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

The interaction between sigma70 and the beta-flap of Escherichia coli RNA polymerase inhibits extension of nascent RNA during early elongation

The sigma-subunit of bacterial RNA polymerase (RNAP) is required for promoter-specific transcription initiation. This function depends on specific intersubunit interactions that occur when sigma associates with the RNAP core enzyme to form RNAP holoenzyme. Among these interactions, that between conserved region 4 of sigma and the flap domain of the RNAP beta-subunit (beta-flap) is critical for recognition of the major class of bacterial promoters. Here, we describe the isolation of amino acid substitutions in region 4 of Escherichia coli sigma(70) that have specific effects on the sigma(70) region 4/beta-flap interaction, either weakening or strengthening it. Using these sigma(70) mutants, we demonstrate that the sigma region 4/beta-flap interaction also can affect events occurring downstream of transcription initiation during early elongation. Specifically, our results provide support for a structure-based proposal that, when bound to the beta-flap, sigma region 4 presents a barrier to the extension of the nascent RNA as it emerges from the RNA exit channel. Our findings support the view that the transition from initiation to elongation involves a staged disruption of sigma-core interactions.

A ratchet mechanism of transcription elongation and its control

RNA chain elongation is a highly processive and accurate process that is finely regulated by numerous intrinsic and extrinsic signals. Here we describe a general mechanism that governs RNA polymerase (RNAP) movement and response to regulatory inputs such as pauses, terminators, and elongation factors. We show that E.coli RNAP moves by a complex Brownian ratchet mechanism, which acts prior to phosphodiester bond formation. The incoming substrate and the flexible F bridge domain of the catalytic center serve as two separate ratchet devices that function in concert to drive forward translocation. The adjacent G loop domain controls F bridge motion, thus keeping the proper balance between productive and inactive states of the elongation complex. This balance is critical for cell viability since it determines the rate, processivity, and fidelity of transcription.

A ribonucleolytic rat torpedoes RNA polymerase II

Three recent papers reveal a fascinating link between pol II termination and ribonucleolytic decay of the nascent transcript by a 5'-3' exonuclease (yeast Rat1 and human Xrn2). The exonuclease travels with pol II and gains access to the nascent RNA after endonucleolytic cleavage at the poly(A) site or at a second cotranscriptional cleavage site (CoTC). It is then thought to track in a 5'-3' direction like a guided torpedo that ultimately helps dissociate the RNA polymerase elongation complex.

Altering the interaction between sigma70 and RNA polymerase generates complexes with distinct transcription-elongation properties

We compare the elongation behavior of native Escherichia coli RNA polymerase holoenzyme assembled in vivo, holoenzyme reconstituted from sigma70 and RNA polymerase in vitro, and holoenzyme with a specific alteration in the interface between sigma70 and RNA polymerase. Elongating RNA polymerase from each holoenzyme has distinguishable properties, some of which cannot be explained by differential retention or rebinding of sigma70 during elongation, or by differential presence of elongation factors. We suggest that interactions between RNA polymerase and sigma70 may influence the ensemble of conformational states adopted by RNA polymerase during initiation. These states, in turn, may affect the conformational states adopted by the elongating enzyme, thereby physically and functionally imprinting RNA polymerase.

The bacteriophage T4 late-transcription coactivator gp33 binds the flap domain of Escherichia coli RNA polymerase

Transcription of bacteriophage T4 late genes requires concomitant DNA replication. T4 late promoters, which consist of a single 8-bp -10 motif, are recognized by a holoenzyme containing Escherichia coli RNA polymerase core and the T4-encoded promoter specificity subunit, gp55. Initiation of transcription at these promoters by gp55-holoenzyme is inefficient, but is greatly activated by the DNA-loaded DNA polymerase sliding clamp, gp45, and the coactivator, gp33. We report that gp33 attaches to the flap domain of the Escherichia coli RNA polymerase beta-subunit and that this interaction is essential for activation. The beta-flap also mediates recognition of -35 promoter motifs by binding to sigma(70) domain 4. The results suggest that gp33 is an analogue of sigma(70) domain 4 and that gp55 and gp33 together constitute two parts of the T4 late sigma. We propose a model for the role of the gp45 sliding clamp in activation of T4 late-gene transcription.

