Herpes simplex virus-induced dUTPase: target site for antiviral chemotherapy

Distribution and effects of amino acid changes in drug-resistant α and β herpesviruses DNA polymerase

Emergence of drug-resistance to all FDA-approved antiherpesvirus agents is an increasing concern in immunocompromised patients. Herpesvirus DNA polymerase (DNApol) is currently the target of nucleos(t)ide analogue-based therapy. Mutations in DNApol that confer resistance arose in immunocompromised patients infected with herpes simplex virus 1 (HSV-1) and human cytomegalovirus (HCMV), and to lesser extent in herpes simplex virus 2 (HSV-2), varicella zoster virus (VZV) and human herpesvirus 6 (HHV-6). In this review, we present distinct drug-resistant mutational profiles of herpesvirus DNApol. The impact of specific DNApol amino acid changes on drug-resistance is discussed. The pattern of genetic variability related to drug-resistance differs among the herpesviruses. Two mutational profiles appeared: one favoring amino acid changes in the Palm and Finger domains of DNApol (in α-herpesviruses HSV-1, HSV-2 and VZV), and another with mutations preferentially in the 3′-5′ exonuclease domain (in β-herpesvirus HCMV and HHV-6). The mutational profile was also related to the class of compound to which drug-resistance emerged.

Uracil-directed ligand tethering: an efficient strategy for uracil DNA glycosylase (UNG) inhibitor development

Uracil DNA glycosylase (UNG) is an important DNA repair enzyme that recognizes and excises uracil bases in DNA using an extrahelical recognition mechanism. It is emerging as a desirable target for small-molecule inhibitors given its key role in a wide range of biological processes including the generation of antibody diversity, DNA replication in a number of viruses, and the formation of DNA strand breaks during anticancer drug therapy. To accelerate the discovery of inhibitors of UNG we have developed a uracil-directed ligand tethering strategy. In this efficient approach, a uracil aldehyde ligand is tethered via alkyloxyamine linker chemistry to a diverse array of aldehyde binding elements. Thus, the mechanism of extrahelical recognition of the uracil ligand is exploited to target the UNG active site, and alkyloxyamine linker tethering is used to randomly explore peripheral binding pockets. Since no compound purification is required, this approach rapidly identified the first small-molecule inhibitors of human UNG with micromolar to submicromolar binding affinities. In a surprising result, these uracil-based ligands are found not only to bind to the active site but also to bind to a second uncompetitive site. The weaker uncompetitive site suggests the existence of a transient binding site for uracil during the multistep extrahelical recognition mechanism. This very general inhibitor design strategy can be easily adapted to target other enzymes that recognize nucleobases, including other DNA repair enzymes that recognize other types of extrahelical DNA bases.

The monomeric dUTPase from Epstein-Barr virus mimics trimeric dUTPases

Deoxyuridine 5'-triphosphate pyrophosphatases (dUTPases) are ubiquitous enzymes cleaving dUTP into dUMP and pyrophosphate. They occur as monomeric, dimeric, or trimeric molecules. The trimeric and monomeric enzymes both contain the same five characteristic sequence motifs but in a different order, whereas the dimeric enzymes are not homologous. Monomeric dUTPases only occur in herpesviruses, such as Epstein-Barr virus (EBV). Here, we describe the crystal structures of EBV dUTPase in complex with the product dUMP and a substrate analog alpha,beta-imino-dUTP. The molecule consists of three domains forming one active site that has a structure extremely similar to one of the three active sites of trimeric dUTPases. The three domains functionally correspond to the subunits of the trimeric form. Domains I and II have the dUTPase fold, but they differ considerably in the regions that are not involved in the formation of the unique active site, whereas domain III has only little secondary structure.

Expression of viral and human dUTPase in Epstein-Barr virus-associated diseases

Deoxyuridine triphosphatase (dUTPase) catalyses the hydrolysis of dUTP to dUMP and pyrophosphate thus preventing the incorporation of uracil into replicating DNA. Previous studies of several virus models have suggested that viral dUTPases may be required for virus replication in resting cells whereas in proliferating cells cellular dUTPase may substitute for a mutant viral protein. Using monoclonal antibodies and immunohistochemistry, Epstein-Barr virus-associated non-neoplastic and neoplastic diseases were studied for the expression of viral and human dUTPases. Oral hairy leukoplakia, an AIDS-associated lesion of the tongue, is known to support EBV replication in the upper epithelial cell layers. In agreement with this, strong focal expression of EBV dUTPase was detected in the upper epithelial cell layers of oral hairy leukoplakia whereas expression of human dUTPase was confined to the basal proliferative cell compartment. Furthermore, in infectious mononucleosis tonsils, rare scattered small lymphoid cells expressed EBV dUTPase, consistent with the expression pattern of other EBV lytic cycle antigens. These findings are in agreement with the notion that EBV replicates in resting cells. Three EBV-associated tumours, Hodgkin lymphoma, Burkitt lymphoma and nasopharyngeal carcinoma, lacked detectable expression of EBV dUTPase, in agreement with the notion that EBV infection is largely latent in these tumours. By contrast, expression of human dUTPase was observed regularly in these tumours. These results suggest that EBV dUTPase may be a suitable target for anti-viral therapy and that inhibitors of human dUTPase should prove useful for the treatment of human tumours, including EBV-associated cancers.

