Purification and characterization of UL9, the herpes simplex virus type 1 origin-binding protein.

UL9, the origin-binding protein of herpes simplex virus type 1 (HSV-1), has been overexpressed in an insect cell overexpression system and purified to homogeneity. In this report, we confirm and extend recent findings on the physical properties, enzymatic activities, and binding properties of UL9. We demonstrate that UL9 exists primarily as a homodimer in solution and that these dimers associate to form a complex nucleoprotein structure when bound to the HSV origin of replication. We also show that UL9 is an ATP-dependent helicase, capable of unwinding partially duplex DNA in a sequence-independent manner. Although the helicase activity of UL9 is demonstrable on short duplex substrates in the absence of single-stranded DNA-binding proteins, the HSV single-stranded DNA-binding protein ICP8 (but not heterologous binding proteins) stimulates UL9 to unwind long DNA sequences of over 500 bases. We were not able to demonstrate unwinding of fully duplex DNA sequences containing the HSV origin of replication. However, in experiments designed to detect origin-dependent unwinding, we did find that UL9 wraps supercoiled DNA independent of sequence or ATP hydrolysis.     

Binding of the herpes simplex virus type 1 UL9 gene product to an origin of viral DNA replication.

The binding of a herpes simplex virus type 1 (HSV-1) encoded polypeptide to a viral origin of DNA replication has been studied by using a gel retardation assay. Incubation of nuclear extract from HSV-1 infected cells with a labelled origin-containing fragment resulted in the formation of a specific retarded complex, the migration of which was further reduced in the presence of an antibody reactive with the UL9 gene product. Introduction of an additional copy of the UL9 gene, under the control of an immediate early (IE) promoter, conferred the ability to express origin binding activity at the non-permissive temperature upon an HSV-1 ts mutant blocked at the IE stage of infection. Endogenous or exogenous proteolytic activity revealed the presence of a relatively protease-resistant domain which retained sequence-specific DNA binding activity. The C-terminal 317 amino acids of the UL9 gene expressed as a fusion protein in Escherichia coli also bound to the origin. Our results demonstrate that the UL9 gene product binds to a viral origin and that sequence specific recognition and binding are specified by the C-terminal 37% of the polypeptide.     

The herpes simplex virus type 1 origin-binding protein carries out origin specific DNA unwinding and forms stem-loop structures.

The UL9 protein of herpes simplex virus type 1 (HSV-1) binds specifically to the HSV-1 oriS and oriL origins of replication, and is a DNA helicase and DNA-dependent NTPase. In this study electron microscopy was used to investigate the binding of UL9 protein to DNA fragments containing oriS. In the absence of ATP, UL9 protein was observed to bind specifically to oriS as a dimer or pair of dimers, which bent the DNA by 35 degrees +/- 15 degrees and 86 degrees +/- 38 degrees respectively, and the DNA was deduced to make a straight line path through the protein complex. In the presence of 4 mM ATP, binding at oriS was enhanced 2-fold, DNA loops or stem-loops were extruded from the UL9 protein complex at oriS, and the DNA in them frequently appeared highly condensed into a tight rod. The stem-loops contained from a few hundred to over one thousand base pairs of DNA and in most, oriS was located at their apex, although in some, oriS was at a border. The DNA in the stem-loops could be stabilized by photocrosslinking, and when Escherichia coli SSB protein was added to the incubations, it bound the stem-loops strongly. Thus the DNA strands in the stem-loops exist in a partially paired, partially single-stranded state presumably making them available for ICP8 binding in vivo. These observations provide direct evidence for an origin specific unwinding by the HSV-1 UL9 protein and for the formation of a relatively stable four-stranded DNA in this process.     

Unwinding of a herpes simplex virus type 1 origin of replication (Ori(S)) by a complex of the viral origin binding protein and the single-stranded DNA binding protein

A herpes simplex virus type 1 (HSV-1) Ori(S) analogue in which the A+T sequence linking the box I and II elements was replaced by two single-stranded oligo(dT)s is unwound by the UL9 protein-ICP8 complex. Unwinding of wild-type Ori(S) by the UL9 protein-ICP8 complex was also observed under conditions which destabilize the A+T sequence. These experiments support a model for the unwinding of Ori(S) in which destabilization of the A+T sequence can generate a single-stranded DNA binding site for ICP8, which then associates with the UL9 protein bound to boxes I and II to promote the bidirectional unwinding of Ori(S).     

