Escherichia coli RNA polymerase holoenzyme: rapid reconstitution from recombinant alpha, beta, beta', and sigma subunits

The Phage-Encoded N-Acetyltransferase Rac Mediates Inactivation of Pseudomonas aeruginosa Transcription by Cleavage of the RNA Polymerase Alpha Subunit

In this study, we describe the biological function of the phage-encoded protein RNA polymerase alpha subunit cleavage protein (Rac), a predicted Gcn5-related acetyltransferase encoded by phiKMV-like viruses. These phages encode a single-subunit RNA polymerase for transcription of their late (structure- and lysis-associated) genes, whereas the bacterial RNA polymerase is used at the earlier stages of infection. Rac mediates the inactivation of bacterial transcription by introducing a specific cleavage in the α subunit of the bacterial RNA polymerase. This cleavage occurs within the flexible linker sequence and disconnects the C-terminal domain, required for transcription initiation from most highly active cellular promoters. To achieve this, Rac likely taps into a novel post-translational modification (PTM) mechanism within the host Pseudomonas aeruginosa. From an evolutionary perspective, this novel phage-encoded regulation mechanism confirms the importance of PTMs in the prokaryotic metabolism and represents a new way by which phages can hijack the bacterial host metabolism.

Controller protein of restriction-modification system Kpn2I affects transcription of its gene by acting as a transcription elongation roadblock

C-proteins control restriction-modification (R-M) systems' genes transcription to ensure sufficient levels of restriction endonuclease to allow protection from foreign DNA while avoiding its modification by excess methyltransferase. Here, we characterize transcription regulation in C-protein dependent R-M system Kpn2I. The Kpn2I restriction endonuclease gene is transcribed from a constitutive, weak promoter, which, atypically, is C-protein independent. Kpn2I C-protein (C.Kpn2I) binds upstream of the strong methyltransferase gene promoter and inhibits it, likely by preventing the interaction of the RNA polymerase sigma subunit with the -35 consensus element. Diminished transcription from the methyltransferase promoter increases transcription from overlapping divergent C-protein gene promoters. All known C-proteins affect transcription initiation from R-M genes promoters. Uniquely, the C.Kpn2I binding site is located within the coding region of its gene. C.Kpn2I acts as a roadblock stalling elongating RNA polymerase and decreasing production of full-length C.Kpn2I mRNA. Mathematical modeling shows that this unusual mode of regulation leads to the same dynamics of accumulation of R-M gene transcripts as observed in systems where C-proteins act at transcription initiation stage only. Bioinformatics analyses suggest that transcription regulation through binding of C.Kpn2I-like proteins within the coding regions of their genes may be widespread.

Use of RNA polymerase molecular beacon assay to measure RNA polymerase interactions with model promoter fragments

RNA polymerase-promoter interactions that keep the transcription initiation complex together are complex and multipartite, and formation of the RNA polymerase-promoter complex proceeds through multiple intermediates. Short promoter fragments can be used as a tool to dissect RNA polymerase-promoter interactions and to pinpoint elements responsible for specific properties of the entire promoter complex. A recently developed fluorometric molecular beacon assay allows one to monitor the enzyme interactions with various DNA probes and quantitatively characterize partial RNA polymerase-promoter interactions. Here, we present detailed protocols for the preparation of an Escherichia coli molecular beacon and its application to study RNA polymerase interactions with model promoter fragments.

Site-specific incorporation of probes into RNA polymerase by unnatural-amino-acid mutagenesis and Staudinger-Bertozzi ligation

A three-step procedure comprising (1) unnatural-amino-acid mutagenesis with 4-azido-phenylalanine, (2) Staudinger-Bertozzi ligation with a probe-phosphine derivative, and (3) in vitro reconstitution of RNA polymerase (RNAP) enables the efficient site-specific incorporation of a fluorescent probe, a spin label, a cross-linking agent, a cleaving agent, an affinity tag, or any other biochemical or biophysical probe, at any site of interest in RNAP. Straightforward extensions of the procedure enable the efficient site-specific incorporation of two or more different probes in two or more different subunits of RNAP. We present protocols for synthesis of probe-phosphine derivatives, preparation of RNAP subunits and the transcription initiation factor σ, unnatural amino acid mutagenesis of RNAP subunits and σ, Staudinger ligation with unnatural-amino-acid-containing RNAP subunits and σ, quantitation of labelling efficiency and labelling specificity, and reconstitution of RNAP.