Human dUTP pyrophosphatase: uracil recognition by a beta hairpin and active sites formed by three separate subunits

BACKGROUND

The essential enzyme dUTP pyrophosphatase (dUTPase) is exquisitely specific for dUTP and is critical for the fidelity of DNA replication and repair. dUTPase hydrolyzes dUTP to dUMP and pyrophosphate, simultaneously reducing dUTP levels and providing the dUMP for dTTP biosynthesis. A high cellular dTTP: dUTP ratio is essential to avoid uracil incorporation into DNA, which would lead to strand breaks and cell death. We report the first detailed atomic-resolution structure of a eukaryotic dUTPase, human dUTPase, and complexes with the uracil-containing deoxyribonucleotides, dUMP, dUDP and dUTP.

RESULTS

The crystal structure reveals that each subunit of the dUTPase trimer folds into an eight-stranded jelly-roll beta barrel, with the C-terminal beta strands interchanged among the subunits. The structure is similar to that of the E. coli enzyme, despite low sequence homology between the two enzymes. The nucleotide complexes reveal a simple and elegant way for a beta hairpin to recognize specific nucleic acids: uracil is inserted into a distorted antiparallel beta hairpin and hydrogen bonds entirely to main-chain atoms. This interaction mimics DNA base pairing, selecting uracil over cytosine and sterically precluding thymine and ribose binding. Residues from the second subunit interact with the phosphate groups and a glycine-rich C-terminal tail of the third subunit caps the substrate-bound active site, causing total complementary enclosure of substrate. To our knowledge, this is the first documented instance of all three subunits of a trimeric enzyme supplying residues that are critical to enzyme function and catalysis.

CONCLUSIONS

The dUTPase nucleotide-binding sites incorporate some features of other nucleotide-binding proteins and protein kinases, but seem distinct in sequence and architecture. The novel nucleic acid base recognition motif appears ancient; higher order structures, such as the ribosome, may have evolved from a motif of this kind. These uracil-beta-hairpin interactions are an obvious way for peptides to become early coenzymes in an RNA world, providing a plausible link to the protein-DNA world. Within the beta hairpin, there is a tyrosine corner motif that normally specifies beta-arch connections; this tyrosine motif was apparently recruited to discriminate against ribonucleotides, more recently than the evolution of the beta hairpin itself.

Replication in vitro and in vivo of an equine infectious anemia virus mutant deficient in dUTPase activity

As an important enzyme in DNA synthesis, dUTPase is present in a wide variety of organisms and viruses and has been identified as a component of the equine infectious anemia virus (EIAV) pol gene. The role of EIAV dUTPase, designated DU, in virus replication in vitro and in vivo was investigated with a recently described infectious molecular clone of EIAV. A deletion mutant that was deficient in dUTPase activity was constructed, and its replication kinetics was examined in fetal equine kidney (FEK) cells and primary equine bone marrow macrophage (EBMM) cells. In FEK cells, which are permissive for EIAV replication, the mutant virus replicated as well as the parental virus. In primary cultures of EBMM cells, which are primary targets of EIAV infection in vivo, the DU mutant showed delayed replication kinetics and replicated to a lower extent than did the parental virus. As the multiplicity of infection decreased, the difference between the parental and mutant viruses increased, such that at the lowest multiplicity of infection tested, there was over a 100-fold difference in virus production. The mutant virus was also much less cytopathic. The role of DU in replication in vivo was examined using a Shetland pony model of EIAV infection. Shetland ponies that were infected with the parental and mutant viruses showed transient virus RNA levels in plasma approximately 5 to 10 days postinfection. The peak virus levels in plasma (as measured by a quantitative reverse transcriptase PCR assay) were 10- to 100-fold lower in the mutant virus-infected animals than in the animals infected with the parental virus. However, ponies infected with the mutant virus mounted similar antibody responses despite the marked differences in virus replication. These studies demonstrate that EIAV DU is important for the efficient replication of the virus in macrophages in vitro and in vivo and suggests that variations in the DU sequence could markedly affect the biological and pathogenic properties of EIAV.

