Mapping of a contact for the RNA 3' terminus in the largest subunit of RNA polymerase

Identifying protein interactions by hydroxyl-radical protein footprinting

Hydroxyl-radical protein footprinting is a straightforward and direct method to map protein sites involved in macromolecular interactions. The first step is to radioactively end-label the protein. Using hydroxyl radicals as a peptide backbone cleavage reagent, the protein is then cleaved in the absence and presence of ligand. Cleavage products are separated by high resolution gel electrophoresis. The digital image of the footprinting gel can be subjected to quantitative analysis to identify changes in the sensitivity of the protein to hydroxyl-radical cleavage. Molecular weight markers are electrophoresed on the same gel and hydroxyl-radical cleavage sites assigned by interpolation between the known cleavage sites of the markers. The results are presented in the form of a difference plot that shows regions of the protein that change their susceptibility to cleavage while bound to a ligand.

An allosteric path to transcription termination

Transcription termination signals in bacteria occur in RNA as a strong hairpin followed by a stretch of U residues at the 3' terminus. To release the transcript, RNA polymerase (RNAP) is thought to translocate forward without RNA synthesis. Here we provide genetic and biochemical evidence supporting an alternative model in which extensive conformational changes across the enzyme lead to termination without forward translocation. In this model, flexible parts of the RNA exit channel (zipper, flap, and zinc finger) assist the initial step of hairpin folding (nucleation). The hairpin then invades the RNAP main channel, causing RNA:DNA hybrid melting, structural changes of the catalytic site, and DNA-clamp opening induced by interaction with the G(trigger)-loop. Our results envision the elongation complex as a flexible structure, not a rigid body, and establish basic principles of the termination pathway that are likely to be universal in prokaryotic and eukaryotic systems.

A Central Role of the RNA Polymerase Trigger Loop in Active-Site Rearrangement during Transcriptional Pausing

Transcriptional pausing by RNA polymerase is an underlying event in the regulation of transcript elongation, yet the physical changes in the transcribing complex that create the initially paused conformation remain poorly understood. We report that this nonbacktracked elemental pause results from an active-site rearrangement whose signature includes a trigger-loop conformation positioned near the RNA 3' nucleotide and a conformation of betaDloopII that allows fraying of the RNA 3' nucleotide away from the DNA template. During nucleotide addition, trigger-loop movements or folding appears to assist NTP-stimulated translocation and to be crucial for catalysis. At a pause, the trigger loop directly contributes to the paused conformation, apparently by restriction of its movement or folding, whereas a previously postulated unfolding of the bridge helix does not. This trigger-loop-centric model can explain many properties of transcriptional pausing.

Structural basis of transcription: role of the trigger loop in substrate specificity and catalysis

New structures of RNA polymerase II (pol II) transcribing complexes reveal a likely key to transcription. The trigger loop swings beneath a correct nucleoside triphosphate (NTP) in the nucleotide addition site, closing off the active center and forming an extensive network of interactions with the NTP base, sugar, phosphates, and additional pol II residues. A histidine side chain in the trigger loop, precisely positioned by these interactions, may literally "trigger" phosphodiester bond formation. Recognition and catalysis are thus coupled, ensuring the fidelity of transcription.

Localization of the Escherichia coli RNA polymerase beta' subunit residue phosphorylated by bacteriophage T7 kinase Gp0.7

During bacteriophage T7 infection, the Escherichia coli RNA polymerase beta' subunit is phosphorylated by the phage-encoded kinase Gp0.7. Here, we used proteolytic degradation and mutational analysis to localize the phosphorylation site to a single amino acid, Thr(1068), in the evolutionarily hypervariable segment of beta'. Using a phosphomimetic substitution of Thr(1068), we show that phosphorylation of beta' leads to increased rho-dependent transcription termination, which may help to switch from host to viral RNA polymerase transcription during phage development.

