A stepwise 2'-hydroxyl activation mechanism for the bacterial transcription termination factor Rho helicase

A scalable framework for the discovery of functional helicase substrates and helicase-driven regulatory switches

Helicases are ubiquitous motor enzymes that remodel nucleic acids (NA) and NA-protein complexes in key cellular processes. To explore the functional repertoire and specificity landscape of helicases, we devised a screening scheme-Helicase-SELEX (Systematic Evolution of Ligands by EXponential enrichment)-that enzymatically probes substrate and cofactor requirements at global scale. Using the transcription termination Rho helicase of Escherichia coli as a prototype for Helicase-SELEX, we generated a genome-wide map of Rho utilization (Rut) sites. The map reveals many features, including promoter- and intrinsic terminator-associated Rut sites, bidirectional Rut tandems, and cofactor-dependent Rut sites with inverted G > C skewed compositions. We also implemented an H-SELEX variant where we used a model ligand, serotonin, to evolve synthetic Rut sites operating in vitro and in vivo in a ligand-dependent manner. Altogether, our data illustrate the power and flexibility of Helicase-SELEX to seek constitutive or conditional helicase substrates in natural or synthetic NA libraries for fundamental or synthetic biology discovery.

A Simple Fluorescence Microplate Assay to Monitor RNA-DNA Hybrid Unwinding by the Bacterial Transcription Termination Factor Rho

Transcription termination factor Rho contributes to shape the transcriptomes of many bacteria and is essential in a large subset of them. Although the transcription termination function of Rho is not always easy to reconstitute and to study in vitro, assays based on the ATP-dependent RNA-DNA hybrid unwinding activity of the factor can prove useful to dissect Rho mechanisms or to seek new antibiotics targeting Rho. However, current in vitro assays of Rho helicase activity are time-consuming, as they usually require radiolabeling of the hybrid substrates and analysis of reaction products by gel electrophoresis. Here, we describe a fluorescence-based microplate assay that informs on Rho helicase activity in a matter of minutes and allows the multiplexed analysis of conditions required for primary biochemical characterization or for drug screening.

Hexameric helicase G40P unwinds DNA in single base pair steps

Most replicative helicases are hexameric, ring-shaped motor proteins that translocate on and unwind DNA. Despite extensive biochemical and structural investigations, how their translocation activity is utilized chemo-mechanically in DNA unwinding is poorly understood. We examined DNA unwinding by G40P, a DnaB-family helicase, using a single-molecule fluorescence assay with a single base pair resolution. The high-resolution assay revealed that G40P by itself is a very weak helicase that stalls at barriers as small as a single GC base pair and unwinds DNA with the step size of a single base pair. Binding of a single ATPγS could stall unwinding, demonstrating highly coordinated ATP hydrolysis between six identical subunits. We observed frequent slippage of the helicase, which is fully suppressed by the primase DnaG. We anticipate that these findings allow a better understanding on the fine balance of thermal fluctuation activation and energy derived from hydrolysis.

Living cells store their genetic code written in molecules of DNA, with two strands of DNA twisted together to form the familiar double helix. When a cell prepares to divide, it must unwind its DNA so that the individual strands can be copied. Enzymes known as DNA helicases play a vital role in this unwinding process; yet, it is not completely clear how these enzymes move along the DNA.

Schlierf et al. have now developed a new approach to see how an individual DNA helicase called G40P unwinds the DNA double helix. The experiments used a molecular ruler to measure the DNA unwinding and showed that the helicase opened the double helix one letter of genetic code at a time. Also, specific sequence of letters within the DNA molecules could slow down and stop G40P or even cause it to move backwards.

DNA helicases work closely with other proteins inside cells to perform their task. DNA primases, for example, are enzymes that create the starting points for making new strands of DNA. Schlierf et al. found that the primase DnaG could also prevent G40P from moving backwards on the DNA, a new and unexpected function of DnaG.