Functional interaction between the herpes simplex virus type 1 polymerase processivity factor and origin-binding proteins: enhancement of UL9 helicase activity

The origin (ori)-binding protein of herpes simplex virus type 1 (HSV-1), encoded by the UL9 open reading frame, has been shown to physically interact with a number of cellular and viral proteins, including three HSV-1 proteins (ICP8, UL42, and UL8) essential for ori-dependent DNA replication. In this report, it is demonstrated for the first time that the DNA polymerase processivity factor, UL42 protein, provides accessory function to the UL9 protein by enhancing the 3'-to-5' helicase activity of UL9 on partially duplex nonspecific DNA substrates. UL42 fails to enhance the unwinding activity of a noncognate helicase, suggesting that enhancement of unwinding requires the physical interaction between UL42 and UL9. UL42 increases the steady-state rate for unwinding a 23/38-mer by UL9, but only at limiting UL9 concentrations, consistent with a role in increasing the affinity of UL9 for DNA. Optimum enhancement of unwinding was observed at UL42/UL9 molecular ratios of 4:1, although enhancement was reduced when high UL42/DNA ratios were present. Under the assay conditions employed, UL42 did not alter the rate constant for dissociation of UL9 from the DNA substrate. UL42 also did not significantly reduce the lag period which was observed following the addition of UL9 to DNA, regardless of whether UL42 was added to DNA prior to or at the same time as UL9. Moreover, addition of UL42 to ongoing unwinding reactions increased the steady-state rate for unwinding, but only after a 10- to 15-min lag period. Thus, the increased affinity of UL9 for DNA most likely is the result of an increase in the rate constant for binding of UL9 to DNA, and it explains why helicase enhancement is observed only at subsaturating concentrations of UL9 with respect to DNA. In contrast, ICP8 enhances unwinding at both saturating and subsaturating UL9 concentrations and reduces or eliminates the lag period. The different means by which ICP8 and UL42 enhance the ability of UL9 to unwind DNA suggest that these two members of the presumed functional replisome may act synergistically on UL9 to effect initiation of HSV-1 DNA replication in vivo.     

Interaction of herpes simplex virus type 1 DNA polymerase and the UL42 accessory protein with a model primer template.

Genetic and biochemical studies have shown that the products of the herpes simplex virus type 1 (HSV-1) DNA polymerase (UL30) and UL42 genes are both required for viral DNA replication. A number of studies have previously suggested that these two proteins specifically interact, and more recent studies have confirmed that the viral DNA polymerase from HSV-1-infected cells consists of a heterodimer of the UL30 (Pol; the catalytic subunit) and UL42 polypeptides. A comparison of the catalytic properties of the Pol-UL42 complex with those of the isolated subunits of the enzyme purified from recombinant baculovirus-infected insect cells indicated that the Pol-UL42 complex is more highly processive than Pol alone on singly primed M13 single-stranded substrates. The results of these studies are consistent with the idea that the UL42 polypeptide is an accessory subunit of the HSV-1 DNA polymerase that acts to increase the processivity of polymerization. Preliminary experiments suggested that the increase in processivity was accompanied by an increase in the affinity of the polymerase for the ends of linear duplex DNA. We have further characterized the effect of the UL42 polypeptide on a defined hairpin primer template substrate. Gel shift and filter binding studies show that the affinity of the Pol catalytic subunit for the 3' terminus of the primer template increases 10-fold in the presence of UL42. DNase I footprinting experiments indicate that the Pol catalytic subunit binds to the primer template at a position that protects 14 bp of the 3' duplex region and an adjacent 18 bases of the single-stranded template. The presence of the UL42 polypeptide results in the additional protection of a contiguous 5 to 14 bp in the duplex region but does not affect the 5' position of the Pol subunit. Free UL42 protects the entire duplex region of the substrate but does not bind to the single-stranded region. Taken together, these results suggest that the increase in processivity in the presence of UL42 is related to the double-stranded DNA-binding activity of free UL42 and that the role of UL42 in the DNA polymerase complex is to act as a clamp, decreasing the probability that the polymerase will dissociate from the template after each cycle of catalysis.     

