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

Torpedo nuclease Rat1 is insufficient to terminate RNA polymerase II in vitro

Termination of RNA polymerase (pol) II transcription in vivo requires the 5'-RNA exonuclease Rat1. It was proposed that Rat1 degrades RNA from the 5'-end that is created by transcript cleavage, catches up with elongating pol II, and acts like a Torpedo that removes pol II from DNA. Here we test the Torpedo model in an in vitro system based on bead-coupled pol II elongation complexes (ECs). Recombinant Rat1 complexes with Rai1, and with Rai1 and Rtt103, degrade RNA extending from the EC until they reach the polymerase surface but fail to terminate pol II. Instead, the EC retains an approximately 18-nucleotide RNA that remains with its 3'-end at the active site and can be elongated. Thus, pol II termination apparently requires a factor or several factors in addition to Rat1, Rai1, and Rtt103, post-translational modifications of these factors, or unusual reaction conditions.

Biosynthesis of Histidine

The biosynthesis of histidine in Escherichia coli and Salmonella typhimurium has been an important model system for the study of relationships between the flow of intermediates through a biosynthetic pathway and the control of the genes encoding the enzymes that catalyze the steps in a pathway. This article provides a comprehensive review of the histidine biosynthetic pathway and enzymes, including regulation of the flow of intermediates through the pathway and mechanisms that regulate the amounts of the histidine biosynthetic enzymes. In addition, this article reviews the structure and regulation of the histidine (his) biosynthetic operon, including transcript processing, Rho-factor-dependent "classical" polarity, and the current model of his operon attenuation control. Emphasis is placed on areas of recent progress. Notably, most of the enzymes that catalyze histidine biosynthesis have recently been crystallized, and their structures have been determined. Many of the histidine biosynthetic intermediates are unstable, and the histidine biosynthetic enzymes catalyze some chemically unusual reactions. Therefore, these studies have led to considerable mechanistic insight into the pathway itself and have provided deep biochemical understanding of several fundamental processes, such as feedback control, allosteric interactions, and metabolite channeling. Considerable recent progress has also been made on aspects of his operon regulation, including the mechanism of pp(p)Gpp stimulation of his operon transcription, the molecular basis for transcriptional pausing by RNA polymerase, and pathway evolution. The progress in these areas will continue as sophisticated new genomic, metabolomic, proteomic, and structural approaches converge in studies of the histidine biosynthetic pathway and mechanisms of control of his biosynthetic genes in other bacterial species.

Single molecule transcription elongation

Single molecule optical trapping assays have now been applied to a great number of macromolecular systems including DNA, RNA, cargo motors, restriction enzymes, DNA helicases, chromosome remodelers, DNA polymerases and both viral and bacterial RNA polymerases. The advantages of the technique are the ability to observe dynamic, unsynchronized molecular processes, to determine the distributions of experimental quantities and to apply force to the system while monitoring the response over time. Here, we describe the application of these powerful techniques to study the dynamics of transcription elongation by RNA polymerase II from Saccharomyces cerevisiae.

Structural basis of transcription: mismatch-specific fidelity mechanisms and paused RNA polymerase II with frayed RNA

We show that RNA polymerase (Pol) II prevents erroneous transcription in vitro with different strategies that depend on the type of DNARNA base mismatch. Certain mismatches are efficiently formed but impair RNA extension. Other mismatches allow for RNA extension but are inefficiently formed and efficiently proofread by RNA cleavage. X-ray analysis reveals that a TU mismatch impairs RNA extension by forming a wobble base pair at the Pol II active center that dissociates the catalytic metal ion and misaligns the RNA 3' end. The mismatch can also stabilize a paused state of Pol II with a frayed RNA 3' nucleotide. The frayed nucleotide binds in the Pol II pore either parallel or perpendicular to the DNA-RNA hybrid axis (fraying sites I and II, respectively) and overlaps the nucleoside triphosphate (NTP) site, explaining how it halts transcription during proofreading, before backtracking and RNA cleavage.