These findings contribute to an ongoing debate among researchers with partially contradictory models for how DNA helicases unwind the DNA double helix. Although originally from a virus, G40P is similar to a helicase enzyme found in bacteria. Therefore, a better understanding of this helicase may lead to new ways to stop bacteria copying their DNA, which might one day become new antibiotics to treat bacterial infections.

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.

Learning from the Leaders: Gene Regulation by the Transcription Termination Factor Rho

The RNA helicase Rho triggers 20-30% of transcription termination events in bacteria. While Rho is associated with most transcription elongation complexes, it only promotes termination of a subset. Recent studies of individual Rho-dependent terminators located within the 5' leader regions of bacterial mRNAs have identified novel mechanisms that govern Rho target specificity and have revealed unanticipated physiological functions for Rho. In particular, the multistep nature of Rho-dependent termination enables regulatory input from determinants beyond the sequence of the Rho loading site, and allows a given Rho-dependent terminator to respond to multiple signals. Further, the unique position of Rho as a sensor of cellular translation has been exploited to regulate the transcription of genes required for protein synthesis, including those specifying Mg(2+) transporters.

Mechanisms of Bacterial Transcription Termination: All Good Things Must End

Transcript termination is essential for accurate gene expression and the removal of RNA polymerase (RNAP) at the ends of transcription units. In bacteria, two mechanisms are responsible for proper transcript termination: intrinsic termination and Rho-dependent termination. Intrinsic termination is mediated by signals directly encoded within the DNA template and nascent RNA, whereas Rho-dependent termination relies upon the adenosine triphosphate-dependent RNA translocase Rho, which binds nascent RNA and dissociates the elongation complex. Although significant progress has been made in understanding these pathways, fundamental details remain undetermined. Among those that remain unresolved are the existence of an inactivated intermediate in the intrinsic termination pathway, the role of Rho-RNAP interactions in Rho-dependent termination, and the mechanisms by which accessory factors and nucleoid-associated proteins affect termination. We describe current knowledge, discuss key outstanding questions, and highlight the importance of defining the structural rearrangements of RNAP that are involved in the two mechanisms of transcript termination.

Mechanism of substrate translocation by a ring-shaped ATPase motor at millisecond resolution

Ring-shaped, hexameric ATPase motors fulfill key functions in cellular processes, such as genome replication, transcription, or protein degradation, by translocating a long substrate through their central pore powered by ATP hydrolysis. Despite intense research efforts, the atomic-level mechanism transmitting chemical energy from hydrolysis into mechanical force that translocates the substrate is still unclear. Here we employ all-atom molecular dynamics simulations combined with advanced path sampling techniques and milestoning analysis to characterize how mRNA substrate is translocated by an exemplary homohexameric motor, the transcription termination factor Rho. We find that the release of hydrolysis product (ADP + Pi) triggers the force-generating process of Rho through a 0.1 millisecond-long conformational transition, the time scale seen also in experiment. The calculated free energy profiles and kinetics show that Rho unidirectionally translocates the single-stranded RNA substrate via a population shift of the conformational states of Rho; upon hydrolysis product release, the most favorable conformation shifts from the pretranslocation state to the post-translocation state. Via two previously unidentified intermediate states, the RNA chain is seen to be pulled by six K326 side chains, whose motions are induced by highly coordinated relative translation and rotation of Rho's six subunits. The present study not only reveals in new detail the mechanism employed by ring-shaped ATPase motors, for example the use of loosely bound and tightly bound hydrolysis reactant and product states to coordinate motor action, but also provides an effective approach to identify allosteric sites of multimeric enzymes in general.

