Characterization of a temperature-sensitive mutant of frog virus 3 defective in DNA replication

Abstract

We have characterized the defect of a temperature-sensitive (ts) DNA − mutant (ts 6642) of frog virus 3 (FV 3). At the nonpermissive temperature (30°) ts 6642 synthesized <3% of the viral DNA that was synthesized at the permissive temperature (23°). When ts 6642-infected cells were incubated at 30° for 4.0 hr and then shifted to permissive temperature, viral DNA synthesis started immediately even when protein synthesis was inhibited at the time of shiftdown. This result implies that at 30°, ts 6642 synthesized all the proteins required for viral DNA replication but that one of these was nonfunctional at the nonpermissive temperature. Further characterization revealed that ts 6642 was probably defective in the initiation of DNA replication. This conclusion was based on the following data: When ts 6642-infected cells incubated at 23° for 4.0 hr were shifted to 30°, there was a gradual decrease in viral DNA synthesis. By 1 to 1.5 hr after the shiftup, viral DNA synthesis was completely inhibited. Analysis of the density of the DNA synthesized after a shiftup in the presence of BUdR and FUdR suggested that residual viral DNA synthesis represented chain elongation, and not initiation of new rounds of DNA replication. The defective protein was therefore involved in the initiation process. Both wild-type FV 3 (FV 3 +) and ts 6642 induced the synthesis of thymidine kinase and DNA polymerase at 30°. Therefore, neither of these enzymes was involved in the DNA replication defect of ts 6642. At the nonpermissive temperature, ts 6642 synthesized all the viral proteins that were detectable at the permissive temperature. However, synthesis of late proteins was delayed, and never reached wild-type levels. Furthermore, the rate of synthesis of late proteins at 30° became dependent upon the multiplicity of infection. These results reinforce our previous conclusion ( R. Goorha and A. Granoff, 1974, Virology 60, 237–250) that in FV3 +-infected cells late proteins (and by implication late mRNAs) were synthesized in the absence of viral DNA replication.