Three-dimensional reconstruction of transcription termination factor rho: orientation of the N-terminal domain and visualization of an RNA-binding site

Diversification of the Rho transcription termination factor in bacteria

Correct termination of transcription is essential for gene expression. In bacteria, factor-dependent termination relies on the Rho factor, that classically has three conserved domains. Some bacteria also have a functional insertion region. However, the variation in Rho structure among bacteria has not been analyzed in detail. This study determines the distribution, sequence conservation, and predicted features of Rho factors with diverse domain architectures by analyzing 2730 bacterial genomes. About half (49.8%) of the species analyzed have the typical Escherichia coli like Rho while most of the other species (39.8%) have diverse, atypical forms of Rho. Besides conservation of the main domains, we describe a duplicated RNA-binding domain present in specific species and novel variations in the bicyclomycin binding pocket. The additional regions observed in Rho proteins exhibit remarkable diversity. Commonly, however, they have exceptional amino acid compositions and are predicted to be intrinsically disordered, to undergo phase separation, or have prion-like behavior. Phase separation has recently been shown to play roles in Rho function and bacterial fitness during harsh conditions in one species and this study suggests a more widespread role. In conclusion, diverse atypical Rho factors are broadly distributed among bacteria, suggesting additional cellular roles.

Convergent evolution in the supercoiling of prokaryotic flagellar filaments

The supercoiling of bacterial and archaeal flagellar filaments is required for motility. Archaeal flagellar filaments have no homology to their bacterial counterparts and are instead homologs of bacterial type IV pili. How these prokaryotic flagellar filaments, each composed of thousands of copies of identical subunits, can form stable supercoils under torsional stress is a fascinating puzzle for which structural insights have been elusive. Advances in cryoelectron microscopy (cryo-EM) make it now possible to directly visualize the basis for supercoiling, and here, we show the atomic structures of supercoiled bacterial and archaeal flagellar filaments. For the bacterial flagellar filament, we identify 11 distinct protofilament conformations with three broad classes of inter-protomer interface. For the archaeal flagellar filament, 10 protofilaments form a supercoil geometry supported by 10 distinct conformations, with one inter-protomer discontinuity creating a seam inside of the curve. Our results suggest that convergent evolution has yielded stable superhelical geometries that enable microbial locomotion.

Mechanisms of hexameric helicases

Ring-shaped hexameric helicases are essential motor proteins that separate duplex nucleic acid strands for DNA replication, recombination, and transcriptional regulation. Two evolutionarily distinct lineages of these enzymes, predicated on RecA and AAA+ ATPase folds, have been identified and characterized to date. Hexameric helicases couple NTP hydrolysis with conformational changes that move nucleic acid substrates through a central pore in the enzyme. How hexameric helicases productively engage client DNA or RNA segments and use successive rounds of NTPase activity to power translocation and unwinding have been longstanding questions in the field. Recent structural and biophysical findings are beginning to reveal commonalities in NTP hydrolysis and substrate translocation by diverse hexameric helicase families. Here, we review these molecular mechanisms and highlight aspects of their function that are yet to be understood.

Tuning the sequence specificity of a transcription terminator

The bacterial hexameric helicase known as Rho is an archetypal sequence-specific transcription terminator that typically halts the synthesis of a defined set of transcripts, particularly those bearing cytosine-rich 3'-untranslated regions. However, under conditions of translational stress, Rho can also terminate transcription at cytosine-poor sites when assisted by the transcription factor NusG. Recent structural, biochemical, and computational studies of the Rho·NusG interaction in Escherichia coli have helped establish how NusG reprograms Rho activity. NusG is found to be an allosteric activator of Rho that directly binds to the ATPase motor domain of the helicase and facilitates closure of the Rho ring around non-ideal (purine-rich) target RNAs. The manner in which NusG acts on Rho helps to explain how the transcription terminator is excluded from acting on RNA polymerase by exogenous factors, such as the antitermination protein NusE, the NusG paralog RfaH, and RNA polymerase-coupled ribosomes. Collectively, an understanding of the link between NusG and Rho provides new insights into how transcriptional and translational fidelity are maintained during gene expression in bacteria.

Mechanism for the Regulated Control of Bacterial Transcription Termination by a Universal Adaptor Protein

NusG/Spt5 proteins are the only transcription factors utilized by all cellular organisms. In enterobacteria, NusG antagonizes the transcription termination activity of Rho, a hexameric helicase, during the synthesis of ribosomal and actively translated mRNAs. Paradoxically, NusG helps Rho act on untranslated transcripts, including non-canonical antisense RNAs and those arising from translational stress; how NusG fulfills these disparate functions is unknown. Here, we demonstrate that NusG activates Rho by assisting helicase isomerization from an open-ring, RNA-loading state to a closed-ring, catalytically active translocase. A crystal structure of closed-ring Rho in complex with NusG reveals the physical basis for this activation and further explains how Rho is excluded from translationally competent RNAs. This study demonstrates how a universally conserved transcription factor acts to modulate the activity of a ring-shaped ATPase motor and establishes how the innate sequence bias of a termination factor can be modulated to silence pervasive, aberrant transcription.