Direct observation of the translocation mechanism of transcription termination factor Rho

Rho is a ring-shaped, ATP-fueled motor essential for remodeling transcriptional complexes and R-loops in bacteria. Despite years of research on this fundamental model helicase, key aspects of its mechanism of translocation remain largely unknown. Here, we used single-molecule manipulation and fluorescence methods to directly monitor the dynamics of RNA translocation by Rho. We show that the efficiency of Rho activation is strongly dependent on the force applied on the RNA but that, once active, Rho is able to translocate against a large opposing force (at least 7 pN) by a mechanism involving ‘tethered tracking’. Importantly, the ability to directly measure dynamics at the single-molecule level allowed us to determine essential motor properties of Rho. Hence, Rho translocates at a rate of ∼56 nt per second under our experimental conditions, which is 2–5 times faster than velocities measured for RNA polymerase under similar conditions. Moreover, the processivity of Rho (∼62 nt at a 7 pN opposing force) is large enough for Rho to reach termination sites without dissociating from its RNA loading site, potentially increasing the efficiency of transcription termination. Our findings unambiguously establish ‘tethered tracking’ as the main pathway for Rho translocation, support ‘kinetic coupling’ between Rho and RNA polymerase during Rho-dependent termination, and suggest that forces applied on the nascent RNA transcript by cellular substructures could have important implications for the regulation of transcription and its coupling to translation in vivo.

The RNA-mediated, asymmetric ring regulatory mechanism of the transcription termination Rho helicase decrypted by time-resolved nucleotide analog interference probing (trNAIP)

Rho is a ring-shaped, ATP-dependent RNA helicase/translocase that dissociates transcriptional complexes in bacteria. How RNA recognition is coupled to ATP hydrolysis and translocation in Rho is unclear. Here, we develop and use a new combinatorial approach, called time-resolved Nucleotide Analog Interference Probing (trNAIP), to unmask RNA molecular determinants of catalytic Rho function. We identify a regulatory step in the translocation cycle involving recruitment of the 2′-hydroxyl group of the incoming 3′-RNA nucleotide by a Rho subunit. We propose that this step arises from the intrinsic weakness of one of the subunit interfaces caused by asymmetric, split-ring arrangement of primary RNA tethers around the Rho hexamer. Translocation is at highest stake every seventh nucleotide when the weak interface engages the incoming 3′-RNA nucleotide or breaks, depending on RNA threading constraints in the Rho pore. This substrate-governed, ‘test to run’ iterative mechanism offers a new perspective on how a ring-translocase may function or be regulated. It also illustrates the interest and versatility of the new trNAIP methodology to unveil the molecular mechanisms of complex RNA-based systems.

Single-molecule fluorescence reveals the unwinding stepping mechanism of replicative helicase

Bacteriophage T7 gp4 serves as a model protein for replicative helicases that couples deoxythymidine triphosphate (dTTP) hydrolysis to directional movement and DNA strand separation. We employed single-molecule fluorescence resonance energy transfer methods to resolve steps during DNA unwinding by T7 helicase. We confirm that the unwinding rate of T7 helicase decreases with increasing base pair stability. For duplexes containing >35% guanine-cytosine (GC) base pairs, we observed stochastic pauses every 2–3 bp during unwinding. The dwells on each pause were distributed nonexponentially, consistent with two or three rounds of dTTP hydrolysis before each unwinding step. Moreover, we observed backward movements of the enzyme on GC-rich DNAs at low dTTP concentrations. Our data suggest a coupling ratio of 1:1 between base pairs unwound and dTTP hydrolysis, and they further support the concept that nucleic acid motors can have a hierarchy of different-sized steps or can accumulate elastic energy before transitioning to a subsequent phase.

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Single DNA unwinding assay recapitulates sequence-dependent unwinding

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High-resolution data reveal an unwinding step size of 2–3 bp

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Two or three hidden steps precede the unwinding step, suggesting 1:1 chemical coupling

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1:1 coupling is maintained at low dNTP, but helicase often slips backward

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.

