ATP-dependent translocation of proteins along single-stranded DNA: models and methods of analysis of pre-steady state kinetics

Processive DNA helicases are able to translocate along single-stranded DNA (ssDNA) with biased directionality in a nucleoside triphosphate-dependent reaction, although translocation is not generally sufficient for helicase activity. An understanding of the mechanism of protein translocation along ssDNA requires pre-steady state transient kinetic experiments. Although ensemble experimental approaches have been developed recently for the study of translocation of proteins along DNA, quantitative analysis of the complete time-courses from these experiments, which is needed to obtain quantitative estimates of translocation kinetic parameters (rate constants, processivity, step sizes and ATP coupling) has been lacking. We discuss three ensemble transient kinetic experiments that can be used to study protein translocation along ssDNA, along with the advantages and limitations of each approach. We further describe methods to analyze the complete kinetic time-courses obtained from such experiments performed with a series of ssDNA lengths under "single-round" conditions (i.e. in the absence of re-binding of dissociated protein to DNA). These analysis methods utilize a sequential "n-step" model for protein translocation along ssDNA and enable quantitative determinations of the rate constant, processivity and step size for translocation through global non-linear least-squares fitting of the full time-courses.     

Mechanism of ATP-dependent translocation of E.coli UvrD monomers along single-stranded DNA

Escherichia coli UvrD protein is a 3' to 5' SF1 DNA helicase involved in methyl-directed mismatch repair and nucleotide excision repair of DNA. Using stopped-flow methods we have examined the kinetic mechanism of translocation of UvrD monomers along single-stranded DNA (ssDNA) in vitro by monitoring the transient kinetics of arrival of protein at the 5'-end of the ssDNA. Arrival at the 5'-end was monitored by the effect of protein on the fluorescence intensity of fluorophores (Cy3 or fluorescein) attached to the 5'-end of a series of oligodeoxythymidylates varying in length from 16 to 124 nt. We find that UvrD monomers are capable of ATP-dependent translocation along ssDNA with a biased 3' to 5' directionality. Global non-linear least-squares analysis of the full kinetic time-courses in the presence of a protein trap to prevent rebinding of free protein to the DNA using the methods described in the accompanying paper enabled us to obtain quantitative estimates of the kinetic parameters for translocation. We find that UvrD monomers translocate in discrete steps with an average kinetic step-size, m=3.68(+/-0.03) nt step(-1), a translocation rate constant, kt=51.3(+/-0.6) steps s(-1), (macroscopic translocation rate, mkt=189.0(+/-0.7) nt s(-1)), with a processivity corresponding to an average translocation distance of 2400(+/-600) nt before dissociation (10 mM Tris-HCl (pH 8.3), 20 mM NaCl, 20% (v/v) glycerol, 25 degrees C). However, in spite of its ability to translocate rapidly and efficiently along ssDNA, a UvrD monomer is unable to unwind even an 18 bp duplex in vitro. DNA helicase activity in vitro requires a UvrD dimer that unwinds DNA with a similar kinetic step-size of 4-5 bp step(-1), but an approximately threefold slower unwinding rate of 68(+/-9) bp s(-1) under the same solution conditions, indicating that DNA unwinding activity requires more than the ability to simply translocate directionally along ss-DNA.     

Continuous assays for DNA translocation using fluorescent triplex dissociation: application to type I restriction endonucleases

Fluorescent assays and accompanying kinetic models are described for the analysis of DNA translocation independent of duplex unwinding. A triplex binding site (TBS) was introduced into DNA substrates at precise loci downstream of recognition sequences for type IA, IB and IC restriction endonucleases (EcoKI, EcoAI and EcoR124I, respectively). Each endonuclease was incubated (without ATP) with substrates on which a hexachlorofluoroscein-labelled triplex-forming oligonucleotide (HEX-TFO) was pre-bound. Following addition of ATP, 1-D enzyme motion resulted in collision with, and displacement of, the HEX-TFO, producing a >twofold increase in fluorescent intensity. Alternatively, a decrease in anisotropy following displacement of a rhodamine-labelled TFO was monitored. Using rapid mixing in a stopped-flow fluorimeter, continuous kinetic profiles were produced in which displacement is preceded by a lag-phase, directly proportional to the distance moved. For each enzyme, we obtained not only the translocation rate but also information on slow isomerisation step(s) at initiation. Furthermore, we demonstrated that enzymes deficient in DNA cleavage but with maximal ATPase activity showed initiation and translocation rates identical to wild-type, confirming that DNA strand breaks are not a pre-requisite of motion.     

