Crystal Structure of the Herpes Simplex Virus 1 DNA Polymerase

doi:10.1074/jbc.M602414200

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Crystal Structure of the Herpes Simplex Virus 1 DNA Polymerase^*

Shenping Liu¹, John D. Knafels, Jeanne S. Chang, Gregory A. Waszak, Eric T. Baldwin², Martin R. Deibel, Jr.³, Darrell R. Thomsen⁴, Fred L. Homa⁵, Peter A. Wells, Monica C. Tory, Roger A. Poorman⁶, Hua Gao, Xiayang Qiu, and Andrew P. Seddon

From the Pfizer Inc., Groton, Connecticut 06340

Received for publication, March 15, 2006 , and in revised form, April 24, 2006.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Herpesviruses are the second leading cause of human viral diseases.Herpes Simplex Virus types 1 and 2 and Varicella-zoster virusproduce neurotropic infections such as cutaneous and genitalherpes, chickenpox, and shingles. Infections of a lymphotropicnature are caused by cytomegalovirus, HSV-6, HSV-7, and Epstein-Barrvirus producing lymphoma, carcinoma, and congenital abnormalities.Yet another series of serious health problems are posed by infectionsin immunocompromised individuals. Common therapies for herpesviral infections employ nucleoside analogs, such as Acyclovir,and target the viral DNA polymerase, essential for viral DNAreplication. Although clinically useful, this class of drugsexhibits a narrow antiviral spectrum, and resistance to theseagents is an emerging problem for disease management. A betterunderstanding of herpes virus replication will help the developmentof new safe and effective broad spectrum anti-herpetic drugsthat fill an unmet need. Here, we present the first crystalstructure of a herpesvirus polymerase, the Herpes Simplex Virustype 1 DNA polymerase, at 2.7 Å resolution. The structuralsimilarity of this polymerase to other ${alpha}$ polymerases has allowedus to construct high confidence models of a replication complexof the polymerase and of Acyclovir as a DNA chain terminator.We propose a novel inhibition mechanism in which a representativeof a series of non-nucleosidic viral polymerase inhibitors,the 4-oxo-dihydroquinolines, binds at the polymerase activesite interacting non-covalently with both the polymerase andthe DNA duplex.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Only eight distinct viruses, spanning three subfamilies, designated ${alpha}$ , $beta$ , and ${gamma}$ , of the greater than 80-member Herpesviridae familyare known to cause clinically significant diseases in humans(1). Herpesviruses possess a common replication cycle in whichthe viral polymerase (POL)⁷ functions at multiple points andis thus an attractive target for the development of antiherpeticdrugs (1-3). In fact, Acyclovir, the first selective anti-viraldrug developed, targets the viral polymerase as a nucleotideanalog (2). However, drug resistances against these nucleotideanalog drugs are severe, especially among the immunocompromisedpopulation (4, 5). Alternative approaches, such as non-nucleotidedrugs, may be needed (1, 6).

The Herpesvirus polymerases exhibit a 34-90% primary sequenceidentity and range in size from 1012 to 1242 amino acids. HerpesSimplex 1 DNA polymerase (HSV POL), the prototype for the herpesvirusPOL family, has 1,235 amino acid residues and exhibits all theenzymatic functions of a polymerase (7). In addition to a polymeraseactivity required to extend the DNA primer chains, HSV POL possessesan intrinsic 3'-5'-exonuclease activity that serves as a proofreadingactivity to ensure the high fidelity of DNA replication (8).HSV POL has also been reported to have an intrinsic RNase Hactivity that presumably functions in the removal of RNA primersduring the processing of Okazaki fragments (9). The RNase Hactivity was initially attributed to a 5'-3'-exonuclease functionassociated with HSV POL; however, this activity was subsequentlyattributed to the potent 3'-5'-exonuclease of HSV POL (7). Invivo, the extreme COOH terminus of the cognate polymerase hasbeen shown at the molecular level to interact with an accessoryfactor, UL42, that serves to increase the processivity of thepolymerase (10, 11). During the predominant rolling circle modeof DNA replication, HSV POL forms a large complex with the viralprimase·helicase complex (7), the details of which, ata molecular level, have yet to be elucidated. Based on sequencesimilarity, HSV POL belongs to the POL ${alpha}$ family, which includeshuman polymerase ${alpha}$ and polymerases from animals and other viruses.Crystal structures of POL ${alpha}$ from thermophilic and archaebacteriaand the apo, editing, and replication complexes of the bacteriophageRB69 POL have been reported (12-16). These structures not onlyrevealed the general architecture of the POL ${alpha}$ polymerase butalso provide important information on interactions of the enzymewith DNA and nucleotides.

Detailed analysis of the HSV POL structure presented here withreference to those previously reported polymerase structuresprovides valuable insight into the domain functions, conformationalchanges required for catalysis, and an enhanced understandingof the herpesvirus DNA replication. Further, combined with otherexperimental data, this analysis enabled us to propose modelsfor the dead-end complex formed with Acyclovir and of a prototypecompound of non-nucleotide POL inhibitors, 4-oxo-dihydroquinolines(4-oxo-DHQ).

