Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.7.7.7 (DNA polymerase)
 17,007 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A guanine derivative with an acyclic side chain, 2-hydroxyethoxymethyl, at position 9 has potent antiviral activity [dose for 50% inhibition (ED(50)) = 0.1 muM] against herpes simplex virus type 1. This acyclic nucleoside analog, termed acycloguanosine, is converted to a monophosphate by a virus-specified pyrimidine deoxynucleoside (thymidine) kinase and is subsequently converted to acycloguanosine di- and triphosphates. In the uninfected host cell (Vero) these phosphorylations of acycloguanosine occur to a very limited extent. Acycloguanosine triphosphate inhibits herpes simplex virus DNA polymerase (DNA nucleotidyltransferase) 10-30 times more effectively than cellular (HeLa S3) DNA polymerase. These factors contribute to the drug's selectivity; inhibition of growth of the host cell requires a 3000-fold greater concentration of drug than does the inhibition of viral multiplication. There is, moreover, the strong possibility of chain termination of the viral DNA by incorporation of acycloguanosine. The identity of the kinase that phosphorylates acycloguanosine was determined after separation of the cellular and virus-specified thymidine kinase activities by affinity chromatography, by reversal studies with thymidine, and by the lack of monophosphate formation in a temperature-sensitive, thymidine kinase-deficient mutant of the KOS strain of herpes simplex virus type 1 (tsA1).
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PMID:Selectivity of action of an antiherpetic agent, 9-(2-hydroxyethoxymethyl) guanine. 20 61

The effect of the nucleoside analog 9-(2-hydroxyethoxymethyl)guanine (acycloguanosine) on herpes simplex virus type 1 DNA synthesis was examined. Acycloguanosine inhibited herpesvirus DNA synthesis in virus-infected cells. The synthesis of host cell DNA was only partially inhibited in actively growing cells at acycloguanosine concentrations several hundred-fold greater than the 50% effective dose for herpes simplex virus type 1. Studies using partially purified enzymes revealed that the triphosphate of this compound inhibited the virus-induced DNA polymerases (DNA nucleotidyltransferases) to a greater degree than the DNA polymerase of the host cell, that the inhibition was dependent upon the base composition of the template, and that the triphosphate was a better substrate for the virus-induced polymerases than for the alpha cellular DNA polymerases.
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PMID:Inhibition of herpes simplex virus-induced DNA polymerase activity and viral DNA replication by 9-(2-hydroxyethoxymethyl)guanine and its triphosphate. 23 89

Spontaneous mutants of mouse FM3A cells (AC1, AC2, and AC3), highly resistant to aphidicolin (3000-, 2500-, and 300-fold increase in resistance, respectively), were isolated by multistep selection. The DNA synthesizing activity in permeabilized cells of all three mutants was substantially resistant to aphidicolin, like that in intact cells. The DNA polymerase activity in nuclear extracts in AC1 and AC3, but not AC2, was resistant to aphidicolin. Partially purified DNA polymerase alpha from AC3, but not from AC1 or AC2, showed resistance to aphidicolin. The apparent Ki value for aphidicolin of AC3 polymerase alpha was three to four times that of the enzyme from the parent cells, but the apparent Km values of the enzyme for dCTP and dTTP were normal. All the mutants showed cross-resistance to both arabinofuranosyladenine and arabinofuranosylcytosine. The AC3 mutant had expanded deoxyribonucleoside triphosphate pools. On two-dimensional polyacrylamide gel electrophoresis, AC1 gave a new protein (mol wt 40 kDa). The aphidicolin-resistance trait was reversible in AC2, unlike in AC1 and AC3. These results show that in mammalian cells there are at least two mechanisms of aphidicolin-resistance that involve an altered DNA polymerase alpha that is resistant to aphidicolin and simultaneous expansion of the four DNA-precursor pools.
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PMID:High level of aphidicolin resistance with multiple mutations in mouse FM3A cell mutants. 212 28

