Unwinding initiation by the viral RNA helicase NPH-II

Viral RNA helicases of the NS3/NPH-II group unwind RNA duplexes by processive, directional translocation on one of the duplex strands. The translocation is preceded by a poorly understood unwinding initiation phase. For NPH-II from vaccinia virus, unwinding initiation is rate limiting for the overall unwinding reaction. To develop a mechanistic understanding of the unwinding initiation, we studied kinetic and thermodynamic aspects of this reaction phase for NPH-II in vitro, using biochemical and single molecule fluorescence approaches. Our data show that NPH-II functions as a monomer and that different stages of the ATP hydrolysis cycle dictate distinct binding preferences of NPH-II for duplex versus single-stranded RNA. We further find that the NPH-II-RNA complex does not adopt a single conformation but rather at least two distinct conformations in each of the analyzed stages of ATP hydrolysis. These conformations interconvert with rate constants that depend on the stage of the ATP hydrolysis cycle. Our data establish a basic mechanistic framework for unwinding initiation by NPH-II and suggest that the various stages of the ATP hydrolysis cycle do not induce single, stage-specific conformations in the NPH-II-RNA complex but primarily control transitions between multiple states.     

Backbone tracking by the SF2 helicase NPH-II

Members of the DExH/D family of proteins, a subset of helicase superfamily 2 (SF2), are involved in virtually all aspects of RNA metabolism. NPH-II, a prototypical member of this protein family, exhibits robust RNA helicase activity in vitro. Using a series of modified substrates to explore the unwinding mechanism of NPH-II, we observed that the helicase tracks exclusively on the loading strand, where it requires covalent continuity and specifically recognizes the ribose-phosphate backbone. NPH-II unwinding was unaffected by lesions and nicks on the top strand, which has a minimal role in substrate recognition. NPH-II required physical continuity of phosphodiester linkages on the loading strand, although abasic regions were tolerated. These findings suggest that SF2 helicases are mechanistically distinct from other helicase families that can tolerate breaks in the loading strand and for which bases are the primary recognition determinant.     

The QRxGRxGRxxxG motif of the vaccinia virus DExH box RNA helicase NPH-II is required for ATP hydrolysis and RNA unwinding but not for RNA binding.

Vaccinia virus NPH-II is an essential nucleic acid-dependent nucleoside triphosphate that catalyzes unidirectional unwinding of duplex RNA containing a 3' tail. NPH-II is the prototypal RNA helicase of the DExH box protein family, which is defined by several shared sequence motifs. The contribution of the conserved QRKGRVGRVNPG region to enzyme activity was assessed by alanine-scanning mutagenesis. Ten mutated versions of NPH-II were expressed in vaccinia virus-infected BSC-40 cells and purified by nickel affinity chromatography and glycerol gradient sedimentation. The mutated proteins were characterized with respect to RNA helicase, nucleic acid-dependent ATPase, and RNA binding functions. Individual alanine substitutions at invariant residues Q-491, G-494, R-495, G-497, R-498, and G-502 caused severe defects in RNA unwinding that correlated with reduced rates of ATP hydrolysis. None of these mutations affected the binding of NPH-II to single-strand RNA or to the tailed duplex RNA used as a helicase substrate. Mutation of the strictly conserved position R-492 inhibited ATPase and helicase activities and also caused a modest decrement in RNA binding. Alanine mutations at the nonconserved position N-500 and the weakly conserved residue P-501 had no apparent effect on any activity associated with NPH-II, whereas a mutation at the weakly conserved position K-493 reduced helicase to one-third and ATPase to two-thirds of the activity of wild-type required for ATP hydrolysis and RNA unwinding but not for RNA binding. Because mutations in the HRxGRxxR motif of the prototypal DEAD box RNA helicase eIF-4A abolish or severely inhibit RNA binding, we surmise that the contribution of conserved helicase motifs to overall protein function is context dependent.     

DNA substrate specificity of DNA helicase E from calf thymus.