Molecular Mechanism of Transcription Inhibition by Peptide Antibiotic Microcin J25

21 amino acid peptide Microcin J25 (MccJ25) inhibits transcription by bacterial RNA polymerase (RNAP). MccJ25-resistance mutations cluster in the RNAP secondary channel through which incoming NTP substrates are thought to reach the catalytic center and the 3' end of the nascent RNA is likely to thread in backtracked transcription complexes. The secondary channel also accepts transcript cleavage factors GreA and GreB. Here, we demonstrate that MccJ25 inhibits GreA/GreB-dependent transcript cleavage, impedes formation of backtracked complexes, and can be crosslinked to the 3'-end of the nascent RNA in elongation complexes. These results place the MccJ25 binding site within the secondary channel. Moreover, single-molecule assays reveal that MccJ25 binding to a transcribing RNAP temporarily stops transcript elongation but has no effect on the elongation velocity between pauses. Kinetic analysis of single-molecule data allows us to put forward a model of transcription inhibition by MccJ25 that envisions the complete occlusion of the secondary channel by bound inhibitor.

Structure and function of the transcription elongation factor GreB bound to bacterial RNA polymerase

Bacterial GreA and GreB promote transcription elongation by stimulating an endogenous, endonucleolytic transcript cleavage activity of the RNA polymerase. The structure of Escherichia coli core RNA polymerase bound to GreB was determined by cryo-electron microscopy and image processing of helical crystals to a nominal resolution of 15 A, allowing fitting of high-resolution RNA polymerase and GreB structures. In the resulting model, the GreB N-terminal coiled-coil domain extends 45 A through a channel directly to the RNA polymerase active site. The model leads to detailed insights into the mechanism of Gre factor activity that explains a wide range of experimental observations and points to a key role for conserved acidic residues at the tip of the Gre factor coiled coil in modifying the RNA polymerase active site to catalyze the cleavage reaction. Mutational studies confirm that these positions are critical for Gre factor function.

The many conformational states of RNA polymerase elongation complexes and their roles in the regulation of transcription

Transcription is highly regulated both by protein factors and by specific RNA or DNA sequence elements. Central to this regulation is the ability of RNA polymerase (RNAP) to adopt multiple conformational states during elongation. This review focuses on the mechanism of transcription elongation and the role of different conformational states in the regulation of elongation and termination. The discussion centers primarily on data from structural and functional studies on Escherichia coli RNAP. To introduce the players, a brief introduction to the general mechanism of elongation, the regulatory proteins, and the conformational states is provided. The role of each of the conformational states in elongation is then discussed in detail. Finally, an integrated mechanism of elongation is presented, bringing together the panoply of experiments.

Promoting elongation with transcript cleavage stimulatory factors

Transcript elongation by RNA polymerase is a dynamic process, capable of responding to a number of intrinsic and extrinsic signals. A number of elongation factors have been identified that enhance the rate or efficiency of transcription. One such class of factors facilitates RNA polymerase transcription through blocks to elongation by stimulating the polymerase to cleave the nascent RNA transcript within the elongation complex. These cleavage factors are represented by the Gre factors from prokaryotes, and TFIIS and TFIIS-like factors found in archaea and eukaryotes. High-resolution structures of RNA polymerases and the cleavage factors in conjunction with biochemical investigations and genetic analyses have provided insights into the mechanism of action of these elongation factors. However, there are yet many unanswered questions regarding the regulation of these factors and their effects on target genes.

Escherichia coli RNA polymerase is the target of the cyclopeptide antibiotic microcin J25

Escherichia coli microcin J25 (MccJ25) is a plasmid-encoded, cyclic peptide antibiotic consisting of 21 unmodified amino acid residues. It is primarily active on gram-negative bacteria related to the producer strain, inducing cell filamentation in an SOS-independent way. A mutation causing resistance to MccJ25 was isolated. Genetic analysis indicated that it resided in the rpoC gene, encoding the beta' subunit of RNA polymerase, at 90 min on the E. coli genetic map. The mutation was genetically crossed on to a plasmid containing the wild-type rpoC gene. The presence of the recombinant plasmid conferred complete resistance to otherwise sensitive strains. Nucleotide sequencing of the plasmid-borne, mutant rpoC gene revealed a ACC (Thr)-to-ATC (Ile) change at codon 931, within homology block G, an evolutionarily conserved region in the large subunits of all RNA polymerases. MccJ25 decreased RNA synthesis both in vivo and in vitro. These results point to the RNA polymerase as the target of microcin action. We favor the possibility that the filamentous phenotype induced by MccJ25 results from impaired transcription of genes coding for cell division proteins. As far as we know, MccJ25 is the first peptide antibiotic shown to affect RNA polymerase.