RecQ helicase-catalyzed DNA unwinding detected by fluorescence resonance energy transfer

A fluorometric assay was used to study the DNA unwinding kinetics induced by Escherichiacoli RecQ helicase.This assay was based on fluorescence resonance energy transfer and carried out onstopped-flow,in which DNA unwinding was monitored by fluorescence emission enhancement of fluoresceinresulting from helicase-catalyzed DNA unwinding.By this method,we determined the DNA unwinding rateof RecQ at different enzyme concentrations.We also studied the dependences of DNA unwinding magnitudeand rate on magnesium ion concentration.We showed that this method could be used to determine thepolarity of DNA unwinding.This assay should greatly facilitate further study of the mechanism for RecQ-catalyzed DNA unwinding.     

Yeast Helicase Pif1 Unwinds RNA:DNA Hybrids with Higher Processivity than DNA:DNA Duplexes

Saccharomyces cerevisiae Pif1, an SF1B helicase, has been implicated in both mitochondrial and nuclear functions. Here we have characterized the preference of Pif1 for RNA:DNA heteroduplexes in vitro by investigating several kinetic parameters associated with unwinding. We show that the preferential unwinding of RNA:DNA hybrids is due to neither specific binding nor differences in the rate of strand separation. Instead, Pif1 is capable of unwinding RNA:DNA heteroduplexes with moderately greater processivity compared with its duplex DNA:DNA counterparts. This higher processivity of Pif1 is attributed to slower dissociation from RNA:DNA hybrids. Biologically, this preferential role of the helicase may contribute to its functions at both telomeric and nontelomeric sites.     

DNA unwinding step-size of E. coli RecBCD helicase determined from single turnover chemical quenched-flow kinetic studies

The mechanism by which Escherichia coli RecBCD DNA helicase unwinds duplex DNA was examined in vitro using pre-steady-state chemical quenched-flow kinetic methods. Single turnover DNA unwinding experiments were performed by addition of ATP to RecBCD that was pre-bound to a series of DNA substrates containing duplex DNA regions ranging from 24 bp to 60 bp. In each case, the time-course for formation of completely unwound DNA displayed a distinct lag phase that increased with duplex length, reflecting the transient formation of partially unwound DNA intermediates during unwinding catalyzed by RecBCD. Quantitative analysis of five independent sets of DNA unwinding time courses indicates that RecBCD unwinds duplex DNA in discrete steps, with an average unwinding "step-size", m=3.9(+/-1.3)bp step(-1), with an average unwinding rate of k(U)=196(+/-77)steps s(-1) (mk(U)=790(+/-23)bps(-1)) at 25.0 degrees C (10mM MgCl(2), 30 mM NaCl (pH 7.0), 5% (v/v) glycerol). However, additional steps, not linked directly to DNA unwinding are also detected. This kinetic DNA unwinding step-size is similar to that determined for the E.coli UvrD helicase, suggesting that these two SF1 superfamily helicases may share similar mechanisms of DNA unwinding.     

