Transformation of BALB/c-3T3 cells by tsA mutants of simian virus 40: temperature sensitivity of the transformed phenotype and retransofrmation by wild-type virus.

The function of the A gene of simian virus 40 (SV40) in transformation of BALB/c-3T3 cells was investigated by infecting at the permissive temperature with wild-type SV40 and with six tsA mutants whose mutation sites map at different positions in the early region of the SV40 genome. Cloned transformants were then characterized as to the temperature sensitivity of the transformed phenotype. Of 16 tsA transformants, 15 were temperature sensitive for the ability to overgrow a monolayer of normal cells, whereas three of three wild-type transformants were not. This pattern of temperature sensitivity of the transformed phenotype was also observed when selected clones were assessed for the ability to grow in soft agar and in medium containing low concentration of serum. The temperature resistance of the one exceptional tsA transformant could be attributed neither to the location of the mutation site in the transforming virus nor to transformation by a revertant virus. This temperature-resistant tsA transformant, however, was demonstrated to contain a higher intracellular concentration of SV40 T antigen than a temperature-sensitive line transformed by the same tsA mutant. A tsA transformant displaying the untransformed phenotype at the nonpermissive temperature was found to be susceptible to retransformation by wild-type virus at this temperature, demonstrating that the temperature sensitivity of the tsA transformants is due to the viral mutation and not to a cellular defect. These results indicate that continuous expression of the product of the SV40 A gene is required to maintain the transformed phenotype in BALB/c-3T3 cells.     

Structural prerequisites of simian virus 40 large T antigen for the maintenance of cell transformation.

We have investigated the functional roles of two structural subsets of simian virus 40 (SV40) large T antigen, namely homo-oligomers and complexes with the host cellular p53 protein, for the transformed phenotype. We examined T antigen produced in cells transformed by temperature-sensitive SV40 large T mutants: heat-sensitive or unrestricted SV40 tsA58-transformed rat cells and unrestricted tsA1499 transformants. In both unrestricted cell lines, T antigen was temperature-sensitive only for the formation of fast sedimenting homo-oligomers. Corresponding to our recent observations obtained with tsA1499-infected monkey cells, in tsA1499 transformants large T was competent to form stable T-p53 complexes independently of the temperature. However, T antigen coded for by tsA58, which is heat-sensitive for binding to p53, occurred in stable complexes with this protein in unrestricted tsA58 transformants under all conditions. Furthermore, in both unrestricted transformants T-p53 complexes arise in the absence of homo-oligomers of T antigen. In conclusion, T antigen homo-oligomers are not involved in cell transformation, whereas T-p53 complexes may be involved in the maintenance of this phenotype.     

Phosphorylation of T-antigen and control T-antigen expression in cells transformed by wild-type and tsA mutants of simian virus 40.

Chinese hamster lung (CHL) cells transformed by wild-type simian virus 40 (cell line CHLWT15) or transformed by the simian virus 40 mutants tsA30 (cell lines CHLA30L1 and CHLA30L2) or tsA239 (cell line CHLA239L1) were used to determine the rates of turnover and synthesis of the T-antigen protein and the rate of turnover of the phosphate group(s) attached to the T-antigen at both the permissive and restrictive temperatures. The phosphate group turned over several times within the lifetime of the protein to which it was attached, with the exception of the phosphate group in the tsA transformants at 40 degrees C, which turned over at the same rate as the T-antigen protein. The steady-state levels of the T-antigens (molecular weights, 92,000 [92K] and 17K) and the amount of simian virus 40-specific RNA was also determined in each of the lines. The CHLA30L1 line contained two to three times more early simian virus 40 RNA than the CHLA30L2 line; although neither line formed colonies in agar at 40 degrees C, CHLA30L1 overgrew a normal monolayer at 40 degrees C. The rate of 92K-T-antigen synthesis was 1.5 times faster in CHLA30L1 than in CHLA30L2 at 33 degrees C and 4 times faster at 40 degrees C. The different phenotype of these two presumably isogenic cell lines seem to be related to the levels of the T-antigens. The ratios of the 92K T-antigen to the 17K T-antigens were similar in the two lines. Transformed CHL cell lines, unlike transformed mouse 3T3 cell lines, were found to contain very small amounts of the 56K T-antigen.     