Elastic coupling between RNA degradation and unwinding by an exoribonuclease

Rrp44 (Dis3) is a key catalytic subunit of the yeast exosome complex and can processively digest structured RNA one nucleotide at a time in the 3' to 5' direction. Its motor function is powered by the energy released from the hydrolytic nuclease reaction instead of adenosine triphosphate hydrolysis as in conventional helicases. Single-molecule fluorescence analysis revealed that instead of unwinding RNA in single base pair steps, Rrp44 accumulates the energy released by multiple single nucleotide step hydrolysis reactions until about four base pairs are unwound in a burst. Kinetic analyses showed that RNA unwinding, not cleavage or strand release, determines the overall RNA degradation rate and that the unwinding step size is determined by the nonlinear elasticity of the Rrp44/RNA complex, but not by duplex stability.

Binding and translocation of termination factor rho studied at the single-molecule level

Rho termination factor is an essential hexameric helicase responsible for terminating 20-50% of all mRNA synthesis in Escherichia coli. We used single-molecule force spectroscopy to investigate Rho-RNA binding interactions at the Rho utilization site of the λtR1 terminator. Our results are consistent with Rho complexes adopting two states: one that binds 57 ± 2nt of RNA across all six of the Rho primary binding sites, and another that binds 85 ± 2nt at the six primary sites plus a single secondary site situated at the center of the hexamer. The single-molecule data serve to establish that Rho translocates 5'→3' toward RNA polymerase (RNAP) by a tethered-tracking mechanism, looping out the intervening RNA between the Rho utilization site and RNAP. These findings lead to a general model for Rho binding and translocation and establish a novel experimental approach that should facilitate additional single-molecule studies of RNA-binding proteins.

Keeping up to speed with the transcription termination factor Rho motor

In bacteria, a subset of transcription termination events requires the participation of the transcription termination factor Rho. Rho is a homo-hexameric, ring-shaped, motor protein that uses the energy derived from its RNA-dependent ATPase activity to directionally unwind RNA and RNA-DNA helices and to dissociate transcription elongation complexes. Despite a wealth of structural, biochemical and genetic data, the molecular mechanisms used by Rho to carry out its biological functions remain poorly understood. Here, we briefly discuss the most recent findings on Rho mechanisms and function and highlight important questions that remain to be addressed.

Suppression of in vivo Rho-dependent transcription termination defects: evidence for kinetically controlled steps

The conventional model of Rho-dependent transcription termination in bacteria requires RNA-dependent translocase activity of the termination factor Rho as well as many kinetically controlled steps to execute efficient RNA release from the transcription elongation complex (EC). The involvement of the kinetically controlled steps, such as RNA binding, translocation and RNA release from the EC, means that this termination process must be kinetically coupled to the transcription elongation process. The existence of these steps in vivo has not previously been delineated in detail. Moreover, the requirement for translocase activity in Rho-dependent termination has recently been questioned by a radical view, wherein Rho binds to the elongating RNA polymerase (RNAP) prior to loading onto the mRNA. Using growth assays, microarray analyses and reporter-based transcription termination assays in vivo, we showed that slowing of the transcription elongation rate by using RNAP mutants (rpoB8 and rpoB3445) and growth of the strains in minimal medium suppressed the termination defects of five Rho mutants, three NusG mutants defective for Rho binding and the defects caused by two Rho inhibitors, Psu and bicyclomycin. These results established the existence of kinetically controlled steps in the in vivo Rho-dependent termination process and further reinforced the importance of 'kinetic coupling' between the two molecular motors, Rho and RNAP, and also argue strongly that the Rho translocation model is an accurate representation of the in vivo situation. Finally, these results indicated that one of the major roles of NusG in in vivo Rho-dependent termination is to enhance the speed of RNA release from the EC.