The Gly-Arg-rich C-terminal domain of pea nucleolin is a DNA helicase that catalytically translocates in the 5'- to 3'-direction

Nucleolin is a major nucleolar phosphoprotein of exponentially growing eukaryotic cells. Here we report the cloning, purification, and characterization of the C-terminal glycine/arginine-rich (GAR) domain of pea nucleolin. The purified recombinant protein (17 kDa) shows ATP-/Mg(2+)-dependent DNA helicase and ssDNA-/Mg(2+)-dependent ATPase activities. The enzyme unwinds DNA in the 5'- to 3'-direction, which is the first report in plant for this directional activity. It unwinds forked/non-forked DNA with equal efficiency. The anti-nucleolin antibodies immunodepleted the activities of the enzyme. The DNA interacting ligands nogalamycin, daunorubicin, actinomycin C1, and ethidium bromide were inhibitory to DNA unwinding (with K(i) values of 0.40, 2.21, 8.0, and 9.0 microM, respectively) and ATPase (with K(i) values of 0.43, 1.65, 4.6, and 7.0 microM, respectively) activities of the enzyme. This study confirms that the unwinding and ATPase activities of pea nucleolin resided in the GAR domain. This study should make important contribution to our better understanding of DNA transaction in plants, mechanism of DNA unwinding, and the mechanism by which these ligands can disturb genome integrity.     

Partial purification and characterization of a DNA helicase from chloroplasts of Glycine max

A DNA helicase activity was detected in extracts of purified chloroplasts from the SB-1 cell line of Glycine max and partially purified by column chromatography on DEAE cellulose, phosphocellulose, and single-stranded DNA cellulose. The chloroplast helicase has a DNA-dependent ATPase activity, and its strand displacement activity is strictly dependent upon the presence of a nucleoside triphosphate and Mg²⁺ or Mn²⁺. Strand displacement activity does not require a free unannealed single-strand or replication fork-like structure.     

Energetics of DNA end binding by E.coli RecBC and RecBCD helicases indicate loop formation in the 3'-single-stranded DNA tail

We examined the equilibrium binding of Escherichia coli RecBC and RecBCD helicases to duplex DNA ends possessing pre-existing single-stranded (ss) DNA ((dT)(n)) tails varying in length (n=0 to 20 nucleotides) in order to determine the contributions of both the 3' and 5' single strands to the energetics of complex formation. Protein binding was monitored by the fluorescence enhancement of a reference DNA labeled at its end with a Cy3 fluorophore. Binding to unlabeled DNA was examined by competition titrations with the Cy3-labeled reference DNA. The affinities of both RecBC and RecBCD increase as the 3'-(dT)(n) tail length increases from zero to six nucleotides, but then decrease dramatically as the 3'-(dT)(n) tail length increases from six to 20 nucleotides. Isothermal titration calorimetry experiments with RecBC show that the binding enthalpy is negative and increases in magnitude with increasing 3'-(dT)(n) tail length up to n=6 nucleotides, but remains constant for n > or =6. Hence, the decrease in binding affinity for 3'-(dT)(n) tail lengths with n > or =6 is due to an unfavorable entropic contribution. RecBC binds optimally to duplex DNA with (dT)6 tails on both the 3' and 5'-ends while RecBCD prefers duplex DNA with 3'-(dT)6 and 5'-(dT)10 tails. These data suggest that both RecBC and RecBCD helicases can destabilize or "melt out" six base-pairs upon binding to a blunt DNA duplex end in the absence of ATP. These results also provide the first evidence that a loop in the 3'-ssDNA tail can form upon binding of RecBC or RecBCD with DNA duplexes containing a pre-formed 3'-ssDNA tail with n > or =6 nucleotides. Such loops may be representative of those hypothesized to form upon interaction of a Chi site contained within the unwound 3' ss-DNA tail with the RecC subunit during DNA unwinding.     

Optimization of a novel potent and selective bacterial DNA helicase inhibitor scaffold from a high throughput screening hit

Benzobisthiazole derivatives were identified as novel helicase inhibitors through high throughput screening against purified Staphylococcus aureus (Sa) and Bacillus anthracis (Ba) replicative helicases. Chemical optimization has produced compound 59 with nanomolar potency against the DNA duplex strand unwinding activities of both B. anthracis and S. aureus helicases. Selectivity index (SI = CC₅₀/IC₅₀) values for 59 were greater than 500. Kinetic studies demonstrated that the benzobisthiazole-based bacterial helicase inhibitors act competitively with the DNA substrate. Therefore, benzobisthiazole helicase inhibitors represent a promising new scaffold for evaluation as antibacterial agents.     