A Hydrophobic Patch on the Flap-tip Helix of E.coli RNA Polymerase Mediates σ70 Region 4 Function

The Escherichia coli RNA polymerase beta subunit contains a flexible flap domain that interacts with region 4 of sigma(70) to position it for recognition of the -35 element of promoters. We report that this function depends on a hydrophobic patch on one face of the short stretch of alpha helix located at the tip of the flap domain, called the flap-tip helix. Disruption of the hydrophobic patch by the substitution of hydrophilic or charged amino acids resulted in a loss of the interaction between the flap and sigma region 4, as determined by protease sensitivity assays, and impaired transcription from -35-dependent promoters. We suggest that contact of the flap-tip helix hydrophobic patch to the sigma region 4 hydrophobic core is essential for stable interaction of the flap-tip helix with region 4. This contact allowed region 4.2 recognition of the -35 promoter element and appeared to stabilize region 4 interaction with the beta' Zn(2+) binding domain. Our studies failed to detect any role for sigma region 1.1 in establishing or maintaining the flap-sigma region 4 interaction, consistent with recent reports placing sigma region 1.1 in the downstream DNA channel.

Downstream DNA selectively affects a paused conformation of human RNA polymerase II

Transcriptional pausing by human RNA polymerase II (RNAPII) in the HIV-1 LTR is caused principally by a weak RNA:DNA hybrid that allows rearrangement of reactive or catalytic groups in the enzyme's active site. This rearrangement creates a transiently paused state called the unactivated intermediate that can backtrack into a more long-lived paused species. We report that three different regions of the not-yet-transcribed DNA just downstream of the pause site affect the duration of the HIV-1 pause, and also can influence pause formation. Downstream DNA in at least one region, a T-tract from +5 to +8, increases pause duration by specifically affecting the unactivated intermediate, without corresponding effects on the active or backtracked states. We suggest this effect depends on RNAPII-modulated DNA plasticity and speculate it is mediated by the "trigger loop" thought to participate in RNAP's catalytic cycle. These findings provide a new framework for understanding downstream DNA effects on RNAP.

Forward translocation is the natural pathway of RNA release at an intrinsic terminator

Intrinsic terminators of bacterial RNA polymerase are small (< approximately 30 bp) sequences containing a dyad symmetry that encodes a hairpin in the RNA, followed immediately by a uridine-rich stretch of 5-9 nucleotides just before the site of RNA release. Formation of the RNA hairpin destabilizes the elongation complex, leading to transcript release. We test a model in which hair-pin formation drives RNA polymerase and the melted DNA bubble downstream without transcript elongation, thus releasing the transcript from its enclosure within the enzyme as an RNA/DNA hybrid. We show that blocking downstream translocation of RNAP and preventing downstream DNA unwinding both inhibit transcript release. We argue that translocation of RNA polymerase is essential and that translocation of the bubble stimulates, but is not required, for RNA release; we conclude that forward translocation is the natural pathway of RNA release at an intrinsic terminator.

HPMA Copolymer-Bound Doxorubicin Induces Apoptosis in Human Ovarian Carcinoma Cells by a Fas-Independent Pathway

The mechanism of cell death in A2780 human ovarian carcinoma cells induced by free doxorubicin (DOX) and N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer-bound DOX [P-(GFLG)-DOX] was investigated. In particular, the involvement of the Fas receptor system in drug-induced apoptosis was evaluated. P-(GFLG)-DOX was shown to effect apoptosis-induced tumor cell death as manifested by positive Annexin V-FITC staining, cleavage of procaspase 3 and its physiological substrate, poly(ADP-ribose) polymerase (PARP), and cleavage of procaspase 8. Using the fluorochrome-labeled caspase inhibitor assay, it was found that both free DOX and P-(GFLG)-DOX activated caspases 3 and 9, but both forms of DOX did not have an effect on the activity of caspase 8, when compared to untreated cells. It was shown that free DOX and P-(GFLG)-DOX upregulated Fas receptor expression at the cell membrane in a time-dependent manner. Triggering the drug-induced Fas receptor with an exogeneous soluble Fas ligand (sFasL) resulted in an increase in the extent of apoptotic cell death, indicating that the Fas signaling pathway remained functionally active. Also, antagonistic anti-Fas ZB4 antibody blocked the increase in the level of apoptosis following the application of sFasL, but did not interfere with drug-induced apoptosis. The study of the functional activity of the Fas receptor and of the activation of the most proximal effector of the caspase cascade, caspase 8, indicated that the Fas receptor pathway was not decisive in the induction of cell death by free DOX and P-(GFLG)-DOX in A2780 cells. This study suggests further investigation of the involvement of the mitochondrial pathway in A2780 cell apoptotic death, induced by free and HPMA copolymer-bound DOX.