A structural model of transcription elongation

The path of the nucleic acids through a transcription elongation complex was tracked by mapping cross-links between bacterial RNA polymerase (RNAP) and transcript RNA or template DNA onto the x-ray crystal structure. In the resulting model, the downstream duplex DNA is nestled in a trough formed by the beta' subunit and enclosed on top by the beta subunit. In the RNAP channel, the RNA/DNA hybrid extends from the enzyme active site, along a region of the beta subunit harboring rifampicin resistance mutations, to the beta' subunit "rudder." The single-stranded RNA is then extruded through another channel formed by the beta-subunit flap domain. The model provides insight into the functional properties of the transcription complex.

The functional role of basic patch, a structural element of Escherichia coli transcript cleavage factors GreA and GreB

The transcript cleavage factors GreA and GreB of Escherichia coli are involved in the regulation of transcription elongation. The surface charge distribution analysis of their three-dimensional structures revealed that the N-terminal domains of GreA and GreB contain a small and large basic "patch," respectively. To elucidate the functional role of basic patch, mutant Gre proteins were engineered in which the size and charge distribution of basic patch were modified and characterized biochemically. We found that Gre mutants lacking basic patch or carrying basic patch of decreased size bind to RNA polymerase and induce transcript cleavage reaction in minimally backtracked ternary elongation complex (TEC) with the same efficiency as the wild type factors. However, they exhibit substantially lower readthrough and cleavage activities toward extensively backtracked and arrested TECs and display decreased efficiency of photocross-linking to the RNA 3'-terminus. Unlike wild type factors, basic patch-less Gre mutants are unable to complement the thermosensitive phenotype of GreA(-):GreB(-) E. coli strain. The large basic patch is required but not sufficient for the induction of GreB-type cleavage reaction and for the cleavage of arrested TECs. Our results demonstrate that the basic patch residues are not directly involved in the induction of transcript cleavage reaction and suggest that the primary role of basic patch is to anchor the nascent RNA in TEC. These interactions are essential for the readthrough and antiarrest activities of Gre factors and, apparently, for their in vivo functions.

Mapping of subunit-subunit contact surfaces on the beta' subunit of Escherichia coli RNA polymerase

The RNA polymerase core enzyme of Escherichia coli with the catalytic activity of RNA polymerization is assembled sequentially under the order: 2alpha --> alpha(2) --> alpha(2)beta --> alpha(2)betabeta'. The core enzyme gains the activities of promoter recognition and transcription initiation after binding the sigma subunit. The subunit-subunit contact surfaces of beta' subunit (1407 residues) were analyzed by testing complex formation between various beta' fragments and either the alpha(2)beta complex or the sigma(70) subunit. Results indicate that two regions, one central region between residues 515 and 842 and the other COOH-terminal proximal region downstream from residue 1141, are involved in binding the alpha(2)beta complex; and the NH(2)-terminal proximal region between residues 201 and 345 plays a major role in binding the sigma(70) subunit. However, both alpha(2)beta binding sites have weak activity of the sigma(70) subunit; likewise, the sigma(70) subunit-contact surface has weak binding activity of the alpha(2)beta complex. The sites involved in the catalytic function of RNA polymerization are all located within two spacer regions sandwiched between these three subunit-subunit contact surfaces.