The intercalating beta-hairpin of T7 RNA polymerase plays a role in promoter DNA melting and in stabilizing the melted DNA for efficient RNA synthesis

Phage T7 RNA polymerase contains within its single polypeptide all the elements for specific recognition and melting of its promoter DNA. Crystallographic studies indicate that a beta-hairpin (230-245) with an intercalating valine residue plays a role in promoter opening. We mutated V237 to several amino acids, deleted five amino acid residues at the tip of the hairpin, and mutated E242 and D240 at the base of the hairpin to define the roles of the tip and base of the hairpin in DNA strand separation. The affinity of the hairpin mutants for the promoter DNA was not significantly affected. Stopped-flow kinetic studies showed that the bimolecular rate of DNA binding and the observed rate of pre-initiation open complex formation that corresponds to the sum of DNA opening and closing steps were within 20 to 40 % of the wild-type polymerase. Yet, most mutants showed a smaller amount of the pre-initiation open complex at equilibrium, indicating that the individual rates of promoter opening and closing steps were altered in the mutants. The base mutants, E242A and D240A, showed both a lower rate of promoter opening and a higher rate of promoter closing, suggesting their role in stabilization of the open complex. The V237D and the deletion mutant showed mainly a lower rate of promoter opening, suggesting that the tip of the hairpin may nucleate DNA opening. The defect in pre-initiation open complex formation affected downstream steps such as the rate of the first phosphodiester bond formation step, but did not affect significantly the apparent K(d) of initiating GTPs. We propose that D240 and E242 anchor the hairpin to the DNA and position the tip of the hairpin to allow V237 to intercalate and distort the DNA during open complex formation. The interactions of E242 and D240 with the upstream junction of the melted dsDNA promoter also align the template strand within the active site for efficient RNA synthesis.     

Early events during folding of wild-type staphylococcal nuclease and a single-tryptophan variant studied by ultrarapid mixing

A continuous-flow mixing device with a dead time of 100 micros coupled with intrinsic tryptophan and 1-anilinonaphthalene-8-sulfonate (ANS) fluorescence was used to monitor structure formation during early stages of the folding of staphylococcal nuclease (SNase). A variant with a unique tryptophan fluorophore in the N-terminal beta-barrel domain (Trp76 SNase) was obtained by replacing the single Trp140 in wild-type SNase with His in combination with Trp substitution of Phe76. A common background of P47G, P117G and H124L mutations was chosen in order to stabilize the protein and prevent accumulation of cis proline isomers under native conditions. In contrast to WT(*) SNase, which shows no changes in tryptophan fluorescence prior to the rate-limiting folding step ( approximately 100 ms), the F76W/W140H variant shows additional changes (enhancement) during an early folding phase with a time constant of 75 micros. Both proteins exhibit a major increase in ANS fluorescence and identical rates for this early folding event. These findings are consistent with the rapid accumulation of an ensemble of states containing a loosely packed hydrophobic core involving primarily the beta-barrel domain while the specific interactions in the alpha-helical domain involving Trp140 are formed only during the final stages of folding. The fact that both variants exhibit the same number of kinetic phases with very similar rates confirms that the folding mechanism is not perturbed by the F76W/W140H mutations. However, the Trp at position 76 reports on the rapid formation of a hydrophobic cluster in the N-terminal beta-sheet region while the wild-type Trp140 is silent during this early stage of folding. Quantitative modeling of the (un)folding kinetics and thermodynamics of these two proteins versus urea concentration revealed that the F76W/W140H mutation selectively destabilizes the native state relative to WT(*) SNase while the stability of transient intermediates remains unchanged, leading to accumulation of intermediates under equilibrium conditions at moderate denaturant concentrations.     