Deciphering the plant splicing code: experimental and computational approaches for predicting alternative splicing and splicing regulatory elements

Extensive alternative splicing (AS) of precursor mRNAs (pre-mRNAs) in multicellular eukaryotes increases the protein-coding capacity of a genome and allows novel ways to regulate gene expression. In flowering plants, up to 48% of intron-containing genes exhibit AS. However, the full extent of AS in plants is not yet known, as only a few high-throughput RNA-Seq studies have been performed. As the cost of obtaining RNA-Seq reads continues to fall, it is anticipated that huge amounts of plant sequence data will accumulate and help in obtaining a more complete picture of AS in plants. Although it is not an onerous task to obtain hundreds of millions of reads using high-throughput sequencing technologies, computational tools to accurately predict and visualize AS are still being developed and refined. This review will discuss the tools to predict and visualize transcriptome-wide AS in plants using short-reads and highlight their limitations. Comparative studies of AS events between plants and animals have revealed that there are major differences in the most prevalent types of AS events, suggesting that plants and animals differ in the way they recognize exons and introns. Extensive studies have been performed in animals to identify cis-elements involved in regulating AS, especially in exon skipping. However, few such studies have been carried out in plants. Here, we review the current state of research on splicing regulatory elements (SREs) and briefly discuss emerging experimental and computational tools to identify cis-elements involved in regulation of AS in plants. The availability of curated alternative splice forms in plants makes it possible to use computational tools to predict SREs involved in AS regulation, which can then be verified experimentally. Such studies will permit identification of plant-specific features involved in AS regulation and contribute to deciphering the splicing code in plants.

Analysis of helicase-RNA interactions using nucleotide analog interference mapping

Nucleotide analog interference mapping (NAIM) is a combinatorial approach that probes individual atoms and functional groups in an RNA molecule and identifies those that are important for a specific biochemical function. Here, we show how NAIM can be adapted to reveal functionally important atoms and groups on RNA substrates of helicases. We explain how NAIM can be used to investigate translocation and unwinding mechanisms of helicases and discuss the advantages and limitations of this powerful chemogenetic approach.

RNA helicases and remodeling proteins

It is becoming increasingly clear that RNA molecules play a major role in all aspects of metabolism. The conformational state and stability of RNA are controlled by RNA remodeling proteins, which are ubiquitous motor proteins in the cell. Here, we review advances in our understanding of the structure and function of three major structural families of RNA remodeling proteins, the hexameric ring proteins, the processive monomeric RNA translocase/helicases, and the functionally diverse DEAD-box remodeling proteins. New studies have revealed molecular mechanisms for coupling between ATP hydrolysis and unwinding, the physical basis for regulatory control by cofactors, and novel functions for RNA remodeling proteins.

The nuts and bolts of ring-translocase structure and mechanism

Ring-shaped, oligomeric translocases are multisubunit enzymes that couple the hydrolysis of Nucleoside TriPhosphates (NTPs) to directed movement along extended biopolymer substrates. These motors help unwind nucleic acid duplexes, unfold protein chains, and shepherd nucleic acids between cellular and/or viral compartments. Substrates are translocated through a central pore formed by a circular array of catalytic subunits. Cycles of nucleotide binding, hydrolysis, and product release help reposition translocation loops in the pore to direct movement. How NTP turnover allosterically induces these conformational changes, and the extent of mechanistic divergence between motor families, remain outstanding problems. This review examines the current models for ring-translocase function and highlights the fundamental gaps remaining in our understanding of these molecular machines.

Evidence for a DNA-Based Mechanism of Intron-Mediated Enhancement

Many introns significantly increase gene expression through a process termed intron-mediated enhancement (IME). Introns exist in the transcribed DNA and the nascent RNA, and could affect expression from either location. To determine which is more relevant to IME, hybrid introns were constructed that contain sequences from stimulating Arabidopsis thaliana introns either in their normal orientation or as the reverse complement. Both ends of each intron are from the non-stimulatory COR15a intron in their normal orientation to allow splicing. The inversions create major alterations to the sequence of the transcribed RNA with relatively minor changes to the DNA structure. Introns containing portions of either the UBQ10 or ATPK1 intron increased expression to a similar degree regardless of orientation. Also, computational predictions of IME improve when both intron strands are considered. These findings are more consistent with models of IME that act at the level of DNA rather than RNA.