DNA helicase E from calf thymus has been characterized with respect to DNA substrate specificity. The helicase was capable of displacing DNA fragments up to 140 nucleotides in length, but was unable to displace a DNA fragment 322 nucleotides in length. DNA competition experiments revealed that helicase E was moderately processive for translocation on single strand M13mp18 DNA, and that the helicase would dissociate and rebind during a 15 minute reaction. Comparison of the rate of ATPase activity catalyzed by helicase E on single strand DNA substrates of different lengths, suggested a processivity consistent with the competition experiments. The helicase displayed a preference for displacing primers whose 5' terminus was fully annealed as opposed to primers with a 12 nucleotide 5' unannealed tail. The presence of a 12 nucleotide 3' tail had no effect on the rate of displacement. DNA helicase E was capable of displacing a primer downstream of either a four nucleotide gap, a one nucleotide gap or a nick in the DNA substrate. Helicase E was inactive on a fully duplex DNA 30 base pairs in length. Calf thymus RP-A stimulated the DNA displacement activity of helicase E. These properties are consistent with a role for DNA helicase E in chromosomal DNA repair.     

Vaccinia virus RNA helicase: nucleic acid specificity in duplex unwinding.

Vaccinia virus RNA helicase (NPH-II) catalyzes nucleoside triphosphate-dependent unwinding of duplex RNAs containing a single-stranded 3' RNA tail. In this study, we examine the structural features of the nucleic acid substrate that are important for helicase activity. Strand displacement was affected by the length of the 3' tail. Whereas NPH-II efficiently unwound double-stranded RNA substrates with 19- or 11-nucleotide (nt) 3' tails, shortening the 3' tail to 4 nt reduced unwinding by an order of magnitude. Processivity of the helicase was inferred from its ability to unwind a tailed RNA substrate containing a 96-bp duplex region. NPH-II exhibited profound asymmetry in displacing hybrid duplexes composed of DNA and RNA strands. A 34-bp RNA-DNA hybrid with a 19-nt 3' RNA tail was unwound catalytically, whereas a 34-bp DNA-RNA hybrid containing a 19-nt 3' DNA tail was 2 orders of magnitude less effective as a helicase substrate. NPH-II was incapable of displacing a 34-bp double-stranded DNA substrate of identical sequence. 3'-Tailed DNA molecules with 24- or 19-bp duplex regions were also inert as helicase substrates. On the basis of current models for RNA-DNA hybrid structures, we suggest the following explanation for these findings. (i) Unwinding of duplex nucleic acids by NPH-II is optimal when the polynucleotide strand of the duplex along which the enzyme translocates has adopted an A-form secondary structure, and (ii) a B-form secondary structure impedes protein translocation through DNA duplexes.     

Biochemical characterization of the DNA substrate specificity of Werner syndrome helicase

Werner syndrome is a hereditary premature aging disorder characterized by genome instability. The product of the gene defective in WS, WRN, is a helicase/exonuclease that presumably functions in DNA metabolism. To understand the DNA structures WRN acts upon in vivo, we examined its substrate preferences for unwinding. WRN unwound a 3'-single-stranded (ss)DNA-tailed duplex substrate with streptavidin bound to the end of the 3'-ssDNA tail, suggesting that WRN does not require a free DNA end to unwind the duplex; however, WRN was completely blocked by streptavidin bound to the 3'-ssDNA tail 6 nucleotides upstream of the single-stranded/double-stranded DNA junction. WRN efficiently unwound the forked duplex with streptavidin bound just upstream of the junction, suggesting that WRN recognizes elements of the fork structure to initiate unwinding. WRN unwound two important intermediates of replication/repair, a 5'-ssDNA flap substrate and a synthetic replication fork. WRN was able to translocate on the lagging strand of the synthetic replication fork to unwind duplex ahead of the fork. For the 5'-flap structure, WRN specifically displaced the 5'-flap oligonucleotide, suggesting a role of WRN in Okazaki fragment processing. The ability of WRN to target DNA replication/repair intermediates may be relevant to its role in genome stability maintenance.     

