Genetic analysis of the susceptibility of mouse cytomegalovirus to acyclovir.

Eight independently derived mouse cytomegalovirus (MCMV) mutants resistant to acyclovir (ACV) were obtained by the sequential plating of wild-type virus in increasing concentrations of ACV. Results of complementation studies among these eight mutants suggest that all had mutations within the same or closely associated genes. A ninth MCMV mutant resistant to phosphonoacetate (PAA) derived by plating wild-type virus in the presence of 100 micrograms of PAA per ml displayed coresistance to ACV and was unable to complement any of the ACV-derived mutants. Recombination experiments among all combinations of the nine MCMV mutants were performed and supported the complementation data in that no recombination could be detected. Seven of the eight ACV-resistant mutants demonstrated cross-resistance to PAA and hypersensitivity to aphidicolin. The one mutant not coresistant to PAA was more susceptible to PAA than was the parent virus. Only a few mutants demonstrated coresistance when the mutants were tested against 9-beta-D-arabinofuranosyladenine (ara-A). The ACV mutant that demonstrated increased susceptibility to PAA was 30-fold more susceptible to ara-A but remained unchanged in susceptibility to aphidicolin. Two of the parent-mutant combinations were selected for DNA synthesis analysis in the presence of ACV (5 microM). A significant decrease in DNA synthesis was demonstrated for both parent viruses, and there was little effect on mutant virus DNA synthesis at the same drug concentration. These results suggest that susceptibility of MCMV to ACV is confined to a product of a single gene and that a mutation of this gene can lead to an altered phenotype when compared with parent virus in susceptibility of DNA synthesis to PAA, ara-A, and aphidicolin, drugs that are known to inhibit DNA polymerase activity.     

Isolation of drug resistant mutants of varicella-zoster virus: cross resistance of acyclovir resistant mutants with phosphonoacetic acid and bromodeoxyuridine

Mutants of Varicella-Zoster Virus (VZV) which are resistant to phosphonoacetic acid (PAA), bromodeoxyuridine (BuDR), and acyclovir (ACV) were obtained by serial passages of VZV with increasing concentrations of these drugs. A PAA-resistant mutant and a BuDR-resistant mutant were found also to be resistant to ACV. Five of 8 ACV-resistant mutants acquired resistance to PAA, but none acquired resistance to BuDR. The BuDR-resistant mutant did not induce viral thymidine kinase (TK) activity, but all the ACV-resistant mutants selected in ACV showed viral TK activity which was suppressed with anti-VZV serum and had almost the same electrophoretic mobility as that of the parent strain on polyacrylamide gel electrophoresis in non-denaturing conditions. However, in competitive TK assay with ACV, 2 of 8 ACV-resistant mutants showed no change of phosphorylation of radioactive thymidine, while the other 6 showed decreased phosphorylation of radioactive thymidine. It was suggested that TK induced by the former 2 ACV-resistant mutants had lost affinity to ACV, and so the mutants could grow in the presence of ACV. Thus of the 8 ACV-resistant mutants selected in ACV, 2 were sensitive to PAA with altered TK activity, 5 were resistant to PAA with unaltered TK activity, and 1 was sensitive to PAA with unaltered TK activity, and may have altered DNA polymerase activity to ACV, retaining sensitivity to PAA. These results suggest that resistance of VZV to ACV results from alterations in the virus-specified TK or DNA polymerase, as demonstrated in HSV resistant to ACV.     

Enhanced survival of ultraviolet-irradiated herpes simplex virus in cells exposed to antiviral agents

Enhanced survival of UV-irradiated HSV-1 is demonstrated in monkey cells exposed to inhibitors of viral DNA synthesis. Phosphonoacetic acid (PAA), adenine arabinoside (ara-A), and cytosine arabinoside (ara-C) pretreatment of infected cells is associated with concentration-dependent reactivation of UV-HSV-1. At concentrations that result in enhanced virus survival, inhibition of cell DNA synthesis is observed by either ara-A or ara-C, but not by PAA. Pretreatment of uninfected cells with acycloguanosine (ACG) is not associated with reactivation of irradiated HSV-1, and this is probably due to insufficient generation of ACG-triphosphate, the active inhibitor of viral and cell DNA synthesis.     