Molecular mechanisms of substrate-controlled ring dynamics and substepping in a nucleic acid-dependent hexameric motor

Ring-shaped hexameric helicases and translocases support essential DNA-, RNA-, and protein-dependent transactions in all cells and many viruses. How such systems coordinate ATPase activity between multiple subunits to power conformational changes that drive the engagement and movement of client substrates is a fundamental question. Using the Escherichia coli Rho transcription termination factor as a model system, we have used solution and crystallographic structural methods to delineate the range of conformational changes that accompany distinct substrate and nucleotide cofactor binding events. Small-angle X-ray scattering data show that Rho preferentially adopts an open-ring state in solution and that RNA and ATP are both required to cooperatively promote ring closure. Multiple closed-ring structures with different RNA substrates and nucleotide occupancies capture distinct catalytic intermediates accessed during translocation. Our data reveal how RNA-induced ring closure templates a sequential ATP-hydrolysis mechanism, provide a molecular rationale for how the Rho ATPase domains distinguishes between distinct RNA sequences, and establish structural snapshots of substepping events in a hexameric helicase/translocase.

Ligand-induced and small-molecule control of substrate loading in a hexameric helicase

Processive, ring-shaped protein and nucleic acid protein translocases control essential biochemical processes throughout biology and are considered high-prospect therapeutic targets. The Escherichia coli Rho factor is an exemplar hexameric RNA translocase that terminates transcription in bacteria. As with many ring-shaped motor proteins, Rho activity is modulated by a variety of poorly understood mechanisms, including small-molecule therapeutics, protein-protein interactions, and the sequence of its translocation substrate. Here, we establish the mechanism of action of two Rho effectors, the antibiotic bicyclomycin and nucleic acids that bind to Rho's primary RNA recruitment site. Using small-angle X-ray scattering and a fluorescence-based assay to monitor the ability of Rho to switch between open-ring (RNA-loading) and closed-ring (RNA-translocation) states, we found bicyclomycin to be a direct antagonist of ring closure. Reciprocally, the binding of nucleic acids to its N-terminal RNA recruitment domains is shown to promote the formation of a closed-ring Rho state, with increasing primary-site occupancy providing additive stimulatory effects. This study establishes bicyclomycin as a conformational inhibitor of Rho ring dynamics, highlighting the utility of developing assays that read out protein conformation as a prospective screening tool for ring-ATPase inhibitors. Our findings further show that the RNA sequence specificity used for guiding Rho-dependent termination derives in part from an intrinsic ability of the motor to couple the recognition of pyrimidine patterns in nascent transcripts to RNA loading and activity.

Loading strategies of ring-shaped nucleic acid translocases and helicases

Ring-shaped nucleic acid translocases and helicases catalyze the directed and processive movement of nucleic acid strands to support essential transactions such as replication, transcription, and chromosome partitioning. Assembled typically as hexamers, ring helicase/translocase systems use coordinated cycles of nucleoside triphosphate (NTP) hydrolysis to translocate extended DNA or RNA substrates through a central pore. Ring formation presents a topological challenge to the engagement of substrate oligonucleotides, and is frequently overcome by distinct loading strategies for shepherding specific motors onto their respective substrates. Recent structural studies that capture different loading intermediates have begun to reveal how different helicase/translocase rings either assemble around substrates or crack open to allow DNA or RNA strand entry, and how dedicated chaperones facilitate these events in some instances. Both prevailing mechanistic models and remaining knowledge gaps are discussed.

In vivo evolution of a catalytic RNA couples trans-splicing to translation

How does a non-coding RNA evolve in cells? To address this question experimentally we evolved a trans-splicing variant of the group I intron ribozyme from Tetrahymena over 21 cycles of evolution in E.coli cells. Sequence variation was introduced during the evolution by mutagenic and recombinative PCR, and increasingly active ribozymes were selected by their repair of an mRNA mediating antibiotic resistance. The most efficient ribozyme contained four clustered mutations that were necessary and sufficient for maximum activity in cells. Surprisingly, these mutations did not increase the trans-splicing activity of the ribozyme. Instead, they appear to have recruited a cellular protein, the transcription termination factor Rho, and facilitated more efficient translation of the ribozyme’s trans-splicing product. In addition, these mutations affected the expression of several other, unrelated genes. These results suggest that during RNA evolution in cells, four mutations can be sufficient to evolve new protein interactions, and four mutations in an RNA molecule can generate a large effect on gene regulation in the cell.

