Virulence regulators RfaH and YaeQ do not operate in the same pathway.

The expression of virulence factors such as hemolysin and lipopolysaccharides in Proteobacteria is regulated by the transcription elongation factor RfaH. RfaH reduces pausing and termination at intergenic sites, and thus allows RNA polymerase to conclude transcription of the distal genes in long virulence operons. The yaeQ gene of Salmonella enterica sv. Typhimurium has been identified as a high-copy-number suppressor of the hemolytic defect in an rfaH deletion strain, leading to speculation regarding a direct role of YaeQ in the transcriptional control of bacterial virulence. In order to evaluate this hypothesis, yaeQ genes from Escherichia coli and S. enterica sv. Typhimurium were cloned and expressed. Their products, purified YaeQ proteins, displayed no antitermination effects in in-vitro transcription assays over a wide range of concentrations, neither by themselves nor in competition with RfaH. When overexpressed in vivo, plasmid-borne E. coli and S. enterica sv. Typhimurium yaeQ genes also failed to restore hemolytic activity in an rfaH deletion strain under conditions in which episomal E. coli rfaH and its orthologs exhibited full complementation of the genomic rfaH deletion. Taken together, our findings do not support the hypothesis of YaeQ involvement in RfaH-dependent regulation of virulence, even in stoichiometric excess in vitro or upon overexpression in vivo.

Binding of the initiation factor sigma(70) to core RNA polymerase is a multistep process.

The interaction of RNA polymerase and its initiation factors is central to the process of transcription initiation. To dissect the role of this interface, we undertook the identification of the contact sites between RNA polymerase and sigma(70), the Escherichia coli initiation factor. We identified nine mutationally verified interaction sites between sigma(70) and specific domains of RNA polymerase and provide evidence that sigma(70) and RNA polymerase interact in at least a two-step process. We propose that a cycle of changes in the interface of sigma(70) with core RNA polymerase is associated with progression through the process of transcription initiation.

Allosteric control of RNA polymerase by a site that contacts nascent RNA hairpins.

DNA, RNA, and regulatory molecules control gene expression through interactions with RNA polymerase (RNAP). We show that a short alpha helix at the tip of the flaplike domain that covers the RNA exit channel of RNAP contacts a nascent RNA stem-loop structure (hairpin) that inhibits transcription, and that this flap-tip helix is required for activity of the regulatory protein NusA. Protein-RNA cross-linking, molecular modeling, and effects of alterations in RNAP and RNA all suggest that a tripartite interaction of RNAP, NusA, and the hairpin inhibits nucleotide addition in the active site, which is located 65 angstroms away. These findings favor an allosteric model for regulation of transcript elongation.

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.

Rapid purification of His(6)-tagged Bacillus subtilis core RNA polymerase.

Bacillus subtilis core RNA polymerase, containing a His(6)-fusion to the C-terminus of the beta' subunit, was isolated by Ni-NTA, Superdex 200 gel filtration, and Mono Q anion-exchange chromatography. The purified core enzyme was shown to be free of the major sigma factor(A) and the transcription factors NusA and GreA. The purification procedure can be completed within 1 working day, is scalable, and yields highly purified and active core RNA polymerase.

Pausing by bacterial RNA polymerase is mediated by mechanistically distinct classes of signals.

Transcript elongation by RNA polymerase is discontinuous and interrupted by pauses that play key regulatory roles. We show here that two different classes of pause signals punctuate elongation. Class I pauses, discovered in enteric bacteria, depend on interaction of a nascent RNA structure with RNA polymerase to displace the 3' OH away from the catalytic center. Class II pauses, which may predominate in eukaryotes, cause RNA polymerase to slide backwards along DNA and RNA and to occlude the active site with nascent RNA. These pauses differ in their responses to antisense oligonucleotides, pyrophosphate, GreA, and general elongation factors NusA and NusG. In contrast, substitutions in RNA polymerase that increase or decrease the rate of RNA synthesis affect both pause classes similarly. We propose that both pause classes, as well as arrest and termination, arise from a common intermediate that itself binds NTP substrate weakly.

Nonequilibrium mechanism of transcription termination from observations of single RNA polymerase molecules.

Cessation of transcription at specific terminator DNA sequences is used by viruses, bacteria, and eukaryotes to regulate the expression of downstream genes, but the mechanisms of transcription termination are poorly characterized. To elucidate the kinetic mechanism of termination at the intrinsic terminators of enteric bacteria, we observed, by using single-molecule light microscopy techniques, the behavior of surface-immobilized Escherichia coli RNA polymerase (RNAP) molecules in vitro. An RNAP molecule remains at a canonical intrinsic terminator for approximately 64 s before releasing DNA, implying the formation of an elongation-incompetent (paused) intermediate by transcription complexes that terminate but not by those that read through the terminator. Analysis of pause lifetimes establishes a complete minimal mechanism of termination in which paused intermediate formation is both necessary and sufficient to induce release of RNAP at the terminator. The data suggest that intrinsic terminators function by a nonequilibrium process in which terminator effectiveness is determined by the relative rates of nucleotide addition and paused state entry by the transcription complex.

Folding of a large ribozyme during transcription and the effect of the elongation factor NusA.