DNA polymerase in nuclei isolated from herpes simplex virus type-2-infected cells. Characterization of the reaction product and inhibition by substrate analogs

Nuclei isolated from herpes simplex virus (HSV) type 2-infected KB cells were examined for their capacity to serve as an in situ source of herpes DNA polymerase. In contrast to purified enzymes with added template, approx. 80% of the DNA synthesized in isolated nuclei was viral. The average size of DNA fragments labeled in vitro was 3.2 X 10(6) Da. Based on an increase in DNA density when nuclei were incubated in the presence of BrdUTP rather than dTTP, 16% of the nucleotides were added during the in vitro reaction. Sucrose gradient analysis of DNA polymerase activity in extracts of isolated nuclei demonstrated the nearly exclusive presence of herpes DNA polymerase. Km concentrations for the four dNTPs were from 0.14 to 0.55 microM. DNA synthesis was inhibited competitively by the 5'-triphosphates of ara-A and ara-C (Ki = 0.03 and 0.22 microM, respectively) but not by the 5'-triphosphate of dideoxythymidine. aATP also served as a substrate (Km = 0.014 microM) for the reaction. We conclude that nuclei from HSV-infected cells have significant advantages for the detailed study of inhibitors of herpesvirus replication.     

Herpes simplex virus resistance and sensitivity to phosphonoacetic acid.

Phosphonoacetic acid (PAA) inhibited the synthesis of herpes simplex virus DNA in infected cells and the activity of the virus-specific DNA polymerase in vitro. In the presence of concentrations of PAA sufficient to prevent virus growth and virus DNA synthesis, normal amounts of early virus proteins (alpha- and beta-groups) were made, but late virus proteins (gamma-group) were reduced to less than 15% of amounts made in untreated infected cells. This residual PAA-insensitive synthesis of gamma-polypeptides occurred early in the virus growth cycle when rates were identical in PAA-treated and untreated infected cells. Passage of virus in the presence of PAA resulted in selection of mutants resistant to the drug. Stable clones of mutant viruses with a range of drug sensitivities were isolated and the emergence of variants resistant to high concentrations of PAA involved the sequential selection of mutants progressively better adapted to growth in the presence of the drug. Increased drug resistance of virus yield or plaque formation was correlated with increased resistance of virus DNA synthesis, gamma-protein synthesis, and resistance of the virus DNA polymerase reaction in vitro to the inhibitory effects of the drug. PAA-resistant strains of herpes simplex virus type 1 (HSV-1) complemented the growth of sensitive strains of homologous and heterologous types in mixed infections in the presence of the drug. Complementation was markedly dependent upon the proportions of the resistant and sensitive partners participating in the mixed infection. Intratypic (HSV-1A X HSV-1B) recombination of the PAA resistance marker(s), Pr, occurred at high frequency relative to plaque morphology (syn) and bromodeoxyuridine resistance (Br, thymidine kinase-negative phenotype) markers, with the most likely order being syn-Br-Pr. Recombinant viruses were as resistant or sensitive to PAA as the parental viruses, and viruses recombinant for their PAA resistance phenotype were also recombinant for the PAA resistance character of the virus DNA polymerase. The results provide additional evidence that the herpesvirus DNA polymerase is the site of action of PAA and illustrate the potential usefulness of PAA-resistant mutants in genetic studies of herpesviruses.     

Acyclovir treatment prevents varicella-zoster virus replication in PBMC during viremia.

The most effective antiviral therapy of varicella and zoster has become acyclovir. Using polymerase chain reaction specific for VZV ORF 14, ORF 29, ORF 63 as well as nucleic acid sequence-based amplification (ORF 63, ORF 68) we tested PBMC of patients with VZV-associated diseases for the presence of viral DNA and RNA, respectively. In PBMC of patients treated with acyclovir neither DNA nor RNA was detectable already one day after the onset of therapy. In three blood sample pairs from zoster patients we were able to detect viral nucleic acid before but not after acyclovir treatment. These results confirm clinical and epidemiological data. It can be concluded that treatment with acyclovir prevents VZV replication in peripheral blood mononuclear cells.     