DNA unwinding by ring-shaped T4 helicase gp41 is hindered by tension on the occluded strand

The replicative helicase for bacteriophage T4 is gp41, which is a ring-shaped hexameric motor protein that achieves unwinding of dsDNA by translocating along one strand of ssDNA while forcing the opposite strand to the outside of the ring. While much study has been dedicated to the mechanism of binding and translocation along the ssDNA strand encircled by ring-shaped helicases, relatively little is known about the nature of the interaction with the opposite, ‘occluded’ strand. Here, we investigate the interplay between the bacteriophage T4 helicase gp41 and the ss/dsDNA fork by measuring, at the single-molecule level, DNA unwinding events on stretched DNA tethers in multiple geometries. We find that gp41 activity is significantly dependent on the geometry and tension of the occluded strand, suggesting an interaction between gp41 and the occluded strand that stimulates the helicase. However, the geometry dependence of gp41 activity is the opposite of that found previously for the E. coli hexameric helicase DnaB. Namely, tension applied between the occluded strand and dsDNA stem inhibits unwinding activity by gp41, while tension pulling apart the two ssDNA tails does not hinder its activity. This implies a distinct variation in helicase-occluded strand interactions among superfamily IV helicases, and we propose a speculative model for this interaction that is consistent with both the data presented here on gp41 and the data that had been previously reported for DnaB.

Structure and mechanism of hexameric helicases

Hexameric helicases are responsible for many biological processes, ranging from DNA replication in various life domains to DNA repair, transcriptional regulation and RNA metabolism, and encompass superfamilies 3-6 (SF3-6).To harness the chemical energy from ATP hydrolysis for mechanical work, hexameric helicases have a conserved core engine, called ASCE, that belongs to a subdivision of the P-loop NTPases. Some of the ring helicases (SF4 and SF5) use a variant of ASCE known as RecA-like, while some (SF3 and SF6) use another variant known as AAA+ fold. The NTP-binding sites are located at the interface between monomers and include amino-acid residues coming from neighbouring subunits, providing a mean for small structural changes within the ATP-binding site to be amplified into large inter-subunit movement.The ring structure has a central channel which encircles the nucleic acid. The topological link between the protein and the nucleic acid substrate increases the stability and processivity of the enzyme. This is probably the reason why within cellular systems the critical step of unwinding dsDNA ahead of the replication fork seems to be almost invariably carried out by a toroidal helicase, whether in bacteria, archaea or eukaryotes, as well as in some viruses.Over the last few years, a large number of biochemical, biophysical and structural data have thrown new light onto the architecture and function of these remarkable machines. Although the evidence is still limited to a couple of systems, biochemical and structural results suggest that motors based on RecA and AAA+ folds have converged on similar mechanisms to couple ATP-driven conformational changes to movement along nucleic acids.

Multiple Escherichia coli RecQ helicase monomers cooperate to unwind long DNA substrates: a fluorescence cross-correlation spectroscopy study

The RecQ family helicases catalyze the DNA unwinding reaction in an ATP hydrolysis-dependent manner. We investigated the mechanism of DNA unwinding by the Escherichia coli RecQ helicase using a new sensitive helicase assay based on fluorescence cross-correlation spectroscopy (FCCS) with two-photon excitation. The FCCS-based assay can be used to measure the unwinding activity under both single and multiple turnover conditions with no limitation related to the size of the DNA strands constituting the DNA substrate. We found that the monomeric helicase was sufficient to perform the unwinding of short DNA substrates. However, a significant increase in the activity was observed using longer DNA substrates, under single turnover conditions, originating from the simultaneous binding of multiple helicase monomers to the same DNA molecule. This functional cooperativity was strongly dependent on several factors, including DNA substrate length, the number and size of single-stranded 3'-tails, and the temperature. Regarding the latter parameter, a strong cooperativity was observed at 37 degrees C, whereas only modest or no cooperativity was observed at 25 degrees C regardless of the nature of the DNA substrate. Consistently, the functional cooperativity was found to be tightly associated with a cooperative DNA binding mode. We also showed that the cooperative binding of helicase to the DNA substrate indirectly accounts for the sigmoidal dependence of unwinding activity on ATP concentration, which also occurs only at 37 degrees C but not at 25 degrees C. Finally, we further examined the influences of spontaneous DNA rehybridization (after helicase translocation) and the single-stranded DNA binding property of helicase on the unwinding activity as detected in the FCCS assay.