Nuclear mRNA quality control in yeast is mediated by Nrd1 co-transcriptional recruitment, as revealed by the targeting of Rho-induced aberrant transcripts

The production of mature export-competent transcripts is under the surveillance of quality control steps where aberrant mRNP molecules resulting from inappropriate or inefficient processing and packaging reactions are subject to exosome-mediated degradation. Previously, we have shown that the heterologous expression of bacterial Rho factor in yeast interferes in normal mRNP biogenesis leading to the production of full-length yet aberrant transcripts that are degraded by the nuclear exosome with ensuing growth defect. Here, we took advantage of this new tool to investigate the molecular mechanisms by which an integrated system recognizes aberrancies at each step of mRNP biogenesis and targets the defective molecules for destruction. We show that the targeting and degradation of Rho-induced aberrant transcripts is associated with a large increase of Nrd1 recruitment to the transcription complex via its CID and RRM domains and a concomitant enrichment of exosome component Rrp6 association. The targeting and degradation of the aberrant transcripts is suppressed by the overproduction of Pcf11 or its isolated CID domain, through a competition with Nrd1 for recruitment by the transcription complex. Altogether, our results support a model in which a stimulation of Nrd1 co-transcriptional recruitment coordinates the recognition and removal of aberrant transcripts by promoting the attachment of the nuclear mRNA degradation machinery.

Mutagenesis-based evidence for an asymmetric configuration of the ring-shaped transcription termination factor Rho

Transcription termination factor Rho is an ATP-dependent ring-shaped molecular motor that tracks along RNA to dissociate RNA-DNA duplexes and transcription complexes in its path. The Rho hexamer contains two distinct sites for interaction with RNA. The primary binding site is composed of pyrimidine-specific binding clefts that are located in the N-terminal domains and anchor Rho to transcripts at C-rich Rut (Rho utilization) sites. Components of the secondary binding site (SBS) in the C-terminal domains directly couple RNA binding to ATP hydrolysis in order to translocate RNA through the Rho ring. Published crystal structures of RNA-bound Rho display distinct architectures ('trimer-of-dimers' or asymmetric hexamer) and SBS-RNA interaction networks that suggested conflicting models of RNA "handoff" or "escort" by the Rho subunits. To probe the mechanism of mechanochemical transduction in Rho, we have mutated into alanines (or glycines) the residues that make SBS contacts with RNA in the 'trimer-of-dimers' structure supporting the "handoff" model. We find that the resulting single-point mutants have similar RNA binding affinities but exhibit significantly different ATP hydrolysis, transcription termination, and RNA-DNA unwinding activities that are more compatible with the asymmetric Rho structure than with the 'trimer-of-dimers' structure and the resulting "handoff" model. We discuss our findings in connection with specific features of the asymmetric Rho structure yet argue that a simple RNA "escort" model is insufficient to account for all experimental evidence.

Conformation changes in E. coli Rho monitored by hydrogen/deuterium exchange and mass spectrometry: response to ligand binding

Escherichia coli Rho is a doughnut-shaped homohexameric ATP-dependent RNA-DNA helicase that releases newly synthesized RNA molecules from transcription complexes. Rho binds 60-80 bases of RNA among six primary RNA binding sites around the inside of its N-terminal crown; the RNA then passes through the central hole of the hexamer. Here it triggers ATP hydrolysis and is moved with respect to the protein. We study protein conformation changes upon ligand binding using amide proton hydrogen/deuterium exchange and mass spectrometry. Global-exchange studies indicate net mass differences of about 15 Da after 1 h of exchange in the presence--versus in the absence--of the ligand MgATP or the RNA poly(C). Sites of ligand-dependent exchange differences were localized by mass determination of the peptic peptides of Rho. A peptide of the N-terminal domain near the known primary RNA sites (aa 56-63) was protected from amide proton exchange in the presence of poly(C), as was a novel N-terminal domain peptide that is not near RNA in the crystal structures or in NMR structures with RNA oligomers (aa 37-46). This result may further define the primary interaction site of RNA with Rho. The Q-loop-containing peptide in the central hole of the protein that interacts with RNA was also protected by RNA (aa 271-286). The exchange rate of one peptide near the ATPase active site (aa 206-218) slowed in the presence of MgATP and increased in the presence of RNA. Overall, the results show changes in a few protein segments rather than a different overall conformation.

