Cysteine 111 affects coupling of single-stranded DNA binding to ATP hydrolysis in the herpes simplex virus type-1 origin-binding protein

Herpes simplex virus type-1 origin-binding protein (UL9 protein) initiates viral replication by unwinding the origins. It possesses sequence-specific DNA-binding activity, single-stranded DNA-binding activity, DNA helicase activity, and ATPase activity that is strongly stimulated by single-stranded DNA. We have examined the role of cysteines in its action as a DNA helicase. The DNA helicase and DNA-dependent ATPase activities of UL9 protein were stimulated by reducing agent and specifically inactivated by the sulfhydryl-specific reagent N-ethylmaleimide. To identify the cysteine responsible for this phenomenon, a conserved cysteine in the vicinity of the ATP-binding site (cysteine 111) was mutagenized to alanine. UL9C111A protein exhibits defects in its DNA helicase and DNA-dependent ATPase activities and was unable to support origin-specific DNA replication in vivo. A kinetic analysis indicates that these defects are due to the inability of single-stranded DNA to induce high affinity ATP binding in UL9C111A protein. The DNA-dependent ATPase activity of UL9C111A protein is resistant to N-ethylmaleimide, while its DNA helicase activity remains sensitive. Accordingly, sensitivity of UL9 protein to N-ethylmaleimide is due to at least two cysteines. Cysteine 111 is involved in coupling single-stranded DNA binding to ATP-binding and subsequent hydrolysis, while a second cysteine is involved in coupling ATP hydrolysis to DNA unwinding.     

Biochemical Characterization of Adeno-Associated Virus Rep68 DNA Helicase and ATPase Activities

The adeno-associated virus (AAV) nonstructural proteins Rep68 and Rep78 are site-specific DNA binding proteins, ATP-dependent site-specific endonucleases, helicases, and ATPases. These biochemical activities are required for viral DNA replication and control of viral gene expression. In this study, we characterized the biochemical properties of the helicase and ATPase activities of homogeneously pure Rep68. The enzyme exists as a monomer in solution at the concentrations used in this study (<380 nM), as judged by its mobility in sucrose density gradients. Using a primed single-stranded (ss) circular M13 substrate, the helicase activity had an optimum pH of 7 to 7.5, an optimum temperature of 45°C, and an optimal divalent-cation concentration of 5 mM MgCl₂. Several nucleoside triphosphates could serve as cofactors for Rep68 helicase activity, and the order of preference was ATP = GTP > CTP = dATP > UTP > dGTP. The K_m values for ATP in both the DNA helicase reaction and the site-specific trs endonuclease reaction were essentially the same, approximately 180 μM. Both reactions were sigmoidal with respect to ATP concentration, suggesting that a dimer or higher-order multimer of Rep68 is necessary for both DNA helicase activity and terminal resolution site (trs) nicking activity. Furthermore, when the enzyme itself was titrated in the trs endonuclease and ATPase reactions, both activities were second order with respect to enzyme concentration. This suggests that a dimer of Rep68 is the active form for both the ATPase and nicking activities. In contrast, DNA helicase activity was linear with respect to enzyme concentration. When bound to ssDNA, the enzyme unwound the DNA in the 3′-to-5′ direction. DNA unwinding occurred at a rate of approximately 345 bp per min per monomeric enzyme molecule. The ATP turnover rate was approximately 30 to 50 ATP molecules per min per enzyme molecule. Surprisingly, the presence of DNA was not required for ATPase activity. We estimated that Rep translocates processively for more than 1,300 bases before dissociating from its substrate in the absence of any accessory proteins. DNA helicase activity was not significantly stimulated by substrates that have the structure of a replication fork and contain either a 5′ or 3′ tail. Rep68 binds only to ssDNA, as judged by inhibition of the DNA helicase reaction with ss or double-stranded (ds) DNA. Consistent with this observation, no helicase activity was detected on blunt-ended ds oligonucleotide substrates unless they also contained an ss 3′ tail. However, if a blunt-ended ds oligonucleotide contained the 22-bp Rep binding element sequence, Rep68 was capable of unwinding the substrate. This means that Rep68 can function both as a conventional helicase for strand displacement synthesis and as a terminal-repeat-unwinding protein which catalyzes the conversion of a duplex end to a hairpin primer. Thus, the properties of the Rep DNA helicase activity suggest that Rep is involved in all three of the key steps in AAV DNA replication: terminal resolution, reinitiation, and strand displacement.     