In vivo dynamics of intracistronic transcriptional polarity

Transcriptional polarity occurs in Escherichia coli when cryptic Rho-dependent transcription terminators become activated as a consequence of reduced translation. Increased spacing between RNA polymerase and the leading ribosome allows the transcription termination factor Rho to bind to mRNA, migrate to the RNA polymerase, and induce termination. Transcriptional polarity results in decreased synthesis of inefficiently translated mRNAs and, therefore, in decreased expression not only of downstream genes in the same operon (intercistronic polarity) but also of the cistron in which termination occurs (intracistronic polarity). To quantitatively measure the effect of different levels of translation on intracistronic transcription termination, the polarity-prone lacZ reporter gene was fused to a range of mutated ribosome binding sites, repressed to different degrees by local RNA structure. The results show that polarity gradually increases with decreasing frequency of translational initiation, as expected. Closer analysis, with the help of a newly developed kinetic model, reveals that efficient intracistronic termination requires very low translational initiation frequencies. This finding is unexpected because Rho is a relatively small protein that binds rapidly to its RNA target, but it appears to be true also for other examples of transcriptional polarity reported in the literature. The conclusion must be that polarity is more complex than just an increased exposure of the Rho binding site as the spacing between the polymerase and the leading ribosome becomes larger. Biological consequences and possible mechanisms are discussed.

A novel mirror-symmetry analysis approach for the study of macromolecular assemblies imaged by electron microscopy

Multivariate statistical symmetry analysis is widely employed in single-particle electron-microscopy studies for the detection of symmetry components within a set of noisy two-dimensional images. So far, this technique has been used to retrieve information from the analysis of end-on view oriented particles only. Here, we propose a method to detect symmetry components from side- and tilted-view oriented particles. This method is validated using a number of in silico generated as well as real datasets, can be used to analyze stoichiometrically heterogeneous datasets, and is useful for separating particle datasets with respect to their symmetry components. Additionally, translational components in lock-washer ring configurations can be detected. Most relevantly, this method represents a powerful tool for the characterisation of distinct symmetry components within multi-layered protein assemblies, and any putative symmetry mismatch between layers. Such configurations have often been postulated, though rarely observed directly, and are thought to have a crucial role in conferring dynamicity to molecular machineries like nucleic acid packaging motors, ClpAP/ClpXP proteases, flagellar motors and the F1/F0 ATPase.

On translocation mechanism of ring-shaped helicase along single-stranded DNA

The ring-shaped helicases represent one important group of helicases that can translocate along single-stranded (ss) DNA and unwinding double-stranded (ds) DNA by using the energy derived from NTP binding and hydrolysis. Despite intensive studies, the mechanism by which the ring-shaped helicase translocates along ssDNA and unwinds dsDNA remains undetermined. In order to understand their chemomechanical-coupling mechanism, two models on NTPase activities of the hexamers in the presence of DNA have been studied here. One model is assumed that, of the six nucleotide-binding sites, three are noncatalytic and three are catalytic. The other model is assumed that all the six nucleotide-binding sites are catalytic. In terms of the sequential NTPase activity around the ring and the previous determined crystal structure of bacteriophage T7 helicase it is shown that the obtained mechanical behaviors such as the ssDNA-translocation size and DNA-unwinding size per dTTPase cycle using the former model are in good quantitative agreement with the previous experimental results for T7 helicase. Moreover, the acceleration of DNA unwinding rate with the stimulation of DNA synthesis by DNA polymerase can also be well explained by using the former model. In contrast, the ssDNA-translocation size and DNA-unwinding size per dTTPase cycle obtained by using the latter model are not consistent with the experimental results for T7 helicase. Thus it is preferred that the former model is the appropriate one for the T7 helicase. Furthermore, using the former model some dynamic behaviors such as the rotational speeds of DNA relative to the T7 helicase when translocation along ssDNA and when unwinding dsDNA have been predicted, which are expected to test in order to further verify the model.

Structural insights into RNA-dependent ring closure and ATPase activation by the Rho termination factor

Hexameric helicases and translocases are required for numerous essential nucleic-acid transactions. To better understand the mechanisms by which these enzymes recognize target substrates and use nucleotide hydrolysis to power molecular movement, we have determined the structure of the Rho transcription termination factor, a hexameric RNA/DNA helicase, with single-stranded RNA bound to the motor domains of the protein. The structure reveals a closed-ring "trimer of dimers" conformation for the hexamer that contains an unanticipated arrangement of conserved loops required for nucleic-acid translocation. RNA extends across a shallow intersubunit channel formed by conserved amino acids required for RNA-stimulated ATP hydrolysis and translocation and directly contacts a conserved lysine, just upstream of the catalytic GKT triad, in the phosphate-binding (P loop) motif of the ATP-binding pocket. The structure explains the molecular effects of numerous mutations and provides new insights into the links between substrate recognition, ATP turnover, and coordinated strand movement.