Rat polymerase beta gapped DNA interactions: antagonistic effects of the 5' terminal PO4 - group and magnesium on the enzyme binding to the gapped DNAs with different ssDNA gaps

The role of the 5′ terminal phosphate group downstream from the primer and magnesium cations in the energetics and dynamics of the gapped DNA recognition by rat polymerase β have been examined, using the fluorescence titration and stopped-flow techniques. The analyses have been performed with the entire series of gapped DNA substrates differing in the size of the ssDNA gap. The 5′ terminal phosphate group and magnesium cations exert antagonistic effect on enzyme binding to gapped DNA that depends on the length of the ssDNA gap. The PO ₄ ⁻ group amplifies the differences between the substrates with different ssDNA gaps, while in the presence of magnesium, affinities and structural changes induced in the DNA are very similar among examined DNA substrates. Both, the phosphate group and Mg⁺² differ dramatically in affecting the thermodynamic response of the gapped DNA-rat pol β system to the salt concentration. The data indicate that these distinct effects result from affecting the structure of the DNA, in the case of the phosphate group, and from direct magnesium binding to the protein. The mechanism of rat enzyme binding depends on the length of the ssDNA gap and the presence of the 5′ terminal phosphate group. Complex formation with DNAs having three, four, and five residues in the gap occurs by a minimum three-step sequential mechanism. Depending on the presence of the 5′ terminal phosphate group and/or magnesium, binding of the enzyme to a DNA containing two residues in the ssDNA gap is described by the same three-step or by a simpler two-step mechanism. With the DNA containing only one residue in the gap, binding is always described by only a two-step mechanism. The PO ₄ ⁻ group and magnesium cations have opposite effects on internal stability of the complexes with different length of the ssDNA gap. While the PO ₄ ⁻ group increases the stability of internal intermediates with the increasing length of the gap, Mg⁺² decreases the stability of the intermediates with longer ssDNA gap. As a result, the combined favorable orientation effect of the phosphate group and the unfavorable Mg⁺² effect lead to the optimal docking of the ssDNA gaps with three and four residues by the enzyme. This work was supported by NIH Grant GM-58565 (to W. B.)     

Mutational analysis of the T4 gp59 helicase loader reveals its sites for interaction with helicase, single-stranded binding protein, and DNA

Efficient DNA replication involves coordinated interactions among DNA polymerase, multiple factors, and the DNA. From bacteriophage T4 to eukaryotes, these factors include a helicase to unwind the DNA ahead of the replication fork, a single-stranded binding protein (SSB) to bind to the ssDNA on the lagging strand, and a helicase loader that associates with the fork, helicase, and SSB. The previously reported structure of the helicase loader in the T4 system, gene product (gp)59, has revealed an N-terminal domain, which shares structural homology with the high mobility group (HMG) proteins from eukaryotic organisms. Modeling of this structure with fork DNA has suggested that the HMG-like domain could bind to the duplex DNA ahead of the fork, whereas the C-terminal portion of gp59 would provide the docking sites for helicase (T4 gp41), SSB (T4 gp32), and the ssDNA fork arms. To test this model, we have used random and targeted mutagenesis to generate mutations throughout gp59. We have assayed the ability of the mutant proteins to bind to fork, primed fork, and ssDNAs, to interact with SSB, to stimulate helicase activity, and to function in leading and lagging strand DNA synthesis. Our results provide strong biochemical support for the role of the N-terminal gp59 HMG motif in fork binding and the interaction of the C-terminal portion of gp59 with helicase and SSB. Our results also suggest that processive replication may involve the switching of gp59 between its interactions with helicase and SSB.     

Mechanistic studies of the T4 DNA (gp41) replication helicase: functional interactions of the C-terminal Tails of the helicase subunits with the T4 (gp59) helicase loader protein