The current progress in antiviral therapy is related to our better understanding of the viral multiplication, with potential targets for specific antiviral action at each step of the multiplication cycle inside the infected cell. Amantadine and Rimantadine are anti-influenza A drugs interfering with the penetration and the release of the virus. Most of the other antiviral drugs which are clinically available have the same target in common, namely the viral DNA polymerase. This holds true for modified nucleosides such as Acycloguanosine (Acyclovir), DHPG, Adenine-Arabinoside, Azidothymidine as well as pyrophosphate derivatives such as phosphonoformic acid. Unfortunately the antiviral chemotherapy must confront 3 obstacles: 1) a possible interference with the normal cellular metabolism, leading to residual cytotoxic side effects; 2) the genetic variability of the viruses, producing drug-resistant mutants and 3) the inability of any antiviral chemotherapeutic agent known to date to eradicate latent viral infection. A new approach of the control of latent infection is suggested with anti sense oligonucleotides of hybridons.
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PMID:Perspectives in antiviral chemotherapy. 221 May 92

Acycloguanosine [9-(2-hydroxyethoxymethyl)guanine; acyclo-Guo] is a potent inhibitor of herpes simplex viruses (HSV); it is selectively phosphorylated in virus-infected cells. In order to define those viral functions that may mediate resistance to acyclo-Guo, the drug sensitivities of temperature-sensitive (ts) and phosphonoacetic acetic acid (PAA)-resistant mutants of HSV-1 and HSV-2 have been determined. Two distinct viral genetic loci are independently associated with acyclo-Guo resistance. Mutations resulting in diminished thymidine kinase activity are associated with resistance to inhibition by acyclo-Guo. Several PAA-resistant viruses that express wild-type levels of thymidine kinase activity are also resistant to acyclo-Guo. This suggests the importance of the viral DNA polymerase region in mediating acyclo-Guo resistance and is consistent with a close relationship between the PAAr mutation site and the AGGr locus. When wild-type HSV-1 is serially propagated under the selective pressure of acyclo-Guo, rapid emergence of resistant virus occurs, accompanied by the simultaneous appearance of thymidine kinase-deficient progeny.
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PMID:Resistance of herpes simplex virus to acycloguanosine: role of viral thymidine kinase and DNA polymerase loci. 624 32

Acyclovir (Zovirax) is a qualified success as an effective and nontoxic antiviral chemotherapeutic agent and at present is approved for the treatment of initial genital herpes and limited life-threatening cutaneous herpes simplex viral infections in the immunocompromised host. Its efficacy in Epstein-Barr, varicella-zoster, and cytomegalorvirus infections appears less promising. According to one controlled study, its efficacy in the treatment of herpes labialis (HSV-1) infections has been disappointing. The highly selective action of acyclovir against viral DNA polymerase and its inhibition of viral DNA chain elongation result in a low incidence of human (host cell) toxicity, as manifested by local irritation at injection sites and a modest incidence of adverse renal effects, which can be reduced by judicious drug use. Newer antiviral agents now under development hold substantial promise for the future of antiviral chemotherapy.
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PMID:Acyclovir and herpesvirus infections. A review of the literature. 632 78

Zovirax (acyclovir, ACV) is now widely accepted as a safe and effective treatment for the management of herpes simplex virus (HSV) infections in normal and immunocompromised patients. However, a common concern with regard to the widespread use of any antimicrobial agent is resistance. The virus specific mechanism of action of ACV involves two virus encoded enzymes, thymidine kinase (TK) and DNA polymerase. Any alteration in the genes coding for these two enzymes would therefore be expected to confer resistance. The findings from two extensive resistance monitoring programs have shown that in immunocompetent patients receiving ACV for the management of acute HSV disease, the incidence of resistance is extremely rare. The situation in the immunocompromised is different. In this patient group HSV disease is severe and protracted often requiring prolonged therapy thus increasing the exposure of the virus to drug. As a result HSV isolates resistant to ACV have occasionally been recovered. Biochemical and genetic analysis of the resistant clinical isolates has shown that resistance in the most part is due to an inability of the virus to produce TK which mirrors the findings with cell culture derived resistant virus. Laboratory studies would indicate that TK-deficient virus would have little clinical impact. Significantly, resistance has rarely been attributed to alterations in the substrate specificity of TK or DNA polymerase. The biological significance of these mutants is unclear but to date there has been no evidence of transmission of resistant virus.
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PMID:Sensitivity monitoring of clinical isolates of herpes simplex virus to acyclovir. 824 94