Chinese hamster ovary cell mutants resistant to DNA polymerase inhibitors. II. Segregational analysis and DNA transfection of the aphr gene

Genetic characterizations of the Chinese hamster ovary cell mutants resistant to the DNA polymerase inhibitors (aphidicolin, ara-A and ara-C) have been described. Resistance to all three inhibitors showed dominance among the progeny of somatic cell crosses between the wild type and mutant parents. Analysis of the segregation of the drug-resistant character among 566 hybrid progeny from somatic crosses between the wild type (aphs, ara-As, and ara-Cs) and the triple mutants (aphr, ara-Ar, ara-Cr) showed the involvement of at least three unlinked genes in controlling the expression of the resistance to different DNA polymerase inhibitors. The mutant (aphr) DNA was used to transfect aphidicolin resistance to recipient mouse Ltk- cells either directly or in combination with the plasmid pTK2 DNA. The aphidicolin resistance of the transfected cells was found to be a stable phenotype and could be used in multiple rounds of transfection, indicating the chromosomal integration of the transfecting gene.     

Chinese hamster ovary cell mutants resistant to DNA polymerase inhibitors

Summary Isolation and characterization of Chinese hamster ovary cell mutants resistant to different DNA polymerase ase inhibitors (aphidicolin, ara-A and ara-C) have been described. A particular mutant (JK3-1-2A) characterized in detail was found to grow and synthesize DNA in medium containing an amount of aphidicolin tenfold greater than that which completely inhibited the growth and the DNA synthesis of the wild-type cells. An almost twofold increase in the specific activity of the DNA polymerase was seen in this mutant. The mutant DNA polymerase showed altered aphidicolin inhibition kinetics of dCMP incorporation; the apparent K _m for dCTP and the apparent K _i for aphidicolin were increased in the mutant. These alterations in the kinetic parameters were, however, abolished upon further purification of the enzyme. Ara-CTP was found to act as a competitive inhibitor of the dCMP incorporation by both the wild type and mutant enzymes. In contrast, the effect of aphidicolin on dCMP incorporation was either competitive (wild-type enzymes) or noncompetitive (mutant enzyme). The data presented showed that the sites of action for aphidicolin and ara-CTP were distinct; likewise the dCTP binding site appeared to be separate from other dNTP(s) binding sites. The drug resistance of the mutant was inherited as a dominant trait.Abbreviations ara-A 9--d-arabinofuranosyl adenine - ara-C 1--d-arabinofuranosyl cytosine - aph aphidicolin     

Genetic evidence that aphidicolin inhibits in vivo DNA synthesis in Chinese hamster ovary cells

Using a genetic approach, Chinese hamster ovary (CHO) cells sensitive (aph^S) and resistant (aph^R) to aphidicolin were grown in the presence or absence of various DNA polymerase inhibitors, and the newly synthesized DNA isolated from [³²P]dNMP-labelled, detergent-permeabilized cells, was characterized after fractionation by gel electrophoresis. The particular aph ^Rmutant CHO cell line used was one selected for resistance to aphidicolin and found to possess an altered DNA polymerase of the a-family. The synthesis of a 24 kb replication intermediate was inhibited in wild-type CHO cells grown in the presence of aphidicolin, whereas the synthesis of this replication intermediate was not inhibited by this drug in the mutant CHO cells or in the aphidicolin-resistant somatic cell hybrid progeny constructed by fusion of wild-type and mutant cell lines. Arabinofuranosylcytosine (ara-C), like aphidicolin, inhibited the synthesis of this 24 kb DNA replication intermediate in the wild-type CHO cells but not in the aph^R mutant cells. However, carbonyldiphosphonate (COMDP) inhibited the synthesis of the 24 kb replication intermediate in both wild-type and mutant cells. N²-(p-n-Butylphenyl)-2 deoxyguanisine-5-triphosphate (BuPdGTP) was found to inhibit the formation of Okazaki fragments equally well in the wild-type and mutant cell lines and thus led to inhibition of synthesis of DNA intermediates in both cases. It appears that aphidicolin and ara-C both affect a common target on the DNA polymerase, which is different from that affected by COMDP in vivo. These data also show that aphidicolin, ara-C and COMDP affect the elongation activity of DNA polymerase but not the initiation activity of the enzyme during DNA replication. This is the first report of such differentiation of the DNA polymerase activities during nuclear DNA replication in mammalian cells. The method of analysis described here for replication intermediates can be used to examine the inhibitory activities of other chemicals on DNA synthesis.     

