Acyclovir in mouse cytomegalovirus infections.

A virus-specified thymidine kinase appears to be a general requirement for herpes virus susceptibility to the antiviral effect of acyclovir. Surprisingly, mouse cytomegalovirus (MCMV), which does not encode for a thymidine kinase, is exquisitely sensitive to the drug both in vitro and in vivo. The drug is active against the virus in the absence of a cellular thymidine kinase and the antiviral activity is not diminished in the presence of excess thymidine or a variety of nucleosides and deoxynucleosides. Thus, a thymidine phosphorylation pathway is not required for the drug's activation of this infection. The enzyme system responsible for phosphorylation of the drug has not been identified. Mouse cytomegalovirus mutants resistant to the drug have been isolated, indicating that the antiMCMV effect results from selective inhibition of viral replication rather than indirectly through toxicity to the host cell. Eight resistant mutants appear to be in the same complementation group and seven of the mutants demonstrate coresistance to phosphonoacetic acid, a marker for the DNA polymerase locus of herpes viruses. The evidence to date indicates that the MCMV DNA polymerases is the final site of action of the drug. Investigations of the antiMCMV activity of acyclovir should provide insights into the antiviral effects of this drug and other nucleoside analogs in other herpes virus infections in which the virus does not code for a thymidine kinase (for example, human cytomegalovirus and Epstein-Barr virus).

Efficacy of acyclovir against mouse cytomegalovirus in vivo.

Acyclovir reduced mortality and organ virus titers in mice inoculated intraperitoneally with 10 50% lethal doses of mouse cytomegalovirus. This susceptibility to acyclovir of a herpesvirus which lacks thymidine kinase is surprising. Alternative phosphorylating enzymes may account for this susceptibility.

Thymidine kinase not required for antiviral activity of acyclovir against mouse cytomegalovirus.

Previous studies of herpesvirus infections have indicated that a virus-specified thymidine kinase is required for the initial phosphorylation of acyclovir [acycloguanosine or 9-(2-hydroxyethoxymethyl)guanine] in the formation of acycloguanosine triphosphate. The latter compound accumulates in infected cells and competitively inhibits the viral DNA polymerase. We found that mouse cytomegalovirus, which does not express a thymidine kinase, was sensitive to the antiviral effects of acyclovir at a 50% inhibitory dose of approximately 0.23 microM. Acyclovir was equally effective against mouse cytomegalovirus in normal 3T3 cells and in 3T3 cells deficient in cellular thymidine kinase. Furthermore, the activity of acyclovir could not be reversed by excess thymidine, which easily reversed the antiviral activity of acyclovir against herpes simplex virus. Using a high-pressure liquid chromatography technique that easily detected acycloguanosine triphosphate in cells infected with herpes simplex virus, we could not detect acycloguanosine triphosphate in mouse cytomegalovirus-infected cells. These experiments demonstrated that the activity of acyclovir against mouse cytomegalovirus is not dependent on a thymidine phosphorylation pathway. Additional experiments are underway to determine whether acycloguanosine triphosphate is produced by another pathway in concentrations sufficient to inhibit mouse cytomegalovirus DNA polymerase.