Separation of lytic and transforming functions of the simian virus 40 A region: two mutants which are temperature sensitive for lytic functions have opposite effects on transformation.

Thirty-six of 40 rat cell clones transformed to anchorage independence at low multiplicity of infection by simian virus 40 tsA58 were heat sensitive for continued expression of the transformed phenotype. tsA1499 is an 81-base-pair deletion at 21 map units which is like tsA58 in that it is also heat sensitive for lytic growth, belongs to the A complementation group, and produces rat cell transformants which contain a thermolabile T antigen. Unlike tsA58, however, tsA1499 generated rat cell transformants efficiently at the temperature at which it was lytically defective, and 10 of 17 clones transformed by tsA1499 were cold rather than heat sensitive for the continued maintenance of the transformed phenotype. The lytic and transforming activities of the A region thus appeared to function independently in mutant tsA1499.     

Role of simian virus 40 gene A function in maintenance of transformation.

Mouse, hamster, and human cells were transformed at the permissive temperature by mutants from simian virus 40 (SV40) complementation group A in order to ascertain the role of the gene A function in transformation. The following parameters of transformation were monitored with the transformed cells under permissive and nonpermissive conditions: morphology; saturation density; colony formation on plastic, on cell monolayers, and in soft agar; uptake of hexose; and the expression of SV40 tumor (T) and surface (S) antigens. Cells transformed by the temperature-sensitive (ts) mutants exhibited the phenotype of transformed cells at the nonrestrictive temperature for all of the parameters studied. However, when grown at the restrictive temperature, they were phenotypically similar to normal, untransformed cells. Growth curves showed that the (ts) A mutant-transformed cells exhibited the growth characteristics of wild-type virus-transformed cells at the permissive temperature and resembled normal cells when placed under restrictive conditions. There were 3-to 51-fold reductions in the levels of saturation density, colony formation, and uptake of hexose when the mutant-transformed cells were the elevated temperature as compared to when they were grown at the permissive temperature. Mutant-transformed cells from the nonpermissive temperature were able to produce transformed foci when shifted down to permissive conditions, indicating that the phenotypically reverted cells were still viable and that the reversion was a reversible event. SV40 T antigen was present in the cells at both temperatures, but S antigen was not detected in cells maintained at the nonpremissive temperature. All of the wild-type virus-transformed cells exhbited a transformed cells exhibited a transformed phenotype when grown under either restrictive or nonrestrictive conditions. Thers results indicate that the SV40 group A mutant-transformed cells are temperature sensitive for the maintenance of growth properties characteristics of transformation. Virus rescued from the mutant-transformed cells by the transfection method was ts, suggesting that the SV40 gene A function, rather than a cellular one, is responsible for the ts behavior of the cells.     

Effects of large and small T antigens on DNA synthesis and cell division in simian virus 40-transformed BALB/c 3T3 cells.

The roles of the large T and small t antigens of simian virus 40 in cellular DNA synthesis and cell division were analyzed in BALB/c 3T3 mouse cells transformed by wild-type, temperature-sensitive A (tsA), or tsA-deletion (tsA/dl) double mutants. Assessment of DNA replication and cell cycle distribution by radioautography of [3H]thymidine-labeled nuclei and by flow microfluorimetry indicate that tsA transformants do not synthesize DNA or divide at the restrictive temperature to the same extent as they do at the permissive temperature or as wild-type transformants do at the restrictive temperature. This confirms earlier studies suggesting that large T induces DNA synthesis and mitosis in transformed cells. Inhibition of replication in tsA transformants at the restrictive temperature, however, is not complete. Some residual cell division does occur but is in large part offset by cell detachment and death. This failure to revert completely to the parental 3T3 phenotype, as indicated by residual cell cycling at the restrictive temperature, was also observed in cells transformed by tsA/dl double mutants which, in addition to producing a ts large T, make no small t protein. Small t, therefore, does not appear to be responsible for the residual cell cycling and plays no demonstrable role in the induction of DNA synthesis or cell division in stably transformed BALB/c 3T3 cells. Comparison of cell cycling in tsA and tsA/dl transformants, normal 3T3 cells, and a transformation revertant suggests that the failure of tsA transformants to revert completely may be due to leakiness of the tsA mutation as well as to a permanent cellular alteration induced during viral transformation. Finally, analysis of cells transformed by tsA/dl double mutants indicates that small t is not required for full expression of growth properties characteristic of transformed cells.     

