Faculty Bibliography

Previous studies with simian virus 40-transformed mouse 3T3 cells which are temperature sensitive for the expression of the transformed phenotype (ts SV3T3 cells) have shown that T-antigen expression and viral DNA transcription are under cell cycle control. Using these ts SV3T3 cells, we studied the expression of the viral genome under proliferating and non-proliferating conditions, in the presence and absence of inhibitors of macromolecular synthesis and of the tumor promoter phorbol myristate acetate. ts SV3TE cells which are growth arrested at 39 degrees C by low serum concentration or saturation density accumulated in G1 and did not express T-antigen. When these cells were induced to proliferate, at either 32 or 39 degrees C, T-antigen synthesis preceded the entry of the cells into the S-phase and was not coupled to DNA replication. G1-arrested ts SV3T3 cells were induced to synthesize T-antigen by phorbol myristate acetate treatment, but T-antigen alone was not sufficient to induce cellular DNA synthesis. Isoleucine deprivation arrested growth of ts SV3T3 cells, but these cells, as well as normal 3T3, did not accumulate in G1 and continued to express T-antigen. The temperature-sensitive expression of the transformed phenotype in the ts SV3T3 cells does not appear to be due to a lack of transcription of specific regions of the integrated simian virus 40 genome at 39 degrees C

We have investigated the kinetics of exit from the resting state of BHK cells which had been arrested by isoleucine deprivation, serum starvation, or high temperature in the case of three ts G1 mutants. In addition, we have studied the effect of imposing a secondary deprivation on cells which had been released from one of the above mentioned blocks. The results obtained show that the quiescent states reached by BHK cells following serum or isoleucine deprivation cannot be differentiated on the basis of the exit kinetics from Smith and Martin's probabilistic A-state. Nevertheless, the response of cells to secondary deprivation is different, depending on the nature of the primary arresting condition used, reflecting physiological differences between the different resting states. A model is presented which postulates that cycle transition specific genes require the presence of different proliferative agents for their expression

A temperature-sensitive mutant of BHK, designated ts BN-2, shows a rapid drop in 3H-thymidine incorporation along with accumulation of the cells in the G1 phase of the cycle when asynchronous cultures are shifted from 33.5 degrees C to the nonpermissive temperature of 39.5 degrees C. Synchronized cultures of ts BN-2 cells did not enter DNA synthesis when shifted up in G1. Shift-up of cultures at the beginning of the S phase resulted in an approximately normal rate of DNA synthesis for about 2 hr. The rate of DNA synthesis then quickly declined, and the cells became arrested in mid-S after completion of approximately 0.5 rounds of DNA replication. At the same time, the majority of the cells were observed to lose the nuclear membrane and displayed premature chromosome condensation. These events were followed by the appearance of cells containing several micronuclei and eventual cell disruption and death. The nonpermissive temperature appeared to have no effect on either the elongation of short fragments of DNA or the execution of mitosis after the completion of the S phase under permissive conditions. The ts defect in this mutant may directly limit the initiation of DNA synthesis or alter the regulation of chromatin condensation

The synthesis of histones and DNA was examined in BHK cells arrested in G1 by isoleucine starvation and in cells progressing into the S phase upon isoleucine refeeding. Approximately 2-3% of the cells were not arrested in G1 and synthesized DNA. The rate of synthesis of DNA and nucleosomal histones observed in cells starved for isoleucine could be accounted for by the presence of these asynchronous cells. Synthesis of H1 histones by cells in G1, however, was 3 times that of the nucleosomal histones and approximately 15% of the rate of H1 histone synthesis in mid-S. Upon entry into S, the histones were synthesized in the same molar ratio in which they are present in chromatin. The possible biological significance of H1 histone synthesis in G1 cells and its implications for the regulatory mechanisms controlling histome synthesis are discussed

A procedure for the isolation of temperature sensitive mutants of BHK cells is described. Mutagenized cells were synchronized in G1 by serum starvation at 33 degrees, and, following release, shifted to 37.5 degrees in the presence of FUdR, to kill cells entering the DNA synthetic phase. Eight independently mutagenized series of cells were carried through four cycles of this selection, and surviving cells were tested for ability to grow at 33 degrees and 39.5 degrees after each cycle. The results suggest that such procedure is effective in enriching for non-leaky ts mutants and favors the isolation of mutants which at 39.5 degrees are inhibited in the processes necessary for DNA synthesis and lose viability rapidly. The effectiveness of repeated selection cycles and the general characteristics of the ts mutants isolated by this method were also evaluated

To define the relationship between simian virus 40 (SV40)-specific T-antigen and cell growth and to look for regulatory mechanisms that might control T-antigen synthesis in transformed cells, we studied the expression of T-antigen and the viral transcription in SV40-transformed cells that were exponentially growing or arrested in the G1-phase of the cell cycle. We took advantage of the behavior of two lines of SV40-transformed mouse 3T3 cells (ts SV3T3), which, although transformed by wild-type SV40, are temperature sensitive for the expression of the transformed phenotype. At 32 degrees C, ts SV3T3 cells behave like standard transformants, whereas at 39 degrees C, they become arrested in G1 after reaching saturatio n density or under serum starvation. At 32 degrees C or growing at 39 degrees C, ts SV3T3 were 100% T-antigen positive and contained virus-specific mRNA. However, after G1 arrest at 39 degrees C, most of the cells became T-antigen negative. This seems to be caused by a lack of transcription of the integrated viral DNA, since these cells contain no appreciable amounts of SV40-specific RNA. Induction of proliferation in resting, T-antigen-negative ts SV3T3 cultures results in the reappearance of T-antigen a few hours before the cells enter DNA synthesis. These results suggest that transcription of the viral genome and T-antigen expression in SV40-transformed cells is subjected to a cell cycle control