Mutations in accessory DNA replicating functions alter the relative mutation frequency of herpes simplex virus type 1 strains in cultured murine cells

The contribution of the herpes simplex virus type 1 (HSV-1)-encoded uracil DNA glycosylase (UNG), thymidine kinase (TK), and dUTPase to the relative mutant frequency (RMF) of the virus in cultured murine cells was examined. A panel of HSV-1 mutants that lacked singly or doubly the UNG, TK, or dUTPase activity were generated by disruption of the enzyme coding regions with the Escherichia coli beta-galactosidase (beta-gal) gene in strain 17syn+. To establish a baseline RMF of strain 17syn+, the beta-gal gene was inserted into the UL3 locus. In all of the viruses, the beta-gal insert served as a phenotypic marker of RMF. A mutant plaque was identified by the lack of beta-gal activity and, in selected cases, positive in situ hybridization for beta-gal sequences. Replication kinetics in NIH 3T3 cells demonstrated that all of the mutants replicated efficiently, generating stocks with equivalent titers. Two independently generated UL3-beta-gal viruses were examined and established a baseline RMF of approximately 0.5% in both NIH 3T3 and LM TK- cells. Loss of dUTPase activity resulted in viruses with fivefold-increased RMFs, indicating that the HSV-1 dUTPase has an antimutator function. The RMF observed for the tk- viruses was reduced as much as 40-fold (RMF of 0.02%), suggesting that the viral TK is a mutator activity. The RMF of two independent UNG- viruses showed no significant difference from the baseline RMF in limited passage; however, following successive passage, the data suggested that UNG activity serves as an antimutator. These results have implications for the natural history of HSV and the development of antiviral therapies.

Antigenic specificities of human CD4+ T-cell clones recovered from recurrent genital herpes simplex virus type 2 lesions

Lesions resulting from recurrent genital herpes simplex virus (HSV) infection are characterized by infiltration of CD4+ lymphocytes. We have investigated the antigenic specificity of 47 HSV-specific CD4+ T-cell clones recovered from the HSV-2 buttock and thigh lesions of five patients. Clones with proliferative responses to recombinant truncated glycoprotein B (gB) or gD of HSV-2 or purified natural gC of HSV-2 comprised a minority of the total number of HSV-specific clones isolated from lesions. The gC2- and gD2-specific CD4+ clones had cytotoxic activity. The approximate locations of the HSV-2 genes encoding HSV-2 type-specific CD4+ antigens have been determined by using HSV-1 x HSV-2 intertypic recombinant virus and include the approximate map regions 0.30 to 0.46, 0.59 to 0.67, 0.67 to 0.73, and 0.82 to 1.0 units. The antigenic specificity of an HLA DQ2-restricted, HSV-2 type-specific T-cell clone was mapped to amino acids 425 to 444 of VP16 of HSV-2 by sequential use of an intertypic recombinant virus containing VP16 of HSV-2 in an HSV-1 background, recombinant VP16 fusion proteins, and synthetic peptides. Each of the remaining four patients also yielded at least one type-specific T-cell clone reactive with an HSV-2 epitope mapping to approximately 0.67 to 0.73 map units. The antigenic specificities of lesion-derived CD4+ T-cell clones are quite diverse and include at least 10 epitopes. Human T-cell clones reactive with gC and VP16 are reported here for the first time.

Identification of tyrosine as a functional residue in the active site of Escherichia coli dUTPase

dUTP nucleotidohydrolase (dUTPase, EC 3.6.1.23) from E. coli contains a total of six tyrosine residues per trimer. About half of them were found to be susceptible to acetylation with N-acetylimidazole or to nitration with tetranitromethane with concomitant loss of activity. Deacetylation with N-hydroxylamine leads to full reactivation. Inhibitory products of dUTP hydrolysis, i.e., dUMP and inorganic pyrophosphate together with the cofactor Mg2+ protect significantly against inactivation and chemical modification. In the Cu(2+)-dUTPase complex, charge transfer from Cu2+ to the tyrosinate anion was perturbed by the presence of the substrate dUTP. These results, together with the occurrence of one tyrosine residue in a strictly conserved sequence motif suggest the critical importance of this residue for the function of the enzyme.

Characterization of equine infectious anemia virus dUTPase: growth properties of a dUTPase-deficient mutant

The putative dUTPase domain was deleted from the polymerase (pol) gene of equine infectious anemia virus (EIAV) to produce a recombinant delta DUpol Escherichia coli expression cassette and a delta DU proviral clone. Expression of the recombinant delta DUpol polyprotein yielded a properly processed and enzymatically active reverse transcriptase, as determined by immunoblot analysis and DNA polymerase activity gels. Transfection of delta DU provirus into feline (FEA) cells resulted in production of virus that replicated to wild-type levels in both FEA cells and fetal equine kidney cells. In contrast, the delta DU virus replicated poorly (less than 1% of wild-type levels) in primary equine macrophage cultures, as measured by reverse transcriptase assays. Preparations of delta DU virus contained negligible dUTPase activity, which confirms that virion-associated dUTPase is encoded in the pol gene region between the RNase H domain and integrase, as has been demonstrated previously for feline immunodeficiency virus (J. H. Elder, D. L. Lerner, C. S. Hasselkus-Light, D. J. Fontenot, E. Hunter, P. A. Luciw, R. C. Montelaro, and T. R. Phillips, J. Virol. 66:1791-1794, 1992). Our results suggest that virus-encoded dUTPase is dispensable for virus replication in dividing cells in vitro but may be required for efficient replication of EIAV in nondividing equine macrophages, the natural host cells for this virus.