Growth of immortal simian virus 40 tsA-transformed human fibroblasts is temperature dependent.

Simian virus 40 (SV40)-mediated transformation of human fibroblasts offers an experimental system for studying both carcinogenesis and cellular aging, since such transformants show the typical features of altered cellular growth but still have a limited life span in culture and undergo senescence. We have previously demonstrated (D. S. Neufeld, S. Ripley, A. Henderson, and H. L. Ozer, Mol. Cell. Biol. 7:2794-2802, 1987) that transformants generated with origin-defective mutants of SV40 show an increased frequency of overcoming senescence and becoming immortal. To clarify further the role of large T antigen, we have generated immortalized transformants by using origin-defective mutants of SV40 encoding a heat-labile large T antigen (tsA58 transformants). At a temperature permissive for large-T-antigen function (35 degrees C), the cell line AR5 had properties resembling those of cell lines transformed with wild-type SV40. However, the AR5 cells were unable to proliferate or form colonies at temperatures restrictive for large-T-antigen function (39 degrees C), demonstrating a continuous need for large T antigen even in immortalized human fibroblasts. Such immortal temperature-dependent transformants should be useful cell lines for the identification of other cellular or viral gene products that induce cell proliferation in human cells.     

Role of the simian virus 40 gene A product in regulation of DNA synthesis in transformed cells.

Cells transformed by tsA mutants of simian virus 40 (SV40) are temperature sensitive for the maintenance of the transformed phenotype. The kinetics of induction of DNA synthesis were determined for hamster cell transformants shifted to the permissive temperature after a 48-h serum arrest at the nonpermissive temperature. DNAsynthesis was initiated in the tsA transformants by 8 h after shiftdown was maximal by 12 h. The presence or absence of fetal bovine serum at the time of temperature shift had no effect on the kinetics of initiation of DNA synthesis. Analysis of TTP in tsA transformants revealed similar levels of incorporation of [3H]thymidine into TTP at both permissive and nonpermissive temperatures. Autoradiography revealed that by 12 h after a shift to the permissive temperature, approximately 50% of the cells exhibited labeled nuclei after a 60-min pulse with [3H]thymidine, indicating that a majority of the cells were actively synthesizing DNA. By 8 to 12 h after a shiftup of confluent tsA transformants to the nonpermissive temperature, the number of labeled nuclei was reduced to approximately 16%, regardless of serum concentration. These data indicate that the SV40 gene A product, either directly or indirectly, regulates cellular DNA synthesis in transformed cells.     

Characterization of flat revertant cells isolated from simian virus 40-transformed mouse and rat cells which contain multiple copies of viral genomes.