Single strand annealing and ATP-independent strand exchange activities of yeast and human DNA2: possible role in Okazaki fragment maturation

The Dna2 protein is a multifunctional enzyme with 5'-3' DNA helicase, DNA-dependent ATPase, 3' exo/endonuclease, and 5' exo/endonuclease. The enzyme is highly specific for structures containing single-stranded flaps adjacent to duplex regions. We report here two novel activities of both the yeast and human Dna2 helicase/nuclease protein: single strand annealing and ATP-independent strand exchange on short duplexes. These activities are independent of ATPase/helicase and nuclease activities in that mutations eliminating either nuclease or ATPase/helicase do not inhibit strand annealing or strand exchange. ATP inhibits strand exchange. A model rationalizing the multiple catalytic functions of Dna2 and leading to its coordination with other enzymes in processing single-stranded flaps during DNA replication and repair is presented.     

Novel ATP-independent RNA annealing activity of the dengue virus NS3 helicase

The flavivirus nonstructural protein 3 (NS3) bears multiple enzymatic activities and represents an attractive target for antiviral intervention. NS3 contains the viral serine protease at the N-terminus and ATPase, RTPase, and helicase activities at the C-terminus. These activities are essential for viral replication; however, the biological role of RNA remodeling by NS3 helicase during the viral life cycle is still unclear. Secondary and tertiary RNA structures present in the viral genome are crucial for viral replication. Here, we used the NS3 protein from dengue virus to investigate functions of NS3 associated to changes in RNA structures. Using different NS3 variants, we characterized a domain spanning residues 171 to 618 that displays ATPase and RNA unwinding activities similar to those observed for the full-length protein. Interestingly, we found that, besides the RNA unwinding activity, dengue virus NS3 greatly accelerates annealing of complementary RNA strands with viral or non-viral sequences. This new activity was found to be ATP-independent. It was determined that a mutated NS3 lacking ATPase activity retained full-RNA annealing activity. Using an ATP regeneration system and different ATP concentrations, we observed that NS3 establishes an ATP-dependent steady state between RNA unwinding and annealing, allowing modulation of the two opposing activities of this enzyme through ATP concentration. In addition, we observed that NS3 enhanced RNA-RNA interactions between molecules representing the ends of the viral genome that are known to be necessary for viral RNA synthesis. We propose that, according to the ATP availability, NS3 could function regulating the folding or unfolding of viral RNA structures.     

Calf thymus DNA helicase F, a replication protein A copurifying enzyme.

A DNA helicase from calf thymus, called DNA helicase F, copurified with replication protein A through several steps of purification including DEAE-Sephacel, hydroxyapatite and single stranded DNA cellulose. It is finally separated from replication protein A on FPLC Mono Q where the DNA helicase elutes after replication protein A. Characterization of the DNA helicase F by affinity labeling with [alpha 32P]ATP indicated that the enzyme has a catalytic subunit of 72 kDa. Gel filtration experiments suggested that DNA helicase F can exist both in a monomeric and an oligomeric form. The enzyme unwinds DNA in the 5'-->3' direction in relation to the strand it binds. All eight deoxyribonucleoside- and ribonucleosidetriphosphates could serve as an energy source. Testing a variety of DNA/DNA substrates demonstrated that the DNA helicase F preferentially unwinds very short substrates and is slightly stimulated by a single stranded 3'-tail. However, replication protein A allowed the DNA helicase to unwind much longer DNA substrates of up to 400 bases, indicating that the copurification of replication protein A with the DNA helicase F might be of functional relevance.     