Spatial organization of the core region of yeast TFIIIB-DNA complexes

The interaction of yeast TFIIIB with the region upstream of the SUP4 tRNATyr gene was extensively probed by use of photoreactive phosphodiesters, deoxyuridines, and deoxycytidines that are site specifically incorporated into DNA. The TATA binding protein (TBP) was found to be in close proximity to the minor groove of a TATA-like DNA sequence that starts 30 nucleotides upstream of the start site of transcription. TBP was cross-linked to the phosphate backbone of DNA from bp -30 to -20 in the nontranscribed strand and from bp -28 to -24 in the transcribed strand (+1 denotes the start site of transcription). Most of the major groove of DNA in this region was shown not to be in close proximity to TBP, thus resembling the binding of TBP to the TATA box, with one notable exception. TBP was shown to interact with the major groove of DNA primarily at bp -23 and to a lesser degree at bp -25 in the transcribed strand. The stable interaction of TBP with the major groove at bp -23 was shown to require the B" subunit of TFIIIB. The S4 helix and flanking region of TBP were shown to be proximal to the major groove of DNA by peptide mapping of the region of TBP cross-linked at bp -23. Thus, TBP in the TFIIIB-SUP4 gene promoter region is bound in the same direction as TBP bound to the TATA box with respect to the transcription start site. The B" and TFIIB-related factor (BRF) subunits of TFIIIB are positioned on opposite sides of the TBP-DNA core of the TFIIIB complex, as indicated by correlation of cross-linking data to the crystal structure of the TBP-TATA box complex. Evidence is given for BRF binding near the C-terminal stirrup of TBP, similar to that of TFIIB near the TBP-TATA box complex. The protein clamp formed around the TBP-DNA complex by BRF and B" would help explain the long half-life of the TFIIIB-DNA complex and its resistance to polyanions and high salt. The path of DNA traversing the surface of TBP at the 3' end of the TATA-like element in the SUP4 tRNA gene is not the same as that of TBP bound to a TATA box element, as shown by the cross-linking of TBP at bp -23.

BglG, the transcriptional antiterminator of the bgl system, interacts with the beta' subunit of the Escherichia coli RNA polymerase

The Escherichia coli BglG protein antiterminates transcription at two terminator sites within the bgl operon in response to the presence of beta-glucosides in the growth medium. BglG was previously shown to be an RNA-binding protein that recognizes a specific sequence located just upstream of each of the terminators and partially overlapping with them. We show here that BglG also binds to the E. coli RNA polymerase, both in vivo and in vitro. By using several techniques, we identified the beta' subunit of RNA polymerase as the target for BglG binding. The region that contains the binding site for BglG was mapped to the N-terminal region of beta'. The beta' subunit, produced in excess, prevented BglG activity as a transcriptional antiterminator. Possible roles of the interaction between BglG and the polymerase beta' subunit are discussed.

Mutations in and monoclonal antibody binding to evolutionary hypervariable region of Escherichia coli RNA polymerase beta' subunit inhibit transcript cleavage and transcript elongation

A 190 amino acid-long region centered around position 1050 of the 1407-amino acid-long beta' subunit of Escherichia coli RNA polymerase (RNAP) is absent from homologues in eukaryotes, archaea and many bacteria. In chloroplasts, the corresponding region can be more than 900 amino acids long. The role of this hypervariable region was studied by deletion mutagenesis of the cloned E. coli rpoC, encoding beta'. Long deletions mimicking beta' from Gram-positive bacteria failed to assemble into RNAP. Mutants with short, 40-60-amino acid-long deletions spanning beta' residues 941-1130 assembled into active RNAP in vitro. These mutant enzymes were defective in the transcript cleavage reaction and had dramatically reduced transcription elongation rates at subsaturating substrate concentrations due to prolonged pausing at sites of transcriptional arrest. Binding of a monoclonal antibody, Pyn1, to the hypervariable region inhibited transcription elongation and intrinsic transcript cleavage and, to a lesser degree, GreB-induced transcript cleavage, but did not interfere with GreB binding to RNAP. We propose that mutations in and antibody binding to the hypervariable, functionally dispensable region of beta' inhibit transcript cleavage and elongation by distorting the flanking conserved segment G in the active center.