A function of yeast mRNA cap methyltransferase, Abd1, in transcription by RNA polymerase II

Capping enzymes bind the phosphorylated pol II CTD permitting cotranscriptional capping of nascent pre-mRNAs. We asked whether these interactions influence pol II function using ChIP in ts mutants of yeast capping enzymes. Pol II occupancy at the 5' ends of PGK1, ENO2, GAL1, and GAL10 was reduced by inactivation of the methyltransferase, Abd1, but not the guanylyltransferase, Ceg1, suggesting that Abd1 contributes to stable promoter binding. At other genes, Abd1 inactivation increased the 5':3' ratio of pol II density in the promoter-proximal region and caused Ser5 hyperphosphorylation of the pol II CTD. These results suggest an additional role for Abd1 in the promoter clearance and/or promoter-proximal elongation steps of transcription. The transcriptional functions of Abd1 are independent of methyltransferase activity. Manipulation of transcription by Abd1 may enhance cotranscriptional capping and also act as a checkpoint to ensure that a nascent transcript has a cap before it can be completed.

Ubiquitous transcriptional pausing is independent of RNA polymerase backtracking

RNA polymerase (RNAP) transcribes DNA discontinuously, with periods of rapid nucleotide addition punctuated by frequent pauses. We investigated the mechanism of transcription by measuring the effect of both hindering and assisting forces on the translocation of single Escherichia coli transcription elongation complexes, using an optical trapping apparatus that allows for the detection of pauses as short as one second. We found that the vast majority of pauses are brief (1-6 s at 21 degrees C, 1 mM NTPs), and that the probability of pausing at any particular position on a DNA template is low and fairly constant. Neither the probability nor the duration of these ubiquitous pauses was affected by hindering or assisting loads, establishing that they do not result from the backtracking of RNAP along the DNA template. We propose instead that they are caused by a structural rearrangement within the enzyme.

Mechanisms of cancer chemoprevention by hop bitter acids (beer aroma) through induction of apoptosis mediated by Fas and caspase cascades

The bitter acids of hops (Humulus lupulus L.) mainly consist of alpha-acids, beta-acids, and their oxidation products that contribute the unique aroma of the beer beverage. Hop bitter acids displayed a strong growth inhibitory effect against human leukemia HL-60 cells, with an estimated IC(50) value of 8.67 microg/mL, but were less effective against human histolytic lymphoma U937 cells. Induction of apoptosis was confirmed in HL-60 cells by DNA fragmentation and the appearance of a sub-G1 DNA peak, which were preceded by dissipation of mitochondrial membrane potential, cytochrome c release, and subsequent induction of pro-caspase-9 and -3 processing. Cleavages of PARP and DFF-45 were accompanied with activation of caspase-9 and -3 triggered by hop bitter acids in HL-60 cells. The change in the expression of Bcl-2, Bcl-X(L), and Bax in response to hop bitter acids was studied, and the Bcl-2 protein level slightly decreased; however, the Bcl-X(L) protein level was obviously decreased, whereas the Bax protein level was dramatically increased, indicating that the control of Bcl-2 family proteins by hop bitter acids might participate in the disruption of mitochondrial integrity. In addition, the results showed that hop bitter acids promoted the up-regulation of Fas and FasL prior to the processing and activation of pro-caspase-8 and cleavage of Bid, suggesting the involvement of a Fas-mediated pathway in hop bitter acids-induced cells. Taken together, these findings suggest that a certain intimate link might exist between receptor- and mitochondria-mediated death signalings that committed to cell death induced by hop bitter acids. The induction of apoptosis by hop bitter acids may offer a pivotal mechanism for their chemopreventive action.