RNA polymerase active center: the molecular engine of transcription

RNA polymerase (RNAP) is a complex molecular machine that governs gene expression and its regulation in all cellular organisms. To accomplish its function of accurately producing a full-length RNA copy of a gene, RNAP performs a plethora of chemical reactions and undergoes multiple conformational changes in response to cellular conditions. At the heart of this machine is the active center, the engine, which is composed of distinct fixed and moving parts that serve as the ultimate acceptor of regulatory signals and as the target of inhibitory drugs. Recent advances in the structural and biochemical characterization of RNAP explain the active center at the atomic level and enable new approaches to understanding the entire transcription mechanism, its exceptional fidelity and control.

The origin of short transcriptional pauses

RNA polymerases are protein molecular machines that transcribe genetic information from DNA into RNA. The elongation of the RNA molecule is frequently interrupted by pauses, the detailed nature of which remains controversial. Here we ask whether backtracking, the central mechanism behind long pauses, could also be responsible for short pauses normally attributed to the ubiquitous pause state. To this end, we model backtracking as a force-biased random walk, giving rise to a broad distribution of pause durations as observed in experiments. Importantly, we find that this single mechanism naturally generates two populations of pauses that are distinct both in duration and trajectory: long-time pauses with the expected behavior of diffusive backtracks, and a new class of short-time backtracks with characteristics similar to those of the ubiquitous pause. These characteristics include an apparent force insensitivity and immobility of the polymerase. Based on these results and a quantitative comparison to published pause trajectories measured with optical tweezers, we suggest that a significant fraction of short pauses are simply due to backtracking.

Rpb9 subunit controls transcription fidelity by delaying NTP sequestration in RNA polymerase II

Rpb9 is a small non-essential subunit of yeast RNA polymerase II located on the surface on the enzyme. Deletion of the RPB9 gene shows synthetic lethality with the low fidelity rpb1-E1103G mutation localized in the trigger loop, a mobile element of the catalytic Rpb1 subunit, which has been shown to control transcription fidelity. Similar to the rpb1-E1103G mutation, the RPB9 deletion substantially enhances NTP misincorporation and increases the rate of mismatch extension with the next cognate NTP in vitro. Using pre-steady state kinetic analysis, we show that RPB9 deletion promotes sequestration of NTPs in the polymerase active center just prior to the phosphodiester bond formation. We propose a model in which the Rpb9 subunit controls transcription fidelity by delaying the closure of the trigger loop on the incoming NTP via interaction between the C-terminal domain of Rpb9 and the trigger loop. Our findings reveal a mechanism for regulation of transcription fidelity by protein factors located at a large distance from the active center of RNA polymerase II.

Mechanism of sequence-specific pausing of bacterial RNA polymerase

Sequence-specific pausing of multisubunit RNA polymerases (RNAPs) represents a rate-limiting step during transcription elongation. Pausing occurs on average every 100 bases of DNA. Several models have been proposed to explain pausing, including backtracking of the ternary elongation complex, delay of translocation of the enzyme along DNA, or a conformational change in the active site preventing formation of the phosphodiester bond. Here, we performed biochemical characterization of previously-reported pauses of Escherichia coli RNAP and found that they are not associated with backtracking or a translocation delay. Instead, the paused complex contains the 3' end of the transcript in the active center and is capable of binding the next cognate NTP. However, bond formation occurs much slower in the paused complex compared with its fully-active counterpart. The pausing is dramatically decreased by a substitution of the base encoding the next incoming NTP and the base encoding the 3' end of the nascent RNA, suggesting that (mis)-alignment of the 3' end of the RNA and the incoming NTP in the active site is crucial for pausing. These pause sites are conserved between E. coli and Thermus thermophilus RNAPs, but are not recognized by Saccharomyces cerevisiae RNAP II, indicating that prokaryotic RNAPs might be more sensitive to the changes in the alignment of the nascent transcript and the substrate NTP in the active site.