Helicase, DNA-binding, and immunological properties of replication-defective simian virus 40 mutant T antigens

Simian virus 40 T antigen (TAg) exhibits nonspecific and origin-specific DNA binding (ori binding) and ATPase and helicase activities, all of which are related to its roles in viral DNA replication. We have characterized some of the properties of four replication-defective but transformation-competent mutant TAgs, C6-2, T22, C11, and C8A. C6-2 and T22 TAgs were each previously determined to lack ori-binding properties, while C11 TAg was reported to lack ATPase activity. The C8A TAg did not exhibit defects in either ori-binding or ATPase functions. We have analyzed additional aspects of these mutant TAgs pertaining to their helicase, DNA-binding, and immunological properties. With the exception of the C11 TAg, all the other TAgs exhibited helicase activity. The lack of helicase activity by C11 TAg was consistent with its previously shown inability to hydrolyze ATP or to replicate viral DNA. These results therefore show that ori-binding and helicase activities are separate functions of TAg. Wild-type and mutant TAgs bound with similar efficiency to either native or denatured calf thymus DNA-cellulose, indicating no marked differences in their nonspecific DNA-binding properties. We also tested the binding of wild-type and mutant TAgs to a monoclonal antibody, PAb 100, that was previously shown to recognize an extremely small class of TAg that may represent a unique conformational form of the protein. Interestingly, while less than 10% of the wild-type, C6-2, C11, and T22 mutant TAgs were recognized by PAb 100, more than 60% of the C8A mutant TAg was bound by this antibody. Therefore, although no defect in biochemical function was observed with the C8A TAg, its deficiency in viral DNA replication may be related to an unusual conformation, as detected by its dramatically increased recognition by PAb 100. These results show that the helicase activity of TAg is not required for its transformation function.     

A Saccharomyces cerevisiae DNA helicase associated with replication factor C.

A novel DNA helicase has been isolated from Saccharomyces cerevisiae. This DNA helicase co-purified with replication factor C (RF-C) during chromatography on S-Sepharose, DEAE-silica gel high performance liquid chromatography (HPLC), Affi-Gel Blue-agarose, heparin-agarose, single-stranded DNA-cellulose, fast protein liquid chromatography MonoS, and hydroxyapatite HPLC. Surprisingly, the helicase could be separated from RF-C by sedimentation on a glycerol gradient in the presence of 200 mM NaCl. The helicase is probably a homodimer of a 60-kDa polypeptide, which by UV cross-linking has been shown to bind ATP. It has a single-stranded DNA-dependent ATPase activity, with a Km for ATP of 60 microM. The DNA helicase activity depends on the hydrolysis of NTP (dNTP), with ATP and dATP the most efficient cofactors, followed by CTP and dCTP. The DNA helicase has a 5' to 3' directionality and is only marginally stimulated by coating the single-stranded DNA with the yeast single-stranded DNA-binding protein RF-A.     

Characterization of the helicase activity and substrate specificity of Mycobacterium tuberculosis UvrD

UvrD is a helicase that is widely conserved in gram-negative bacteria. A uvrD homologue was identified in Mycobacterium tuberculosis on the basis of the homology of its encoded protein with Escherichia coli UvrD, with which it shares 39% amino acid identity, distributed throughout the protein. The gene was cloned, and a histidine-tagged form of the protein was expressed and purified to homogeneity. The purified protein had in vitro ATPase activity that was dependent upon the presence of DNA. Oligonucleotides as short as four nucleotides were sufficient to promote the ATPase activity. The DNA helicase activity of the enzyme was only fueled by ATP and dATP. UvrD preferentially unwound 3'-single-stranded tailed duplex substrates over 5'-single-stranded ones, indicating that the protein had a duplex-unwinding activity with 3'-to-5' polarity. A 3' single-stranded DNA tail of 18 nucleotides was required for effective unwinding. By using a series of synthetic oligonucleotide substrates, we demonstrated that M. tuberculosis UvrD has an unwinding preference towards nicked DNA duplexes and stalled replication forks, representing the likely sites of action in vivo. The potential role of M. tuberculosis UvrD in maintenance of bacterial genomic integrity makes it a promising target for drug design against M. tuberculosis.     