Stimulation of transcription by mutations affecting conserved regions of RNA polymerase II

Mutations that increase the low-level transcription of the Saccharomyces cerevisiae HIS4 gene, which results from deletion of the genes encoding transcription factors BAS1, BAS2, and GCN4, were isolated previously in SIT1 (also known as RPO21, RPB1, and SUA8), the gene encoding the largest subunit of RNA polymerase II (RNAPII). Here we show that sit1 substitutions cluster in two conserved regions of the enzyme which form part of the active site. Six sit1 mutations, affect region F, a region that is involved in transcriptional elongation and in resistance to alpha-aminatin. Four sit1 substitutions lie in another region involved in transcriptional elongation, region D, which binds Mg2+ ions essential for RNA catalysis. One region D substitution is lethal unless suppressed by a substitution in region G and interacts genetically with PPR2, the gene encoding transcription elongation factor IIS. Some sit1 substitutions affect the selection of transcriptional start sites at the CYC1 promoter in a manner reminiscent of that of sua8 (sua stands for suppression of upstream ATG) mutations. Together with previous findings which indicate that regions D and G are in close proximity to the 3' end of the nascent transcript and that region F is involved in the translocation process, our results suggest that transcriptional activation by the sit1 mutations results from alteration of the RNAPII active center.

The largest subunit of human RNA polymerase III is closely related to the largest subunit of yeast and trypanosome RNA polymerase III

In both yeast and mammalian systems, considerable progress has been made toward the characterization of the transcription factors required for transcription by RNA polymerase III. However, whereas in yeast all of the RNA polymerase III subunits have been cloned, relatively little is known about the enzyme itself in higher eukaryotes. For example, no higher eukaryotic sequence corresponding to the largest RNA polymerase III subunit is available. Here we describe the isolation of cDNAs that encode the largest subunit of human RNA polymerase III, as suggested by the observations that (1) antibodies directed against the cloned protein immunoprecipitate an active enzyme whose sensitivity to different concentrations of alpha-amanitin is that expected for human RNA polymerase III; and (2) depletion of transcription extracts with the same antibodies results in inhibition of transcription from an RNA polymerase III, but not from an RNA polymerase II, promoter. Sequence comparisons reveal that regions conserved in the RNA polymerase I, II, and III largest subunits characterized so far are also conserved in the human RNA polymerase III sequence, and thus probably perform similar functions for the human RNA polymerase III enzyme.

Modular organization of the catalytic center of RNA polymerase

The Fe2+ ion that specifically replaces Mg2+ in the active center of RNA polymerase generates reactive hydroxyl radicals that cause highly localized cleavage of polypeptide chains. Mapping of the cleavage sites revealed the overall architecture of the active center. Nine distinct sites, five in the beta subunit and four in the beta' subunit of Escherichia coli RNA polymerase, all at or near highly conserved sequence motifs, are brought together in the enzyme's ternary structure within the distance of approximately 1 nm from the active center Me2+. These sites are located in at least six different domains of the subunits, reflecting modular organization of the active center.

Domain organization of Escherichia coli transcript cleavage factors GreA and GreB

The GreA and GreB proteins of Escherichia coli induce cleavage of the nascent transcript in ternary elongation complexes of RNA polymerase. Gre factors are presumed to have two biologically important and evolutionarily conserved functions: the suppression of elongation arrest and the enhancement of transcription fidelity. A three-dimensional structure of GreB was generated by homology modeling on the basis of the known crystal structure of GreA. Both factors display similar overall architecture and surface charge distribution, with characteristic C-terminal globular and N-terminal coiled-coil domains. One major difference between the two factors is the "basic patch" on the surface of the coiled-coil domain, which is much larger in GreB than in GreA. In both proteins, a site near the basic patch cross-links to the 3' terminus of RNA in the ternary transcription complex. GreA/GreB hybrid molecules were constructed by genetic engineering in which the N-terminal domain of one protein was fused to the C-terminal domain of the other. In the hybrid molecules, both the coiled-coil and the globular domains contribute to specific binding of Gre factors to RNA polymerase, whereas the antiarrest activity and the GreA or GreB specificity of transcript cleavage is determined by the N-terminal domain. These results implicate the basic patch of the N-terminal coiled-coil domain as an important functional element responsible for the interactions with nascent transcript and determining the size of the RNA fragment to be excised during the course of the cleavage reaction.