Eight clones of flat revertants were isolated by negative selection from simian virus 40 (SV40)-transformed mouse and rat cell lines in which two and six viral genome equivalents per cell were integrated, respectively. These revertants showed either a normal cell phenotype or a phenotype intermediate between normal and transformed cells as to cellular morphology and saturation density and were unable to grow in soft agar medium. One revertant derived from SV40-transformed mouse cells was T antigen positive, whereas the other seven revertants were T antigen negative. SV40 could be rescued only from the T-antigen-positive revertant by fusion with permissive monkey cells. The susceptibility of the revertants to retransformation by wild-type SV40 was variable among these revertants. T-antigen-negative revertants from SV40-transformed mouse cells were retransformed at a frequency of 3 to 10 times higher than their grandparental untransformed cells. In contrast, T-antigen-negative revertants from SV40-transformed rat cells could not be retransformed. The arrangement of viral genomes was analyzed by digestion of cellular DNA with restriction enzymes of different specificity, followed by detection of DNA fragments containing a viral sequence and rat cells were serially arranged within the length of about 30 kilobases, with at least two intervening cellular sequences. A head-to-tail tandem array of unit length viral genomes was present in at least one insertion site in the transformed rat cells. All of the revertants had undergone a deletion(s), and only a part of the viral genome was retained in T-antigen-negative revertants. A relatively high frequency of reversion in the transformed rat cells suggests that reversion occurs by homologous recombination between the integrated viral genomes.     

Phenotype-specific phosphorylation of simian virus 40 tsA mutant large T antigens in tsA N-type and A-type transformants.

To identify molecular differences between simian virus 40 (SV40) tsA58 mutant large tumor antigen (large T) in cells of tsA58 N-type transformants [FR(tsA58)A cells], which revert to the normal phenotype after the cells are shifted to the nonpermissive growth temperature, and mutant large T in tsA58 A-type transformants [FR(tsA58)57 cells], which maintain their transformed phenotype after the temperature shift, we asked whether the biological activity of these mutant large T antigens at the nonpermissive growth temperature might correlate with phosphorylation at specific sites. At the permissive growth temperature, the phosphorylation patterns of the mutant large T proteins in FR(tsA58)A (N-type) cells and in FR(tsA58)57 (A-type) cells were largely indistinguishable from that of wild-type large T in FR(wt648) cells. After a shift to the nonpermissive growth temperature, no significant changes in the phosphorylation patterns of wild-type large T in FR(wt648) or of mutant large T in FR(tsA58)57 (A-type) cells were observed. In contrast, the phosphorylation pattern of mutant large T in FR(tsA58)A (N-type) cells changed in a characteristic manner, leading to an apparent underphosphorylation at specific sites. Phosphorylation of the cellular protein p53 was analyzed in parallel. Characteristic differences in the phosphorylation pattern of p53 were observed when cells of N-type and A-type transformants were kept at 39 degrees C as opposed to 32 degrees C. However, these differences did not relate to the different phenotypes of FR(tsA58)A (N-type) and FR(tsA58)57 (A-type) cells at the nonpermissive growth temperature. Our results, therefore, suggest that phosphorylation of large T at specific sites correlates with the transforming activity of tsA mutant large T in SV40 N-type and A-type transformants. This conclusion was substantiated by demonstrating that the biological properties as well as the phosphorylation patterns of SV40 tsA28 mutant large T in cells of SV40 tsA28 N-type and A-type transformants were similar to those in FR(tsA58)A (N-type) and in FR(tsA58)57 (A-type) cells, respectively. The phenotype-specific phosphorylation of tsA mutant large T in tsA A-type transformants probably is a cellular process induced during establishment of SV40 tsA A-type transformants, since tsA28 A-type transformant cells could be obtained by a large-T-dependent in vitro progression of cells of the tsA28 N-type transformant tsA28.3 (M. Osborn and K. Weber, J. Virol. 15:636-644, 1975).     

Simian virus 40 small t antigen is not required for the maintenance of transformation but may act as a promoter (cocarcinogen) during establishment of transformation in resting rat cells.

Simian virus 40 deletion mutants affecting the 20,000-dalton (20K) t antigen and tsA mutants rendering the 90K T antigen temperature sensitive, as well as double mutants containing both mutations, induced host DNA synthesis in resting rat cells at the restrictive temperature. Nonetheless, the deletion mutants and double mutants did not induce transformation in resting cells even at the permissive temperature. On the other hand, the deletion mutants did induce full transformants when actively growing rat cells were infected; the transformants grew efficiently in agar and to high saturation densities on platic. The double mutants did not induce T-antigen-independent (temperature-insensitive) transformants which were shown previously to arise preferentially from resting cells. Thus, small t antigen was dispensable for the maintenance of the transformed phenotype in T-antigen-dependent rat transformants (transformants derived from growing cells) and may play a role in the establishment of T-antigen-independent transformants. We attempt to establish a parallel between transformation induced by chemical carcinogens and simian virus 40-induced transformation.     