Antiherpes therapies are principally targeted at viral thymidine kinases and utilize nucleoside analogs, the triphosphates of which are inhibitors of viral DNA polymerase or result in toxic effects when incorporated into DNA. The most frequently used drug, aciclovir (Zovirax), is a relatively poor substrate for thymidine kinase and high-resolution structural information on drugs and other molecules binding to the target is therefore important for the design of novel and more potent chemotherapy, both in antiherpes treatment and in gene therapy systems where thymidine kinase is expressed. Here, we report for the first time the binary complexes of HSV-1 thymidine kinase (TK) with the drug molecules aciclovir and penciclovir, determined by X-ray crystallography at 2.37 A resolution. Moreover, from new data at 2.14 A resolution, the refined structure of the complex of TK with its substrate deoxythymidine (R = 0.209 for 96% of all data) now reveals much detail concerning substrate and solvent interactions with the enzyme. Structures of the complexes of TK with four halogen-containing substrate analogs have also been solved, to resolutions better than 2.4 A. The various TK inhibitors broadly fall into three groups which together probe the space of the enzyme active site in a manner that no one molecule does alone, so giving a composite picture of active site interactions that can be exploited in the design of novel compounds.
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PMID:Exploring the active site of herpes simplex virus type-1 thymidine kinase by X-ray crystallography of complexes with aciclovir and other ligands. 971 11

The vast majority of the world population is infected with at least one member of the human herpesvirus family. Herpes simplex virus (HSV) infections are the cause of cold sores and genital herpes as well as life-threatening or sight-impairing disease mainly in immunocompromized patients, pregnant women and newborns. Since the milestone development in the late 1970s of acyclovir (Zovirax), a nucleosidic inhibitor of the herpes DNA polymerase, no new non-nucleosidic anti-herpes drugs have been introduced. Here we report new inhibitors of the HSV helicase-primase with potent in vitro anti-herpes activity, a novel mechanism of action, a low resistance rate and superior efficacy against HSV in animal models. BAY 57-1293 (N-[5-(aminosulfonyl)-4-methyl-1,3-thiazol-2-yl]-N-methyl-2-[4-(2-pyridinyl)phenyl]acetamide), a well-tolerated member of this class of compounds, significantly reduces time to healing, prevents rebound of disease after cessation of treatment and, most importantly, reduces frequency and severity of recurrent disease. Thus, this class of drugs has significant potential for the treatment of HSV disease in humans, including those resistant to current medications.
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PMID:New helicase-primase inhibitors as drug candidates for the treatment of herpes simplex disease. 1192 30

The quiet pandemic of herpes simplex virus (HSV) infection has plagued humanity since ancient times, causing mucocutaneous infection, such as herpes labialis and herpes genitalis. Disease symptoms often interfere with everyday activities and occasionally HSV infections are the cause of life-threatening or sight-impairing disease, especially in neonates and the immunocompromised patient population. After primary or initial infection the virus persists for life in a latent form in neurons of the host, periodically reactivating and often resulting in significant psychosocial distress for the patient. Currently, no cure is available. In the mid-1950s the first antiviral, idoxuridine, was developed for topical treatment of herpes disease and, in 1978, vidarabine was licensed for systemic use to treat HSV encephalitis. Acyclovir (Zovirax), a potent, specific and tolerable nucleosidic inhibitor of the herpes DNA polymerase, was a milestone in the development of antiviral drugs in the late 1970s. In the mid-1990s, when acyclovir became a generic drug, valacyclovir (Valtrex) and famciclovir (Famvir), prodrugs of the gold standard and penciclovir (Denavir), Vectavir), a close analogue, were launched. Though numerous approaches and strategies were tested and considerable effort was expended in the search of the next generation of an antiherpetic therapy, it proved difficult to outperform acyclovir. Notable in this regard was the award of a Nobel Prize in 1988 for the elucidation of mechanistic principles which resulted in the development of new drugs such as acyclovir. Vaccines, interleukins, interferons, therapeutic proteins, antibodies, immunomodulators and small-molecule drugs with specific or nonspecific modes of action lacked either efficacy or the required safety profile to replace the nucleosidic drugs acyclovir, valacyclovir, penciclovir and famciclovir as the first choice of treatment. Recently though, new inhibitors of the HSV helicase-primase with potent in vitro antiherpes activity, novel mechanisms of action, low resistance rates and superior efficacy against HSV in animal models have been discovered. This review summarises the current therapeutic options, discusses the potential of preclinical or investigational drugs and provides an up-to-date interpretation of the challenge to establish novel treatments for herpes simplex disease.
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PMID:Novel agents and strategies to treat herpes simplex virus infections. 1255 12


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