Human DNA helicase IV is nucleolin, an RNA helicase modulated by phosphorylation

The cDNA encoding human DNA helicase IV (HDH IV), a 100-kDa protein which unwinds DNA in the 5′ to 3′ direction with respect to the bound strand, was cloned and sequenced. It was found to be identical to the human cDNA encoding nucleolin, a ubiquitous eukaryotic protein essential for pre-ribosome assembly. HDH IV/nucleolin can unwind RNA-RNA duplexes, as well as DNA-DNA and DNA-RNA duplexes. Phosphorylation of HDH IV/nucleolin by cdc2 kinase and casein kinase II enhanced its unwinding activity in an additive way. The Gly-rich C-terminal domain possesses a limited ATP-dependent duplex-unwinding activity which contributes to the helicase activity of HDH IV/nucleolin.     

RECQL5 helicase: Connections to DNA recombination and RNA polymerase II transcription

The RecQ family of helicases are traditionally viewed as recombination factors, important for maintaining genome stability. RECQL5 is unique among these proteins in being associated with RNA polymerase II, the enzyme responsible for transcribing all protein-encoding genes in eukaryotes. Here, we describe the possible implications of recent studies and discuss models for RECQL5 function.     

Human DNA helicase VIII: a DNA and RNA helicase corresponding to the G3BP protein, an element of the ras transduction pathway.

Human DNA helicase VIII (HDH VIII) was isolated in the course of a systematic study of the DNA unwinding enzymes present in human cells. From a HeLa cell nuclear extract a protein with an Mrof 68 kDa in SDS-PAGE was isolated, characterised and micro-sequenced. The enzyme shows ATP- and Mg2+-dependent activity is not stimulated by RPA, prefers partially unwound 3'-tailed substrates and moves along the bound strand in the 5' to 3' direction. HDH VIII can also unwind partial RNA/DNA and RNA/RNA duplexes. Microsequencing of the polypeptide showed that this enzyme corresponds to G3BP, an element of the Ras pathway which binds specifically to the GTPase-activating protein. HDH VIII/G3BP is analogous to the heterogeneous nuclear ribonucleoproteins and contains a sequence rich in RGG boxes similar to the C-terminal domain of HDH IV/nucleolin, another DNA and RNA helicase.     

The yeast Pif1p DNA helicase preferentially unwinds RNA DNA substrates

Pif1p is the prototypical member of the PIF1 family of DNA helicases, a subfamily of SFI helicases conserved from yeast to humans. Baker's yeast Pif1p is involved in the maintenance of mitochondrial, ribosomal and telomeric DNA and may also have a general role in chromosomal replication by affecting Okazaki fragment maturation. Here we investigate the substrate preferences for Pif1p. The enzyme was preferentially active on RNA–DNA hybrids, as seen by faster unwinding rates on RNA–DNA hybrids compared to DNA–DNA hybrids. When using forked substrates, which have been shown previously to stimulate the enzyme, Pif1p demonstrated a preference for RNA–DNA hybrids. This preferential unwinding could not be correlated to preferential binding of Pif1p to the substrates that were the most readily unwound. Although the addition of the single-strand DNA-binding protein replication protein A (RPA) stimulated the helicase reaction on all substrates, it did not diminish the preference of Pif1p for RNA–DNA substrates. Thus, forked RNA–DNA substrates are the favored substrates for Pif1p in vitro. We discuss these findings in terms of the known biological roles of the enzyme.     

Mutations altering the interplay between GkDnaC helicase and DNA reveal an insight into helicase unwinding

Replicative helicases are essential molecular machines that utilize energy derived from NTP hydrolysis to move along nucleic acids and to unwind double-stranded DNA (dsDNA). Our earlier crystal structure of the hexameric helicase from Geobacillus kaustophilus HTA426 (GkDnaC) in complex with single-stranded DNA (ssDNA) suggested several key residues responsible for DNA binding that likely play a role in DNA translocation during the unwinding process. Here, we demonstrated that the unwinding activities of mutants with substitutions at these key residues in GkDnaC are 2-4-fold higher than that of wild-type protein. We also observed the faster unwinding velocities in these mutants using single-molecule experiments. A partial loss in the interaction of helicase with ssDNA leads to an enhancement in helicase efficiency, while their ATPase activities remain unchanged. In strong contrast, adding accessory proteins (DnaG or DnaI) to GkDnaC helicase alters the ATPase, unwinding efficiency and the unwinding velocity of the helicase. It suggests that the unwinding velocity of helicase could be modulated by two different pathways, the efficiency of ATP hydrolysis or protein-DNA interaction.     