Amino acid changes within conserved region III of the herpes simplex virus and human cytomegalovirus DNA polymerases confer resistance to 4-oxo-dihydroquinolines,a novel class of herpesvirus antiviral agents

The 4-oxo-dihydroquinolines (PNU-182171 and PNU-183792) are nonnucleoside inhibitors of herpesvirus polymerases (R. J. Brideau et al., Antiviral Res. 54:19-28, 2002; N. L. Oien et al., Antimicrob. Agents Chemother. 46:724-730, 2002). In cell culture these compounds inhibit herpes simplex virus type 1 (HSV-1), HSV-2, human cytomegalovirus (HCMV), varicella-zoster virus (VZV), and human herpesvirus 8 (HHV-8) replication. HSV-1 and HSV-2 mutants resistant to these drugs were isolated and the resistance mutation was mapped to the DNA polymerase gene. Drug resistance correlated with a point mutation in conserved domain III that resulted in a V823A change in the HSV-1 or the equivalent amino acid in the HSV-2 DNA polymerase. Resistance of HCMV was also found to correlate with amino acid changes in conserved domain III (V823A+V824L). V823 is conserved in the DNA polymerases of six (HSV-1, HSV-2, HCMV, VZV, Epstein-Barr virus, and HHV-8) of the eight human herpesviruses; the HHV-6 and HHV-7 polymerases contain an alanine at this amino acid. In vitro polymerase assays demonstrated that HSV-1, HSV-2, HCMV, VZV, and HHV-8 polymerases were inhibited by PNU-183792, whereas the HHV-6 polymerase was not. Changing this amino acid from valine to alanine in the HSV-1, HCMV, and HHV-8 polymerases alters the polymerase activity so that it is less sensitive to drug inhibition. In contrast, changing the equivalent amino acid in the HHV-6 polymerase from alanine to valine alters polymerase activity so that PNU-183792 inhibits this enzyme. The HSV-1, HSV-2, and HCMV drug-resistant mutants were not altered in their susceptibilities to nucleoside analogs; in fact, some of the mutants were hypersensitive to several of the drugs. These results support a mechanism where PNU-183792 inhibits herpesviruses by interacting with a binding determinant on the viral DNA polymerase that is less important for the binding of nucleoside analogs and deoxynucleoside triphosphates.     

Genetics of resistance to phosphonoacetic acid in strain KOS of herpes simplex virus type 1.

A DNA- temperature-sensitive mutant of herpes simplex virus type 1 exhibiting thermolabile DNA polymerase activity, tsD9, was shown to be resistant to phosphonoacetic acid (PAA) when plated at the permissive temperature. ts+ revertants of tsD9 were PAA sensitive and exhibited DNA polymerase activity intermediate between that of the wild-type virus and tsD9, indicating that both temperature sensitivity and sensitivity to PAA are controlled by the same gene. Since the position of tsD9 on the existing herpes simplex virus type 1 linkage map is known, the locus for PAA resistance--and therefore for the structural gene for viral DNA polymerase--has been identified.     

Susceptibility of varicella-zoster virus to thymidine analogues

Ten strains of varicella-zoster virus (VZV) were tested for susceptibility to 17 nucleoside analogues by a plaque reduction assay using human embryonic lung fibroblast cells. The compounds employed were 5-substituted arabinosyluracils and 2'-deoxyuridines, 2'-fluoro-arabinosylpyrimidines (F-araPyr) and acyclovir. In terms of the 50% plaque reduction dose (PD50), 4- to 40-fold difference were found between the 10 strains of VZV in susceptibilities to each compound. VZV was highly susceptible to 5-halogenovinyl-arabinosyluracils (XV-araUs); the PD50 values of these compounds were less than 0.001 micrograms/ml. VZV was much more susceptible than herpes simplex virus (HSV) type 1 to XV-araUs, but less susceptible than either HSV type 1 or type 2 to 5-ethyl-2'-deoxyuridine, 5-ethyl-arabinosyluracil and acyclovir.     

