Simian virus 40 A gene function: DNA content analysis of Chinese hamster cells transformed by an early temperature-sensitive virus mutant

Analysis of simian virus 40 infection of CV-1 cells by quantitative two-color fluorescence with flow cytometry

Quantitative two-color fluorescent analysis of Simian virus (SV40) infection of permissive CV-1 cells was investigated. Analysis included by quantitation of cellular DNA, the early viral tumor (T) antigen with a monoclonal antibody, and late viral (V) antigens with a polyclonal antibody. T antigen was detected in all phases of the cell cycle at 6 and 12 h, after SV40 infection of growth arrested cells. At later time intervals, the percentage of T-antigen-positive cells increased with the induction of the cells into successive rounds of DNA synthesis and an increase in tetraploid-polyploid cells. The amount of T antigen per cell increased as the cells entered the successive stages of the cell cycle (G0/G1----G2 + M----tetraploid S and G2 + M). The V antigen from adsorbed virus was detected immediately after infection. Synthesis of V antigen began in late S and G2 + M phases of the cell cycle. This quantitative analysis allows a definitive determination of antigen per cell in a population correlated with the cell cycle and may be useful in correlating viral and cellular events with transformation.

Analysis of intracellular antigens by flow cytometry

Quantitative immunofluorescence is routinely used in flow cytometric assay of cell surface antigens. Intracellular antigens have not been as tractable. Recent publications (Proc Natl Acad Sci 80:5573-5577, 1983; Cytometry 6:208-214, 1985) and the results presented here demonstrate that highly specific staining and subsequent quantitative analysis are not only possible but rather easily achieved. High purity antibodies and optimized fixing and staining technique are required. Under conditions presented in this paper, 97% of fluorescein specific signal is specific to the T antigen of SV40 when monoclonal antibody to this antigen is used with a transformed cell line. Three levels of quantitative analysis are discussed: estimation of the fraction of positive cells in a mixed +/- population, estimation of the average content of antigen in a population of cells, and measurement of the distribution of antigen content within a population of cells. Results are presented that demonstrate that relatively low specific signal (measured as percentage of total signal) can be tolerated to achieve the first level and that the current methods available that produce a high specific signal are sufficient to achieve the second level. The third level will require further research aimed at lowering the variation introduced by the method of measurement.

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.

Hormonal regulation of the transformation phenotype in simian virus 40-transformed rat embryonic preadipose cell lines

The regulation of transformed phenotypes was studied in newly isolated preadipose cell lines which were established after infection with simian virus 40 tsA58 dl2009. The clonal cell lines isolated exhibited most of the characteristics typical of transformed cells. The transformants, however, were able to differentiate into adipocytes in the presence of low calf serum (0.5%) and a combination of several hormones, including hydrocortisone and insulin. Treatment with insulin alone stimulated the growth of these cells but did not induce lipid accumulation without added hydrocortisone. The effect of hydrocortisone was accompanied by a restoration of growth control in the transformants after they reached high cell density. The blot hybridization analysis of cellular DNAs digested by restriction enzymes revealed that simian virus 40 genomes were integrated at multiple separate sites at which a head-to-tail oligomeric insertion took place. Large T antigen was synthesized in growing cells but was regulated at high cell density when cells were committed to differentiate by glucocorticoids. These results suggest that the glucocorticoid hydrocortisone is capable of restoring growth regulation at high cell densities to simian virus 40-transformed preadipose cell lines.

Hormonal regulation of the transformation phenotype in simian virus 40-transformed rat embryonic preadipose cell lines

The regulation of transformed phenotypes was studied in newly isolated preadipose cell lines which were established after infection with simian virus 40 tsA58 dl2009. The clonal cell lines isolated exhibited most of the characteristics typical of transformed cells. The transformants, however, were able to differentiate into adipocytes in the presence of low calf serum (0.5%) and a combination of several hormones, including hydrocortisone and insulin. Treatment with insulin alone stimulated the growth of these cells but did not induce lipid accumulation without added hydrocortisone. The effect of hydrocortisone was accompanied by a restoration of growth control in the transformants after they reached high cell density. The blot hybridization analysis of cellular DNAs digested by restriction enzymes revealed that simian virus 40 genomes were integrated at multiple separate sites at which a head-to-tail oligomeric insertion took place. Large T antigen was synthesized in growing cells but was regulated at high cell density when cells were committed to differentiate by glucocorticoids. These results suggest that the glucocorticoid hydrocortisone is capable of restoring growth regulation at high cell densities to simian virus 40-transformed preadipose cell lines.

Cell growth and differentiation in vitro in mouse macrophages transformed by a tsA mutant of simian virus 40. I. Cellular response in proliferative and phagocytic activities to the shift of temperature differs depending on the culture state in mouse bone marrow cells transformed by the tsA640 mutant of simian virus 40