Application of an inducible system to engineer unmarked conditional mutants of essential genes of Pseudomonas aeruginosa

The Phi CTX-based integration vector pYM101 harboring a tightly controlled modified phage T7 early gene promoter/LacI(q) repressor (T7/LacI) system was constructed for the generation of unmarked conditional mutants in Pseudomonas aeruginosa. Promoter activity of the T7/LacI system was demonstrated to be dependent on the presence of the inducer isopropyl -beta-D-1-thiogalactopyranoside (IPTG), as evaluated by measuring beta-galactosidase activity. In the absence of the inducer, the promoter was silent as its activity was lower than those of a promoter-less lacZ control. Unmarked conditional mutants of four predicted essential genes (lolCDE (PA2988-86), lpxC (PA4406), rho (PA5239), and def (PA0019)) were successfully constructed using this recombination system. In the absence of IPTG, the growth of all mutants was repressed; however, the addition of either 0.1 or 1mM IPTG restored growth rates to levels nearly identical to wild-type cells. It was therefore demonstrated that the inducible integration vector pYM101 is suitable for the creation of unmarked conditional mutants of P. aeruginosa, and is particularly useful for examining the function of essential genes.

A prehydrolysis state of an AAA+ ATPase supports transcription activation of an enhancer-dependent RNA polymerase

ATP hydrolysis-dependent molecular machines and motors often drive regulated conformational transformations in cell signaling and gene regulation complexes. Conformational reorganization of a gene regulation complex containing the major variant form of bacterial RNA polymerase (RNAP), Esigma(54), requires engagement with its cognate ATP-hydrolyzing activator protein. Importantly, this activated RNAP is essential for a number of adaptive responses, including those required for bacterial pathogenesis. Here we characterize the initial encounter between the enhancer-dependent Esigma(54) and its cognate activator AAA+ ATPase protein, before ADP+P(i) formation, using a small primed RNA (spRNA) synthesis assay. The results show that in a prehydrolysis state, sufficient activator-dependent rearrangements in Esigma(54) have occurred to allow engagement of the RNAP active site with single-stranded promoter DNA to support spRNA synthesis, but not to melt the promoter DNA. This catalytically competent transcription intermediate has similarity with the open promoter complex, in that the RNAP dynamics required for DNA scrunching should be occurring. Significantly, this work highlights that prehydrolysis states of ATPases are functionally important in the molecular transformations they drive.

The NPH-II helicase displays efficient DNA x RNA helicase activity and a pronounced purine sequence bias

The superfamily 2 vaccinia viral helicase nucleoside triphosphate phosphohydrolase-II (NPH-II) exhibits robust RNA helicase activity but typically displays little activity on DNA substrates. NPH-II is thus believed to make primary contacts with backbone residues of an RNA substrate. We report an unusual nucleobase bias, previously unreported in any superfamily 1 or 2 helicase, whereby purines are heavily preferred as components of both RNA and DNA tracking strands. The observed sequence bias allows NPH-II to efficiently unwind a DNA x RNA hybrid containing a purine-rich DNA track derived from the 3'-untranslated region of an early vaccinia gene. These results provide insight into potential biological functions of NPH-II and the role of sequence in targeting NPH-II to appropriate substrates. Furthermore, they demonstrate that in addition to backbone contacts, nucleotide bases play an important role in modulating the behavior of NPH-II. They also establish that processive helicase enzymes can display sequence selectivity.