Sister chromatid exchange in FR3T3 rat fibroblasts transformed by Simian virus 40

The frequency of Sister Chromatid Exchange (SCE) was determined at low (33 degrees C) and high (40.5 degrees C) temperatures in cell lines derived from FR3T3 rat fibroblast cells after transformation either with Wild-Type Simian Virus 40 (SV40-WT), with an origin-defective SV40 (SV40-ori-), or with the early temperature-sensitive mutant tsA30. Of these cell lines, SV40-WT-, SV40-ori--, and one class of tsA30-transformants (A-type) express the transformed phenotype both at 33 and 40.5 degrees C. The other tsA30-transformants (N-type) revert to a normal phenotype at high temperature. As compared with normal FR3T3 cells, all transformants exhibited, at 33 degrees C, increased numbers of metaphases with high SCE rates. At 40.5 degrees C, all cell lines which expressed a transformed phenotype (SV40-WT, tsA30 type A, SV40-ori-) exhibited substantially increased SCE rates. That this increase was not related to a possible induction of viral replication by BrdU, was proven by Southern blot analysis and by SCE data on SV40-ori--transformed cells. By contrast, no such temperature-induced increase of SCE rates was observed in tsA30-transformants of type N.     

Synthesis of first trimester placental alkaline phosphatase in cultured human term placental cells

Alkaline phosphatase activity in human placental cells transformed by a tsA mutant of simian virus 40 (SV40) can be greatly induced by growing these cells at 40 degrees C, the temperature at which the tsA transformants regain their nontransformed phenotype. The induction of alkaline phosphatase in these cells requires the synthesis of both RNA and protein. The induced alkaline phosphatase from a SV40 tsA30 mutant-transformed term placental cell line (TPA30-1) was purified, characterized, and compared with alkaline phosphatase from term placenta and first trimester placenta. The form of alkaline phosphatase found in TPA30-1 cells differs from the phosphatase of term placenta in physiochemical and immunological properties. The TPA30-1 phosphatase is, however, indistinguishable from the alkaline phosphatase of human first trimester placenta by several criteria, including electrophoretic mobility, apparent molecular weight (Mr = 165,000), size of monomeric subunit (Mr = 77,000), heat lability, and sensitivity to inhibition by amino acids and EDTA. In addition, alkaline phosphatase from both TPA30-1 cells and first trimester placenta can be inactivated by antiserum to liver alkaline phosphatase but not by antiserum to term placental alkaline phosphatase. The induction of first trimester phosphatase in cells derived from term placenta provides a system for the study of alkaline phosphatase gene regulation in human placenta.     

Recombination Between Endogenous and Exogenous Simian Virus 40 Genes. I. Rescue of a Simian Virus 40 Temperature-Sensitive Mutant by Passage in Permissive Transformed Monkey Lines