Escherichia coli RecQ is a rapid, efficient, and monomeric helicase

RecQ family helicases play a key role in chromosome maintenance. Despite extensive biochemical, biophysical, and structural studies, the mechanism by which helicase unwinds double-stranded DNA remains to be elucidated. Using a wide array of biochemical and biophysical approaches, we have previously shown that the Escherichia coli RecQ helicase functions as a monomer. In this study, we have further characterized the kinetic mechanism of the RecQ-catalyzed unwinding of duplex DNA using the fluorometric stopped-flow method based on fluorescence resonance energy transfer. Our results show that RecQ helicase binds preferentially to 3'-flanking duplex DNA. Under the pre-steady-state conditions, the burst amplitude reveals a 1:1 ratio between RecQ and DNA substrate, suggesting that an active monomeric form of RecQ helicase is involved in the catalysis. Under the single-turnover conditions, the RecQ-catalyzed unwinding is independent of the 3'-tail length, indicating that functional interactions between RecQ molecules are not implicated in the DNA unwinding. It was further determined that RecQ unwinds DNA rapidly with a step size of 4 bp and a rate of approximately 21 steps/s. These kinetic results not only further support our previous conclusion that E. coli RecQ functions as a monomer but also suggest that some of the Superfamily 2 helicases may function through an "inchworm" mechanism.

Structural mechanism of inhibition of the Rho transcription termination factor by the antibiotic bicyclomycin

Rho is a hexameric RNA/DNA helicase/translocase that terminates transcription of select genes in bacteria. The naturally occurring antibiotic, bicyclomycin (BCM), acts as a noncompetitive inhibitor of ATP turnover to disrupt this process. We have determined three independent X-ray crystal structures of Rho complexed with BCM and two semisynthetic derivatives, 5a-(3-formylphenylsulfanyl)-dihydrobicyclomycin (FPDB) and 5a-formylbicyclomycin (FB) to 3.15, 3.05, and 3.15 A resolution, respectively. The structures show that BCM and its derivatives are nonnucleotide inhibitors that interact with Rho at a pocket adjacent to the ATP and RNA binding sites in the C-terminal half of the protein. BCM association prevents ATP turnover by an unexpected mechanism, occluding the binding of the nucleophilic water molecule required for ATP hydrolysis. Our data explain why only certain elements of BCM have been amenable to modification and serve as a template for the design of new inhibitors.

Bismuth–dithiol inhibition of the Escherichia coli rho transcription termination factor

Bismuth-dithiol mixtures are proven antimicrobial agents with unknown mechanism(s) of action. We show that select bismuth-dithiol solutions inhibit the Escherichia coli rho transcription termination factor. Rho is an essential enzyme in most Gram-negative prokaryotes and without rho function the cells are not viable. Bismuth complexes with 2,3-dimercapto-1-propanol (BiBAL) (3:1 solutions) functioned as a noncompetitive inhibitor with respect to ATP in the rho poly(C)-dependent ATPase assay (I50=60 microM) and as a competitive inhibitor with respect to ribo(C)10 in the poly(dC)-ribo(C)10-dependent ATPase assay. The minimum inhibitory concentration (MIC) of bacterial growth for BiBAL (3:1) in the liquid culture assay using E. coli W3350 was 16 microM. Using the tnaA/lacZ fusion reporter assay we showed that sublethal amounts (3 microM) of BiBAL (3:1 solution) led to a small increase (37%) in in vivo beta-galactosidase activity in E. coli SVS1144, which corresponds to antitermination of the tna operon as a result of rho inhibition. We concluded that BiBAL was a potent in vitro rho inhibitor but its effect on in vivo rho processes was modest indicating that other mechanisms contributed to the antibacterial activity of BiBAL. Our study suggests that structural changes in the dithiol unit that provide greater bismuth binding may improve rho specificity, a macromolecular target not previously recognized for bismuth therapy.

Inhibition of the Escherichia coli RecA protein: zinc(II), copper(II) and mercury(II) trap RecA as inactive aggregates

In bacteria, the RecA protein plays important roles in a number of DNA recombination and repair processes, including homologous recombination, SOS induction and recombinational DNA repair. We have explored the idea that the Escherichia coli RecA protein's functions could be controlled by small molecules. We investigated the 2:1 complex of zinc(II) with 1,4-dithio-l-threitol (l-DTT) that inhibits the E. coli rho transcription terminator, which is a hexameric ATP motor protein and is structurally homologous to RecA. We found that both the complex and ZnCl(2) inhibit the single-stranded DNA-dependent ATPase activity of RecA at sub-millimolar concentrations. Investigation of a variety of metal dications (0.4 mM final concentration) determined that zinc(II), copper(II) and mercury(II) all induce the precipitation of RecA, while the dichloride salts of calcium, manganese, barium, cobalt, and nickel do not. The inhibition of RecA activity by Zn(II), Cu(II) and Hg(II) results from the metal-dependent initiation of RecA aggregation. These observations may have implications for the design of biophysical experiments requiring solid-phase RecA protein, for a more complete understanding of metal toxicities, and for the design of metal-chelate inhibitors of prokaryotic DNA repair.