Structural modules of the large subunits of RNA polymerase. Introducing archaebacterial and chloroplast split sites in the beta and beta' subunits of Escherichia coli RNA polymerase

The beta and beta' subunits of Escherichia coli DNA-dependent RNA polymerase are highly conserved throughout eubacterial and eukaryotic kingdoms. However, in some archaebacteria and chloroplasts, the corresponding sequences are "split" into smaller polypeptides that are encoded by separate genes. To test if such split sites can be accommodated into E. coli RNA polymerase, subunit fragments encoded by the segments of E. coli rpoB and rpoC genes corresponding to archaebacterial and chloroplast split subunits were individually overexpressed. The purified fragments, when mixed in vitro with complementing intact RNA polymerase subunits, yielded an active enzyme capable of catalyzing the phosphodiester bond formation. Thus, the large subunits of eubacteria and eukaryotes are composed of independent structural modules corresponding to the smaller subunits of archaebacteria and chloroplasts.

Localization of nusA-suppressing amino acid substitutions in the conserved regions of the beta' subunit of Escherichia coli RNA polymerase

Escherichia coli RNA polymerase is composed of four different subunits, alpha (present in two copies), beta, beta' and sigma. Among these, the beta' polypeptide shares nine conserved regions with the largest subunits of eukaryotic RNA polymerases, but its role is poorly understood. We isolated novel mutations in a plasmid-borne copy of rpoC, which encodes beta', as dominant suppressors of two temperature-sensitive nusA alleles. All 20 suppressors of nusA11 (single missense mutation) isolated had either of two specific substitutions: Lys for Glu-402 (rpoC10) and Thr for Ala-904 (rpoC111) in the beta' subunit. In vivo and in vitro transcription assays revealed that the rpoC10 allele of beta' participates in Rho-dependent transcription termination. On the other hand, of 20 suppressors of nusA134 (deletion of C-terminal one-third) scattered at 18 distinct sites, 16 were assigned to one of six conserved regions C-I. These results suggested that the conserved domains of the beta' subunit of E. coli RNA polymerase are involved in transcript termination or interaction with termination factor(s).

Mapping of catalytic residues in the RNA polymerase active center

When the Mg2+ ion in the catalytic center of Escherichia coli RNA polymerase (RNAP) is replaced with Fe2+, hydroxyl radicals are generated. In the promoter complex, such radicals cleave template DNA near the transcription start site, whereas the beta' subunit is cleaved at a conserved motif NADFDGD (Asn-Ala-Asp-Phe-Asp-Gly-Asp). Substitution of the three aspartate residues with alanine creates a dominant lethal mutation. The mutant RNAP is catalytically inactive but can bind promoters and form an open complex. The mutant fails to support Fe2+-induced cleavage of DNA or protein. Thus, the NAD-FDGD motif is involved in chelation of the active center Mg2+.

Amino acid substitutions in the two largest subunits of Escherichia coli RNA polymerase that suppress a defective Rho termination factor affect different parts of the transcription complex

Among the earliest rpoBC mutations identified are three suppressors of the conditional lethal rho allele, rho201. These three mutations are of particular interest because, unlike rpoB8, they do not increase termination at all rho-dependent and rho-independent terminators. rpoB211 and rpoB212 both change Asn-1072 to His in conserved region H of rpoB (betaN1072H), whereas rpoC214 changes Arg-352 to Cys in conserved region C of rpoC (beta'R352C). Both substitutions significantly reduce the overall rate of transcript elongation in vitro relative to wild-type RNA polymerase; however, they probably slow elongation for different reasons. The nucleotide triphosphate concentrations required at the T7 A1 promoter for both abortive trinucleotide synthesis and for promoter escape are much greater for betaN1072H. In contrast, beta'R352C and two adjacent substitutions (beta'G351S and beta'S350F), but not betaN1072H, formed open complexes of greatly reduced stability. The sequence in this region of beta' modestly resembles a region of Escherichia coli DNA polymerase I that contacts the phosphate backbone of DNA in co-crystals. Core determinants affecting open complex formation do not reside exclusively in beta', however, since the Rifr mutation rpoB2 in beta also dramatically destabilized open complexes. We suggest that the principal defects of the two Rho-suppressing substitutions may differ, perhaps reflecting a greater role of beta region H in nucleoside triphosphate-binding and nucleotide addition and of beta' region C in contacts to the DNA strands that could be important for translocation. Although both probably suppress rho201 by slowing RNA chain elongation, these differences may lead to terminator specificity that depends on the rate-limiting step at different sites.