X-ray crystal structure of Escherichia coli RNA polymerase σ70 holoenzyme

Escherichia coli RNA polymerase (RNAP) is the most studied bacterial RNAP and has been used as the model RNAP for screening and evaluating potential RNAP-targeting antibiotics. However, the x-ray crystal structure of E. coli RNAP has been limited to individual domains. Here, I report the x-ray structure of the E. coli RNAP σ(70) holoenzyme, which shows σ region 1.1 (σ1.1) and the α subunit C-terminal domain for the first time in the context of an intact RNAP. σ1.1 is positioned at the RNAP DNA-binding channel and completely blocks DNA entry to the RNAP active site. The structure reveals that σ1.1 contains a basic patch on its surface, which may play an important role in DNA interaction to facilitate open promoter complex formation. The α subunit C-terminal domain is positioned next to σ domain 4 with a fully stretched linker between the N- and C-terminal domains. E. coli RNAP crystals can be prepared from a convenient overexpression system, allowing further structural studies of bacterial RNAP mutants, including functionally deficient and antibiotic-resistant RNAPs.

Francisella RNA polymerase contains a heterodimer of non-identical α subunits

Background

All sequenced genomes of representatives of the Francisella genus contain two rpoA genes, which encode non-identical RNA polymerase (RNAP) subunits, α1 and α2. In all other bacteria studied to date, a dimer of identical α subunits initiates the assembly of the catalytically proficient RNAP core (subunit composition α₂ββ'). Based on an observation that both α1 and α2 are incorporated into Francisella RNAP, Charity et al. (2007) previously suggested that up to four different species of RNAP core enzyme might form in the same Francisella cell.

Results

By in vitro assembly from fully denatured state, we determined that both Francisella α subunits are required for efficient dimerization; no homodimer formation was detected. Bacterial two-hybrid system analysis likewise indicated strong interactions between the α1 and α2 N-terminal domains (NTDs, responsible for dimerization). NTDs of α2 did not interact detectably, while weak interaction between α1 NTDs was observed. This weak homotypic interaction may explain low-level transcription activity observed in in vitro RNAP reconstitution reactions containing Francisella large subunits (β', β) and α1. No activity was observed with RNAP reconstitution reactions containing α2, while robust transcription activity was detected in reactions containing α1 and α2. Phylogenetic analysis based on RpoA resulted in a tree compatible with standard bacterial taxonomy with both Francisella RpoA branches positioned within γ-proteobacteria. The observed phylogeny and analysis of constrained trees are compatible with Francisella lineage-specific rpoA duplication followed by acceleration of evolutionary rate and subfunctionalization.

Conclusions

The results strongly suggest that most Francisella RNAP contains α heterodimer with a minor subfraction possibly containing α1 homodimer. Comparative sequence analysis suggests that this heterodimer is oriented, in a sense that only one monomer, α1, interacts with the β subunit during the α₂β RNAP subassembly formation. Most likely the two rpoA copies in Francisella have emerged through a lineage-specific duplication followed by subfunctionalization of interacting paralogs.

ExsA recruits RNA polymerase to an extended -10 promoter by contacting region 4.2 of sigma-70

ExsA is a member of the AraC family of transcriptional activators and is required for expression of the Pseudomonas aeruginosa type III secretion system (T3SS). ExsA-dependent promoters consist of two binding sites for monomeric ExsA located approximately 50 bp upstream of the transcription start sites. Binding to both sites is required for recruitment of sigma(70)-RNA polymerase (RNAP) to the promoter. ExsA-dependent promoters also contain putative -35 hexamers that closely match the sigma(70) consensus but are atypically spaced 21 or 22 bp from the -10 hexamer. Because several nucleotides located within the putative -35 region are required for ExsA binding, it is unclear whether the putative -35 region makes an additional contribution to transcription initiation. In the present study we demonstrate that the putative -35 hexamer is dispensable for ExsA-independent transcription from the P(exsC) promoter and that deletion of sigma(70) region 4.2, which contacts the -35 hexamer, has no effect on ExsA-independent transcription from P(exsC). Region 4.2 of sigma(70), however, is required for ExsA-dependent activation of the P(exsC) and P(exsD) promoters. Genetic data suggest that ExsA directly contacts region 4.2 of sigma(70), and several amino acids were found to contribute to the interaction. In vitro transcription assays demonstrate that an extended -10 element located in the P(exsC) promoter is important for overall promoter activity. Our collective data suggest a model in which ExsA compensates for the lack of a -35 hexamer by interacting with region 4.2 of sigma(70) to recruit RNAP to the promoter.