Influence of substrate composition on the helicase activity of transcription termination factor Rho: reduced processivity of Rho hexamers during unwinding of RNA-DNA hybrid regions

Transcription termination factor Rho forms ring-shaped hexameric structures that load onto segments of the nascent RNA transcript that are C-rich and mostly single-stranded. This interaction converts Rho hexamers into active molecular motors that use the energy resulting from their ATP hydrolase activity to move towards the transcript 3'-end. Upon translocation along the RNA chain, Rho can displace physical roadblocks, such as those formed by RNA-DNA helices, a feature that is likely central to the transcription termination mechanism. To study this "translocase" (helicase) activity, we have designed a collection of Rho substrate chimeras containing an RNA-DNA helix located at various positions with respect to a short (47 nucleotides) artificial loading site. We show that these synthetic constructs represent interesting model substrates able to engage in a productive interaction with Rho and to direct NTP-dependent [5'-->3']-translocation of the hexamers. Using both single and multiple-cycle experimental set-ups, we have also found that Rho helicase activity is strongly dependent on the substrate composition and reaction conditions. For this reason, the rate-limiting step of the helicase reaction could not be identified unambiguously. Yet, the linear dependence of the reaction rate on the hybrid length suggests that helicase action on the RNA-DNA region could be controlled by a unique slow step such as Rho activation, conformational rearrangement, or DNA release. Moreover, removal of the DNA strand occurred at a significant cost for the Rho enzyme, inducing, on average, dissociation from the substrate for every 60-80 base-pairs of hybrid unwound. These results are discussed in relation to the known requirements for Rho substrates, general features of hexameric helicases, and current models for Rho-dependent transcription termination.

Nucleotide binding induces conformational changes in Escherichia coli transcription termination factor Rho

The Escherichia coli Rho protein uses the energy of ATP binding and hydrolysis to translocate along RNA and cause transcription termination. Using fluorescence stopped-flow kinetic studies, we have discerned the conformational changes in the Rho protein that occur upon nucleotide and nucleic acid binding. We show that the 2', (3')-O-[N-methylanthraniloyl] derivative of ATP (mant-ATP) is a good fluorescent substrate of Rho and is hydrolyzed with a K(m) comparable with that for ATP but a k(cat) five to six times slower than that for ATP. The kinetics of ATP and mant-ATP binding indicates that, in the absence of RNA, the Rho protein is structurally distinct from the Rho hexamer found when bound to RNA or DNA. In the absence of RNA, the nucleotide-binding rates are 50- to 70-fold slower, and the dissociation rates are 40- to 120-fold slower than the corresponding rates in the presence of RNA. We conclude that RNA or DNA binding to the primary nucleic acid binding sites causes conformational changes in the Rho hexamer that result in the opening of the subunit interfaces. Furthermore, the kinetic studies revealed a unique protein conformational change in the Rho.RNA complex upon ATP binding that is a result of RNA contacting the secondary nucleic acid binding sites in the central channel of the Rho ring. This conformational change seems to render the Rho ring competent in ATP hydrolysis and translocation.

Rho Factor: Transcription Termination in Four Steps

Rho factor is a hexameric ring-shaped helicase which terminates transcription in Escherichia coli. Two recent crystal structures of Rho in complex with nucleic acid reveal how this helicase ring loads onto mRNA and encircles it.

Structure of the Rho transcription terminator: mechanism of mRNA recognition and helicase loading

In bacteria, one of the major transcriptional termination mechanisms requires a RNA/DNA helicase known as the Rho factor. We have determined two structures of Rho complexed with nucleic acid recognition site mimics in both free and nucleotide bound states to 3.0 A resolution. Both structures show that Rho forms a hexameric ring in which two RNA binding sites--a primary one responsible for target mRNA recognition and a secondary one required for mRNA translocation and unwinding--point toward the center of the ring. Rather than forming a closed ring, the Rho hexamer is split open, resembling a "lock washer" in its global architecture. The distance between subunits at the opening is sufficiently wide (12 A) to accommodate single-stranded RNA. This open configuration most likely resembles a state poised to load onto mRNA and suggests how related ring-shaped enzymes may be breached to bind nucleic acids.

ATP binding to Rho transcription termination factor. Mutant F355W ATP-induced fluorescence quenching reveals dynamic ATP binding