We compare the activities of the wild-type (gp41WT) and mutant (gp41delta C20) forms of the bacteriophage T4 replication helicase. In the gp41delta C20 mutant the helicase subunits have been genetically truncated to remove the 20 residue C-terminal tail peptide domains present in the wild-type enzyme. Here, we examine the interactions of these helicase forms with the T4 gp59 helicase loader and the gp32 single-stranded DNA binding proteins, both of which are physically and functionally coupled with the helicase in the T4 DNA replication complex. We show that the wild-type and mutant forms of the helicase do not differ in their ability to assemble into dimers and hexamers, nor in their interactions with gp61 (the T4 primase). However they do differ in their gp59-stimulated unwinding activities and in their abilities to translocate along a ssDNA strand that has been coated with gp32. We demonstrate that functional coupling between gp59 and gp41 involves direct interactions between the C-terminal tail peptides of the helicase subunits and the loading protein, and measure the energetics and kinetics of these interactions. This work helps to define a gp41-gp59 assembly pathway that involves an initial interaction between the C-terminal tails of the helicases and the gp59 loader proteins, followed by a conformational change of the helicase subunits that exposes new interaction surfaces, which can then be trapped by the gp59 protein. Our results suggest that the gp41-gp59 complex is then poised to bind ssDNA portions of the replication fork. We suggest that one of the important functions of gp59 may be to aid in the exposure of the ssDNA binding sites of the helicase subunits, which are otherwise masked and regulated by interactions with the helicase carboxy-terminal tail peptides.     

Human RECQ5beta, a protein with DNA helicase and strand-annealing activities in a single polypeptide

Proteins belonging to the highly conserved RecQ helicase family are essential for the maintenance of genomic stability. Here, we describe the biochemical properties of the human RECQ5beta protein. Like BLM and WRN, RECQ5beta is an ATP-dependent 3'-5' DNA helicase that can promote migration of Holliday junctions. However, RECQ5beta required the single-stranded DNA-binding protein RPA in order to mediate the efficient unwinding of oligonucleotide-based substrates. Surprisingly, we found that RECQ5beta possesses an intrinsic DNA strand-annealing activity that is inhibited by RPA. Analysis of deletion variants of RECQ5beta revealed that the DNA helicase activity resides in the conserved N-terminal portion of the protein, whereas strand annealing is mediated by the unique C-terminal domain. Moreover, the strand-annealing activity of RECQ5beta was strongly inhibited by ATPgammaS, a poorly hydrolyzable analog of ATP. This effect was alleviated by mutations in the ATP-binding motif of RECQ5beta, indicating that the ATP-bound form of the protein cannot promote strand annealing. This is the first demonstration of a DNA helicase with an intrinsic DNA strand-annealing function residing in a separate domain.     

Three-state kinetic folding mechanism of the H2A/H2B histone heterodimer: the N-terminal tails affect the transition state between a dimeric intermediate and the native dimer

The H2A/H2B heterodimer is a component of the nucleosome core particle, the fundamental repeating unit of chromatin in all eukaryotic cells. The kinetic folding mechanism for the H2A/H2B dimer has been determined from unfolding and refolding kinetics as a function of urea using stopped-flow, circular dichroism and fluorescence methods. The kinetic data are consistent with a three-state mechanism: two unfolded monomers associate to form a dimeric intermediate in the dead-time of the SF instrument (approximately 5 ms); this intermediate is then converted to the native dimer by a slower, first-order reaction. Analysis of the burst-phase amplitudes as a function of denaturant indicates that the dimeric kinetic intermediate possesses approximately 50% of the secondary structure and approximately 60% of the surface area burial of the native dimer. The stability of the dimeric intermediate is approximately 30% of that of the native dimer at the monomer concentrations employed in the SF experiments. Folding-to-unfolding double-jump experiments were performed to monitor the formation of the native dimer as a function of folding delay times. The double-jump data demonstrate that the dimeric intermediate is on-pathway and obligatory. Formation of a transient dimeric burst-phase intermediate has been observed in the kinetic mechanism of other intertwined, segment-swapped, alpha-helical, DNA-binding dimers, such as the H3-H4 histone dimer, Escherichia coli factor for inversion stimulation and E.coli Trp repressor. The common feature of a dimeric intermediate in these folding mechanisms suggests that this intermediate may accelerate protein folding, when compared to the folding of archael histones, which do not populate a transient dimeric species and fold more slowly.     