Passage of the simian virus 40 (SV40) temperature-sensitive (ts) mutant tsD202 at the permissive temperature in each of three permissive lines of SV40-transformed monkey CV1 cells resulted in the emergence of temperature-insensitive virus, which plated like wild-type SV40 at the restrictive temperature on normal CV1 cells. In independent experiments, the amount of temperature-insensitive virus that appeared after passage on transformed cells was from 10(3)- to 10(6)-fold greater than the amount of ts-revertant virus that appeared after an equal number of passages in nontransformed CV1 cells. The virus rescued by passage on transformed cells bred true upon sequential plaque purification, plated on normal CV1 cells with single-hit kinetics at the restrictive temperature, and displayed no selective growth advantage on transformed cells compared to non-transformed cells. Hence, the reversion of the ts phenotype is neither due to complementation effects nor to the selection of preexisting revertants, which grow better on transformed cells. In the accompanying article (T. Vogel et al., J. Virol. 24:541-550, 1977), we present biochemical evidence that the rescue of tsD202 mediated by passage on transformed cells is due to recombination with the resident SV40 genome. Parallel experiments in which tsA, tsB, and tsC SV40 mutants were passaged in each of the three permissive lines of SV40-transformed monkey cells resulted in either only borderline levels of rescue (tsA mutants) or no detectable rescue (tsB and tsC mutants). Evidence is presented that the resident SV40 genome of the transformed monkey lines is itself a late ts mutant, and we suggest that this accounts for the lack of detectable rescue of the tsB and tsC mutants. We furthermore suggest that the borderline level of rescue observed with two tsA mutants is related to a previous finding (Y. Gluzman et al., J. Virol. 22:256-266, 1977) which indicated that the resident SV40 genome of the permissive transformed monkey cells is defective in the function required for initiation of viral DNA synthesis.     

Simian virus 40 gene A function and maintenance of transformation.

Transformants have been isolated after infection of rat embryo cells at 33 C with either wild-type simian virus 40 or with the temperature-sensitive gene A mutants, tsA7 and tsA28. Examination of properties usually associated with transformation such as growth in 1% serum, growth rate, saturation density, and morphology show that these properties are temperature dependent in the tsA transformants characterized, but are not temperature dependent in the wild-type transformants that have been examined. In the most thoroughly characterized tsA transformants the expression of T antigen also appears to be temperature dependent. These data suggest that an active A function is required for the maintenance of transformation in these cells. In the lytic cycle, the A function is involved in the initiation of DNA synthesis. Thus transformation by simian virus 40 may be the direct consequence of the introduction of the simian virus 40 replicon and the presence of its DNA initiator function, which causes the cell to express a transformed phenotype.     

Alteration in cyclic adenosine 3':5'-monophosphate binding proteins during the phenotypic change of mouse macrophages transformed by a temperature-sensitive mutant (tsA640) of SV40

By using a photoaffinity ligand, cell extracts from transformed macrophages that were established by infection with temperature-sensitive mutants (tsA640) of simian virus 40 (SV40) were examined for cyclic adenosine 3':5'-monophosphate (cAMP)-binding proteins. At the nonpermissive temperature for SV40 large T antigen, 39.0 degrees C, no significant cAMP-binding proteins could be detected, such as primary mouse macrophages. At the permissive temperature of 33.0 degrees C, cAMP-binding proteins appeared later than SV40 T antigen expression and cellular DNA synthesis. The profile of cAMP-binding proteins was similar to that of resting, but not proliferating, mouse clonal fibroblasts (BALB/c 3T3). These and previous results suggest that SV40 T antigen influences the expression of cAMP-binding proteins in tsA640-transformed macrophages; the large/small T antigen converts the profile of cAMP-binding proteins from macrophage to fibroblastic cells.     

Induction of fibronectin expression, actin cable formation, and entry into S phase following reexpression of T antigen in mouse macrophages transformed by the tsA640 mutant of SV40

Mouse macrophages transformed by a temperature-sensitive mutant (tsA640) of simian virus 40 (SV40) were examined by immunofluorescence microscopy for fibronectin expression and actin distribution. Resting cultures of tsA640 transformants incubated at a temperature nonpermissive for SV40 large T antigen (39.0 degrees C) exhibited phagocytic activity and did not exhibit cellular fibronectin and actin cables, like primary cultures of resident macrophages. When the resting cultures were sparsely seeded and shifted down to the permissive temperature of 33.0 degrees C, expression of large T antigen in the nucleus, expression of fibronectin in the cytoplasm, and cellular entry into S phase occurred in that temporal order, followed by actin cable formation, cellular proliferation, and diminishment of phagocytic activity. The expression of T antigen and fibronectin was sensitive to actinomycin D and cycloheximide. The expression of fibronectin was insensitive to inhibitors of DNA synthesis, whereas the expression of actin cables was sensitive. These results suggest that SV40 T antigen leads macrophages to express fibronectin and actin cables, as well as resumption of cell proliferation, and that entry into S phase is not required for fibronectin expression but may be required for actin cable formation.     