The flap domain is required for pause RNA hairpin inhibition of catalysis by RNA polymerase and can modulate intrinsic termination

Bacterial RNA polymerase (RNAP) responds to formation of RNA secondary structures (hairpins) in newly synthesized RNA. Depending on the spacing of the hairpin from the RNA 3' end and the intervening RNA sequence, the hairpin can prolong pausing or cause transcriptional termination. At the his pause site, the pause hairpin contacts a flexible domain on RNAP called the flap, which forms a critical part of a hairpin-interaction site on the enzyme. We report that pause hairpin-flap interaction stabilizes an inhibited configuration of RNAP's active site without changing RNAP's translocation register. The distal part of the flap (the flap tip) is required for the hairpin to affect the active site, but not for hairpin formation. In contrast, the flap tip is not required for intrinsic termination, but can modulate it at suboptimal termination signals.

Role of the non-template strand of the elongation bubble in intrinsic transcription termination

Intrinsic transcription terminators of Escherichia coli and other bacteria, consisting primarily of an RNA hairpin preceding a terminal uridine-rich RNA segment, suffice to dissociate the otherwise stable elongation complex of core RNA polymerase. The essential functions of the hairpin and U-rich segments have been established, although the precise mechanism of termination is unknown. We identify another element of the terminator, namely the non-template DNA strand in the region of the terminal transcription bubble. Failure of the terminal bubble to rewind through complementary base-pairing strongly reduces the efficiency of terminator function, suggesting that the natural pathway of termination consists of coupled rewinding of the DNA template and unwinding of the RNA/DNA hybrid at the site of release.

Diversity in the rates of transcript elongation by single RNA polymerase molecules

Single-molecule measurements of the activities of a variety of enzymes show that rates of catalysis may vary markedly between different molecules in putatively homogeneous enzyme preparations. We measured the rate at which purified Escherichia coli RNA polymerase moves along a approximately 2650-bp DNA during transcript elongation in vitro at 0.5 mm nucleoside triphosphates. Individual molecules of a specifically biotinated RNA polymerase derivative were tagged with 199-nm diameter avidin-coated polystyrene beads; enzyme movement along a surface-linked DNA molecule was monitored by observing changes in bead Brownian motion by light microscopy. The DNA was derived from a naturally occurring transcription unit and was selected for the absence of regulatory sequences that induce lengthy pausing or termination of transcription. With rare exceptions, individual enzyme molecules moved at a constant velocity throughout the transcription reaction; the distribution of velocities across a population of 140 molecules was unimodal and was well fit by a Gaussian. However, the width of the Gaussian, sigma = 6.7 bp/s, was considerably larger than the precision of the velocity measurement (1 bp/s). The observations show that different transcription complexes have differences in catalytic rate (and thus differences in structure) that persist for thousands of catalytic turnovers. These differences may provide a parsimonious explanation for the complex transcription kinetics observed in bulk solution.

Context and conformation dictate function of a transcription antitermination switch

In bacteriophage l, transcription elongation is regulated by the N protein, which binds a nascent mRNA hairpin (termed boxB) and enables RNA polymerase to read through distal terminators. We have examined the structure, energetics and in vivo function of a number of N-boxB complexes derived from in vitro protein selection. Trp18 fully stacks on the RNA loop in the wild-type structure, and can become partially or completely unstacked when the sequence context is changed three or four residues away, resulting in a recognition interface in which the best binding residues depend on the sequence context. Notably, in vivo antitermination activity correlates with the presence of a stacked aromatic residue at position 18, but not with N-boxB binding affinity. Our work demonstrates that RNA polymerase responds to subtle conformational changes in cis-acting regulatory complexes and that approximation of components is not sufficient to generate a fully functional transcription switch.

RNA-structural mimicry in Escherichia coli ribosomal protein L4-dependent regulation of the S10 operon

Ribosomal protein L4 regulates the 11-gene S10 operon in Escherichia coli by acting, in concert with transcription factor NusA, to cause premature transcription termination at a Rho-independent termination site in the leader sequence. This process presumably involves L4 interaction with the leader mRNA. Here, we report direct, specific, and independent binding of ribosomal protein L4 to the S10 mRNA leader in vitro. Most of the binding energy is contributed by a small hairpin structure within the leader region, but a 64-nucleotide sequence is required for the bona fide interaction. Binding to the S10 leader mRNA is competed by the 23 S rRNA L4 binding site. Although the secondary structures of the mRNA and rRNA binding sites appear different, phosphorothioate footprinting of the L4-RNA complexes reveals close structural similarity in three dimensions. Mutational analysis of the mRNA binding site is compatible with the structural model. In vitro binding of L4 induces structural changes of the S10 leader RNA, providing a first clue for how protein L4 may provoke transcription termination.