Rho transcription termination factor mutant, F355W, showed tryptophan fluorescence intensity approximately twice that of wild-type Rho at equivalent protein concentrations and underwent a decrease in relative fluorescence intensity at 350 nm when 100 microm ATP was added in the presence or absence of RNA. Titration of this fluorescence quenching with varying concentrations of ATP (0-600 microm), where Rho is shown to exist as a hexamer (400 nm Rho), revealed tight and loose ATP-binding sites. Bicyclomycin, a specific inhibitor of Rho, increased the tight ATP binding and was used to calibrate ATP-induced fluorescence quenching by using [gamma-(32)P]ATP filter binding. For the Rho mutant F355W, three tight (K(d)(1) = 3 +/- 0.3 microm) and three loose (K(d)(2) = 58 +/- 3 microm) ATP-binding sites per hexamer were seen on Scatchard analysis in the absence of bicyclomycin and poly(C). In the presence of bicyclomycin, the K(d)(1) changed from 3.0 to 1.4 microm, but K(d)(2) underwent a lesser change. The non-hydrolyzable ATP analogue, gamma-S-ATP, gave a similar profile with three tight (K(d)(1) = 0.2 microm) and three loose (K(d)(2) = 70 microm) ATP-binding sites per hexamer. Adding poly(C) to F355W did not alter the K(d)(1) or K(d)(2) for ATP or for gamma-S-ATP. ADP-induced quenching produced 5.5 loose (K(d) = 92 microm) binding sites in the absence of poly(C), and the binding became weaker (K(d) = 175 microm) in the presence of poly(C). The data suggest that in the presence of ADP Rho has six equivalent nucleotide-binding sites. When ATP was added these sites converted to three tight and three loose binding loci. We propose an alternating ATP site mechanism where ATP binding creates heterogeneity in the ATP binding in adjacent subunits, and we suggest that ATP binding to a neighboring loose site stimulates hydrolysis at a neighboring tight binding site such that all six subunits can be potential "active" sites for ATP hydrolysis. The dynamic nature of the ATP binding to Rho is discussed in the terms of the mechanism of RNA tracking driven by ATP hydrolysis.

Rho-dependent termination and ATPases in transcript termination

Transcription factor Rho is a ring-shaped, homohexameric protein that causes transcript termination through actions on nascent RNAs that are coupled to ATP hydrolysis. The Rho polypeptide has a distinct RNA-binding domain (RNA-BD) of known structure as well as an ATP-binding domain (ATP-BD) for which a structure has been proposed based on homology modeling. A model is proposed in which Rho first makes an interaction with a nascent RNA on a C-rich, primarily single-stranded rut region of the transcript as that region emerges from the exit site of RNA polymerase. A subsequent step involves a temporary release of one subunit of the hexamer to allow the 3' segment of the nascent transcript to enter the central channel of the Rho ring. Actions of the Rho structure in the channel on the 3' segment that are coupled to ATP hydrolysis pull the RNA from its contacts with the template and RNA polymerase, thus causing termination of its synthesis.

Flexibility of the rings: structural asymmetry in the DnaB hexameric helicase

DnaB is the primary replicative helicase in Escherichia coli and the hexameric DnaB ring has previously been shown to exist in two states in the presence of nucleotides. In one, all subunits are equivalent, while in the other, there are two different subunit conformations resulting in a trimer of dimers. Under all conditions that we have used for electron microscopy, including the absence of nucleotide, some rings exist as trimers of dimers, showing that the symmetry of the DnaB hexamer can be broken prior to nucleotide binding. Three-dimensional reconstructions reveal that the N-terminal domain of DnaB makes two very different contacts with neighboring subunits in the trimer of dimers, but does not form a predicted dimer with a neighboring N-terminal domain. Within the trimer of dimers, the helicase domain exists in two alternate conformations, each of which can form symmetrical hexamers depending upon the nucleotide cofactor used. These results provide new information about the modular architecture and domain dynamics of helicases, and suggest, by comparison with the hexameric bacteriophage T7 gp4 and SV40 large T-antigen helicases, that a great structural and mechanistic diversity may exist among the hexameric helicases.

The Methanobacterium thermoautotrophicum MCM protein can form heptameric rings

Mini-chromosome maintenance (MCM) proteins form a conserved family found in all eukaryotes and are essential for DNA replication. They exist as heteromultimeric complexes containing as many as six different proteins. These complexes are believed to be the replicative helicases, functioning as hexameric rings at replication forks. In most archaea a single MCM protein exists. The protein from Methanobacterium thermoautotrophicum (mtMCM) has been reported to assemble into a large complex consistent with a dodecamer. We show that mtMCM can assemble into a heptameric ring. This ring contains a C-terminal helicase domain that can be fit with crystal structures of ring helicases and an N-terminal domain of unknown function. While the structure of the ring is very similar to that of hexameric replicative helicases such as bacteriophage T7 gp4, our results show that such ring structures may not be constrained to have only six subunits.

Transcription termination and anti-termination in E. coli

Transcription termination in Escherichia coli is controlled by many factors. The sequence of the DNA template, the structure of the transcript, and the actions of auxiliary proteins all play a role in determining the efficiency of the process. Termination is regulated and can be enhanced or suppressed by host and phage proteins. This complex reaction is rapidly yielding to biochemical and structural analysis of the interacting factors. Below we review and attempt to unify into basic principles the remarkable recent progress in understanding transcription termination and anti-termination.