Intermolecular triplex formation distorts the DNA duplex in the regulatory region of human papillomavirus type-11.

A conformational distortion in the DNA duplex at the regulatory region of human papillomavirus type-11 next to an intermolecular triplex, formed with a synthetic oligonucleotide, was investigated with several chemical probes. The sequence targeted for triplex formation borders on the binding sites for the regulatory proteins encoded by the viral E2 open reading frame. Dimethyl sulfate, diethyl pyrocarbonate, and OsO4 all react to a greater extent with nucleotides in the duplex that are immediately adjacent to the triplex as compared to other bases throughout the duplex. This hypermodification was observed on both the polypurine and polypyrimidine strands of the duplex DNA. Similar hyperreactivity of bases flanking a triplex also was seen when the contiguous target polypurine tract was effectively extended by mutating interrupting pyrimidines in the human papillomavirus type-11 sequence to purines. We propose that this hyperreactivity is due to a structural distortion caused by the junction between the triplex and the duplex tracts.     

Herpes Simplex Virus Type 1 Single Strand DNA Binding Protein and Helicase/Primase Complex Disable Cellular ATR Signaling

Herpes Simplex Virus type 1 (HSV-1) has evolved to disable the cellular DNA damage response kinase, ATR. We have previously shown that HSV-1-infected cells are unable to phosphorylate the ATR substrate Chk1, even under conditions in which replication forks are stalled. Here we report that the HSV-1 single stranded DNA binding protein (ICP8), and the helicase/primase complex (UL8/UL5/UL52) form a nuclear complex in transfected cells that is necessary and sufficient to disable ATR signaling. This complex localizes to sites of DNA damage and colocalizes with ATR/ATRIP and RPA, but under these conditions, the Rad9-Rad1-Hus1 checkpoint clamp (9-1-1) do not. ATR is generally activated by substrates that contain ssDNA adjacent to dsDNA, and previous work from our laboratory has shown that ICP8 and helicase/primase also recognize this substrate. We suggest that these four viral proteins prevent ATR activation by binding to the DNA substrate and obstructing loading of the 9-1-1 checkpoint clamp. Exclusion of 9-1-1 prevents recruitment of TopBP1, the ATR kinase activator, and thus effectively disables ATR signaling. These data provide the first example of viral DNA replication proteins obscuring access to a DNA substrate that would normally trigger a DNA damage response and checkpoint signaling. This unusual mechanism used by HSV suggests that it may be possible to inhibit ATR signaling by preventing recruitment of the 9-1-1 clamp and TopBP1.     

The catalytic subunit of the DNA polymerase of herpes simplex virus type 1 interacts specifically with the C terminus of the UL8 component of the viral helicase-primase complex.

The herpes simplex virus type 1 (HSV-1) UL8 DNA replication protein is a component of a trimeric helicase-primase complex. Sixteen UL8-specific monoclonal antibodies (MAbs) were isolated and characterized. In initial immunoprecipitation experiments, one of these, MAb 804, was shown to coprecipitate POL, the catalytic subunit of the HSV-1 DNA polymerase, from extracts of insect cells infected with recombinant baculoviruses expressing the POL and UL8 proteins. Coprecipitation of POL was dependent on the presence of UL8 protein. Rapid enzyme-linked immunosorbent assays (ELISAs), in which one protein was bound to microtiter wells and binding of the other protein was detected with a UL8- or POL-specific MAb, were developed to investigate further the interaction between the two proteins. When tested in the ELISAs, five of the UL8-specific MAbs consistently inhibited the interaction, raising the possibility that these antibodies act by binding to epitopes at or near a site(s) on UL8 involved in its interaction with POL. The epitopes recognized by four of the inhibitory MAbs were approximately located by using a series of truncated UL8 proteins expressed in mammalian cells. Three of these MAbs recognized an epitope near the C terminus of UL8, which was subjected to fine mapping with a series of overlapping peptides. The C-terminal peptides were then tested in the ELISA for their ability to inhibit the POL-UL8 interaction: the most potent exhibited a 50% inhibitory concentration of approximately 5 microM. Our findings suggest that the UL8 protein may be involved in recruiting HSV-1 DNA polymerase into the viral DNA replication complex and also identify a potential new target for antiviral therapy.     