The functional anatomy of an intrinsic transcription terminator

To induce dissociation of the transcription elongation complex, a typical intrinsic terminator forms a G.C-rich hairpin structure upstream from a U-rich run of approximately eight nucleotides that define the transcript 3' end. Here, we have adapted the nucleotide analog interference mapping (NAIM) approach to identify the critical RNA atoms and functional groups of an intrinsic terminator during transcription with T7 RNA polymerase. The results show that discrete components within the lower half of the hairpin stem form transient termination-specific contacts with the RNA polymerase. Moreover, disruption of interactions with backbone components of the transcript region hybridized to the DNA template favors termination. Importantly, comparative NAIM of termination events occurring at consecutive positions revealed overlapping but distinct sets of functionally important residues. Altogether, the data identify a collection of RNA terminator components, interactions and spacing constraints that govern efficient transcript release. The results also suggest specific architectural rearrangements of the transcription complex that may participate in allosteric control of intrinsic transcription termination.

Structural mimicry in the phage phi21 N peptide-boxB RNA complex

We determined the solution structure of a 22-amino-acid peptide from the amino-terminal domain of the bacteriophage phi21 N protein in complex with its cognate 24-mer boxB RNA hairpin using heteronuclear magnetic resonance spectroscopy. The N peptide binds as an alpha-helix and interacts predominately with the major groove side of the 5' half of the boxB RNA stem-loop. This binding interface is defined by surface complementarity of polar and nonpolar interactions, and little sequence-specific recognition. The phi21 boxB loop (CUAACC) has hydrogen bond and backbone torsions typical of the "U-turn" motif, as well as base stacking of the last 4 nt, and a hydrogen bonded C:C pair closing the loop. The exposed face of the phi21 boxB loop, in complex with the N peptide, is strikingly similar to the GNRA tetraloop-like folds of the related lambda and P22 bacteriophage N peptide-boxB RNA complexes. The N peptide-boxB complexes of the various phage, while individually distinct, provide similar structural features for interactions with the Escherichia coli host factors to enable antitermination.

RNA polymerase mutations that impair conversion to a termination-resistant complex by Q antiterminator proteins

Bacteriophage lambda Q-protein stably binds and modifies RNA polymerase (RNAP) to a termination-resistant form. We describe amino acid substitutions in RNAP that disrupt Q-mediated antitermination in vivo and in vitro. The positions of these substitutions in the modeled RNAP/DNA/RNA ternary elongation complex, and their biochemical properties, suggest that they do not define a binding site for Q in RNAP, but instead act by impairing interactions among core RNAP subunits and nucleic acids that are essential for Q modification. A specific conjecture is that Q modification stabilizes interactions of RNAP with the DNA/RNA hybrid and optimizes alignment of the nucleic acids in the catalytic site. Such changes would inhibit the activity of the RNA hairpin of an intrinsic terminator to disrupt the 5'-terminal bases of the hybrid and remove the RNA 3' terminus from the active site.

Co-overexpression of Escherichia coli RNA polymerase subunits allows isolation and analysis of mutant enzymes lacking lineage-specific sequence insertions

The study of mutant enzymes can reveal important details about the fundamental mechanism and regulation of RNA polymerase, the central enzyme of gene expression. However, such studies are complicated by the multisubunit structure of RNA polymerase and by its indispensability for cell growth. Previously, mutant RNA polymerases have been produced by in vitro assembly from isolated subunits or by in vivo assembly upon overexpression of a single mutant subunit. Both approaches can fail if the mutant subunit is toxic or incorrectly folded. Here we describe an alternative strategy, co-overexpression and in vivo assembly of RNA polymerase subunits, and apply this method to characterize the role of sequence insertions present in the Escherichia coli enzyme. We find that co-overexpression of its subunits allows assembly of an RNA polymerase lacking a 188-amino acid insertion in the beta' subunit. Based on experiments with this and other mutant E. coli enzymes with precisely excised sequence insertions, we report that the beta' sequence insertion and, to a lesser extent, an N-terminal beta sequence insertion confer characteristic stability to the open initiation complex, frequency of abortive initiation, and pausing during transcript elongation relative to RNA polymerases, such as that from Bacillus subtilis, that lack the sequence insertions.

