Cell cycle dependence of synthesis of unintegrated viral DNA in mouse cells newly infected with murine leukemia virus

Abstract

We have studied Moloney murine leukemia virus (MuLV) replication in newly infected NIH/3T3 cells brought to a stationary phase by serum depletion. Progeny viruses were markedly decreased under these conditions. Studies of the early phase of the virus cycle by the Southern blot hybridization procedure revealed that levels of unintegrated linear double-stranded and supercoiled viral DNAs were decreased in quiescent NIH/3T3 cells as compared to levels detected in serum-replenished cells. When serum was added to quiescent cells up to 48 hr postinfection, we could detect an increase of viral DNA, suggesting the presence of a stable intermediate encoding viral information. In order to characterize this intermediate, stationary cells were labeled with BrdU at the time of serum addition so that substituted viral DNA molecules made under serum stimulation could be separated on CsCl gradients from those made under serum depletion. The analysis of this experiment revealed that upon serum addition, the majority of viral DNA was fully substituted (HH), indicating that it must have been synthesized from an RNA template. Also, an important part of viral DNA made after serum addition had an intermediate density (HL), suggesting that incomplete molecules made in quiescent cells were completed after serum addition. Our results clearly show that host factors are required for synthesis of viral DNA in NIH/3T3 cells newly infected with MuLV.