Mammalian DNA helicase.

A forked DNA was constructed to serve as a substrate for DNA helicases. It contains features closely resembling a natural replication fork. The DNA was prepared in large amounts and was used to assay displacement activity during isolation from calf thymus DNA polymerases alpha holoenzyme. One form of DNA polymerase alpha holoenzyme is possibly involved leading strand replication at the replication fork and possesses DNA dependent ATPase activity (Ottiger, H.-P. and Hübscher, U. (1984) Proc. Natl. Acad. Sci. USA 81, 3993-3997). The enzyme can be separated from DNA polymerase alpha by velocity sedimentation in conditions of very low ionic strength and then be purified by chromatography on Sephacryl S-200 and ATP-agarose. At all stages of purification, DNA dependent ATPase and displacement activity profiles were virtually superimposable. The DNA dependent ATPase can displace a hybridized DNA fragment with a short single-stranded tail at its 3'hydroxyl end only in the presence of ATP, and this displacement relies on ATP hydrolysis. Furthermore, homogeneous single-stranded binding proteins from calf thymus as well as from other tissues cannot perform this displacement reaction. By all this token the DNA dependent ATPase appears to be a DNA helicase. It is suggested that this DNA helicase might act in concert with DNA polymerase alpha at the leading strand, possibly pushing the replication fork ahead of the polymerase.     

DNA translocation activity of the multifunctional replication protein ORF904 from the archaeal plasmid pRN1

The replication protein ORF904 from the plasmid pRN1 is a multifunctional enzyme with ATPase-, primase- and DNA polymerase activity. Sequence analysis suggests the presence of at least two conserved domains: an N-terminal prim/pol domain with primase and DNA polymerase activities and a C-terminal superfamily 3 helicase domain with a strong double-stranded DNA dependant ATPase activity. The exact molecular function of the helicase domain in the process of plasmid replication remains unclear. Potentially this motor protein is involved in duplex remodelling and/or origin opening at the plasmid replication origin. In support of this we found that the monomeric replication protein ORF904 forms a hexameric ring in the presence of DNA. It is able to translocate along single-stranded DNA in 3′–5′ direction as well as on double-stranded DNA. Critical residues important for ATPase activity and DNA translocation activity were identified and are in agreement with a homology model of the helicase domain. In addition we propose that a winged helix DNA-binding domain at the C-terminus of the helicase domain could assist the binding of the replication protein specifically to the replication origin.     

The p53 complex from monkey cells modulates the biochemical activities of simian virus 40 large T antigen.

We have compared the ATPase, DNA-binding, and helicase activities of free simian virus 40 (SV40) large T antigen (To) and T antigen complexed with cellular p53 (T+p53). Each activity is essential for productive viral infection. The T+p53 and To fractions were prepared by sequential immunosorption of infected monkey cells with monoclonal antibodies specific for p53 and T antigen. The immune-complexed T fractions were then assayed in parallel. For ATP hydrolysis, the Vmax for T+p53 was 143 nmol of ADP per min per mg of protein, or 18-fold greater than for To. ATP had no effect on the stability of the T+p53 complex. The T+p53 complex was significantly more active than To in hydrolyzing dATP, dGTP, GTP, and UTP. Of the nucleotide substrates tested, the greatest relative increase (T+p53/To) was in hydrolyzing dGTP and GTP. In DNase footprinting assays performed under replication conditions, the T+p53 complex protected regions I, II, and III of origin DNA while equivalent amounts of To protected only regions I and II. Region III is known to contribute to the efficiency of DNA replication and contains the SP1-binding sites of the early viral promoter. The T+p53 fraction was also a more efficient helicase than To, especially with a GC-rich primer and template. Thus, the T+p53 complex has enhanced ATPase, GTPase, DNA-binding, and helicase activities. These findings imply that complex formation between cellular monkey p53 and SV40 T antigen modulates a number of essential activities of T in SV40 productive infection.     