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Protein Expression and Purification—A fusion protein consistingof bacterial maltose-binding protein and full-length HSV 1 POLwas constructed with either one factor Xa cleavage site at thelinker region or with a second factor Xa site right after Asn-42of HSV POL. The maltose-binding protein-HSV POL fusion proteinwas expressed in a baculovirus/insect cell system, and cellswere harvested 65 h post-infection by slow speed centrifugation.Proteins were resolved by phosphocellulose chromatography, andthe pooled fusion protein was cleaved by treatment with endogenousprotease (one factor Xa site construct) or by factor Xa (constructwith two factor Xa sites). The cleaved product, Asn-42-COOH-terminal,was further purified on a hydroxyapatite column followed bya heparin column. The purified protein was >95% pure as shownvia SDS-PAGE and characterized by mass spectrum analysis, aminoacid analysis, and NH₂-terminal analysis. The purified polymeraseproved to be highly active with radioactive nucleotide incorporationassay. Selenomethionine-labeled HSV POL was expressed in thebaculovirus insect cell system (17). Judged by the disappearanceof normal methionine, $~$ 60% of normal methionine was substitutedwith selenomethionine.

Crystallization and Data Collection—Purified protein wasconcentrated to $~$ 20 mg/ml in a buffer of 20 mM HEPES, pH 7.0,100 mM guanidine HCl, 5 mM dithiothreitol, 11.1% Me₂SO, and10% glycerol. Crystals were grown by hanging drop vapor diffusionagainst a well buffer of 100 mM HEPES, pH 7.0, 50 mM ammoniumsulfate, 5 mM dithiothreitol, 100 mM guanidine HCl, and 4% polyethyleneglycol-3350. For cryoprotection, crystals were transferred intoa cryoprotectant buffer of 100 mM HEPES, pH 7.0, 60 mM ammoniumsulfate, 5 mM dithiothreitol, 100 mM guanidine HCl, 10% polyethyleneglycol-3350, 11% Me₂SO, 10% polyethylene glycol-1000 by slowexchange with mother liquor and soaked in this buffer overnight.For heavy atom soaking, heavy atom compounds were added intocryoprotectant buffer to desired concentrations. Crystals weremounted with cryoloops and cooled immediately into liquid nitrogenafterward. The crystals of HSV POL belong to space group P2₁2₁2₁,with typical unit cell dimensions of a = 103.9 Å, b =125.6 Å, c = 220.6 Å. The diffraction data werecollected on beamline 17ID of Advanced Ploton Source at ArgonneNational Laboratory (Argonne, IL) and processed with the programHKL2000 (18). Further data processing was conducted using programsuite CCP4 (19) (Table 1).

View this table:
[in this window]
[in a new window]

TABLE 1
Data collection, phasing, and refinement statistics Numbers in parentheses are in the highest resolution shell. Wavelengths used were 1.0 Å 0.9794 Å, 0.9504 Å for native and derivative crystals, respectively. Resolutions observed and used were 111.0-2.7 Å for native and 50-3.2 Å for derivative (3.5 Å for phasing). The native data set was collected on a crystal soaked in 1 mM mercury acetate for 2 h. Four weakly bound mercury atoms are found in the structure. The derivative I(hkl) and I(-h-k-l) were separated for scaling. R.m.s.d., root mean square deviation.

Structure Determination and Refinement—Molecular packingsuggested two molecules/asymmetric unit. Molecular replacementattempts with RB69 POL as search model failed to give solutions.Soaking of many different heavy atom compound solutions eitherdestroyed the diffraction or introduced very few specific bindingsites, thus very little phase information. The severe non-isomorphismbetween different crystals also severely limits the usage ofmultiple isomorphous replacement phasing method. The most promisingheavy atom derivative was from crystals soaked in 20 mM trimethylleadacetate overnight: useful anomalous signal could be detectedin a two-wavelength data set up to 5.0 Å. At this resolutionthe model building was impossible despite some secondary structureelements from one of the 3'-5'-exonuclease domains, and oneof the palm subdomains could be recognized. The structure ofHSV POL was eventually determined using multiple anomalous dispersionmethod with a crystal formed by selenomethionine-incorporatedprotein and soaked in 20 mM trimethyllead acetate overnight.The wavelengths were chosen at the absorption edges of seleniumand lead, respectively, to maximize the anomalous and dispersivesignals (Table 1). Heavy atom sites were found with the programSHELXD (20). Because selenomethionine incorporation in insectcells is still not very robust (17), the incorporation levelof the protein used in crystallization is $~$ 50-60%. Of a totalof 40 selenomethionine sites 37 were found, along with 14 leadsites. Heavy atom refinement and phase calculations were carriedout using the program MLPHARE implemented in CCP4 (19). Themaximum useful phase information is at 3.5 Å. After heavyatom refinement and phase calculations, initial electron densitywas improved with the program SOLOMON (21), and the qualityof the electron density was ready for tracing. A phased rotationand translation search of fragments of known POL structuresof the POL ${alpha}$ family in the experimentally phased electron densitymap was used to locate some known domains with the program MOLREP(22). Selenomethionine sites were used for sequence registration.A model was built with the program O (23). After model building,the initial model was refined against higher resolution nativedata (Table 1) with the refinement programs CNX (24) and REFMAC(25). In the final model, molecule A starts at 60 and ends at1197, with peptides 504-513, 640-700, 1036-1066, and 1080-1135missing. Molecule B starts at 59 and ends at 1197, with peptides236-240, 641-700, and 1098-1135 missing. Peptide 641-700 isthe linking peptide between the NH₂-terminal domain and thepolymerase domain. Peptide 1198 to the carboxyl end of the molecule(1235) is involved in accessory factor binding (10, 11). Othermissing peptides are all located at the protein surface. Somesurface peptides such as NB, NC, P3, P4, and PB (Fig. 1) havevery large temperature factors, reflecting their flexibility.To compare protein structures, domain superimposition of HSVPOL with other polymerase structures was carried out using theprogram LSQMAN (26).