Allosteric control of Escherichia coli rRNA promoter complexes by DksA

The Escherichia coli DksA protein inserts into the RNA polymerase (RNAP) secondary channel, modifying the transcription initiation complex so that promoters with specific kinetic characteristics are regulated by changes in the concentrations of ppGpp and NTPs. We used footprinting assays to determine the specific kinetic intermediate, RP(I), on which DksA acts. Genetic approaches identified substitutions in the RNAP switch regions, bridge helix, and trigger loop that mimicked, reduced, or enhanced DksA function on rRNA promoters. Our results indicate that DksA binding in the secondary channel of RP(I) disrupts interactions with promoter DNA at least 25 A away, between positions -6 and +6 (the transcription start site is +1). We propose a working model in which the trigger loop and bridge helix transmit effects of DksA to the switch region(s), allosterically affecting switch residues that control clamp opening/closing and/or that interact directly with promoter DNA. DksA thus inhibits the transition to RP(I). Our results illustrate in mechanistic terms how transcription factors can regulate initiation promoter-specifically without interacting directly with DNA.

RNA polymerase elongation factors

The elongation phase of transcription by RNA polymerase is highly regulated and modulated. Both general and operon-specific elongation factors determine the local rate and extent of transcription to coordinate the appearance of transcript with its use as a messenger or functional ribonucleoprotein or regulatory element, as well as to provide operon-specific gene regulation.

Bridge helix and trigger loop perturbations generate superactive RNA polymerases

BACKGROUND

Cellular RNA polymerases are highly conserved enzymes that undergo complex conformational changes to coordinate the processing of nucleic acid substrates through the active site. Two domains in particular, the bridge helix and the trigger loop, play a key role in this mechanism by adopting different conformations at various stages of the nucleotide addition cycle. The functional relevance of these structural changes has been difficult to assess from the relatively small number of static crystal structures currently available.

RESULTS

Using a novel robotic approach we characterized the functional properties of 367 site-directed mutants of the Methanocaldococcus jannaschii RNA polymerase A' subunit, revealing a wide spectrum of in vitro phenotypes. We show that a surprisingly large number of single amino acid substitutions in the bridge helix, including a kink-inducing proline substitution, increase the specific activity of RNA polymerase. Other 'superactivating' substitutions are located in the adjacent base helices of the trigger loop.

CONCLUSION

The results support the hypothesis that the nucleotide addition cycle involves a kinked bridge helix conformation. The active center of RNA polymerase seems to be constrained by a network of functional interactions between the bridge helix and trigger loop that controls fundamental parameters of RNA synthesis.

Function of the Bacillus subtilis transcription elongation factor NusG in hairpin-dependent RNA polymerase pausing in the trp leader

NusA and NusG are transcription elongation factors that bind to RNA polymerase (RNAP) after sigma subunit release. Escherichia coli NusA (NusA(Ec)) stimulates intrinsic termination and RNAP(Ec) pausing, whereas NusG(Ec) promotes Rho-dependent termination and pause escape. Both Nus factors also participate in the formation of RNAP(Ec) antitermination complexes. We showed that Bacillus subtilis NusA (NusA(Bs)) stimulates intrinsic termination and RNAP(Bs) pausing at U107 and U144 in the trpEDCFBA operon leader. Pausing at U107 and U144 participates in the transcription attenuation and translational control mechanisms, respectively, presumably by providing additional time for trp RNA-binding attenuation protein (TRAP) to bind to the nascent trp leader transcript. Here, we show that NusG(Bs) causes modest pause stimulation at U107 and dramatic pause stimulation at U144. NusA(Bs) and NusG(Bs) act synergistically to increase the U107 and U144 pause half-lives. NusG(Bs)-stimulated pausing at U144 requires RNAP(Bs), whereas NusA(Bs) stimulates pausing of RNAP(Bs) and RNAP(Ec) at the U144 and E. coli his pause sites. Although NusG(Ec) does not stimulate pausing at U144, it competes with NusG(Bs)-stimulated pausing, suggesting that both proteins bind to the same surface of RNAP(Bs). Inactivation of nusG results in the loss of RNAP pausing at U144 in vivo and elevated trp operon expression, whereas plasmid-encoded NusG complements the mutant defects. Overexpression of nusG reduces trp operon expression to a larger extent than overexpression of nusA.

Optical investigations of the RNA polymerase molecular motor

Molecular motors have been extensively studied over the past 25 years using a range of optical microscopy methods. The specific example of RNA polymerase, responsible for transcribing the information encoded in DNA into RNA, illustrates the strength of the convergence between these recent approaches and the vast store of data collected over the past half century using the more "classical" approaches of genetics, biochemistry, and structure elucidation.