Multiple Functions of Nuclear DNA Helicase Ⅱ （RNA Helicase A） in Nucleic Acid Metabolism

Secondary structures of nucleic acids play an importantrole in regulating their transactions as carriers of thegenetic information, including DNA replication, trans-cription, RNA processing, RNA transport, and translation.Resolving double-stranded (ds) DNA or RNA is usually anenergy-dependent process that can be accomplished byproteins termed DNA or RNA helicases, which are presentin all prokaryotic and eukaryotic organisms. Earlier attemptsto find mammalian helicases led to the detect…     

DnaB helicase affects the initiation specificity of Escherichia coli primase on single-stranded DNA templates

The effect of DnaB helicase on the initiation specificity of primase was studied biochemically using a series of single-stranded DNA templates in which each nucleotide of the trinucleotide d(CTG) initiation sequence was systematically varied. DnaB helicase accelerated the rate of primer syntheisis, prevented "overlong" primers from forming and decreased the initiation specificity of primase. In the presence of DnaB helicase, all trinucleotides could serve as the primer initiation site although there was a distinct preference for d(CAG). These data may explain the high chromosomal prevalence of octanucleotides containing CTG on the leading strand and its complement CAG on the lagging strand. The specificity of DnaB helicase places it on the lagging strand template where it stimulates the initiation of Okazaki fragment synthesis. In the absence of DnaB helicase, primase preferentially primed the d(CTG) template. In the presence of DnaB helicase, the initiation preference was not only altered but also the preferred initiating nucleotide was found to be GTP rather than ATP, for both the d(CTG) and the d(CAG) templates. This suggested that the specificity of primase for the d(CTG) initiation trinucleotide was predominantly unaffected in the absence of DnaB helicase on short ssDNA templates, whereas in conjunction with DnaB helicase, the specificity was altered and this alteration has significant implications in the replication of Escherichia coli chromosome in vivo.     

Dynamic coupling between the motors of DNA replication: hexameric helicase, DNA polymerase, and primase

Helicases are molecular motor proteins that couple NTP hydrolysis to directional movement along nucleic acids. A class of helicases characterized by their ring-shaped hexameric structures translocate processively and unidirectionally along single-stranded (ss) DNA to separate the strands of double-stranded (ds) DNA, aiding both in the initiation and fork progression during DNA replication. These replicative ring-shaped helicases are found from virus to human. We review recent biochemical and structural studies that have expanded our understanding on how hexameric helicases use the NTPase reaction to translocate on ssDNA, unwind dsDNA, and how their physical and functional interactions with the DNA polymerase and primase enzymes coordinate replication of the two strands of dsDNA.     

Recognition and cooperation between the ATP-dependent RNA helicase RhlB and ribonuclease RNase E

The Escherichia coli protein RhlB is an ATP-dependent motor that unfolds structured RNA for destruction by partner ribonucleases. In E. coli, and probably many other related gamma-proteobacteria, RhlB associates with the essential endoribonuclease RNase E as part of the multi-enzyme RNA degradosome assembly. The interaction with RNase E boosts RhlB's ATPase activity by an order of magnitude. Here, we examine the origins and implications of this effect. The location of the interaction sites on both RNase E and RhlB are refined and analysed using limited protease digestion, domain cross-linking and homology modelling. These data indicate that RhlB's carboxy-terminal RecA-like domain engages a segment of RNase E that is no greater than 64 residues. The interaction between RhlB and RNase E has two important consequences: first, the interaction itself stimulates the unwinding and ATPase activities of RhlB; second, RhlB gains proximity to two RNA-binding sites on RNase E, with which it cooperates to unwind RNA. Our homology model identifies a pattern of residues in RhlB that may be key for recognition of RNase E and which may communicate the activating effects. Our data also suggest that the association with RNase E may partially repress the RNA-binding activity of RhlB. This repression may in fact permit the interplay of the helicase and adjacent RNA binding segments as part of a process that steers substrates to either processing or destruction, depending on context, within the RNA degradosome assembly.