Streptolydigin-resistant mutants in an evolutionarily conserved region of the beta' subunit of Escherichia coli RNA polymerase

Mutations conferring streptolydigin resistance onto Escherichia coli RNA polymerase have been found exclusively in the beta subunit (Heisler, L. M., Suzuki, H., Landick, R., and Gross, C. A. (1993) J. Biol. Chem. 268, 25369-25375). We report here the isolation of a streptolydigin-resistant mutation in the E. coli rpoC gene, encoding the beta' subunit. The mutation is the Phe793-->Ser substitution, which occurred in an evolutionarily conserved segment of the beta' subunit. The homologous segment in the eukaryotic RNA polymerase II largest subunit harbors mutations conferring alpha-amanitin resistance. Both streptolydigin and alpha-amanitin are inhibitors of transcription elongation. Thus, the two antibiotics may inhibit transcription in their respective systems by a similar mechanism, despite their very different chemical nature.

Evolution of viral DNA-dependent RNA polymerases

The DNA-dependent RNA polymerase (DdRP or RNAP) is an essential enzyme of transcription of replicating systems of prokaryotic and eukaryotic organisms as well as cytoplasmic DNA viruses. DdRPs are complex multisubunit enzymes consisting of 8-14 subunits, including two large subunits and several smaller polypeptides (small subunits). An extensive search between the amino acid sequences of the known largest subunit of DNA-dependent RNA polymerases (RPO1) of different organisms indicates that all these polypeptides possess a universal heptapeptide NADFDGD in domain D. All RPO1 harbor a second well-conserved hexapeptide RQP(TS)LH upstream (26-31 amino acids) of the universal motif. The genes encoding the largest subunit of DdRP of insect iridescent virus type 6 (IIV6), fish lymphocystis disease virus (LCDV), and molluscum contagiosum virus (MCV-1), all members of the group of cytoplasmic DNA viruses, were identified by PCR technology. With the exception of IIV6, all other viral RPO1 possess the two C-terminal conserved regions G and H. The lack of C-terminal repetitive heptapeptide (YSPTSPS), which is a common feature of the largest subunit of eukaryotic RNAPII, is an additional characteristic of RPO1 proteins of LCDV and of MCV-1. All viral RPO1 proteins were found to be lacking the amino acid N at a distinct position in domain F. This amino acid is known to be highly conserved in alpha-amanitin-sensitive eukaryotic RNA polymerases II. Comparison of the amino acid sequences of the RPO1 polypeptides of IIV6, LCDV, and MCV-1 with the corresponding prokaryotic, eukaryotic, and viral proteins revealed differences in amino acid similarity and phylogenetic relationships. IIV6 RPO1 possesses the closest similarity to the homologous subunit of eukaryotic RNAPII and lower but also significant similarity to that of eukaryotic RNAPI and RNAPIII, archaeal, eubacterial, and viral polymerases. The similarity between RPO1 of IIV6 and the cellular polymerase subunits is consistently higher than to the RPO1 of other cytoplasmic DNA viruses, for example, vaccinia and variola virus, African swine fever virus (ASFV), and MCV-1. The RPO1 of LCDV shows the highest similarity to the RPO1 of IIV6 and significant lower similarity to the eukaryotic polymerases II and III as well as to the archaebacteral subunit. However, it is still considerably more similar to the cellular polymerase subunits than to the homologous viral proteins. The RPO1 of IIV6 possesses more similarity to cellular polymerases than the complete RPO1 of LCDV, indicating that there is a substantial difference in the organization of the RPO1 genes between these members of two genera of the Iridoviridae family. Analysis of the MCV-1 RPO1 revealed high amino acid homologies to the corresponding polypeptides of vaccinia and variola virus. The viral RPO1 proteins, including vaccinia and variola virus, MCV-1, ASFV, IIV6, and LCDV, share the common feature of showing the highest similarity to the largest subunit of eukaryotic RNAPII than to that of RNAPI, RNAPIII, and RPO1 of archaebacterias, eubacterias, ASFV, IIV6, and LCDV. Evolution of the individual largest subunit of DdRPs was tentatively investigated by generating phylogenetic trees using multiple amino acid alignments. These indicate that the RPO1 proteins of IIV6 and LCDV might have evolved from the largest subunit of eukaryotic RNAPII after divergence from the homologous subunits of RNAPI and RNAPIII. In contrast, evolutionary development of the RPO1 of vaccinia and variola virus, MCV-1, and ASFV seems to be quite different, with their common ancestor diverging from cellular homologues before the separation of the three types of eukaryotic ploymerases and having probably diverged earlier from their common lineage with cellular proteins.