Thermal probing of E. coli RNA polymerase off-pathway mechanisms

RNA polymerase (RNAP) is an essential enzyme for cellular gene expression. In an effort to further understand the enzyme's importance in the cell's response to temperature, we have probed the kinetic mechanism of Escherichia coli RNAP by studying the force-velocity behavior of individual RNAP complexes at temperatures between 7 and 45 degrees C using optical tweezers. Within this temperature range and at saturating nucleotide concentrations, the pause-free transcription velocity of RNAP was independent of force and increased monotonically with temperature with an elongation activation energy of 9.7+/-0.7 kcal/mol. Interestingly, the pause density at cold temperatures (7 to 21 degrees C) was five times higher than that measured above room temperature. A simple kinetic model revealed a value of 1.29+/-0.05 kcal/mol for the activation energy of pause entry, suggesting that pause entry is indeed a thermally accessible process. The dwell time distribution of all observable pauses was independent of temperature, directly confirming a prediction of the model recently proposed for Pol II in which pauses are diffusive backtracks along the DNA. Additionally, we find that the force at which the polymerase arrests (the arrest force) presents a maximum at 21 degrees C, an unexpected result as this is not the optimum temperature for bacterial growth. This observation suggests that arrest could play a regulatory role in vivo, possibly through interactions with specific elongation factors.

The RNA polymerase II trigger loop functions in substrate selection and is directly targeted by alpha-amanitin

Structural, biochemical, and genetic studies have led to proposals that a mobile element of multisubunit RNA polymerases, the Trigger Loop (TL), plays a critical role in catalysis and can be targeted by antibiotic inhibitors. Here we present evidence that the Saccharomyces cerevisiae RNA Polymerase II (Pol II) TL participates in substrate selection. Amino acid substitutions within the Pol II TL preferentially alter substrate usage and enzyme fidelity, as does inhibition of transcription by alpha-amanitin. Finally, substitution of His1085 in the TL specifically renders Pol II highly resistant to alpha-amanitin, indicating a functional interaction between His1085 and alpha-amanitin that is supported by rerefinement of an alpha-amanitin-Pol II crystal structure. We propose that alpha-amanitin-inhibited Pol II elongation, which is slow and exhibits reduced substrate selectivity, results from direct alpha-amanitin interference with the TL.

Transient reversal of RNA polymerase II active site closing controls fidelity of transcription elongation

To study fidelity of RNA polymerase II (Pol II), we analyzed properties of the 6-azauracil-sensitive and TFIIS-dependent E1103G mutant of rbp1 (rpo21), the gene encoding the catalytic subunit of Pol II in Saccharomyces cerevisiae. Using an in vivo retrotransposition-based transcription fidelity assay, we observed that rpb1-E1103G causes a 3-fold increase in transcription errors. This mutant showed a 10-fold decrease in fidelity of transcription elongation in vitro. The mutation does not appear to significantly affect translocation state equilibrium of Pol II in a stalled elongation complex. Primarily, it promotes NTP sequestration in the polymerase active center. Furthermore, pre-steady-state analyses revealed that the E1103G mutation shifted the equilibrium between the closed and the open active center conformations toward the closed form. Thus, open conformation of the active center emerges as an intermediate essential for preincorporation fidelity control. Similar mechanisms may control fidelity of DNA-dependent DNA polymerases and RNA-dependent RNA polymerases.

Structural basis of transcription inhibition by alpha-amanitin and implications for RNA polymerase II translocation

To study how RNA polymerase II translocates after nucleotide incorporation, we prepared elongation complex crystals in which pre- and post-translocation states interconvert. Crystal soaking with the inhibitor alpha-amanitin locked the elongation complex in a new state, which was refined at 3.4-A resolution and identified as a possible translocation intermediate. The DNA base entering the active site occupies a 'pretemplating' position above the central bridge helix, which is shifted and occludes the templating position. A leucine residue in the trigger loop forms a wedge at the shifted bridge helix, but moves by 13 A to close the active site during nucleotide incorporation. Our results support a Brownian ratchet mechanism that involves swinging of the trigger loop between open, wedged and closed positions, and suggest that alpha-amanitin impairs nucleotide incorporation and translocation by trapping the trigger loop and bridge helix.