Helicase motif Ia is involved in single-strand DNA-binding and helicase activities of the herpes simplex virus type 1 origin-binding protein,UL9

UL9 is a multifunctional protein essential for herpes simplex virus type 1 (HSV-1) replication in vivo. UL9 is a member of the superfamily II helicases and exhibits helicase and origin-binding activities. It is thought that UL9 binds the origin of replication and unwinds it in the presence of ATP and the HSV-1 single-stranded DNA (ssDNA)-binding protein. We have previously characterized the biochemical properties of mutants in all helicase motifs except for motif Ia (B. Marintcheva and S. Weller, J. Biol. Chem. 276:6605-6615, 2001). Structural information for other superfamily I and II helicases indicates that motif Ia is involved in ssDNA binding. By analogy, we hypothesized that UL9 motif Ia is important for the ssDNA-binding function of the protein. On the basis of sequence conservation between several UL9 homologs within the Herpesviridae family and distant homology with helicases whose structures have been solved, we designed specific mutations in motif Ia and analyzed them genetically and biochemically. Mutant proteins with residues predicted to be involved in ssDNA binding (R112A and R113A/F115A) exhibited wild-type levels of intrinsic ATPase activity and moderate to severe defects in ssDNA-stimulated ATPase activity and ssDNA binding. The S110T mutation targets a residue not predicted to contact ssDNA directly. The mutant protein with this mutation exhibited wild-type levels of intrinsic ATPase activity and near wild-type levels of ssDNA-stimulated ATPase activity and ssDNA binding. All mutant proteins lack helicase activity but were able to dimerize and bind the HSV-1 origin of replication as well as wild-type UL9. Our results indicate that residues from motif Ia contribute to the ssDNA-binding and helicase activities of UL9 and are essential for viral growth. This work represents the successful application of an approach based on a combination of bioinformatics and structural information from related proteins to deduce valuable information about a protein of interest.     

A truncated herpes simplex virus origin binding protein which contains the carboxyl terminal origin binding domain binds to the origin of replication but does not alter its conformation.

We have studied the DNA binding properties of a polypeptide consisting of the carboxyl terminal 37% of UL9, the herpes simplex virus type 1 (HSV-1) origin of replication binding protein. Using a Sindbis virus expression system, we expressed and partially purified this truncated form of UL9 (UL9CT) which contains the site-specific DNA binding domain. UL9CT specifically recognized UL9 binding sites on a 200 base pair DNA fragment containing the HSV origin ori(s) and appeared to bind as a dimer to each site. DNAse I footprint analysis showed that UL9CT protected the two high affinity binding sites of ori(s), but unlike full-length UL9, UL9CT did not induce a conformational change in the origin. Addition of anti-UL9CT antibody to the UL9CT-origin complex, however, caused a conformational change in the origin to be evident. Our results suggest that a domain, or domains, in the amino terminus are necessary for a UL9-induced origin conformational change to occur and that UL9-UL9 interactions between binding sites are involved.     

Effect of third strand composition on the triple helix formation: purine versus pyrimidine oligodeoxynucleotides.

Exon 5 of the human aprt gene contains an oligo-purine-oligopyrimidine stretch of 17 bp (5'-CCCTCTTCTCTCTCCT-3') within the coding region. (T,C)-, (G,T)- and (G,A)-containing oligonucleotides were compared for their ability to form stable triple helices with their DNA target. (G,T) oligodeoxynucleotides, whether parallel or antiparallel, were unable to bind to this sequence. This is in contrast to (G,A) (purine) and (T,C) (pyrimidine) oligonucleotides, which bind to the duplex at near neutral pH. Binding was highly sequence specific, as unrelated competitors were unable to interfere with target recognition. A major difference between the purine and pyrimidine oligodeoxynucleotides was observed in the kinetics of binding: the (G,A) oligonucleotide binds to its target much faster than the (T,C) oligomer. With the purine oligonucleotide, complete binding was achieved in a matter of minutes at micromolar concentrations, whereas several hours were required with the pyrimidine oligomer. Thus, the general observation that triplex formation is slow with pyrimidine oligodeoxynucleotides does not hold for (G,A) oligodeoxynucleotides. Purine and pyrimidine oligodeoxynucleotides covalently linked to a psoralen group were able to induce crosslinks on the double-stranded DNA target upon UV irradiation. This study provides a detailed comparison of the different types of DNA triplexes under the same experimental conditions.     