In vitro-selected drug-resistant varicella-zoster virus mutants in the thymidine kinase and DNA polymerase genes yield novel phenotype-genotype associations and highlight differences between antiherpesvirus drugs

Varicella zoster virus (VZV) is usually associated with mild to moderate illness in immunocompetent patients. However, older age and immune deficiency are the most important risk factors linked with virus reactivation and severe complications. Treatment of VZV infections is based on nucleoside analogues, such as acyclovir (ACV) and its valyl prodrug valacyclovir, penciclovir (PCV) as its prodrug famciclovir, and bromovinyldeoxyuridine (BVDU; brivudin) in some areas. The use of the pyrophosphate analogue foscarnet (PFA) is restricted to ACV-resistant (ACV(r)) VZV infections. Since antiviral drug resistance is an emerging problem, we attempt to describe the contributions of specific mutations in the viral thymidine kinase (TK) gene identified following selection with ACV, BVDU and its derivative BVaraU (sorivudine), and the bicyclic pyrimidine nucleoside analogues (BCNAs), a new class of potent and specific anti-VZV agents. The string of 6 Cs at nucleotides 493 to 498 of the VZV TK gene appeared to function as a hot spot for nucleotide insertions or deletions. Novel amino acid substitutions (G24R and T86A) in VZV TK were also linked to drug resistance. Six mutations were identified in the "palm domain" of VZV DNA polymerase in viruses selected for resistance to PFA, PCV, and the 2-phophonylmethoxyethyl (PME) purine derivatives. The investigation of the contributions of specific mutations in VZV TK or DNA polymerase to antiviral drug resistance and their impacts on the structures of the viral proteins indicated specific patterns of cross-resistance and highlighted important differences, not only between distinct classes of antivirals, but also between ACV and PCV.     

Mutations in the herpes simplex virus DNA polymerase gene can confer resistance to 9-beta-D-arabinofuranosyladenine.

Mutants of herpes simplex virus type 1 resistant to the antiviral drug 9-beta-D-arabinofuranosyladenine (araA) have been isolated and characterized. AraA-resistant mutants can be isolated readily and appear at an appreciable frequency in low-passage stocks of wild-type virus. Of 13 newly isolated mutants, at least 11 were also resistant to phosphonoacetic acid (PAA). Of four previously described PAA-resistant mutants, two exhibited substantial araA resistance. The araA resistance phenotype of one of these mutants, PAAr5, has been mapped to the HpaI-B fragment of herpes simplex virus DNA by marker transfer, and araA resistance behaved in marker transfer experiments as if it were closely linked to PAA resistance, a recognized marker for the viral DNA polymerase locus. PAAr5 induced viral DNA polymerase activity which was much less susceptible to inhibition by the triphosphate derivative of araA than was wild-type DNA polymerase. These genetic and biochemical data indicate that the herpes simplex virus DNA polymerase gene is a locus which, when mutated, can confer resistance to araA and thus that the herpes simplex virus DNA polymerase is a target for this antiviral drug.     

Chemoenzymatic syntheses and anti-HIV-1 activity of glucose-nucleoside conjugates as prodrugs

Phosphodiester linked conjugates of various nucleosides such as d4U, d4T, IdUrd, ddI, ddA, virazole, ara-A, and ara-C containing a glucosyl moiety have been described. These compounds were designed to act as prodrugs, where the corresponding 5'-monophosphates may be generated intracellularly. The synthesis of the glycoconjugates was achieved in good yields by condensation of a glucosyl phosphoramidite 7 with nucleosides in the presence of an activating agent. It was demonstrated that the glucose conjugates improve the water solubility of the nucleoside analogues, for example, up to 31-fold for the ara-A conjugate compared to that of ara-A alone. The new conjugates were tested for their anti-HIV-1 activity in human lymphocytes. These derivatives offer a convenient design for potential prodrug candidates with the possibility of improving the physicochemical properties and therapeutic activity of nucleoside analogues.     