Transcription regulation of restriction-modification system Esp1396I

The convergently transcribed restriction (R) and methylase (M) genes of the Restriction-Modification system Esp1396I are tightly regulated by a controller (C) protein that forms part of the CR operon. We have mapped the transcriptional start sites from each promoter and examined the regulatory role of C.Esp1396I in vivo and in vitro. C-protein binding at the CR and M promoters was analyzed by DNA footprinting and a range of biophysical techniques. The distal and proximal C-protein binding sites at the CR promoter are responsible for activation and repression, respectively. In contrast, a C-protein dimer binds to a single site at the M-promoter to repress the gene, with an affinity much greater than for the CR promoter. Thus, during establishment of the system in a naïve host, the activity of the M promoter is turned off early, preventing excessive synthesis of methylase. Mutational analysis of promoter binding sites reveals that the tetranucleotide inverted repeats long believed to be important for C-protein binding to DNA are less significant than previously thought. Instead, symmetry-related elements outside of these repeats appear to be critical for the interaction and are discussed in terms of the recent crystal structure of C.Esp139I bound to the CR promoter.

Static and kinetic site-specific protein-DNA photocrosslinking: analysis of bacterial transcription initiation complexes

Static site-specific protein-DNA photocrosslinking permits identification of protein-DNA interactions within multiprotein-DNA complexes. Kinetic site-specific protein-DNA photocrosslinking - involving rapid-quench-flow mixing and pulsed-laser irradiation - permits elucidation of pathways and kinetics of formation of protein-DNA interactions within multiprotein-DNA complexes. We present detailed protocols for application of static and kinetic site-specific protein-DNA photocrosslinking to bacterial transcription initiation complexes.

Recombinant Thermus aquaticus RNA Polymerase for Structural Studies

Advances in the structural biology of bacterial transcription have come from studies of RNA polymerases (RNAPs) from the thermophilic eubacteria Thermus aquaticus (Taq) and Thermus thermophilus (Tth). These structural studies have been limited by the fact that only endogenous Taq or Tth RNAP, laboriously purified from large quantities of Taq or Tth cell paste and offering few options for genetic modification, is suitable for structural studies. Recombinant systems for the preparation of Taq RNAP by co-overexpression and assembly in the heterologous host, Escherichia coli, have been described, but these did not yield enzyme suitable for crystallographic studies. Here we describe recombinant systems for the preparation of Taq RNAP harboring full or partial deletions of the Taq beta' non-conserved domain (NCD), yielding enzyme suitable for crystallographic studies. This opens the way for structural studies of genetically manipulated enzymes, allowing the preparation of more crystallizable enzymes and facilitating detailed structure/function analysis. Characterization of the Taqbeta'NCD deletion mutants generated in this study showed that the beta'NCD is important for the efficient binding of the sigma subunit, confirming previous hypotheses. Finally, preliminary structural analysis (at 4.1Angstroms resolution) of one of the recombinant mutants revealed a previously unobserved conformation of the beta-flap, further defining the range of conformations accessible to this flexible structural element.

Cyclic AMP receptor protein and RhaR synergistically activate transcription from the L-rhamnose-responsive rhaSR promoter in Escherichia coli

The Escherichia coli rhaSR operon encodes two AraC family transcription activator proteins, RhaS and RhaR, which regulate expression of the l-rhamnose catabolic regulon in response to l-rhamnose availability. RhaR positively regulates rhaSR in response to l-rhamnose, and RhaR activation can be enhanced by the cyclic AMP (cAMP) receptor protein (CRP) protein. CRP is a well-studied global transcription regulator that binds to DNA as a dimer and activates transcription in the presence of cAMP. We investigated the mechanism of CRP activation at rhaSR both alone and in combination with RhaR in vivo and in vitro. Base pair substitutions at potential CRP binding sites in the rhaSR-rhaBAD intergenic region demonstrate that CRP site 3, centered at position -111.5 relative to the rhaSR transcription start site, is required for the majority of the CRP-dependent activation of rhaSR. DNase I footprinting confirms that CRP binds to site 3; CRP binding to the other potential CRP sites at rhaSR was not detected. We show that, at least in vitro, CRP is capable of both RhaR-dependent and RhaR-independent activation of rhaSR from a total of three transcription start sites. In vitro transcription assays indicate that the carboxy-terminal domain of the alpha subunit (alpha-CTD) of RNA polymerase is at least partially dispensable for RhaR-dependent activation but that the alpha-CTD is required for CRP activation of rhaSR. Although CRP requires the presence of RhaR for efficient in vivo activation of rhaSR, DNase I footprinting assays indicated that cooperative binding between RhaR and CRP does not make a significant contribution to the mechanism of CRP activation at rhaSR. It therefore appears that CRP activates transcription from rhaSR as it would at simple class I promoters, albeit from a relatively distant position.

