyme, upon which they confer promoter DNA-specific transcription initiation to the polymerase. We have mapped a major interaction site between one of the sigma species, sigma70, and beta'. Using far-Western blotting analysis of chemically cleaved and genetically engineered protein fragments, we have identified a N-terminal fragment of beta' (residues 60-309) that could bind sigma70. We were able to more precisely map the interaction domain to amino acid residues 260-309 of beta' using nickel nitrilotriacetic acid co-immobilization assays.

The flagellar anti-sigma factor FlgM actively dissociates Salmonella typhimurium sigma28 RNA polymerase holoenzyme

The anti-sigma factor FlgM of Salmonella typhimurium inhibits transcription of class 3 flagellar genes through a direct interaction with the flagellar-specific sigma factor, sigma28. FlgM is believed to prevent RNA polymerase (RNAP) holoenzyme formation by sequestering free sigma28. We have analyzed FlgM-mediated inhibition of sigma28 activity in vitro. FlgM is able to inhibit sigma28 activity even when sigma28 is first allowed to associate with core RNAP. Surface plasmon resonance (SPR) was used to evaluate the interaction between FlgM and both sigma28 and sigma28 holoenzyme (Esigma28). The Kd of the sigma28-FlgM complex is approximately 2 x 10(-10) M; missense mutations in FlgM that cause a defect in sigma28 inhibition in vivo increase the Kd of this interaction by 4- to 10-fold. SPR measurements of Esigma28 dissociation in the presence of FlgM indicate that FlgM destabilizes Esigma28, presumably via an interaction with the sigma subunit. Our data provide the first direct evidence of an interaction between FlgM and Esigma28. We propose that this secondary activity of FlgM, which we term holoenzyme destabilization, enhances the sensitivity of the cell to changes in FlgM levels during flagellar biogenesis.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.