Selection and characterization of mutant S49 T-lymphoma cell lines resistant to phosphonoformic acid: evidence for inhibition of ribonucleotide reductase

Phosphonoformic acid (PFA) and its congener phosphonoacetic acid (PAA) are inhibitors of viral replication whose mechanism of action appears to be the inhibition of viral DNA polymerase. These drugs inhibit mammalian DNA polymerase to a lesser extent. We sought to characterize the effects of phonoformic acid on mammalian cells by examining mutants of S49 cells (a mouse T-lymphoma line), which were selected by virtue of their resistance to phosphonoformic acid. The 11 mutant lines that were resistant to growth inhibition by 3 mM PFA had a range of growth rates, cell cycle distribution abnormalities, and resistance to the inhibitory effects of thymidine, acycloguanosine (acyclovir), aphidicolin, deoxyadenosine, and novobiocin. Most mutant lines had pools of ribonucleoside triphosphates and deoxyribonucleoside triphosphates similar to those of wild-type S49 cells. However, one line (PFA 3-9) had a greatly elevated dCTP pool. When this mutant line was further characterized, no apparent defect in DNA polymerase alpha activity was seen, but an increased ribonucleotide reductase activity, as assayed by CDP reduction in permeabilized cells, was observed. The CDP reductase activity in the PFA 3-9 cells decreased to wild-type control levels, and the CDP reductase activity of wild-type cells was also greatly reduced when PFA (2-3 mM) was added to permeabilized cells during the enzyme assay. These results demonstrate that PFA can directly inhibit ribonucleotide reductase activity in permeabilized cells. In addition, when PFA was added to exponentially growing cultures of either wild-type or PFA 3-9 mutant cells, the drug caused an arrest in S phase of the cell cycle and a decrease in all four deoxyribonucleotide pools, with the most dramatic decrease in the dCTP pools. The reduction in the dCTP pool level could be reversed by addition of exogenous deoxycytidine, but this reversed PFA toxicity only marginally. These observations suggest that PFA is an inhibitor of mammalian ribonucleotide reductase and that partial resistance to PFA can be effected by mutation to increased CDP reductase activity resulting in a large dCTP pool. This mutation results in less than twofold resistance to PFA, suggesting that other sites of inhibition coexist.     

DNA polymerase and thymidine kinase activities in MC-29 virus-induced transplantable hepatoma and the effect of cytostatic treatment on these activities

The activity of DNA polymerases and thymidine kinase was compared in the MC-29 leukosis virus-induced transplantable hepatoma and in the livers of rats treated with cyclophosphamide (CP), cytosine-arabinoside (ara-C) and 5-fluoro-uracil (5-FU). The specific activity of DNA polymerase was twenty times greater in the MC-29 leukosis virus-induced hepatoma, while thymidine kinase was only 3–5 times greater than in the liver.All three enzymes showed Michaelis-Menten kinetics in their substrate and template saturation curves. The template utilization of DNA polymerases from hepatoma and from liver was compared. Both had higher activities on a poly(dA) · poly(dT) template at pH 8.0, than on DNA at pH 7.5. After chromatography on a phosphocellulose column two polymerases were separated. The first peak eluted by 0.15 M KCl preferred DNA as template (polymerase α). The second eluted by 0.5 M KCl worked better on poly(dA) · poly(dT) (polymerase β). Thymidine kinase was eluted by 0.25 M KCl. Inhibition by N-ethylmaleimide (NEM) showed the polymerase α to be sensitive and the polymerase β to be resistant to the sulfhydryl blocking agent; similar to the respective enzymes of other eukaryotic cells. The specific acitivity of DNA polymerase decreased after CP treatment at 6 h and 72 h and after ara-C treatment at 72 h. The specific activities of thymidine kinase were not changed significantly in response to the drug administrations.     

Genetic characterization of the vaccinia virus DNA polymerase: cytosine arabinoside resistance requires a variable lesion conferring phosphonoacetate resistance in conjunction with an invariant mutation localized to the 3'-5' exonuclease domain.