An RNA Polymerase Mutant Deficient in DNA Melting Facilitates Study of Activation Mechanism: Application to an Artificial Activator of Transcription

Transcription initiation is a major target for the regulation of gene expression in all organisms. Transcription activators can stimulate different steps in the initiation process including the initial binding of RNA polymerase (RNAP) to the promoter and a subsequent promoter-melting step. Typically, kinetic assays are required to determine whether an activator exerts its effect on the initial binding of RNAP or on the promoter-melting step. Here we take advantage of a mutant Escherichia coli RNAP that is deficient in promoter melting to assess the ability of an activator to stabilize the initial binding of RNAP to the promoter. For the well-characterized activator CRP, we show that this RNAP mutant can be used to distinguish between effects on initial binding and promoter melting; these results provide an independent confirmation of the results of kinetic analysis. We then employ the melting-deficient RNAP mutant to demonstrate an effect of an artificial activator of transcription on the initial binding of RNAP. Our findings demonstrate that a melting-deficient RNAP mutant can be used to trap a normally unstable intermediate in transcription initiation, thus providing a novel tool for probing activation mechanism.

An intersubunit contact stimulating transcription initiation by E coli RNA polymerase: interaction of the alpha C-terminal domain and sigma region 4

The C-terminal domain of the Escherichia coli RNA polymerase (RNAP) alpha subunit (alphaCTD) stimulates transcription initiation by interacting with upstream (UP) element DNA and a variety of transcription activators. Here we identify specific substitutions in region 4.2 of sigma 70 (sigma(70)) and in alphaCTD that decrease transcription initiation from promoters containing some, but not all, UP elements. This decrease in transcription derives from a decrease in the initial equilibrium constant for RNAP binding (K(B)). The open complexes formed by the mutant and wild-type RNAPs differ in DNAse I sensitivity at the junction of the alphaCTD and sigma DNA binding sites, correlating with the differences in transcription. A model of the DNA-alphaCTD-sigma region 4.2 ternary complex, constructed from the previously determined X-ray structures of the Thermus aquaticus sigma region 4.2-DNA complex and the E. coli alphaCTD-DNA complex, indicates that the residues identified by mutation in sigma region 4.2 and in alphaCTD are in very close proximity. Our results strongly suggest that alphaCTD, when bound to an UP element proximal subsite, contacts the RNAP sigma(70) subunit, increasing transcription. Previous data from the literature suggest that this same sigma-alphaCTD interaction also plays a role in transcription factor-mediated activation.

The response regulator BvgA and RNA polymerase alpha subunit C-terminal domain bind simultaneously to different faces of the same segment of promoter DNA

Examination of the binding of FeBABE-conjugated BvgA to the fha promoter of Bordetella pertussis has revealed that three dimers, formed by head-to-head association of monomers, bind one face of the DNA helix from the inverted-heptad primary binding site to the -35 region. The orientation of BvgA monomers within the dimers is the same as that recently demonstrated by X-ray crystallographic methods for a dimer of the C-terminal domain of NarL bound to DNA. Use of FeBABE conjugates of RNAP alpha subunit C-terminal domain showed that binding of this domain is linearly coincident with binding of the BvgA dimers, but to a different helical face. These results reveal a previously undescribed mode of interaction between RNAP alpha-CTD and a transcriptional activator.

The sigma(70) subunit of RNA polymerase is contacted by the (lambda)Q antiterminator during early elongation

The Q protein of bacteriophage lambda is a transcription antiterminator that modifies the elongation properties of E. coli RNA polymerase (RNAP). To do this, DNA-bound (lambda)Q must first engage a paused elongation complex. Here we show that this engagement of (lambda)Q with RNAP involves an interaction between (lambda)Q and sigma(70), demonstrating that sigma(70) can be a target of regulation during elongation. Furthermore, we provide evidence that this interaction between (lambda)Q and sigma(70) stabilizes a conformation of RNAP that requires the disengagement of a segment of sigma(70) from the core enzyme. Recent structure-based models posit that the transition from the initiation to the elongation phase of transcription involves the staged displacement of sigma(70) from the RNAP core. Our findings provide support for this proposal.

The RNA polymerase alpha subunit from Sinorhizobium meliloti can assemble with RNA polymerase subunits from Escherichia coli and function in basal and activated transcription both in vivo and in vitro

Sinorhizobium meliloti, a gram-negative soil bacterium, forms a nitrogen-fixing symbiotic relationship with members of the legume family. To facilitate our studies of transcription in S. meliloti, we cloned and characterized the gene for the alpha subunit of RNA polymerase (RNAP). S. meliloti rpoA encodes a 336-amino-acid, 37-kDa protein. Sequence analysis of the region surrounding rpoA identified six open reading frames that are found in the conserved gene order secY (SecY)-adk (Adk)-rpsM (S13)-rpsK (S11)-rpoA (alpha)-rplQ (L17) found in the alpha-proteobacteria. In vivo, S. meliloti rpoA expressed in Escherichia coli complemented a temperature sensitive mutation in E. coli rpoA, demonstrating that S. meliloti alpha supports RNAP assembly, sequence-specific DNA binding, and interaction with transcriptional activators in the context of E. coli. In vitro, we reconstituted RNAP holoenzyme from S. meliloti alpha and E. coli beta, beta', and sigma subunits. Similar to E. coli RNAP, the hybrid RNAP supported transcription from an E. coli core promoter and responded to both upstream (UP) element- and Fis-dependent transcription activation. We obtained similar results using purified RNAP from S. meliloti. Our results demonstrate that S. meliloti alpha functions are conserved in heterologous host E. coli even though the two alpha subunits are only 51% identical. The ability to utilize E. coli as a heterologous system in which to study the regulation of S. meliloti genes could provide an important tool for our understanding and manipulation of these processes.