4-Oxo-DHQ Binding Assay—Mixtures of HSV POL (100 nM) and/oractivated calf thymus DNA (Amersham Biosciences) and/or a ¹⁴C-labeled4-oxo-DHQ (PHA-708620, an analog of PNU-183792) (6) were incubatedfor 5 min and then subjected to rapid filtration by centrifugation(3 min, 14,000 x g) in a Microcon centrifugal concentrator unit(30,000 MWCO, cellulose membrane; Millipore). Aliquots of theresulting filtrate were scintillation counted (Ultima Gold scintillant).Comparison of the quantity of the 4-oxo-DHQ in the filtrateof test samples relative to control samples ([¹⁴C]4-oxo-DHQonly) yielded a measure of the amount of bound and free 4-oxo-DHQ.All steps were performed at ambient temperature. The buffersolutions used were either 6.4 mM sodium HEPES, 1 mM Tris-HCl,11.7 mM KCl, 0.025 mM NaCl, 4.5 or 10 mM MgCl₂ (or CaCl₂), 0.1mM EDTA, 2 mM CHAPS, 4.5 mM dithiothreitol, 5% glycerol, 5%Me₂SO, 0.046 mg/ml of bovine serum albumin, 0.001% azide, pH7.5.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The overall architecture of HSV POL closely resembles that ofother POL ${alpha}$ structures despite being at least 300 amino acidresidues longer and exhibiting a low sequence homology (range16-50%). HSV POL is comprised of 6 structure domains: a pre-NH₂domain, an NH₂ domain, a 3'-5'-exonuclease domain, and polymerasepalm, fingers, and thumb domains. Based on sequence conservationin the POL ${alpha}$ polymerases family (5), the exonuclease domain containsconserved regions exo I, exo II (region IV), and exo III ( ${delta}$ -Cregion). Regions III and VI belong to the fingers, regions I,II, and VII are located in the palm subdomain, and the thumbsubdomain contains the conserved region V (Fig. 1A). These domainsassemble to form a disk-like shape around a central hole, withthe NH₂ and COOH termini at opposite sides of the protein (Fig. 1A).Three grooves can be seen emanating from the central hole (Fig. 1B).The first groove, located at the interface of NH₂-terminal andexonuclease domains, is lined with positively charged side chains(Fig. 1B). In the RB69 POL replicating complex structure (14,15), the analogous groove binds the 5'-extension of the single-strandedDNA template (16). In HSV POL these positively charged sidechains are predicted to interact with the phosphate backboneof the single-stranded DNA template. The second groove, locatedbetween the exonuclease domain and the tip of the thumb domain,leads to the putative exonuclease active site. In the RB69 POLediting complex structures (14, 15), the unwound primer strandbinds in this groove. The DNA duplex, in both the editing andreplicating complex structures, binds to a third groove formedby the palm and thumb subdomains (15, 16).

In the HSV POL crystal form there are two molecules in the crystallographicasymmetry unit. Each molecule adopts a slightly different conformationand can be superimposed as two groups. Group 1 consists of thepre-NH₂-terminal, NH₂-terminal, the exonuclease domain, andthe finger domain (root mean square deviation 0.8 A for 595C ${alpha}$ ). Group 2 consists of the palm and thumb domains (root meansquare deviation 0.95 A for 300 C ${alpha}$ ). Both conformations are closeto the open state observed in the apo RB69 POL structure (14);however, some conformational differences are observed when eitherof the two conformations of the HSV POL molecules is comparedwith RB69 POL and other POL ${alpha}$ structures. No consistent concertedmotions among different domains are observed when multiple structuresare compared. The 3'-5'-exonuclease domain and polymerase palm,fingers, and thumb domains of HSV POL can be individually superimposedwith the equivalent domain structures from other POL ${alpha}$ structures.In the POL ${alpha}$ -conserved regions all the residues of HSV POL canbe superimposed with those in RB69 POL. For example, the residuesof the secondary structures of the 3'-5'-exonuclease domain,essential for the fidelity of the viral DNA duplication (27),can be overlaid with those of RB69 POL, bringing Asp-368, Glu-370,and Asp-471 of HSV POL to Asp-114, Glu-116, and Asp-222 of RB69POL that form the metal binding site for the nuclease activity(15). Key residues for polymerase catalysis are located on thepalm and fingers domains and are superimposable with those ofother POL ${alpha}$ and will be discussed in the modeling section. Inthe structures of RB69 POL the thumb domain interacts with thebackbone of DNA duplex, and the tip and base of this domainadopt different conformations at the editing and replicationmodes. Interestingly, the conformation of the thumb domain ofHSV POL is similar to that of the replicating conformation ofRB69 POL and thus does not require a large conformational changeupon DNA binding (Fig. 1B). Sequence conservation in the thumbdomain does not need to be high, as DNA duplex binding involvescollective interactions; however, high sequence conservationof this domain in the herpes POL family as well as the conservedregion V across POL ${alpha}$ family does make sense in the context ofinteracting with DNA duplex backbone (e.g. Arg-959, Arg-1039,His-1051, and Arg-1071). Large deletions or insertions in thesedomains of the POL ${alpha}$ family usually occur at loops or form someadditional secondary structures distant from the catalytic centers.