Accumulation of cells with 4N DNA content at nonpermissive temperature in rat embryo diploid cells transformed by tsA mutant of simian virus 40

Primary rat embryo cells were transformed by a tsA mutant (tsA640) of simian virus 40 (SV40). Proliferation of all four independent diploid transformants was suppressed at a nonpermissive temperature (40.3 degrees C), being accompanied by a marked increase in the fraction of cells with a 4N DNA content (a 4N peak in the flow cytofluorogram). However, in this case, the fraction of cells with a 2N DNA content (a 2N peak in the flow cytofluorogram) was preserved. Both effects (suppression of proliferation and increase in the 4N peak) diminished when transformed cells were superinfected with wild-type SV40. The increased 4N peak was preserved, albeit not completely, for at least 24 hours, when cells were further incubated in the presence of hydroxyurea at the nonpermissive temperature. On the other hand, the preserved 2N peak all but disappeared within 24 hours, when cells were further incubated in the presence of colcemid at the nonpermissive temperature. These results suggest that the thermolabile large T antigen of SV40 directly or indirectly induces an accumulation of cells with a 4N DNA content, at the nonpermissive temperature, by prolonging the G2 (and/or late S) period.     

Transformation of BALB/c-3T3 cells by tsA mutants of simian virus 40: effect of transformation technique on the transformed phenotype.

Simian virus 40 tsA-transformed BALB/c-3T3 cells isolated as foci of overgrowth in liquid medium were compared with those isolated as colonies in soft agar. Efficiencies of transformation were equivalent in the two procedures. Cells isolated as foci were able to grow in agar and vice versa. No difference in temperature sensitivity of the transformed phenotype was detected when tsA transformants selected in agar were compared with those selected as foci. The use of the two different transformation procedures, then, did not form the basis for generation of different transformed phenotypes, and transformants generated in both ways were dependent upon expression of the A gene for maintenance of the transformed state.     

Temperature dependency for maintenance of transformation in mouse cells transformed by simian virus 40 tsA mutants.

Mouse embryo fibroblasts and 3T3 cells were transformed by wild-type, tsB4, tsA7, tsA58, and tsA209 simian virus 40. Clones of transformants were generated both in soft agar and in liquid medium by focus formation and at both high and relatively low multiplicities of infection. All transformants were assayed for three phenotypes of transformation: (i) the ability to form highly multinucleated cells in cytochalasin B-supplemented medium, i.e., uncontrolled nuclear division; (ii) the capacity to continue DNA synthesis at increasing cell density; and (iii) the ability to form colonies in soft agar. The great majority of mouse embryo fibroblast transformants generated with tsA mutant virus were temperature sensitive for transformation in all three assays, regardless of the input multiplicity or whether they were generated in liquid medium or soft agar. These transformants exhibited a normal or near-normal phenotype at the nonpermissive temperature of 40 degrees C. All but one of the transformants which appeared transformed at both temperatures were in the A209 group. In contrast to mouse embryo fibroblasts, transformants generated with 3T3 cells and tsA virus were often not temperature sensitive, exhibiting the transformation phenotypes at both temperatures. This phenomenon was more often observed when 3T3 transformants were generated in soft agar. These results, along with other published data, suggest that uncontrolled nuclear division and uncontrolled DNA synthesis are a function of the simian virus 40 A gene. Finally, with the 3T3 transformants, there was often discordance in the expression of transformation among the three phenotypes. Some tsA transformants were temperature sensitive in one of two assays but were transformed at both 33 and 40 degrees C in the remaining assay(s). Other transformants exhibited a normal cytochalasin B response at either temperature but were temperature sensitive in the other assays.