Architecture of Fis-activated transcription complexes at the Escherichia coli rrnB P1 and rrnE P1 promoters

The transcription factor Fis activates the Escherichia coli rRNA promoters rrnB P1 and rrnE P1 by binding to sites centered at -71 and -72, respectively, and interacting with the C-terminal domain of the alpha subunit of RNA polymerase (RNAP alphaCTD). To understand the mechanism of activation by Fis at these promoters, we used oriented alpha-heterodimeric RNAPs and heterodimers of Fis to determine whether one or both subunits of alpha and Fis participate in the alphaCTD-Fis interaction. Our results imply that only one alphaCTD in the alpha dimer and only one activation-proficient subunit in the Fis dimer are required for activation by Fis. A library of alanine substitutions in alpha was used to identify the alphaCTD determinants required for Fis-dependent transcription at rrnB P1 and rrnE P1. We propose that the transcriptional activation region of the promoter-proximal subunit of the Fis dimer interacts with a determinant that includes E273 of one alphaCTD to activate transcription. We further suggest that the Fis contact to alphaCTD results in alphaCTD interactions with DNA that differ somewhat from those that occur at UP elements in the absence of Fis. The accompanying paper shows that the 273 determinant on alphaCTD is also targeted by Fis at the proP P2 promoter where the activator binds overlapping the -35 hexamer. Thus, similar Fis-alphaCTD interactions are used for activation of transcription when the activator is bound at very different positions on the DNA.

The C-terminal domains of the RNA polymerase alpha subunits: contact site with Fis and localization during co-activation with CRP at the Escherichia coli proP P2 promoter

Fis is a versatile transactivator that functions at many different promoters. Fis activates transcription at the RpoS-dependent proP P2 promoter when bound to a site that overlaps the minus sign35 hexamer by a mechanism that requires the C-terminal domain of the alpha subunit of RNA polymerase (alphaCTD). The region on Fis responsible for activating transcription through the alphaCTD has been localized to a short beta-turn near the DNA-binding determinant on one subunit of the Fis homodimer. We report here that Fis-dependent activation of proP P2 transcription requires two discrete regions on the alphaCTD. One region, consisting of residues 264-265 and 296-297, mediates DNA binding. A second patch, comprising amino acid residues 271-273, forms a ridge on the surface of the alphaCTD that we propose interacts with Fis. The accompanying paper shows that these same regions on alphaCTD are utilized for transcriptional activation at the rrnB and rrnE P1 promoters by Fis bound to a site upstream of the core promoter (centered at minus sign71/minus sign72). In addition to stimulation of proP P2 transcription by Fis, CRP co-activates this promoter when bound to a remote site upstream from the promoter (centered at -121.5). RNA polymerase preparations lacking one alphaCTD of the alpha dimer were employed to demonstrate that the beta'-associated alpha(II)CTD was utilized preferentially by Fis at proP P2 in the presence and absence of CRP. These experiments define the overall architecture of the proP P2 initiation complex where Fis and CRP each function through a different alphaCTD.

Role of the RNA polymerase alpha subunits in MetR-dependent activation of metE and metH: important residues in the C-terminal domain and orientation requirements within RNA polymerase

Many transcription factors activate by directly interacting with RNA polymerase (RNAP). The C terminus of the RNAP alpha subunit (alphaCTD) is a common target of activators. We used both random mutagenesis and alanine scanning to identify alphaCTD residues that are crucial for MetR-dependent activation of metE and metH. We found that these residues localize to two distinct faces of the alphaCTD. The first is a complex surface consisting of residues important for alpha-DNA interactions, activation of both genes (residues 263, 293, and 320), and activation of either metE only (residues 260, 276, 302, 306, 309, and 322) or metH only (residues 258, 264, 290, 294, and 295). The second is a distinct cluster of residues important for metE activation only (residues 285, 289, 313, and 314). We propose that a difference in the location of the MetR binding site for activation at these two promoters accounts for the differences in the residues of alpha required for MetR-dependent activation. We have designed an in vitro reconstitution-purification protocol that allows us to specifically orient wild-type or mutant alpha subunits to either the beta-associated or the beta'-associated position within RNAP (comprising alpha(2), beta, beta', and sigma subunits). In vitro transcriptions using oriented alpha RNAP indicate that a single alphaCTD on either the beta- or the beta'-associated alpha subunit is sufficient for MetR activation of metE, while MetR interacts preferentially with the alphaCTD on the beta-associated alpha subunit at metH. We propose that the different alphaCTD requirements at these two promoters are due to a combination of the difference in the location of the activation site and limits on the rotational flexibility of the alphaCTD.