The hexameric ring structure of the Escherichia coli RuvB branch migration protein

The RuvB protein is part of the homologous recombination machinery in prokaryotic cells. Many studies have shown that RuvB is organized into hexameric rings functioning as DNA pumps at Holliday junctions, using ATP hydrolysis to drive branch migration. Structures now exist for two RuvB proteins, as well as for several structurally homologous proteins, including the replication factor-C small subunit (RFCS). Two models for the possible hexameric organization of RuvB subunits have been proposed, based upon the hexameric structures of NSF and HslU, two AAA-ATPases involved in vesicle fusion and proteolysis, respectively. We have used electron microscopy to generate an improved three-dimensional reconstruction of the double hexamers formed by Escherichia coli RuvB on double-stranded DNA. We find that an atomic model of the hexameric RFCS provides a significantly better fit to the RuvB hexamer than do the models for RuvB generated from NSF and HslU. This suggests that there may be a highly conserved structure for many proteins involved in different aspects of DNA replication, recombination, transcription and repair.

Electron microscopic studies of the translin octameric ring

Translin is thought to participate in a variety of cellular activities including chromosomal translocations, translational regulation of mRNA expression, and mRNA transport. It forms an octameric ring structure capable of sequence-specific binding of both DNA and RNA substrates. We have used electron microscopy and single-particle image analysis to generate a three-dimensional reconstruction of the Translin ring. The subunits appear to have two distinct domains that assemble to form an open channel with diameter of approximately 30 A at one end and approximately 50 A at the opposite end. In the presence of either DNA or RNA containing consensus binding sequences, the largest opening into the central cavity is filled with density. Strikingly, although Translin shows significant sequence homology to only one other protein, Translin-associated factor X, the quaternary organization and the dimerization of subunits in the ring are very similar to those observed for hexameric ring helicases. This suggests that many of the structures in DNA and RNA metabolism may have similar quaternary organization.

Identification of an RNA-binding Site in the ATP binding domain of Escherichia coli Rho by H2O2/Fe-EDTA cleavage protection studies

Transcription factor Rho is a ring-shaped, homohexameric protein that causes transcript termination through actions on nascent RNAs that are coupled to ATP hydrolysis. The Rho polypeptide has a distinct RNA binding domain of known structure as well as an ATP binding domain for which a structure has been proposed based on homology modeling. Treatment of Rho with H2O2 in the presence of Fe-EDTA caused single-cut cleavage at a number of points that coincide with solvent-exposed loops in both the known and predicted structures, thereby providing support for the validity of the tertiary and quaternary structural models of Rho. The binding of ATP caused one distinct change in the cleavage pattern, a strong protection at a cleavage point in the P-loop of the ATP binding domain. Binding of RNA and single-stranded DNA (poly(dC)) caused strong protection at several accessible parts of the oligosaccharide/oligonucleotide binding (OB) fold in the RNA binding domain. RNA molecules but not DNA molecules also caused a strong, ATP-dependent protection at a cleavage site in the predicted Q-loop of the ATP binding domain. These results suggest that Rho has two distinct binding sites for RNA. Besides the site composed of multiples of the RNA binding domain, to which single-stranded DNA as well as RNA can bind, it has a separate, RNA-specific site on the Q-loop in the ATP binding domain. In the proposed quaternary structure of Rho, the Q-loops from the six subunits form the upper entrance to the hole in the ring-shaped hexamer through which the nascent transcript is translocated by actions coupled to ATP hydrolyses.

RNA passes through the hole of the protein hexamer in the complex with the Escherichia coli Rho factor

Escherichia coli transcription termination factor Rho is a ring-shaped hexameric protein that uses the energy derived from ATP hydrolysis to dissociate RNA transcripts from the ternary elongation complex. To test a current model for the interaction of Rho with RNA, three derivatives of Rho were made containing single cysteine residues and modified with a photo-activable cross-linker. The positions for the cysteines were: 1) in part of the primary RNA-binding site in the N terminus (Cys-82 Rho); 2) in a connecting polypeptide proposed to be on the outside of the hexamer (Cys-153 Rho); and 3) near the proposed secondary RNA-binding site in the ATP-binding domain (Cys-325 Rho). Results from the cross-linking of the modified Rho proteins to a series of lambda cro RNA derivatives showed that Cys-82 Rho formed cross-links with all transcripts containing the Rho utilization (rut) site, that Cys-325 Rho formed cross-links to transcripts that had the rut site and 10 or more residues 3' of the rut site, and that Cys-153 did not form cross-links with any of the transcripts. From a model of the quaternary structure of Rho, which is largely based on homology to the F(1)-ATPase, amino acid 82 is located near the top of the hexamer, and amino acid 325 is located on a solvent-accessible loop in the center of the hexamer. These data are consistent with binding of the rut region of RNA around the crown, with its 3'-segment passing through the center of the Rho hexamer.

A tale of toroids in DNA metabolism

A strikingly large number of the proteins involved in DNA metabolism adopt a toroidal -- or ring-shaped -- quaternary structure, even though they have completely unrelated functions. Given that these proteins all use DNA as a substrate, their convergence to one shape is probably not a coincidence. Ring-forming proteins may have been selected during evolution for advantages conferred by the toroidal shape on their interactions with DNA.