HSV POL possesses a 250-amino acid NH₂-terminal extension relativeto RB69 POL that forms the pre-NH₂- and part of the NH₂-terminaldomains. The pre-NH₂-terminal domain is unique to the herpesDNA POL family, and its function is unknown. With the exceptionof the first 42 residues, which are not present in our constructand are unique to herpes simplex 1 and 2 POL, the sequence similaritiesof this domain are high among the herpes POL family members.With the exception of two short $beta$ strands forming an anti-parallel $beta$ sheet, this domain lacks defined secondary structural elements(Fig. 2A) and interacts mainly with the 3'-5'-exonuclease domainlocated at the surface of the protein. Topologically, the highlyconserved FYNPYL sequence at the NH₂ terminus of this domainis positioned directly upstream of the putative binding groovefor the 5'-extension of the single-stranded DNA template (Fig. 2A),suggesting a possible role for this domain in interacting withthe viral primase·helicase complex during leading strandDNA synthesis (7). If confirmed, disruption of these interactionswould provide a new path to design anti-herpes drugs.

The NH₂-terminal domain of HSV POL consists of three motifs.The first motif (141-200 and 299-362) consists of two almostperpendicular $beta$ 3 sheets (N1, N9 and N11, and N2, N3, N4, N10)plus short ${alpha}$ helices NA and NE. The second motif (201-298) isa $beta$ ${alpha}$ $beta$ $beta$ ${alpha}$ $beta$ fold (N5, NC, N6, N7, ND, and N8), and the third (594-639)consists of two helixes separated in primary sequence from thefirst two motifs by the 3'-5'-exonuclease domain (Fig. 2B).The first motif is conserved within the herpes POL family, butwith the NH₂-terminal extension it is much larger than the equivalentdomain in known ${alpha}$ POL structures. The $beta$ ${alpha}$ $beta$ $beta$ ${alpha}$ $beta$ motif is a typical RNAbinding motif (RNP) found in ribonucleoproteins (28). The four $beta$ strands and two ${alpha}$ helices of this motif approximately superimposewith those of human ribonucleoprotein A1 (PDB code 1HA1) witha root mean square deviation of 1.61 for 46 C ${alpha}$ atoms. In theRNP motif, the face of the $beta$ sheet above the ${alpha}$ helices providesan open platform for RNA binding (28). The analogous face inHSV POL contains a cluster of highly conserved positive charged(Arg-255, Arg-270, and Arg-302) and aromatic (Tyr-204, Tyr-206,and Tyr-293) residues that could interact with the RNA backboneand bases (Fig. 2B). The third motif of this domain has a structurecommon to others members of the POL ${alpha}$ family and consists oftwo ${alpha}$ helices of similar length, NF and NH, connected by a short ${alpha}$ helix NG (HSV POL) or a loop. Together with the first and thethird motifs of this domain, the putative RNA binding face formsa cleft that would likely accommodate the binding of an RNAor DNA terminus. In support of this, all of the RB69 POL structurescontain a guanine nucleotide in this pocket (14-16).

View larger version (49K):
[in this window]
[in a new window]

FIGURE 1.
A, overall structure of herpes simplex 1 DNA polymerase in ribbon diagram. Pre-NH₂ domain, NH₂-terminal domain, 3'-5'-exonuclease domain, polymerase palm subdomain, finger subdomain, and thumb subdomain are colored pink, cyan, yellow, green, red, and blue, respectively. Domain boundary of HSV POL: pre-NH₂-terminal domain, from NH₂-terminal to 140; NH₂-terminal domain, 141-362 and 594-639; 3'-5'-exonuclease domain, 363-593; palm domain, 701-766 and 826-956; fingers domain, 767-825; and thumb domain, 957-1197. The COOH-terminal accessory protein binding peptide, 1200-1235, is missing in both molecules. Secondary structure assignments: pre-NH₂ domain, pN1, 74-79; pN2, 94-99. NH₂-terminal domain, N1, 146-149; N2, 151-157; NA, 169-173; N3, 179-187; N4, 193-198; N5, 204-208; NB, 209-212; NC, 221-232; N6, 249-257; N7, 266-272; ND, 276-283; N8, 290-293; NE, 299-305; N9, 314-318; N10, 341-345; N11, 350-352; NF, 594-604; NG, 610-615; NH, 618-632. 3'-5'-exonuclease domain, E1, 363-372; E2, 390-399; E3, 408-414; EA, 421-429; E4, 436-440; EB, 443-456; E5, 464-464; EC, 471-480; E6, 521-524; ED, 525-530; EE, 540-547; EF, 560-566; EG, 568-592. Palm subdomain, P1, 707-709; P2, 713-718; PA, 721-730; PB, 740-745; P3, 755-757; P4, 761-764; PC, 831-855; PD, 859-865; P5, 879-885; P6, 889-895; PE, 902-917; P7, 924-926; P8, 928-930; P9, 932-935; P10, 940-945; P11, 950-953. Fingers, FA, 773-794; FB, 797-814 and 817-822. Thumb subdomain, TA, 964-979; TB, 981-989; TC, 1005-1022; T1, 1033-1036; TD, 1050-1060; T2, 1071-1072; TE, 1087-1095; TF, 1146-1151; TG, 1158-1176; TH, 1181-1191. B, an electrostatic representation of HSV POL DNA binding surface, with duplicating DNA strands superimposed from RB69 POL structure. Red and blue colors represent negative and positive charges, respectively. Modeled template DNA strand in magenta and primer strand in yellow, with ribbon diagram for the backbone and stick model for bases and riboses. The incoming nucleotide is also modeled to indicate the polymerase active site (carbon atoms in cyan). Panel B is roughly a back view of panel A. Figs. 1A and 3, A, B, and D, are generated with the program MOLSCRIPT (32) and Figs. 1B and 2, A and B, with PyMol (33).