Characterization of the ATPase activity of the Escherichia coli RecG protein reveals that the preferred cofactor is negatively supercoiled DNA

RecG is a member of the superfamily 2 helicase family. Its possible role in vivo is ATP hydrolysis driven regression of stalled replication forks. To gain mechanistic insight into how this is achieved, a coupled spectrophotometric assay was utilized to characterize the ATPase activity of RecG in vitro. The results demonstrate an overwhelming preference for negatively supercoiled DNA ((-)scDNA) as a cofactor for the hydrolysis of ATP. In the presence of (-)scDNA the catalytic efficiency of RecG and the processivity (as revealed through heparin trapping), were higher than on any other cofactor examined. The activity of RecG on (-)scDNA was not due to the presence of single-stranded regions functioning as loading sites for the enzyme as relaxed circular DNA treated with DNA gyrase, resulted in the highest levels of ATPase activity. Relaxation of (-)scDNA by a topoisomerase resulted in a 12-fold decrease in ATPase activity, comparable to that observed on both linear double-stranded (ds)DNA and (+)scDNA. In addition to the elevated activity in the presence of (-)scDNA, RecG also has high activity on model 4Y-substrates (i.e. chicken foot structures). This is due largely to the high apparent affinity of the enzyme for this DNA substrate, which is 46-fold higher than a 2Y-substrate (i.e. a three-way with two single-stranded (ss)DNA arms). Finally, the enzyme exhibited significant, but lower activity on ssDNA. This activity was enhanced by the Escherichia coli stranded DNA-binding protein (SSB) protein, which occurs through stabilizing of the binding of RecG to ssDNA. Stabilization is not afforded by the bacteriophage gene 32 protein, indicating a species specific, protein-protein interaction is involved. These results combine to provide significant insight into the manner and timing of the interaction of RecG with DNA at stalled replication forks.     

Characterization of the adenosinetriphosphatase activity of the Escherichia coli RecBCD enzyme: relationship of ATP hydrolysis to the unwinding of duplex DNA

We find that the rate of dsDNA-dependent ATPase activity is biphasic, with a fast component which represents the unwinding of the dsDNA and a slow component which results from the ssDNA-dependent ATPase activity of recBCD enzyme. Comparison of the ATPase and helicase activities permits evaluation of the efficiency of ATP hydrolysis during unwinding. This efficiency can be calculated from the maximum rates of ATPase and helicase activities and is found to range between 2.0 and 3.0 ATP molecules hydrolyzed per base pair of DNA unwound. The number of ATP molecules hydrolyzed per base pair unwound is not altered by temperature but does increase at low concentrations of DNA and high concentrations of sodium chloride and magnesium acetate. The apparent Km values for the DNA and ATP substrates of recBCD enzyme dsDNA-dependent ATPase activity at 25 degrees C were determined to be 0.13 nM DNA molecules and 85 microM ATP, respectively. The observed kcat value is approximately 45 microM ATP s-1 (microM recBCD enzyme)-1. If this rate is corrected for the measured stoichiometry of recBCD enzyme binding to dsDNA, the kcat for ATPase activity corresponds to an ATP hydrolysis rate of approximately 740 ATP molecules s-1 (functional recBCD complex)-1 at 25 degrees C.     