We compared in vitro transcription-initiated folding of the ribozyme from Bacillus subtilis RNase P to refolding from the full-length, denatured state by monitoring the appearance of its catalytic activity. At 37 degrees C, Mg(2+)-initiated refolding of the wild type and a circularly permutate ribozyme takes minutes and is limited by a kinetic trap. Transcription by T7 RNA polymerase alters the folding pathway of both RNAs and introduces new kinetic traps. Transcription by the core Escherichia coli RNA polymerase yields the same result, in spite of its 4-fold-slower elongation rate. However, the presence of its elongation factor NusA accelerates more than 10-fold the transcription-initiated folding of the circularly, permutated ribozyme by E. coli RNA polymerase. The effect of NusA likely is caused by its enhancement of transcriptional pausing because NusA did not accelerate transcription-initiated folding using a mutant RNA polymerase that failed to pause or respond to NusA during ribozyme synthesis. We conclude that both transcription and specific pausing therein can alter RNA-folding pathways.

Interaction of a nascent RNA structure with RNA polymerase is required for hairpin-dependent transcriptional pausing but not for transcript release.

Nascent RNA structures may regulate RNA chain elongation either directly through interaction with RNA polymerase or indirectly by disrupting nascent RNA contacts with polymerase or DNA. To distinguish these mechanisms we tested whether the effects of the his leader pause RNA hairpin could be mimicked by pairing of antisense DNA or RNA oligonucleotides to the nascent transcript. The his pause hairpin inhibits nucleotide addition when it forms 11 nucleotides from the transcript 3' end. It also can terminate transcription when base changes extend its stem to

Transcription activation by the bacteriophage Mu Mor protein requires the C-terminal regions of both alpha and sigma70 subunits of Escherichia coli RNA polymerase.

Middle transcription of bacteriophage Mu requires Escherichia coli RNA polymerase and a Mu-encoded protein, Mor. Consistent with these requirements, the middle promoter, Pm, has a -10 hexamer but lacks a recognizable -35 hexamer. Interactions between Mor and RNA polymerase were studied using in vitro transcription, DNase I footprinting, and the yeast interaction trap system. We observed reduced promoter activity in vitro using reconstituted RNA polymerases with C-terminal deletions in alpha or sigma70. As predicted if alpha were binding to Pm, we detected a polymerase-dependent footprint in the -60 region. Reconstituted RNA polymerases containing Ala substitutions in the alpha C-terminal domain were used to assay Mor-dependent transcription from Pm in vitro. The D258A substitution and alpha deletion gave large reductions in activation, whereas the L262A, R265A, and N268A substitutions caused smaller reductions. The interaction trap assay revealed weak interactions between Mor and both alpha and sigma70; consistent with a key role of alpha-D258, the D258A substitution abolished interaction, whereas the R265A substitution did not. We propose that: (i) alpha-D258 is a Mor "contact site"; and (ii) residues Leu-262, Arg-265, and Asn-268 indirectly affect Mor-polymerase interaction by stabilizing the ternary complex via alpha-DNA contact.

Distortion in the spacer region of Pm during activation of middle transcription of phage Mu.

Transcription from the middle promoter, Pm, of phage Mu is initiated by Escherichia coli RNA polymerase holoenzyme (E sigma 70; RNAP) and the phage-encoded activator, Mor. Point mutations in the spacer region between the -10 hexamer and the Mor binding site result in changes of promoter activity in vivo. These mutations are located at the junction between a rigid T-tract and adjacent, potentially deformable G + C-rich DNA segment, suggesting that deformation of the spacer region may play a role in the transcriptional activation of Pm. This prediction was tested by using dimethyl sulfate and potassium permanganate footprinting analyses. Helical distortion involving strand separation was detected at positions -32 to -34, close to the predicted interface between Mor and RNAP. Promoter mutants in which this distortion was not detected exhibited a lack of melting in the -12 to -1 region and reduced promoter activity in vivo. We propose that complexes containing the distortion represent stressed intermediates rather than stable open complexes and thus can be envisaged as a transition state in the kinetic pathway of Pm activation in which stored torsional energy could be used to facilitate melting around the transcription start point.

Transcription activation by the bacteriophage Mu Mor protein: analysis of promoter mutations in Pm identifies a new region required for promoter function.

Middle transcription of bacteriophage Mu requires Escherichia coli RNA polymerase holoenzyme and a Mu-encoded protein, Mor. Consistent with these requirements, the middle promoter, Pm, has a recognizable -10 region but lacks a -35 region. Mutagenesis of this promoter (from -70 to +10) was performed using mutagenic oligonucleotide-directed PCR. The resulting fragments were cloned into a promoter-lacZfusion vector and analyzed for promoter activity by assaying beta-galactosidase production. Single point mutations with a Down phenotype were clustered in three regions: the -10 region, the Mor footprint region and the spacer between them. Gel retardation experiments with purified Mor protein and promoter mutants demonstrated that sequences important for Mor binding are located within the Mor footprint region and lead us to propose the existence of a dyad symmetry element involved in Mor binding. In agreement with this prediction, glutaraldehyde crosslinking of Mor in solution generated a species with the size of a dimer. These experiments also identified an unusual group of mutations located in the spacer region adjacent to the Mor footprint. These mutations alter promoter activity without affecting Mor binding. A circular permutation assay revealed that Mor does not introduce a significant bend upon binding to its target sequence.