The glutamate switch of bacteriophage T7 DNA helicase: role in coupling nucleotide triphosphate (NTP) and DNA binding to NTP hydrolysis

The DNA helicase encoded by gene 4 of bacteriophage T7 forms a hexameric ring in the presence of dTTP, allowing it to bind DNA in its central core. The oligomerization also creates nucleotide-binding sites located at the interfaces of the subunits. DNA binding stimulates the hydrolysis of dTTP but the mechanism for this two-step control is not clear. We have identified a glutamate switch, analogous to the glutamate switch found in AAA+ enzymes that couples dTTP hydrolysis to DNA binding. A crystal structure of T7 helicase shows that a glutamate residue (Glu-343), located at the subunit interface, is positioned to catalyze a nucleophilic attack on the γ-phosphate of a bound nucleoside 5'-triphosphate. However, in the absence of a nucleotide, Glu-343 changes orientation, interacting with Arg-493 on the adjacent subunit. This interaction interrupts the interaction of Arg-493 with Asn-468 of the central β-hairpin, which in turn disrupts DNA binding. When Glu-343 is replaced with glutamine the altered helicase, unlike the wild-type helicase, binds DNA in the presence of dTDP. When both Arg-493 and Asn-468 are replaced with alanine, dTTP hydrolysis is no longer stimulated in the presence of DNA. Taken together, these results suggest that the orientation of Glu-343 plays a key role in coupling nucleotide hydrolysis to the binding of DNA.     

Robust translocation along a molecular monorail: the NS3 helicase from hepatitis C virus traverses unusually large disruptions in its track

The NS3 helicase is essential for replication of the hepatitis C virus. This multifunctional Superfamily 2 helicase protein unwinds nucleic acid duplexes in a stepwise, ATP-dependent manner. Although kinetic features of its mechanism are beginning to emerge, little is known about the physical determinants for NS3 translocation along a strand of nucleic acid. For example, it is not known whether NS3 can traverse covalent or physical discontinuities on the tracking strand. Here we provide evidence that NS3 translocates with a mechanism that is different from its well-studied relative, the Vaccinia helicase NPH-II. Like NPH-II, NS3 translocates along the loading strand (the strand bearing the 3'-overhang) and it fails to unwind substrates that contain nicks, or covalent discontinuities in the loading strand. However, unlike NPH-II, NS3 readily unwinds RNA duplexes that contain long stretches of polyglycol, which are moieties that bear no resemblance to nucleic acid. Whether located on the tracking strand, the top strand, or both, long polyglycol regions fail to disrupt the function of NS3. This suggests that NS3 does not require the continuous formation of specific contacts with the ribose-phosphate backbone as it translocates along an RNA duplex, which is an observation consistent with the large NS3 kinetic step size (18 base-pairs). Rather, once NS3 loads onto a substrate, the helicase can translocate along the loading strand of an RNA duplex like a monorail train following a track. Bumps in the track do not significantly disturb NS3 unwinding, but a break in the track de-rails the helicase.     

Structure of the connector of bacteriophage T7 at 8A resolution: structural homologies of a basic component of a DNA translocating machinery

The three-dimensional structure of the bacteriophage T7 head-to-tail connector has been obtained at 8A resolution using cryo-electron microscopy and single-particle analysis from purified recombinant connectors. The general morphology of the T7 connector is that of a 12-folded toroidal homopolymer with a channel that runs along the longitudinal axis of the particle. The structure of the T7 connector reveals many structural similarities with the connectors from other bacteriophages. Docking of the atomic structure of the varphi29 connector into the three-dimensional reconstruction of T7 connector reveals that the narrow, distal region of the two oligomers are almost identical. This region of the varphi29 connector has been suggested to be involved in DNA translocation, and is composed of an alpha-beta-alpha-beta-beta-alpha motif. A search for alpha-helices in the same region of the T7 three-dimensional map has located three alpha-helices in approximately the same position as those of the varphi29 connector. A comparison of the predicted secondary structure of several bacteriophage connectors, including among others T7, varphi29, P22 and SPP1, reveals that, despite the lack of sequence homology, they seem to contain the same alpha-beta-alpha-beta-beta-alpha motif as that present in the varphi29 connector. These results allow us to suggest a common architecture related to a basic component of the DNA translocating machinery for several viruses.