Of a controversial nature are reports that HSV POL possessesan intrinsic 5'-3'-RNase H activity that specifically degradesRNA·DNA heteroduplexes or duplex DNA (7, 9). This activityis required for the excision of the RNA primers that initiatethe synthesis of Okazaki fragments at the replication fork duringthe lagging strand DNA synthesis (7). The existence of an RNAbinding motif in this domain suggests that this could be the5'-3'-RNase H catalytic center. Inspection of the HSV POL structurereveals a cluster of residues that could form a metal ion bindingsite necessary for nuclease activity. In the RB69 POL structuresa cluster of highly conserved residues, Glu-294, Asp-306, andTyr-204, are observed near the phosphate tail of the guaninenucleotide. Topologically, binding of a single strand RNA primeror DNA in this cleft during DNA replication is plausible whenone considers that the cleft is on the opposite side of theDNA binding surface (Fig. 1, A and B). Conversely, by analogywith other POL ${alpha}$ , the possibility cannot be excluded of the involvementof this domain in the autoregulation of the POL synthesis viabinding to its own mRNA (12, 13).

A model of the replication complex of HSV POL was constructedby superimposing individual domains of HSV POL onto those ofthe replication complex of RB69 POL. The palm domain of thereplicating RB69 POL complex was chosen as the reference, andthe HSV POL domains were individually superimposed onto theRB69 POL structure. In all apo-POL ${alpha}$ , as well as in the editingcomplex RB69 POL structures, there is a kink at the highly conservedresidues Asn-815-Ser-816 on the second ${alpha}$ helix (FB) of the fingerdomain. In the replicating RB69 POL complex structure the FBhelix is continuous, and our model was adjusted accordingly.The continuous nature of helix FB is required to bring the highlyconserved Tyr-818-Gly-819 (Tyr-567-Gly-568 in RB69 POL) intoclose proximity with the catalytic site (Fig. 3A). No adjustmentswere made to smooth out the joints between domains after superimposition,and only a few side chains of key residues needed to be adjustedto adopt the conformations present in the RB69 POL replicatingcomplex (Fig. 3A). This simple model can easily explain thesequence activity relationship of HSV POL (Fig. 3A). The sidechains of Asp-717, Asp-888, and carbonyl oxygen of Phe-718 (Asp-411,Asp-623, and Leu-412 in RB69 POL) are involved in metal ioncoordination required for the polymerase catalysis. The riboseof the incoming nucleotide also interacts with Leu-721 and Tyr-722and with the strictly conserved Tyr-722, providing a "stericgating" effect against incorporation of ribonucleotides (16).The positively charged side chains of Arg-785, Arg-789, andLys-811 from the fingers domain interact with the phosphategroups of the incoming nucleotide (Fig. 3A) and are importantfor the positioning of the phosphate moiety to the 3'-OH ofthe primer end and for neutralizing the accumulated negativecharge of the reaction intermediate (16). The side chain ofAsn-815 stacks against the base of the incoming nucleotide andprovides an explanation for the resistance of HSV POL N815S/Tmutant to Acyclovir (5). The side chain of Tyr-818 preventsthe protrusion of mismatched nascent base pairs into the DNAminor groove, ensuring the incorporation of the correct nucleotides(16). The single-stranded template would make a sharp turn atthe POL active site and extend into the groove formed betweenthe NH₂-terminal domain and the exonuclease domain. The DNAduplex would exit through the groove between the thumb and palmdomains close to the COOH-terminal region that interacts withUL42. During rolling circle DNA replication, HSV POL could potentiallyinteract with the viral helicase·primase complex throughthe pre-NH₂ domain to process the newly unwound single-strandedDNA template. The HSV POL accessory protein UL42 increases theprocessivity of the polymerase by anchoring HSV POL to the newlysynthesized DNA duplex through the interactions with the COOH-terminalregion.

View larger version (59K):
[in this window]
[in a new window]

FIGURE 2.
Unique functional domains of herpes simplex 1 DNA polymerase. A, a ribbon diagram of the pre-NH₂-terminal domain in cyan, with electrostatic surface representation of the putative single-stranded DNA binding groove. For clarity, only surfaces from NH₂-terminal and exonuclease domains are shown. The DNA duplex is modeled. B, ribbon diagram of the NH₂-terminal domain embedded in the electrostatic surface representation to show the putative RNA binding cleft. The $beta$ ${alpha}$ $beta$ $beta$ ${alpha}$ motif is on the left.