Shortening of RNA:DNA hybrid in the elongation complex of RNA polymerase is a prerequisite for transcription termination

Passage of E. coli RNA polymerase through an intrinsic transcription terminator, which encodes an RNA hairpin followed by a stretch of uridine residues, results in quick dissociation of the elongation complex. We show that folding of the hairpin disrupts the three upstream base pairs of the 8 bp RNA:DNA hybrid, a major stability determinant in the complex. Shortening the weak rU:dA hybrid from 8 nt to 5 nt causes dissociation of the complex. During termination, the hairpin does not directly compete for base pairing with the 8 bp hybrid. Thus, melting of the hybrid seems to result from spatial restrictions in RNA polymerase that couple the hairpin formation with the disruption of the hybrid immediately downstream from the stem. Our results suggest that a similar mechanism disrupts elongation complexes of yeast RNA polymerase II in vitro.

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.

NusA-stimulated RNA polymerase pausing and termination participates in the Bacillus subtilis trp operon attenuation mechanism invitro

The trp RNA-binding attenuation protein (TRAP) regulates expression of the Bacillus subtilis trpEDCFBA operon by transcription attenuation and translation control mechanisms. Both mechanisms require the binding of tryptophan-activated TRAP to the 11 (G/U)AG-repeat segment in the trp leader transcript. To promote termination, TRAP must bind to the nascent RNA before the antiterminator structure forms. Because only 20 nucleotides separate the TRAP-binding site from the 3' end of the antiterminator, TRAP has a short time frame to control this regulatory decision. Synchronization of factor binding and/or RNA folding with the RNA polymerase position is a major challenge in all attenuation mechanisms. Because RNA polymerase pausing allows this synchronization in many attenuation mechanisms, we performed experiments in vitro to determine whether pausing participates in the B. subtilis trp attenuation mechanism. We identified two NusA-stimulated pause sites in the trp leader region. Formation of pause hairpins participates in pausing at both positions. The first pause occurred at the nucleotide just preceding the critical overlap between the alternative antiterminator and terminator structures. TRAP binding to transcripts containing preexisting pause complexes releases RNA polymerase, suggesting that pausing provides additional time for TRAP to bind and promote termination. The second pause is downstream from the trp leader termination point, raising the possibility that this pause event participates in the trpE translation control mechanism. NusA also increases the efficiency of termination in the trp leader region and shifts termination one nucleotide upstream. Finally, NusA-stimulated termination is cooperative, suggesting that binding of multiple NusA molecules influences termination.

Fluorescence resonance energy transfer analysis of escherichia coli RNA polymerase and polymerase-DNA complexes

Fluorescence resonance energy transfer (FRET) is a technique allowing measurements of atomic-scale distances in diluted solutions of macromolecules under native conditions. This feature makes FRET a powerful tool to study complicated biological assemblies. In this report we review the applications of FRET to studies of transcription initiation by Escherichia coli RNA polymerase. The versatility of FRET for studies of a large macromolecular assembly such as RNA polymerase is illustrated by examples of using FRET to address several different aspects of transcription initiation by polymerase. FRET has been used to determine the architecture of polymerase, its complex with single-stranded DNA, and the conformation of promoter fragment bound to polymerase. FRET has been also used as a binding assay to determine the thermodynamics of promoter DNA fragment binding to the polymerase. Functional conformational changes in the specificity subunit of polymerase responsible for the modulation of the promoter binding activity of the enzyme and the mechanistic aspects of the transition from the initiation to the elongation complex were also investigated.