RNA polymerase alpha and sigma(70) subunits participate in transcription of the Escherichia coli uhpT promoter

Fundamental questions in bacterial gene regulation concern how multiple regulatory proteins interact with the transcription apparatus at a single promoter and what are the roles of protein contacts with RNA polymerase and changes in DNA conformation. Transcription of the Escherichia coli uhpT gene, encoding the inducible sugar phosphate transporter, is dependent on the response regulator UhpA and is stimulated by the cyclic AMP receptor protein (CAP). UhpA binds to multiple sites in the uhpT promoter between positions -80 and -32 upstream of the transcription start site, and CAP binds to a single site centered at position -103.5. The role in uhpT transcription of portions of RNA polymerase Esigma(70) holoenzyme which affect regulation at other promoters was examined by using series of alanine substitutions throughout the C-terminal domains of RpoA (residues 255 to 329) and of RpoD (residues 570 to 613). Alanine substitutions that affected in vivo expression of a uhpT-lacZ transcriptional fusion were tested for their effect on in vitro transcription activity by using reconstituted holoenzymes. Consistent with the binding of UhpA near the -35 region, residues K593 and K599 in the C-terminal region of RpoD were necessary for efficient uhpT expression in response to UhpA alone. Their requirement was overcome when CAP was also present. In addition, residues R265, G296, and S299 in the DNA-binding surface of the C-terminal domain of RpoA (alphaCTD) were important for uhpT transcription even in the presence of CAP. Substitutions at several other positions had effects in cells but not during in vitro transcription with saturating levels of the transcription factors. Two DNase-hypersensitive sites near the upstream end of the UhpA-binding region were seen in the presence of all three transcription factors. Their appearance required functional alphaCTD but not the presence of upstream DNA. These results suggest that both transcription activators depend on or interact with different subunits of RNA polymerase, although their role in formation of proper DNA geometry may also be crucial.

Localization of amino acids required for Fis to function as a class II transcriptional activator at the RpoS-dependent proP P2 promoter

ProP is an integral membrane transporter of proline, glycine betaine, and several other osmoprotecting compounds. Fis plus RpoS collaborate to promote a burst of proP transcription in late exponential growth phase. This brief period of ProP synthesis enables stationary phase cells to cope with a potential hyperosmotic shock. Fis activates the RpoS (sigma(38))-dependent proP P2 promoter by binding to a site within the promoter region centered at -41 and thus functions as a class II activator. We show here that activation by Fis at this promoter is completely dependent upon the alpha-CTD of RNA polymerase and that the activation domain on Fis is localized to a four amino acid ridge on the surface of Fis adjacent to the helix-turn-helix DNA binding domain in only one subunit of the homodimer. Fis mutants containing amino acid substitutions within this region are defective in cooperative binding interactions with the sigma(38)-form of RNA polymerase. Some of these substitutions also alter interactions with DNA sequences flanking the core binding site, but we show that changes in Fis-mediated curvature do not affect promoter activity. We conclude that the same amino acids are used by Fis to activate transcription from a class I (-71, rrnB P1) and class II (-41, proP P2) location, but this region is distinct from that required to regulate the Hin site-specific DNA inversion reaction.

Interdependence of the position and orientation of SoxS binding sites in the transcriptional activation of the class I subset of Escherichia coli superoxide-inducible promoters

SoxS is the direct transcriptional activator of the member genes of the Escherichia coli superoxide regulon. At class I SoxS-dependent promoters, e.g. zwf and fpr, whose SoxS binding sites ('soxbox') lie upstream of the -35 region of the promoter, activation requires the C-terminal domain of the RNA polymerase alpha-subunit, while at class II SoxS-dependent promoters, e.g. fumC and micF, whose binding sites overlap the -35 region, activation is independent of the alpha-CTD. To determine whether SoxS activation of its class I promoters shows the same helical phase-dependent spacing requirement as class I promoters activated by catabolite gene activator protein, we increased the 7 bp distance between the 20 bp zwf soxbox and the zwf -35 promoter hexamer by 5 bp and 11 bp, and we decreased the 15 bp distance between the 20 bp fpr soxbox and the fpr -35 promoter hexamer by the same amounts. In both cases, displacement of the binding site by a half or full turn of the DNA helix prevented transcriptional activation. With constructs containing the binding site of one gene fused to the promoter of the other, we demonstrated that the positional requirements are a function of the specific binding site, not the promoter. Supposing that opposite orientation of the SoxS binding site at the two promoters might account for the positional requirements, we placed the zwf and fpr soxboxes in the reverse orientation at the various positions upstream of the promoters and determined the effect of orientation on transcription activation. We found that reversing the orientation of the zwf binding site converts its positional requirement to that of the fpr binding site in its normal orientation, and vice versa. Analysis by molecular information theory of DNA sequences known to bind SoxS in vitro is consistent with the opposite orientation of the zwf and fpr soxboxes.