Selective nucleoside POL inhibitors, such as Acyclovir, becomeactive after being converted to triphosphates by viral and cellularenzymes and being incorporated into the 3'-end of the growingprimer strand (3, 4). Using synthetic oligonucleotide duplexto study single dNTP incorporation, it has been shown that althoughAcyclovir triphosphate, mimicking a incoming dGTP substrate,can inhibit HSV POL competitively against dGTP incorporation,potent inhibition of HSV POL was observed only upon bindingof the next dNTP coded by the template subsequent to the incorporationof Acyclovir monophosphate onto the 3'-end of the primer (29).Combined with the fact that the Acyclovir monophosphate-incorporatedDNA duplex alone does not inhibit HSV POL strongly (29), itis fair to suggest that the dead-end complex of HSV POL withthe next incoming nucleotide and the Acyclovir monophosphate-incorporatedDNA duplex mimics a replicating complex. In our HSV POL replicationmodel (Fig. 3A) and model of the Acyclovir monophosphate·HSVPOL dead-end complex (Fig. 3B), the side chain of conservedresidues Tyr-722 and Tyr-887 would limit modifications on theribose for the incorporation of the inhibitor and the bindingof the modified DNA duplex (3). The correctly matched base pairingof the incorporated inhibitor with the template strand, andsmaller chemical moieties linked to the bases, would not bepredicted to interfere with the binding of the complementaryincoming nucleotide or distort the geometry of minor grooveof the newly formed product DNA that would interact with theconserved KKKY (938-941) motif and the side chains of Tyr-818,Tyr-884, and Asp-886 (Fig. 3, A and B). These interactions,which involve the penultimate base pair, would normally servethe function of sensing mismatches in the newly formed DNA duplex(16). Together with the nascent base pair, these interactionsare apparently sufficient to lock HSV POL into a dead-end complex,thus terminating DNA chain elongation. A large part of the specificityof these nucleoside inhibitors is derived from the specificphosphorylation of the prodrug form by viral nucleotide kinases(2), and drug resistance can arise from mutations of these viralproteins (5). Because these compounds have to be covalentlyincorporated, resistance mutations in the POL gene may occurat sites that modulate the kinetics of the reactions catalyzedby HSV POL. To avoid lethality, mutations that confer drug resistanceagainst nucleoside inhibitors usually occur at sites that arenot directly involved in catalysis, such as the invariant YGDTDS(884-889) sequence in region I (5). Indeed, mutations in HSVPOL from the common Acyclovir-resistant virus strains causealtered K_m and K_cat, but they do not directly contact with inhibitorin our model (30).

View larger version (84K):
[in this window]
[in a new window]

FIGURE 3.
HSV POL replicating and inhibiting model. A, replicating model. The carbon atoms of HSV POL shown in stick are light gray, whereas those of primer DNA strand and dTTP are dark gray and those of the template are purple. Black dashed lines are shown for hydrogen bonds and ion interactions involving the incoming nucleotide and catalytic ions. B, model of Acyclovir·HSV POL dead-end complex. Hydrogen bonds involving Acyclovir are shown in black dashes. Key residues interacting with the Acyclovir-incorporated DNA, including the conserved KKKY motif (938-941), are shown. C, chemical structure of PNU-183792, a 4-oxo-DHQ type of herpes polymerase inhibitor. D, a novel inhibition mechanism of a family of broad spectrum inhibitor 4-oxo-DHQ. Residues interacting with inhibitor are highlighted.

Based on models presented in Fig. 3, A and B, it is interestingto speculate why the K_m for the incoming nucleotide is muchhigher as a substrate for the incorporation into a normal DNAduplex than the K_d for its binding to a Acyclovir monophosphate-terminatedone (29). Apparently, the 3'-OH of the primer strand would bein close contact with the ${alpha}$ phosphate, and part of the bindingenergy would be utilized to overcome the repulse for the incorporationreaction (Fig. 3A). On the other hand, a smaller moiety andthe absence of the 3'-OH group make Acyclovir monophosphatea better group to interact with the incoming nucleotide.

4-Oxo-DHQs represent an important class of non-nucleoside antiherpesdrugs and in pre-clinic trials show broad anti-HSV activity(1, 6). In contrast to nucleoside inhibitors such as Acyclovir,this class of inhibitors is not dependent on viral or cellularphosphorylation events to generate an active form and does notform covalent complexes with HSV POL. As such, the patternsof resistance against this class of agents would be predictedto be different from those of nucleoside analogs (31). The bindingof a radioisotope-labeled 4-oxo-DHQ, PNU-183792 (Fig. 3C), toHSV POL was characterized using a near-equilibrium binding assayunder conditions amenable to in vitro HSV POL activity assays.The results clearly showed that PNU-183792 binds only to theDNA duplex·HSV POL complex and not to the enzyme or theDNA duplex alone. The affinity of PNU-183792 toward HSV POL·DNAduplex is enhanced in the presence of Mg²⁺ or Ca²⁺ ions. Theseresults explain our failure to see electron density of a 4-oxo-DHQbound to HSV POL in either co-crystallization or soaking experimentswith different compounds. Kinetic assays also showed that 4-oxo-DHQsare competitive with incoming nucleotides. These observationsallowed us to propose a model for the inhibition of HSV POLby PNU-183792 (Fig. 3D). In our model, PNU-183792 replaces theincoming nucleotide and dislocates the template base from theactive site. The aromatic moiety of PNU-183792 stacks againstthe base pair of the primer 3'-end and the template and alsointeracts with the active site residues of HSV POL (Fig. 3D),consistent with mutant sensitivity data of these compounds (31).The morpholine side or right side of the molecule can toleratelarge modifications and locates at the phosphate binding channel.The chlorophenyl group binds to a hydrophobic pocket lined byPhe-820, Gln-617, Gln-618, and Val-823 (Fig. 3D). These residuesare found in mutant virus strains that have dramatically decreasedbinding affinity for 4-oxo-DHQ (31). The location of the chlorophenylgroup also explains the tight structure-activity relationshipobserved on 4-oxo-DHQs (34).

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Analysis of HSV POL suggests the existence of a putative viralprimase/helicase-interacting domain and the location of a putativeRNA binding domain. If confirmed, they enrich our understandingof how herpes viruses replicate and also provide additionalpathways to develop anti-herpes drugs. The replication modelof HSV POL presented here also gives clues on viral replication.The detailed dead-end complex model of HSV POL with Acyclovirprovides an explanation at the molecular level of drug resistanceand a basis for improving these existing drugs. Finally, thenovel inhibition mechanism of the 4-oxo-DHQs may provide a strategicinsight for the development of anti-herpetic drugs and the discoveryof drugs against other viruses.