Transcription termination: primary intermediates and secondary adducts

In living organisms, stable elongation complexes of RNA polymerase dissociate at specific template positions in a process of transcription termination. It has been suggested that the dissociation is not the immediate cause of termination but is preceded by catalytic inactivation of the elongation complex. In vitro reducing ionic strength can be used to stabilize very unstable and catalytically inactive complex at the point of termination; the previous biochemical characterization of this complex has led to important conclusions regarding termination mechanism. Here we analyze in detail the complexes formed between DNA template, nascent RNA, and Escherichia coli RNA polymerase during transcription through the tR2 terminator of bacteriophage lambda. At low ionic strength, the majority of elongation complexes fall apart upon reaching the terminator. Released RNA and DNA efficiently rebind RNA polymerase (RNAP) and form binary RNAP.RNA and RNAP.DNA complexes, which are indistinguishable from binary complexes obtained by direct mixing of the purified nucleic acids and the enzyme. A small fraction of elongation complexes that reach termination point escapes dissociation because RNA polymerase has backtracked from the terminator to an upstream DNA position. Thus, transcription elongation to a terminator site produces no termination intermediates that withstand dissociation in the time scale appropriate for biochemical studies.

The transcriptional regulator RfaH stimulates RNA chain synthesis after recruitment to elongation complexes by the exposed nontemplate DNA strand

The transcriptional regulatory protein RfaH controls expression of several operons that encode extracytoplasmic components in bacteria. Regulation by RfaH occurs during transcript elongation and depends on a 5'-proximal, transcribed nucleic acid sequence called ops that induces transcriptional pausing in vitro and in vivo. We report that RfaH recognizes RNA polymerase transcribing RfaH-regulated operons by interacting with the ops sequence in the exposed nontemplate DNA strand of ops-paused transcription complexes. Although RfaH delays escape from the ops pause, once escape occurs, RfaH enhances elongation by suppressing pausing and rho-dependent termination without apparent involvement of other accessory proteins. This activity predicts a cumulative antitermination model for RfaH's regulation of ops-containing operons in vivo.

A role for interaction of the RNA polymerase flap domain with the sigma subunit in promoter recognition

In bacteria, promoter recognition depends on the RNA polymerase sigma subunit, which combines with the catalytically proficient RNA polymerase core to form the holoenzyme. The major class of bacterial promoters is defined by two conserved elements (the -10 and -35 elements, which are 10 and 35 nucleotides upstream of the initiation point, respectively) that are contacted by sigma in the holoenzyme. We show that recognition of promoters of this class depends on the "flexible flap" domain of the RNA polymerase beta subunit. The flap interacts with conserved region 4 of sigma and triggers a conformational change that moves region 4 into the correct position for interaction with the -35 element. Because the flexible flap is evolutionarily conserved, this domain may facilitate promoter recognition by specificity factors in eukaryotes as well.

Multisubunit RNA polymerases

Transcription of the genetic information in all cells is carried out by multisubunit RNA polymerases (RNAPs). Comparison of the crystal structures of a bacterial and a eukaryotic RNAP reveals a conserved core that comprises the active site and a multifunctional clamp. Together with a further structure of eukaryotic RNAP bound to DNA and RNA, these results elucidate many aspects of the transcription mechanism, including initiation, elongation, nucleotide addition, processivity and proofreading.

Crystal structure of the transcription elongation/anti-termination factor NusA from Mycobacterium tuberculosis at 1.7 A resolution

Mycobacterium tuberculosis is the cause of tuberculosis in humans, a disease that affects over a one-third of the world's population. This slow-growing pathogen has only one ribosomal RNA operon, thus making its transcriptional apparatus a fundamentally interesting target for drug discovery. NusA binds to RNA polymerase and modulates several of the ribosomal RNA transcriptional processes. Here, we report the crystal structure of NusA, and reveal that the molecule consists of four domains. They are organised as two distinct entities. The N-terminal domain (residues 1 to 99) that resembles the B chain of the Rad50cd ATP binding cassette-ATPase (ABC-ATPase) and a C-terminal module (residues 108 to 329) consisting of a ribosomal S1 protein domain followed by two K homology domains. The S1 and KH domains are tightly integrated together to form an extensive RNA-binding structure, but are flexibly tethered to the N-terminal domain. The molecule's surfaces and architecture provide insights into RNA and polymerase interactions and the mechanism of pause site discrimination. They also allow us to rationalize certain termination-defective and cold shock-sensitive mutations in the nusA gene that have been studied in Escherichia coli.

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.