Design, biochemical, biophysical and biological properties of cooperative antisense oligonucleotides.

Short oligonucleotides that can bind to adjacent sites on target mRNA sequences are designed and evaluated for their binding affinity and biological activity. Sequence-specific binding of short tandem oligonucleotides is compared with a full-length single oligonucleotide (21mer) that binds to the same target sequence. Two short oligonucleotides that bind without a base separation between their binding sites on the target bind cooperatively, while oligonucleotides that have a one or two base separation between the binding oligonucleotides do not. The binding affinity of the tandem oligonucleotides is improved by extending the ends of the two oligonucleotides with complementary sequences. These extended sequences form a duplex stem when both oligonucleotides bind to the target, resulting in a stable ternary complex. RNase H studies reveal that the cooperative oligonucleotides bind to the target RNA with sequence specificity. A short oligonucleotide (9mer) with one or two mismatches does not bind at the intended site, while longer oligonucleotides (21mers) with one or two mismatches still bind to the same site, as does a perfectly matched 21mer, and evoke RNase H activity. HIV-1 inhibition studies reveal an increase in activity of the cooperative oligonucleotide combinations as the length of the dimerization domain increases.     

The herpes simplex virus type 1 DNA polymerase processivity factor, UL42, does not alter the catalytic activity of the UL9 origin-binding protein but facilitates its loading onto DNA

The herpes simplex virus type 1 UL42 DNA polymerase processivity factor interacts physically with UL9 and enhances its ability to unwind short, partially duplex DNA. In this report, ATP hydrolysis during translocation of UL9 on single-stranded (ss) or partially duplex DNA was examined in the presence and absence of UL42 to determine the effect of UL42 on the catalytic function of UL9. Our studies reveal that a homodimer of UL9 is sufficient for DNA translocation coupled to ATP hydrolysis, and the steady-state ATPase catalytic rate was greater on partially duplex DNA than on ss DNA in the presence or absence of UL42. Although UL42 protein increased the steady-state rate for ATP hydrolysis by UL9 during translocation on either partially duplex or ss DNA, UL42 had no significant effect on the intrinsic ATPase activity of UL9. UL42 also had no effect on the catalytic rate of ATP hydrolysis when UL9 was not limiting but enhanced the steady-state ATPase rate at only subsaturating UL9 concentrations. At subsaturating UL9 to DNA ratios, stoichiometric concentrations of UL42 were shown to increase the amount of UL9 bound to ss DNA at equilibrium. These data support a model whereby UL42 increases the ability of UL9 to load onto DNA, thus increasing its ability to assemble into a functional complex capable of unwinding duplex DNA.     

Formation of stable DNA triplexes

Triple-helical nucleic acids are formed by binding an oligonucleotide within the major groove of duplex DNA. These complexes offer the possibility of designing oligonucleotides which bind to duplex DNA with considerable sequence specificity. However, triple-helix formation with natural nucleotides is limited by (i) the requirement for low pH, (ii) the requirement for homopurine target sequences, and (iii) their relatively low affinity. We have prepared modified oligonucleotides to overcome these limitations, including the addition of positive charges to the sugar and/or base, the inclusion of cytosine analogues, the development of nucleosides for recognition of pyrimidine interruptions and the attachment of one or more cross-linking groups. By these means we are able to generate triplexes which have high affinities at physiological pH at sequences that contain pyrimidine interruptions.     