FOOTNOTES

The atomic coordinates and structure factors (code 2GV9) havebeen deposited in the Protein Data Bank, Research Collaboratoryfor Structural Bioinformatics, Rutgers University, New Brunswick,NJ (http://www.rcsb.org/).

^* The costs of publication of this article were defrayed in partby the payment of page charges. This article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate this fact.

² Present address: Pharmaceutical Research Inst., Bristol-MyersSquibb Co., Rte. 206 and Provinceline Rd., Princeton, NJ 08540.

³ Present address: Proteos, 4717 Campus Dr., Kalamazoo, MI 49008.

⁴ Present Address: 6916 Willson Dr., Kalamazoo, MI 49009.

⁵ Present address: University of Pittsburgh, Dept. of MolecularGenetics and Biochemistry, School of Medicine, 200 Lothrop St.,BSTWR W1256, Pittsburgh, PA 15261.

⁶ Present address: PharmOptima LLC, 4717 Campus Dr., Kalamazoo,MI 49008.

¹ To whom correspondence should be addressed: Pfizer Inc., Exploratory Medicinal Sciences, Eastern Point Rd., Groton, CT 06340. Tel.: 860-686-6959; Fax: 860-686-2095; E-mail: shenping.liu{at}pfizer.com.

⁷ The abbreviations used are: POL, DNA polymerase; HSV, Herpesvirus;HSV POL, herpes simplex 1 DNA polymerase; DHQ, dihydroquinolines;CHAPS, 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonicacid.

ACKNOWLEDGMENTS

We thank Tim Benson, Barry Finzel, and Bill Watts for help withdata collection and discussion.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Coen, D. M., and Schaffer, P. A. (2003) Nat. Rev. 2, 278-288
Elion, G. B. (1989) Science 244, 241-247[CrossRef][Medline] [Order article via Infotrieve]
De Clercq, E. (2001) J. Clin. Virol. 22, 73-89[CrossRef][Medline] [Order article via Infotrieve]
Bacon, T. H., Levin, M. J., Leary, J. J., Sarisky, R. T., Sutton, D. (2003) Clin. Microbiol. Rev. 16, 114-128[Abstract/Free Full Text]
Gilbert, C., Bestman-Smith, J., and Boivin, G. (2002) Drug Resistance Update 5, 88-114[CrossRef][Medline] [Order article via Infotrieve]
Wathen, M. W. (2002) Rev. Med. Virol. 12, 167-178[CrossRef][Medline] [Order article via Infotrieve]
Lehman, I. R., and Boehmer, P. E. (1999) J. Biol. Chem. 274, 28059-28062[Free Full Text]
Knopf, K. W. (1979) Eur. J. Biochem. 98, 231-244[Medline] [Order article via Infotrieve]
Crute, J. J., and Lehman, I. R. (1989) J. Biol. Chem. 264, 19266-19270[Abstract/Free Full Text]
Digard, P., Bebrin, W. R., Weisshart, K., and Coen, D. M. (1993) J. Virol. 67, 398-406[Abstract/Free Full Text]
Zuccola, H. J., Filman, D. J., Coen, D. M., and Hogle, J. M. (2000) Mol. Cell 5, 267-278[CrossRef][Medline] [Order article via Infotrieve]
Rodriguez, A. C., Park, H. W., Mao, C., and Beese, L. S. (2000) J. Mol. Biol. 299, 447-462[CrossRef][Medline] [Order article via Infotrieve]
Zhao, Y., Jeruzalmi, D., Moarefi, I., Leighton, L., Lasken, R., and Kuriyan, J. (1999) Structure 7, 1189-1199[Medline] [Order article via Infotrieve]
Wang, J., Sattar, A., Wang, C. C., Karam, J. D., Konigsberg, W. H., and Steitz, T. A. (1997) Cell 89, 1087-1099[CrossRef][Medline] [Order article via Infotrieve]
Shamoo, Y., and Steitz, T. A. (1999) Cell 99, 155-166[CrossRef][Medline] [Order article via Infotrieve]
Franklin, M., Wang, J., and Steitz, T. A. (2001) Cell 105, 657-667[CrossRef][Medline] [Order article via Infotrieve]
Bellizzi, J. J., III, Widom, J., Kemp, C., Lu, J. Y., Das, A. K., Hofmann, S. L., and Clardy, J. (2000) Proc. Natl. Acad. Sci. U. S. A. 97, 4573-4578[Abstract/Free Full Text]
Otwinowski, Z., and Minor, W. (1997) in Macromolecular Crystallography (Carter, J. C. W., and Sweet, R. M., eds) pp. 307-326, Academic Press, New York
Collaborative Computing Project 4 (1994) Acta Crystallogr. Sect. D Biol. Crystallogr. 50, 760-763[CrossRef][Medline] [Order article via Infotrieve]
Uson, I., and Sheldrick, G. M. (1999) Curr. Opin. Struct. Biol. 9, 643-648[CrossRef][Medline] [Order article via Infotrieve]
Abrahams, J. P. (1996) Acta Crystallogr. Sect. D Biol. Crystallogr. 52, 30-42[CrossRef][Medline] [Order article via Infotrieve]
Vagin, A., and Teplyakov, A. (1997) J. Appl. Crystallogr. 30, 1022-1025[CrossRef]
Jones, T. A., Zou, J.-Y., Cowan, S. W., and Kjeldgaard, M. (1991) Acta Crystallogr. Sect. A, 47, 110-119
Brunger, A. T. (1992) XPLOR Version 3.1., Yale University Press, New Haven, CT
Murshudov, G. N., Vagin, A. A., and Dodson, E. J. (1997) Acta Cryst. Sect. D Biol. Crystallogr. 53, 240-255[CrossRef][Medline] [Order article via Infotrieve]
Kleywegt, G. J., Zou, J. Y., Kjedgaard, M., and Jones, T. A. (2001) in International Tables for Crystallography (Rossmann, M. G., and Arnold, E., eds) Vol. F, pp. 353-356, Kluwer Academic Publishers, Dordrecht, The Netherlands
Hwang, Y. T., Liu, B. Y., Hong, C. Y., Shillitoe, E. J., and Hwang, C. B. C. (1999) J. Virol. 73, 5326-5332[Abstract/Free Full Text]
Burd, C. G., and Dreyfuss, G. (1994) Science 26, 615-621
Reardon, J. E., and Spector, T. (1989) J. Biol. Chem. 264, 7405-7411[Abstract/Free Full Text]
Huang, L., Ishi, K. K., Zuccola, H., Gehring, A. M., Hwang C. B. C., Hogle, J., and Coen, D. M. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 447-452[Abstract/Free Full Text]
Thomsen, D. R., Oien, N. L., Hopkins, T. A., Knechtel, M. L., Brideau, R. J., Wathen, M. W., and Homa, F. L. (2003) J. Virol. 77, 1868-1876[Abstract/Free Full Text]
Kraulis, P. J. (1991) J. Appl. Crystallogr. 24, 946-950[Medline] [Order article via Infotrieve]
DeLano, W. L. (2002). The PyMOL Molecular Graphics System, DeLano Scientific, San Carlos, CA
Schnute, M. E., Cudahy, M. M., Brideau, R. J., Homa, F. L., Hopkins, T. A., Knechtel, M. L., Oien, N. L., Pitts, T. W., Poorman, R. A., Wathen, M. W., Wieber, J. L. (2005) J Med. Chem. 48, 5794-5804[CrossRef][Medline] [Order article via Infotrieve]