Crystal structure of the GreA transcript cleavage factor from Escherichia coli

Transcription elongation factors stimulate the activity of DNA-dependent RNA polymerases by increasing the overall elongation rate and the completion of RNA chains. One group of such factors, which includes Escherichia coli GreA, GreB and eukaryotic SII (TFIIS), acts by inducing hydrolytic cleavage of the transcript within the RNA polymerase, followed by release of the 3'-terminal fragment. Here we report the crystal structure of GreA at 2.2 A resolution. The structure contains an amino-terminal domain consisting of an antiparallel alpha-helical coiled-coil dimer which extends into solution, reminiscent of the coiled coil in seryl-tRNA synthetases. A site near the tip of the coiled-coil 'finger' plays a direct role in the transcript cleavage reaction by contacting the 3'-end of the transcript. The structure exhibits an unusual asymmetric charge distribution which indicates the manner in which GreA interacts with the RNA polymerase elongation complex.

Termination-altering amino acid substitutions in the beta' subunit of Escherichia coli RNA polymerase identify regions involved in RNA chain elongation

To identify regions of the largest subunit of RNA polymerase that are potentially involved in transcript elongation and termination, we have characterized amino acid substitutions in the beta' subunit of Escherichia coli RNA polymerase that alter expression of reporter genes preceded by terminators in vivo. Termination-altering substitutions occurred in discrete segments of beta', designated 2, 3a, 3b, 4a, 4b, 4c, and 5, many of which are highly conserved in eukaryotic homologs of beta'. Region 2 substitutions (residues 311-386) are tightly clustered around a short sequence that is similar to a portion of the DNA-binding cleft in E. coli DNA polymerase I. Region 3b (residues 718-798) corresponds to the segment of the largest subunit of RNA polymerase II in which amanitin-resistance substitutions occur. Region 4a substitutions (residues 933-936) occur in a segment thought to contact the transcript 3' end. Region 5 substitutions (residues 1308-1356) are tightly clustered in conserved region H near the carboxyl terminus of beta'. A representative set of mutant RNA polymerases were purified and revealed unexpected variation in percent termination at six different rho-independent terminators. Based on the location and properties of these substitutions, we suggest a hypothesis for the relationship of subunits in the transcription complex.

Histidine-tagged RNA polymerase: dissection of the transcription cycle using immobilized enzyme

A stretch of six histidine residues (His6) has been genetically fused to the C terminus of the beta' polypeptide of Escherichia coli RNA polymerase. The His6-tagged beta' subunit assembles into RNA polymerase molecules which perform all vital in vivo functions and behave qualitatively normally in vitro. The His6 tag permits rapid purification of the enzyme directly from crude cell extracts or from an in vitro reconstitution reaction by adsorption to Ni(2+)-chelating agarose resin, followed by elution with imidazole. The enzyme bound to the matrix remains transcriptionally active. The immobilized enzyme can withstand repeated buffer changes without substantial activity loss and permits controlled stepwise 'walking' of the transcriptional complex along the DNA template, and isolation of defined intermediates in the transcription cycle. The immobilized RNA polymerase provides a powerful experimental system for structural and functional analysis of RNA polymerase and its interaction with regulatory factors.