Transcription termination factor rho prefers catalytically active elongation complexes for releasing RNA

RNA polymerase pauses at different DNA sequences during transcription elongation, and this pausing is associated with distinct conformational state(s) of the elongation complex (EC). Transcription termination by the termination factor Rho, an RNA-dependent molecular motor, requires pausing of the EC in the termination zone of Rho-dependent terminators. We hypothesized that the conformational state(s) of the EC associated with this pausing would influence the action of Rho. Analyses of the pausing behavior of the EC at the termination points of two well known Rho-dependent terminators revealed that Rho prefers actively transcribing complexes for termination. RNA release kinetics from stalled ECs showed that the rate of RNA release by Rho was reduced if the EC was irreversibly backtracked, if its RNA exit channel was modified by an RNA hairpin, or the bridge helix/trigger loop movement in its active site was perturbed. These defects were overcome significantly by enhancing the rate of ATP hydrolysis either by increasing the concentration of ATP or by using a Rho mutant with higher ATPase activity. We propose that the force generated from ATP hydrolysis of Rho is the key factor in dislodging the EC through its molecular motor action, and this process is facilitated when the EC is in a catalytically competent state, undergoing rapid "Brownian ratchet" motion.

Human U2 snRNA genes exhibit a persistently open transcriptional state and promoter disassembly at metaphase

In mammals, small multigene families generate spliceosomal U snRNAs that are nearly as abundant as rRNA. Using the tandemly repeated human U2 genes as a model, we show by footprinting with DNase I and permanganate that nearly all sequences between the enhancer-like distal sequence element and the initiation site are protected during interphase whereas the upstream half of the U2 snRNA coding region is exposed. We also show by chromatin immunoprecipitation that the SNAPc complex, which binds the TATA-like proximal sequence element, is removed at metaphase but remains bound under conditions that induce locus-specific metaphase fragility of the U2 genes, such as loss of CSB, BRCA1, or BRCA2 function, treatment with actinomycin D, or overexpression of the tetrameric p53 C terminus. We propose that the U2 snRNA promoter establishes a persistently open state to facilitate rapid reinitiation and perhaps also to bypass TFIIH-dependent promoter melting; this open state would then be disassembled to allow metaphase chromatin condensation.

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.

Still looking for the magic spot: the crystallographically defined binding site for ppGpp on RNA polymerase is unlikely to be responsible for rRNA transcription regulation

Identification of the RNA polymerase (RNAP) binding site for ppGpp, a central regulator of bacterial transcription, is crucial for understanding its mechanism of action. A recent high-resolution X-ray structure defined a ppGpp binding site on Thermus thermophilus RNAP. We report here effects of ppGpp on 10 mutant Escherichia coli RNAPs with substitutions for the analogous residues within 3-4 A of the ppGpp binding site in the T. thermophilus cocrystal. None of the substitutions in E. coli RNAP significantly weakened its responses to ppGpp. This result differs from the originally reported finding of a substitution in E. coli RNAP eliminating ppGpp function. The E. coli RNAPs used in that study likely lacked stoichiometric amounts of omega, an RNAP subunit required for responses of RNAP to ppGpp, in part explaining the discrepancy. Furthermore, we found that ppGpp did not inhibit transcription initiation by T. thermophilus RNAP in vitro or shorten the lifetimes of promoter complexes containing T. thermophilus RNAP, in contrast to the conclusion in the original report. Our results suggest that the ppGpp binding pocket identified in the cocrystal is not the one responsible for regulation of E. coli ribosomal RNA transcription initiation and highlight the importance of inclusion of omega in bacterial RNAP preparations.