CiteULike

Complore

Connotea

Del.icio.us Add to Digg

Digg

Technorati What's this?

This article has been cited by other articles:

D. B. Gammon, R. Snoeck, P. Fiten, M. Krecmerova, A. Holy, E. De Clercq, G. Opdenakker, D. H. Evans, and G. Andrei
Mechanism of Antiviral Drug Resistance of Vaccinia Virus: Identification of Residues in the Viral DNA Polymerase Conferring Differential Resistance to Antipoxvirus Drugs
J. Virol., December 15, 2008; 82(24): 12520 - 12534.
[Abstract] [Full Text] [PDF]

W. Tian, Y. T. Hwang, and C. B. C. Hwang
The Enhanced DNA Replication Fidelity of a Mutant Herpes Simplex Virus Type 1 DNA Polymerase Is Mediated by an Improved Nucleotide Selectivity and Reduced Mismatch Extension Ability
J. Virol., September 1, 2008; 82(17): 8937 - 8941.
[Abstract] [Full Text] [PDF]

F. Bogani and P. E. Boehmer
The replicative DNA polymerase of herpes simplex virus 1 exhibits apurinic/apyrimidinic and 5'-deoxyribose phosphate lyase activities
PNAS, August 19, 2008; 105(33): 11709 - 11714.
[Abstract] [Full Text] [PDF]

K. F. Bryant and D. M. Coen
Inhibition of Translation by a Short Element in the 5' Leader of the Herpes Simplex Virus 1 DNA Polymerase Transcript
J. Virol., January 1, 2008; 82(1): 77 - 85.
[Abstract] [Full Text] [PDF]

S. Chou and G. I. Marousek
Accelerated Evolution of Maribavir Resistance in a Cytomegalovirus Exonuclease Domain II Mutant
J. Virol., January 1, 2008; 82(1): 246 - 253.
[Abstract] [Full Text] [PDF]

S. Chou, G. I. Marousek, L. C. Van Wechel, S. Li, and A. Weinberg
Growth and Drug Resistance Phenotypes Resulting from Cytomegalovirus DNA Polymerase Region III Mutations Observed in Clinical Specimens
Antimicrob. Agents Chemother., November 1, 2007; 51(11): 4160 - 4162.
[Abstract] [Full Text] [PDF]

M. Hogg, P. Aller, W. Konigsberg, S. S. Wallace, and S. Doublie
Structural and Biochemical Investigation of the Role in Proofreading of a beta Hairpin Loop Found in the Exonuclease Domain of a Replicative DNA Polymerase of the B Family
J. Biol. Chem., January 12, 2007; 282(2): 1432 - 1444.
[Abstract] [Full Text] [PDF]

G. M. Scott, A. Weinberg, W. D. Rawlinson, and S. Chou
Multidrug Resistance Conferred by Novel DNA Polymerase Mutations in Human Cytomegalovirus Isolates
Antimicrob. Agents Chemother., January 1, 2007; 51(1): 89 - 94.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

All Versions of this Article:
281/26/18193 most recent
M602414200v1

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Crystal Structure of the Herpes Simplex Virus 1 DNA Polymerase*

Crystal Structure of the Herpes Simplex Virus 1 DNA Polymerase^*