Rep-dependent initiation of adeno-associated virus type 2 DNA replication by a herpes simplex virus type 1 replication complex in a reconstituted system

Productive infection by adeno-associated virus type 2 (AAV) requires coinfection with a helper virus, e.g., adenovirus or herpesviruses. In the case of adenovirus coinfection, the replication machinery of the host cell performs AAV DNA replication. In contrast, it has been proposed that the herpesvirus replication machinery might replicate AAV DNA. To investigate this question, we have attempted to reconstitute AAV DNA replication in vitro using purified herpes simplex virus type 1 (HSV-1) replication proteins. We show that the HSV-1 UL5, UL8, UL29, UL30, UL42, and UL52 gene products along with the AAV Rep68 protein are sufficient to initiate replication on duplex DNA containing the AAV origins of replication, resulting in products several hundred nucleotides in length. Initiation can occur also on templates containing only a Rep binding site and a terminal resolution site. We further demonstrate that initiation of DNA synthesis can take place with a subset of these factors: Rep68 and the UL29, UL30, and UL42 gene products. Since the HSV polymerase and its accessory factor (the products of the UL30 and UL42 genes) are unable to efficiently perform synthesis by strand displacement, it is likely that in addition to creating a hairpin primer, the AAV Rep protein also acts as a helicase for DNA synthesis. The single-strand DNA binding protein (the UL29 gene product) presumably prevents reannealing of complementary strands. These results suggest that AAV can use the HSV replication apparatus to replicate its DNA. In addition, they may provide a first step for the development of a fully reconstituted AAV replication assay.     

Herpes simplex virus-1 helicase-primase. Physical and catalytic properties.

Herpes simplex virus type 1 (HSV-1) encodes a helicase-primase that consists of the products of the UL5, UL8, and UL52 genes (Crute, J. J., Tsurumi, T., Zhu, L., Weller, S. K., Olivo, P. D., Challberg, M. D., Mocarski, E. S. and Lehman, I. R. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 2186-2189). Further characterization of the three-subunit enzyme isolated from HSV-1-infected CV-1 cells shows it to be a heterotrimer, consisting of one polypeptide encoded by each of the UL5, UL8, and UL52 genes. Analysis of the primase and helicase components of the HSV-1 helicase-primase has shown that the primase component synthesizes oligoribonucleotide primers 8-12 nucleotides in length. The helicase component unwinds duplex DNA substrates at the rate of about two nucleotides/s, but only in the presence of the HSV-1-encoded single-stranded DNA binding protein. Thus, the HSV-1 helicase-primase contains the requisite enzymatic activities that permit it to function at the viral replication fork.     

Design and simple routes of synthesis of oligonucleotide conjugates for studies of DNA triple helix formation

A series of oligonucleotides conjugated to intercalators, as well as fluorescent and lipophilic substances, minor groove binders and photoactive molecules were synthesized for studies of their ability to form a stable triple helix. Purine-rich short double stranded DNA fragments from HIV-1 genome and pyrimidine 16-mer oligodeoxyribonucleotide were used as models. A conjugate of a dipyrido[3,2-a:2',3'-c]phenazine-ruthenium (II) complex and a triple helix-forming oligonucleotide was constructed. Upon sequence-specific duplex and triplex formation of the conjugate, the ruthenium complex becomes highly fluorescent. The attached ruthenium complex induces a stabilization of the DNA triple helix and a significant increase of the time of residence of the third strand on the duplex.     

DESIGN AND SIMPLE ROUTES OF SYNTHESIS OF OLIGONUCLEOTIDE CONJUGATES FOR STUDIES OF DNA TRIPLE HELIX FORMATION

A series of oligonucleotides conjugated to intercalators, as well as fluorescent and lipophilic substances, minor groove binders and photoactive molecules were synthesized for studies of their ability to form a stable triple helix. Purine-rich short double stranded DNA fragments from HIV-1 genome and pyrimidine 16-mer oligodeoxyribonucleotide were used as models. A conjugate of a dipyrido[3,2-a:2′,3′-c]phenazine-ruthenium (II) complex and a triple helix-forming oligonucleotide was constructed. Upon sequence-specific duplex and triplex formation of the conjugate, the ruthenium complex becomes highly fluorescent. The attached ruthenium complex induces a stabilization of the DNA triple helix and a significant increase of the time of residence of the third strand on the duplex.