Transcription processing at 1,N2-ethenoguanine by human RNA polymerase II and bacteriophage T7 RNA polymerase

The DNA lesion 1,N(2)-ethenoguanine (1,N(2)-epsilon G) is formed endogenously as a by-product of lipid peroxidation or by reaction with epoxides that result from the metabolism of the industrial pollutant vinyl chloride, a known human carcinogen. DNA replication past 1,N(2)-epsilon G and site-specific mutagenesis studies on mammalian cells have established the highly mutagenic and genotoxic properties of the damaged base. However, there is as yet no information on the processing of this lesion during transcription. Here, we report the results of transcription past a site-specifically modified 1,N(2)-epsilon G DNA template. This lesion contains an exocyclic ring obstructing the Watson-Crick hydrogen-bonding edge of guanine. Our results show that 1,N(2)-epsilon G acts as a partial block to the bacteriophage T7 RNA polymerase (RNAP), which allows nucleotide incorporation in the growing RNA with the selectivity A>G>(C=-1 deletion)>>U. In contrast, 1,N(2)-epsilon G poses an absolute block to human RNAP II elongation, and nucleotide incorporation opposite the lesion is not observed. Computer modeling studies show that the more open active site of T7 RNAP allows lesion bypass when the 1,N(2)-epsilon G adopts the syn-conformation. This orientation places the exocyclic ring in a collision-free empty pocket of the polymerase, and the observed base incorporation preferences are in agreement with hydrogen-bonding possibilities between the incoming nucleotides and the Hoogsteen edge of the lesion. On the other hand, in the more crowded active site of the human RNAP II, the modeling studies show that both syn- and anti-conformations of the 1,N(2)-epsilon G are sterically impermissible. Polymerase stalling is currently believed to trigger the transcription-coupled nucleotide excision repair machinery. Thus, our data suggest that this repair pathway is likely engaged in the clearance of the 1,N(2)-epsilon G from actively transcribed DNA.

A tunable ratchet driving human RNA polymerase II translocation adjusted by accurately templated nucleoside triphosphates loaded at downstream sites and by elongation factors

When nucleoside triphosphate (NTP) substrates and alpha-amanitin are added to a human RNA polymerase II elongation complex simultaneously, the reaction becomes stalled in the core of the bond synthesis mechanism. The mode of stalling is influenced by NTP substrates at the active site and at downstream sites and by transcription factor IIF (TFIIF) and TFIIS. NTP substrates templated at i+2, i+3, and i+4 downstream DNA sites can reverse the previously stable binding of an NTP loaded at the i+1 substrate site. Deoxy-(d)NTPs and NDPs (nucleoside diphosphates) do not substitute for NTPs at the i+2 and i+3 positions (considered together) or the i+4, i+5, and i+6 positions (considered together). The mode of stalling is altered by changing the number of downstream template sites that are accurately occupied by NTPs and by changing NTP concentration. In the presence of the translocation blocker alpha-amanitin, a steady state condition is established in which RNA polymerase II stably loads an NTP substrate at i+1 and forms a phosphodiester bond but cannot rapidly complete bond synthesis by releasing pyrophosphate. These observations support a role for incoming NTP substrates in stimulating translocation; results appear inconsistent with the secondary pore being the sole route of NTP entry for human RNA polymerase II, and results indicate mechanisms of dynamic error avoidance and error correction during rapid RNA synthesis.

Allosteric control of the RNA polymerase by the elongation factor RfaH

Efficient transcription of long polycistronic operons in bacteria frequently relies on accessory proteins but their molecular mechanisms remain obscure. RfaH is a cellular elongation factor that acts as a polarity suppressor by increasing RNA polymerase (RNAP) processivity. In this work, we provide evidence that RfaH acts by reducing transcriptional pausing at certain positions rather than by accelerating RNAP at all sites. We show that ‘fast’ RNAP variants are characterized by pause-free RNA chain elongation and are resistant to RfaH action. Similarly, the wild-type RNAP is insensitive to RfaH in the absence of pauses. In contrast, those enzymes that may be prone to falling into a paused state are hypersensitive to RfaH. RfaH inhibits pyrophosphorolysis of the nascent RNA and reduces the apparent Michaelis–Menten constant for nucleotides, suggesting that it stabilizes the post-translocated, active RNAP state. Given that the RfaH-binding site is located 75 Å away from the RNAP catalytic center, these results strongly indicate that RfaH acts allosterically. We argue that despite the apparent differences in the nucleic acid targets, the time of recruitment and the binding sites on RNAP, unrelated antiterminators (such as RfaH and λQ) utilize common strategies during both recruitment and anti-pausing modification of the transcription complex.