Bacterial promoter architecture: subsite structure of UP elements and interactions with the carboxy-terminal domain of the RNA polymerase alpha subunit

We demonstrate here that the previously described bacterial promoter upstream element (UP element) consists of two distinct subsites, each of which, by itself, can bind the RNA polymerase holoenzyme alpha subunit carboxy-terminal domain (RNAP alphaCTD) and stimulate transcription. Using binding-site-selection experiments, we identify the consensus sequence for each subsite. The selected proximal subsites (positions -46 to -38; consensus 5'-AAAAAARNR-3') stimulate transcription up to 170-fold, and the selected distal subsites (positions -57 to -47; consensus 5'-AWWWWWTTTTT-3') stimulate transcription up to 16-fold. RNAP has subunit composition alpha(2)betabeta'sigma and thus contains two copies of alphaCTD. Experiments with RNAP derivatives containing only one copy of alphaCTD indicate, in contrast to a previous report, that the two alphaCTDs function interchangeably with respect to UP element recognition. Furthermore, function of the consensus proximal subsite requires only one copy of alphaCTD, whereas function of the consensus distal subsite requires both copies of alphaCTD. We propose that each subsite constitutes a binding site for a copy of alphaCTD, and that binding of an alphaCTD to the proximal subsite region (through specific interactions with a consensus proximal subsite or through nonspecific interactions with a nonconsensus proximal subsite) is a prerequisite for binding of the other alphaCTD to the distal subsite.

Histidine codons appended to the gene encoding the RPO22 subunit of vaccinia virus RNA polymerase facilitate the isolation and purification of functional enzyme and associated proteins from virus-infected cells

Vaccinia virus encodes a eukaryotic-like RNA polymerase composed of two large and six small subunit protein species. A replication-competent virus with 10 histidine codons added to the single endogenous J4R open reading frame was constructed. The altered migration of the 22-kDa subunit of RNA polymerase on SDS-polyacrylamide gel electrophoresis confirmed that J4R encoded the RPO22 subunit and that the mutant virus was genetically stable. The histidine-tagged RNA polymerase bound quantitatively to metal-affinity resins and was eluted in an active form upon addition of imidazole. Glycerol gradient sedimentation of the eluted fraction indicated that most of the RPO22 in infected cells is associated with RNA polymerase. Using stringent washing conditions, metal-affinity chromatography resulted in a several hundred-fold increase in RNA-polymerase-specific activity, and substantially pure enzyme was obtained with an additional conventional chromatography step. When mild conditions were used for washing the metal-affinity resin, the vaccinia virus-encoded capping enzyme, early transcription factor, and nucleoside triphosphate phosphohydrolase I specifically co-eluted with the tagged RNA polymerase, consistent with their physical association. The ability to selectively bind RNA polymerase to an affinity column provided a simple and rapid method of concentrating and purifying active enzyme and protein complexes.

Upstream A-tracts increase bacterial promoter activity through interactions with the RNA polymerase alpha subunit

Upstream A-tracts stimulate transcription from a variety of bacterial promoters, and this has been widely attributed to direct effects of the intrinsic curvature of A-tract-containing DNA. In this work we report experiments that suggest a different mechanism for the effects of upstream A-tracts on transcription. The similarity of A-tract-containing sequences to the adenine- and thymine-rich upstream recognition elements (UP elements) found in some bacterial promoters suggested that A-tracts might increase promoter activity by interacting with the alpha subunit of RNA polymerase (RNAP). We found that an A-tract-containing sequence placed upstream of the Escherichia coli lac or rrnB P1 promoters stimulated transcription both in vivo and in vitro, and that this stimulation required the C-terminal (DNA-binding) domain of the RNAP alpha subunit. The A-tract sequence was protected by wild-type RNAP but not by alpha-mutant RNAPs in footprints. The effect of the A-tracts on transcription was not as great as that of the most active UP elements, consistent with the degree of similarity of the A-tract sequence to the UP element consensus. A-tracts functioned best when positioned close to the -35 hexamer rather than one helical turn farther upstream, similar to the positioning optimal for UP element function. We conclude that A-tracts function as UP elements, stimulating transcription by providing binding site(s) for the RNAP alphaCTD, and we suggest that these interactions could contribute to the previously described wrapping of promoter DNA around RNAP.