Biochemical analysis of the intrinsic Mcm4-Mcm6-mcm7 DNA helicase activity

Mcm proteins play an essential role in eukaryotic DNA replication, but their biochemical functions are poorly understood. Recently, we reported that a DNA helicase activity is associated with an Mcm4-Mcm6-Mcm7 (Mcm4,6,7) complex, suggesting that this complex is involved in the initiation of DNA replication as a DNA-unwinding enzyme. In this study, we have expressed and isolated the mouse Mcm2, 4,6,7 proteins from insect cells and characterized various mutant Mcm4,6,7 complexes in which the conserved ATPase motifs of the Mcm4 and Mcm6 proteins were mutated. The activities associated with such preparations demonstrated that the DNA helicase activity is intrinsically associated with the Mcm4,6,7 complex. Biochemical analyses of these mutant Mcm4,6,7 complexes indicated that the ATP binding activity of the Mcm6 protein in the complex is critical for DNA helicase activity and that the Mcm4 protein may play a role in the single-stranded DNA binding activity of the complex. The results also indicated that the two activities of DNA helicase and single-stranded DNA binding can be separated.     

Rep protein as a helicase in an active, isolatable replication fork of duplex phi X174 DNA

Rep protein as a helicase combines its actions with those of gene A protein and single-stranded DNA binding protein to separate the strands of phi X174 duplex DNA and thereby can generate and advance a replication fork (Scott, J. F., Eisenberg, S., Bertsch, L. L., and Kornberg, A. (1977) Proc. Natl. Acad. Sci. U. S. A. 74, 193-197). Tritium-labeled rep protein is bound in an active gene A protein. phi X174 closed circular duplex supercoiled DNA complex in a 1:1 ratio. Catalytic separation of the strands of the duplex by rep protein, as measured by incorporation of tritium-labeled single-stranded DNA binding protein, requires ATP at a Km value of 8 microM, and hydrolyzes two molecules of ATP for every base pair melted. When coupled to replication in the synthesis of single-strand viral circles, a "looped" rolling-circle intermediate is formed that can be isolated in an active form containing gene A protein, rep protein, single-stranded DNA binding protein, and DNA polymerase III holoenzyme. Unlike the binding of rep protein to single-stranded DNA, where its ATPase activity is distributive, binding to the replicating fork is not affected by ATP, further suggesting a processive action linked to gene A protein. Limited tryptic hydrolysis of rep protein abolishes its replicative activity without affecting significantly its binding of ATP and its ATPase action on single-stranded DNA. These results augment earlier findings by describing the larger role of rep proteins as a helicase, linked in a complex ith other proteins, at the replication fork of a duplex DNA.     

A novel DNA helicase from calf thymus.

We report the purification and characterization of a novel DNA helicase from calf thymus tissue. This enzyme partially copurifies with DNA polymerase epsilon* through many of the chromatographic procedures used to isolate it. The enzyme contains an intrinsic DNA-dependent ATPase activity. It can displace short oligonucleotides annealed to long single stranded substrates, in an ATP-dependent reaction. Use of this assay indicates that the DNA helicase translocates in a 3' to 5' direction with respect to the substrate strand to which it is bound. Maximal efficiency of displacement is accomplished by hydrolysis of (d)ATP as cofactor, however, (d)CTP can also be utilized resulting in a 5-fold decrease in the level of displacement. Displacement activity is enhanced by the presence of saturating amounts of Escherichia coli single stranded DNA-binding protein, not affected by the presence of phage T4 gene 32 protein, and inhibited by human replication factor A. The DNA helicase has a molecular mass of approximately 104 kDa as measured by denaturing gel electrophoresis, and an S value of 5.4 obtained from glycerol gradient sedimentation. Direct [alpha-32P]ATP cross-linking labels a protein of molecular mass approximately 105 kDa, providing further evidence that this polypeptide contains the helicase active site. In view of the differences in the properties of this helicase from four others recently identified in calf and designated A through D, we propose the name helicase E.     