Herpes simplex virus type 1 dUTPase mutants are attenuated for neurovirulence, neuroinvasiveness, and reactivation from latency

Herpes simplex virus type 1 (HSV-1) encodes a dUTPase which has been shown to be dispensable for normal viral replication in cultured cells (S. J. Caradonna and Y. Cheng, J. Biol. Chem. 256:9834-9837, 1981; F. B. Fisher and V. G. Preston, Virology 148:190-197, 1986). However, the importance of this enzyme in vivo has not been determined. In this report, HSV-1 strain 17 syn+ and two isogenic engineered dUTPase-negative mutants were characterized in the mouse model. Both mutants replicated with wild-type kinetics and achieved wild-type titers in cultured cells. The mutants were 10-fold less neurovirulent than 17 syn+ following intracranial inoculation and more than 1,000-fold less virulent following footpad inoculation. The dUTPase- mutants replicated with wild-type kinetics in the footpad and entered and replicated efficiently in the peripheral nervous system of the mouse. However, their replication in the central nervous system was significantly reduced. The dUTPase- strains established latent infections but displayed a greatly reduced reactivation frequency in vivo. Neurovirulence, neuroinvasiveness, and reactivation frequency were all restored by recombination with wild-type dUTPase sequences. These results have important implications with regard to anti-herpesvirus therapeutic strategies.

Inhibition of herpes simplex virus types 1 and 2 replication in vitro by mercurithio analogs of deoxyuridine

The in vitro antiviral activity of several 5-mercurithio analogs of 2'-deoxyuridine (dUrd) on the replication of herpes simplex virus types 1 (HSV-1) and 2 (HSV-2) were examined. Of those compounds tested, the thioglycerol analog of 5-mercuri-2'-deoxyuridine (HgdUrd) was most effective in inhibiting the replication of HSV-1 in KB cells with a 50% inhibitory dose (ID50) of 0.001 micrograms/ml while the glutathione analog of HgdUrd was the most effective in inhibiting the replication of HSV-2 with a ID50 of 0.075 micrograms/ml. Conversely in HeLa TK- cells, the mercaptoguanosine analog of HgdUrd was the most effective compound in inhibiting virus replication with ID50S of 0.098 and 0.001 micrograms/ml for HSV-1 and HSV-2 respectively. These results suggest that these mercurithio analogs of dUrd are as effective as acyclovir in preventing the replication of these herpesviruses.

Inhibition of phosphorylation of cellular dUTP nucleotidohydrolase as a consequence of herpes simplex virus infection

During an infection with herpes simplex virus, activity of cellular dUTPase decreases as a function of time, post-infection, while virus-encoded dUTPase activity increases. Prelabeling of cells with 35S-methionine and immunoprecipitation analysis, using monoclonal antibodies, indicates that cellular dUTPase protein levels remain the same (with respect to levels in uninfected cells) throughout the infection period. New synthesis of cellular dUTPase does not occur in infected cells as determined by 35S-methionine labeling during infection. Further characterization of the cellular dUTPase, in uninfected cells, reveals that the protein is post-translationally phosphorylated at serine residues. Pulse labeling of virus-infected cells with 32P-orthophosphate reveals that the phosphorylation rate of the cellular dUTPase protein decreases significantly as a function of time post-infection. In an effort to establish that phosphate turnover was occurring on the cellular dUTPase protein, cells were prelabeled with 32P-orthophosphate and then infected with HSV in the absence of label. Evidence from this experiment indicates that the phosphate moiety is removed from the cellular dUTPase protein during the infection. A series of viable virus mutants was generated by insertional inactivation of the HSV dUTPase gene. These mutants do not express viral dUTPase activity and HSV dUTPase protein is not detected by western blot analysis. However, in contrast to the wild-type situation, these mutant virus retain significant cellular dUTPase activity throughout infection. Interestingly, phosphorylation of cellular dUTPase protein is now readily detectable in each of the mutant virus-infected cells. These studies indicate that cellular dUTPase activity is diminished in wild-type HSV-infected cells by a process of dephosphorylation. It also appears that in mutant HSV, lacking the virus dUTPase, the mechanism of dephosphorylation and thus inactivation of cellular dUTPase is not functional. The end result is that the mutant virus can now rely on the cellular activity for its survival.