DNA-based positive control mutants in the binding site sequence of 434 repressor

As detected by chemical nuclease treatments, the conformation of the 434 repressor-DNA complex depends on the sequence of the bound DNA (Bell, A. C., and Koudelka, G. B. (1993) J. Mol. Biol. 234, 542-553). We show here that these DNA sequence-dependent conformational changes alter the efficiency with which the repressor activates transcription from 434 PRM. Several lines of evidence suggest that binding site sequence affects the repressor's ability to activate transcription by altering the accessibility of the activation surface on the repressor to RNA polymerase. The results presented here show that in addition to affecting transcription by altering the overall binding affinity of protein for DNA, DNA sequence may also modulate the activity of the DNA-bound protein.

Identification of an UP element consensus sequence for bacterial promoters

The UP element, a component of bacterial promoters located upstream of the -35 hexamer, increases transcription by interacting with the RNA polymerase alpha-subunit. By using a modification of the SELEX procedure for identification of protein-binding sites, we selected in vitro and subsequently screened in vivo for sequences that greatly increased promoter activity when situated upstream of the Escherichia coli rrnB P1 core promoter. A set of 31 of these upstream sequences increased transcription from 136- to 326-fold in vivo, considerably more than the natural rrnB P1 UP element, and was used to derive a consensus sequence: -59 nnAAA(A/T)(A/T)T(A/T)TTTTnnAAAAnnn -38. The most active selected sequence contained the derived consensus, displayed all of the properties of an UP element, and the interaction of this sequence with the alpha C-terminal domain was similar to that of previously characterized UP elements. The identification of the UP element consensus should facilitate a detailed understanding of the alpha-DNA interaction. Based on the evolutionary conservation of the residues in alpha responsible for interaction with UP elements, we suggest that the UP element consensus sequence should be applicable throughout eubacteria, should generally facilitate promoter prediction, and may be of use for biotechnological applications.

Ada protein-RNA polymerase sigma subunit interaction and alpha subunit-promoter DNA interaction are necessary at different steps in transcription initiation at the Escherichia coli Ada and aidB promoters

The methylated form of the Ada protein (meAda) binds the ada and aidB promoters between 60 and 40 base pairs upstream from the transcription start and activates transcription of the Escherichia coli ada and aidB genes. This region is also a binding site for the alpha subunit of RNA polymerase and resembles the rrnB P1 UP element in A/T content and location relative to the core promoter. In this report, we show that deletion of the C-terminal domain of the alpha subunit severely decreases meAda-independent binding of RNA polymerase to ada and aidB, affecting transcription initiation at these promoters. We provide evidence that meAda activates transcription by direct interaction with the C-terminal domain of RNA polymerase sigma70 subunit (amino acids 574-613). Several negatively charged residues in the sigma70 C-terminal domain are important for transcription activation by meAda; in particular, a glutamic acid to valine substitution at position 575 has a dramatic effect on meAda-dependent transcription. Based on these observations, we propose that the role of the alpha subunit at ada and aidB is to allow initial binding of RNA polymerase to the promoters. However, transcription initiation is dependent on meAda-sigma70 interaction.

Hybrid Bordetella pertussis-Escherichia coli RNA polymerases: selectivity of promoter activation

We constructed hybrid Bordetella pertussis-Escherichia coli RNA polymerases and compared productive interactions between transcription activators and cognate RNA polymerase subunits in an in vitro transcription system. Virulence-associated genes of B. pertussis, in the presence of their activator BvgA, are transcribed by all variants of hybrid RNA polymerases, whereas transcription at the E. coli lac promoter regulated by the cyclic AMP-catabolite gene activator protein has an absolute requirement for the E. coli alpha subunit. This suggests that activator contact sites involve a high degree of selectivity.

Transcription activation at class II CAP-dependent promoters: two interactions between CAP and RNA polymerase

At Class II catabolite activator protein (CAP)-dependent promoters, CAP activates transcription from a DNA site overlapping the DNA site for RNA polymerase. We show that transcription activation at Class II CAP-dependent promoters requires not only the previously characterized interaction between an activating region of CAP and the RNA polymerase alpha subunit C-terminal domain, but also an interaction between a second, promoter-class-specific activating region of CAP and the RNA polymerase alpha subunit N-terminal domain. We further show that the two interactions affect different steps in transcription initiation. Transcription activation at Class II CAP-dependent promoters provides a paradigm for understanding how an activator can make multiple interactions with the transcription machinery, each interaction being responsible for a specific mechanistic consequence.