In this report, we describe the isolation, molecular genetic mapping, and phenotypic characterization of vaccinia virus mutants resistant to cytosine arabinoside (araC) and phosphonoacetic acid (PAA). At 37 degrees C, 8 microM araC was found to prevent macroscopic plaque formation by wild-type virus and to cause a 10(4)-fold reduction in viral yield. Mutants resistant to 8 microM araC were selected by serial passage of a chemically mutagenized viral stock in the presence of drug. Because recovery of mutants required that initial passages be performed under less stringent selective conditions, and because plaque-purified isolates were found to be cross-resistant to 200 micrograms of PAA per ml, it seemed likely that resistance to araC required more than one genetic lesion. This hypothesis was confirmed by genetic and physical mapping of the responsible mutations. PAAr was accorded by the acquisition of one of three G-A transitions in the DNA polymerase gene which individually alter cysteine 356 to tyrosine, glycine 372 to aspartic acid, or glycine 380 to serine. AraCr was found to require one of these substitutions plus an additional T-C transition within codon 171 of the DNA polymerase gene, a change which replaces the wild-type phenylalanine with serine. Congenic viral stocks carrying one of the three PAAr lesions, either alone or in conjunction with the upstream araCr lesion, in an otherwise wild-type background were generated. The PAAr mutations conferred nearly complete resistance to PAA, a slight degree of resistance to araC, hypersensitivity to aphidicolin, and decreased spontaneous mutation frequency. Addition of the mutation at codon 171 significantly augmented araC resistance and aphidicolin hypersensitivity but caused no further change in mutation frequency. Several lines of evidence suggest that the PAAr mutations primarily affect the deoxynucleoside triphosphate-binding site, whereas the codon 171 mutation, lying within a conserved motif associated with 3'-5' exonuclease function, is postulated to affect the proofreading exonuclease of the DNA polymerase.     

Thymidine kinase with altered substrate specificity of acyclovir resistant varicella-zoster virus

The acyclovir resistant mutant of varicella-zoster virus ACV-R (A 8) induced the same level of thymidine kinase activity in infected cells as the parent Kawaguchi strain. However, it induced less deoxycytidine kinase activity and did not induce phosphorylating activity for the nucleotide analogue, 9-(2 hydroxy-ethoxymethyl)-guanine-(acyclovir). Another acyclovir resistant mutant, ACV-R (A 4), which is cross-resistant to phosphonoacetate and is thought to be a viral DNA polymerase mutant, induced the same level of phosphorylating activities for thymidine, deoxycytidine and acyclovir as the parent strain. The altered substrate specificity of thymidine kinase induced by ACV-R (A 8) is concluded to confer resistance to acyclovir on ACV-R (A 8).     

Induction of DNA ligase I by 1-beta-D-arabinosylcytosine and aphidicolin in MiaPaCa human pancreatic cancer cells

Exposure of MiaPaCa cells to 1-beta-D-arabinosylcytosine (ara-C) resulted in an increase in DNA ligase levels up to threefold compared to that in the untreated control cells, despite significant growth inhibition. Increased levels of DNA ligase I protein appear to correlate with the appearance of increased mRNA levels. The [(3)H]thymidine incorporation experiment and the biochemical assay of total polymerase activity revealed that an increase in DNA ligase I levels after treatment with ara-C was not accompanied by an increase of DNA synthesis or an increased presence of DNA polymerase activity inside cells. When cells resumed DNA synthesis after drug treatment, DNA ligase I levels began to drop, indicating that increased DNA ligase I is not required for DNA synthesis. An increase in DNA ligase I was also observed in cells treated with aphidicolin, another inhibitor of DNA synthesis that inhibits DNA polymerases without incorporating itself into DNA, indicating that an increase in DNA ligase I levels could be caused by the arrest of DNA replication by these agents. Interestingly, caffeine, which is a well-known inhibitor of DNA damage checkpoint kinases, abrogated the increase in DNA ligase I in MiaPaCa cells treated with ara-C and aphidicolin, suggesting that caffeine-sensitive kinases might be important mediators in the pathway leading to the increase in DNA ligase I levels in response to anticancer drugs, including ara-C and aphidicolin. We propose that ara-C and aphidicolin induce damage to the DNA strand by arresting DNA replication forks and subsequently increase DNA ligase I levels to facilitate repair of DNA damage.