The nuclease activity of the yeast DNA2 protein, which is related to the RecB-like nucleases, is essential in vivo

Saccharomyces cerevisiae Dna2 protein is required for DNA replication and repair and is associated with multiple biochemical activities: DNA-dependent ATPase, DNA helicase, and DNA nuclease. To investigate which of these activities is important for the cellular functions of Dna2, we have identified separation of function mutations that selectively inactivate the helicase or nuclease. We describe the effect of six such mutations on ATPase, helicase, and nuclease after purification of the mutant proteins from yeast or baculovirus-infected insect cells. A mutation in the Walker A box in the C-terminal third of the protein affects helicase and ATPase but not nuclease; a mutation in the N-terminal domain (amino acid 504) affects ATPase, helicase, and nuclease. Two mutations in the N-terminal domain abolish nuclease but do not reduce helicase activity (amino acids 657 and 675) and identify the putative nuclease active site. Two mutations immediately adjacent to the proposed nuclease active site (amino acids 640 and 693) impair nuclease activity in the absence of ATP but completely abolish nuclease activity in the presence of ATP. These results suggest that, although the Dna2 helicase and nuclease activities can be independently affected by some mutations, the two activities appear to interact, and the nuclease activity is regulated in a complex manner by ATP. Physiological analysis shows that both ATPase and nuclease are important for the essential function of DNA2 in DNA replication and for its role in double-strand break repair. Four of the nuclease mutants are not only loss of function mutations but also exhibit a dominant negative phenotype.     

Modulation of the herpes simplex virus type-1 UL9 DNA helicase by its cognate single-strand DNA-binding protein, ICP8

The mechanism of stimulation of a DNA helicase by its cognate single-strand DNA-binding protein was examined using herpes simplex virus type-1 UL9 DNA helicase and ICP8. UL9 and ICP8 are two essential components of the viral replisome that associate into a complex to unwind the origins of replication. The helicase and DNA-stimulated ATPase activities of UL9 are greatly elevated as a consequence of this association. Given that ICP8 acts as a single-strand DNA-binding protein, the simplest model that can account for its stimulatory effect predicts that it tethers UL9 to the DNA template, thereby increasing its processivity. In contrast to the prediction, data presented here show that the stimulatory activity of ICP8 does not depend on its single-strand DNA binding activity. Our data support an alternative hypothesis in which ICP8 modulates the activity of UL9. Accordingly, the data show that the ICP8-binding site of UL9 constitutes an inhibitory region that maintains the helicase in an inefficient ground state. ICP8 acts as a positive regulator by neutralizing this region. ICP8 does not affect substrate binding, ATP hydrolysis, or the efficiency of translocation/DNA unwinding. Rather, we propose that ICP8 increases the efficiency with which substrate binding and ATP hydrolysis are coupled to translocation/DNA unwinding.     

The severe acute respiratory syndrome (SARS) coronavirus NTPase/helicase belongs to a distinct class of 5' to 3' viral helicases

The putative NTPase/helicase protein from severe acute respiratory syndrome coronavirus (SARS-CoV) is postulated to play a number of crucial roles in the viral life cycle, making it an attractive target for anti-SARS therapy. We have cloned, expressed, and purified this protein as an N-terminal hexahistidine fusion in Escherichia coli and have characterized its helicase and NTPase activities. The enzyme unwinds double-stranded DNA, dependent on the presence of a 5' single-stranded overhang, indicating a 5'o 3' polarity of activity, a distinct characteristic of coronaviridae helicases. We provide the first quantitative analysis of the polynucleic acid binding and NTPase activities of a Nidovirus helicase, using a high throughput phosphate release assay that will be readily adaptable to the future testing of helicase inhibitors. All eight common NTPs and dNTPs were hydrolyzed by the SARS helicase in a magnesium-dependent reaction, stimulated by the presence of either single-stranded DNA or RNA. The enzyme exhibited a preference for ATP, dATP, and dCTP over the other NTP/dNTP substrates. Homopolynucleotides significantly stimulated the ATPase activity (15-25-fold) with the notable exception of poly(G) and poly(dG), which were non-stimulatory. We found a large variation in the apparent strength of binding of different homopolynucleotides, with dT24 binding over 10 times more strongly than dA24 as observed by the apparent Km.