It was shown previously that mouse bone marrow cells transformed by simian virus 40 (SV40) show a reversible cell density-dependent phenotypic transition between the nonmacrophage (rapidly growing) and the macrophage (stationary) states; cells in low-density cultures are in the growing phase, express SV40 T antigen strongly as revealed by immunofluorescence, and lose typical macrophage properties such as immune phagocytosis; whereas cells in high-density cultures are in the stationary (nongrowing) phase, express SV40 T antigen weakly, and recover their macrophage properties (Takayama, 1980). In the hope of clarifying the relationship between T antigen, cell growth, and macrophage-specific cellular function, we examined the behavior at 33 and 39 degrees C of mouse bone marrow cells transformed by an SV40 gene A mutant (tsA640) whose mutation renders the molecular weight of 90K (large) T antigen temperature sensitive. The results presented in this paper suggest that functional large T antigen is required for cells in the stationary phase to initiate multiplication when transferred at lower density and is not necessary for a majority of them to maintain the nongrowing state (viability) at both high and lower cell densities, whereas it is required for cells in the growing phase to keep multiplying without losing their viability. The results also suggest that the functional large T antigen does not play a direct role in maintaining the cells as either phagocytic or nonphagocytic. It is also suggested that the physiological or tsA mutation-mediated arrest of growth may or may not be accompanied by induction and/or maintenance of cellular phagocytic activity depending on the culture state.

Tumorigenicity of tsA and wild-type simian virus 40 transformed cells inoculated onto the chicken chorioallantoic membrane

This study compares the tumorigenicity of SV40 primary tumor cell lines, tsA and wild-type SV40-transformed Chinese hamster cells, at two temperatures, 37 degrees C and 40.5 degrees C, inoculated onto the chorioallantoic membrane of the chicken egg. The SV40 primary tumor cell lines varied in their efficiency of takes at 37 degrees C from 78% for the H65-90B tumor line, 73% for the H80-7A and 25% for the H80-4 line. At 40.5 degrees C the H80-4 was unable to form tumors; however, the H80-7A and H80-4 produced 70% and 20% tumors respectively. Histologically, all CAM tumors were fibrosarcomas identical to the transplanted tumors, however, the tumor(s) at 40.5 degrees C were smaller. Chinese hamster wild-type SV40-transformed cells were equally efficient (32%) at tumor production at both temperatures. The tsA-SV40-transformed Chinese hamster cells (A58 and A58-2) induced 34% tumors at 37 degrees C and 9% tumors at 40.5 degrees C. At 37 degrees C these tumors were typical fibrosarcomas; however, the 40.5 degrees C tumors were smaller and less cellular, resembling a more differentiated fibrosarcoma. Therefore, the tsA Chinese hamster transformed cells were less efficient at tumor induction at the non-permissive temperature; however, the primary tumor lines also demonstrated a variability in tumorigenicity (H65-90B and H80-4). Possibly factors other than the temperature-sensitive viral protein (big "T" antigen) may be involved in establishing a tumor on the chicken CAM.

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.

Simian virus 40 A gene function: further characterization and growth of tsA transformed chinese hamster cells

Chinese hamster embryo cells transformed with the tsA 58 mutant of Simian virus 40 express the transformed phenotype at the permissive temperature (33 degrees C or 37 degrees C) and a "normal" phenotype at the nonpermissive temperature (40.5 degrees C). Immunofluorescence and immunoprecipitation of T antigens demonstrated that the "T" antigen (100 K) has an increase rate of synthesis and degradation at 40.5 degrees C. However, the cells continue to replicate at the nonpermissive temperature when assayed by flow cytometry and autoradiography. This DNA synthesis was cellular, not viral, and not owing to an increase in DNA repair. When the cell cycle distributions of G1, S, and G2 + M were assayed by the fraction labeled mitoses method, no differences were evident at the permissive and nonpermissive temperature; however, the doubling time was lengthened at 40.5 degrees C (13 hours vs. 100 hours). These results suggest that at 40.5 degrees C, the tsA transformed cells are cycling and dying. However, if the transformed cells are seeded onto monolayers of normal Chinese hamster cells at 40.5 degrees C, the cells are growth arrested when measured by growth assays, flow cytometry, autoradiography, and immunofluorescence for T antigen. Therefore, growth arrest can be obtained in tsA 58 transformed Chinese hamster cells when cocultured with normal Chinese hamster cells.

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.

Replication of Chinese hamster embryo cells transformed by temperature-sensitive T-antigen mutants of simian virus 40

Chinese hamster embryo cells transformed by simian virus 40 temperature-sensitive T-antigen mutants replicated when confluent at 40.5 degrees C, regardless of the selection method, selection temperature, or virus strain used.

Density dependent inhibition of both growth and T-antigen expression in revertants isolated from simian virus 40-transformed mouse SVT2 cells

Phenotypic revertants were isolated from simian virus 40-transformed cells in order to examine the relationship between simian virus 40 T-antigen expression and G1 arrest of growth. Revertant clones with increased adherence were selected from cultures of SVT2, a simian virus 40-transformed BALB/c mouse cell line, and screened to find arrestable revertant clones which inhibited DNA synthesis when crowded. The clones selected from untreated SVT2 were unstable and showed little or no inhibition of DNA synthesis when crowded. Stable revertants were found after treatment of SVT2 with Colcemid to increase ploidy. The stable revertants all lost most transformed growth properties tested, including tumorigenicity, but only a few showed the same degree of inhibition of DNA synthesis at high cell density as BALB/3T3. All revertant clones expressed T antigen at low cell density. Three revertants showed coordinate inhibition of DNA synthesis and apparent loss of T antigen at high cell density. We suggest that changes in gene dosage rather than mutations caused the altered properties of the new revertants and that continued DNA synthesis in confluent cultures may be the transformed phenotype that requires the least simian virus 40 T antigen.