Temperature-Sensitive Simian Virus 40-Transformed Cells: Phenomena Accompanying Transition from the Transformed to the “Normal” State

Temperature-sensitive simian virus (SV 40)-transformed 3T3 cells (tsSV3T3), which express the transformed phenotype when growing at 32 C but not at 39 C, were used to study changes in growth behavior during shift-up or shift-down experiments. In cultures of tsSV3T3 cells which had reached or were beyond monolayer density at 32 C, DNA synthesis reached very low levels within 24 to 48 h after shift-up. When cells which had been allowed to grow to high densities at 32 C were shifted to 39 C, not only cell growth stopped, but within two to three days the cultures shed a large number of cells into the medium. These cells were nonviable, and shedding stopped only when the number of cells attached had been reduced to that characteristic of the saturation density at 39 C. The remaining attached cells were viable and after the shift to 32 C were again able to grow from the monolayer to high cell densities. This behavior has been compared with that of normal 3T3 and wild-type SV3T3 cells under different conditions. We have also isolated new tsSV3T3 lines, using cells which had been infected with non-mutagenized wild-type SV40. This further demonstrates that the temperature sensitivity of these lines is due to a cellular rather than a viral mutation.     

In vitro tumoricidal activity of macrophages against virus-transformed lines with temperature-dependent transformed phenotypic characteristics.

The susceptibility of targets to destruction by tumoricidal rat and mouse macrophages was studied with virus-transformed cell lines in which various elements of the transformed phenotype are only expressed at specific temperatures. BHK cells transformed by the ts3 mutant of polyoma virus, rat embryo 3Y1 cells transformed by a temperature-sensitive A cistron mutant of simian virus 40 (SV40) and the ts-H6-15 temperature-sensitive line of SV40-transformed mouse 3T3 cells were killed in vitro by macrophages at both the permissive (33 °C) or nonpermissive (39 °C) temperatures for expression of the transformed phenotype. 3T3, 3Y1 and BHK cells transformed by wild-type SV40 or polyoma virus were also destroyed by tumoricidal macrophages at both 33 and 39 °C, but untransformed 3T3, 3Y1, and BHK cells were not. Thus, transformed cells are killed by macrophages regardless of whether or not they express cell surface LETS protein or Forssman antigen, display surface changes which permit agglutination by low doses of plant lectins, express SV40 T antigen, have a low saturation density, or exhibit density-dependent inhibition of DNA synthesis.     

Simian Virus 40-Host Cell Interactions. I. Temperature-Sensitive Regulation of SV40 T Antigen in 3T3 Mouse Cells Transformed by the ts*101 Temperature-Sensitive Early Mutant of SV40

BALB/3T3 and Swiss/3T3 mouse cells transformed at permissive temperature (33 C) by the early temperature-sensitive mutant of simian virus 40 (SV40), ts(*)101, exhibited a temperature-dependent modulation of SV40 tumor (T) antigen as assayed by immunofluorescence. The percentage of T antigen-positive nuclei in ts(*)101 transformed cells was reduced at restrictive temperature (39 C) when compared to 33 C and to wild-type SV40 transformed cells at either 33 C or 39 C. The percentage of T antigen-positive nuclei in ts(*)101 transformed cells returned to the 33 C control level when the cells were shifted from 39 to 33 C. The ts(*)101 transformed cells could be superinfected with wild-type, but not ts(*)101, virions at 39 C as assayed by an increase in T antigen-positive nuclei.     

Conditionally lethal mutations in Chinese hamster cells. I. Isolation of a temperature-sensitive line and its investigation by cell cycle studies

The isolation of a temperature sensitive cell line from the Chinese hamster line CCL39 of the American Type Culture Collection is described. At the nonpermissive temperature (39°C) the cells become attached to the surface of tissue culture dishes, but no microscopically observable colonies are formed upon prolonged incubation. Exposure to the high temperature for more than 24 hours leads to an almost complete loss in viability. A karyotypic analysis showed that this new line has lost one of the medium-sized metacentric chromosomes, although no proof is available so far to show that this loss is not simply coincidental. In nonsynchronized cultures transferred to 39°C DNA synthesis stops first, RNA synthesis shortly thereafter, while protein synthesis (turnover) continues for a longer time. After such a shift the cell number increases by less than 15% as measured with the Coulter counter. Studies with synchronized cultures give the following results: (1) one round of DNA synthesis can occur at 39°C when the cells are released from serum starvation or a hydroxyurea block, or when mitotic cells are placed at 39°C; (2) the entry of cells into metaphase of mitosis at 39°C is almost normal when the preceding time interval at 39°C is only eight hours (release of cells from G₁/S boundary), but considerably reduced when the cells spend an additional 12 to 15 hours at 39°C in G₁ (release from serum starvation). Infection by SV40 virus temporarily induces DNA synthesis after it has come to a stop at the nonpermissive temperature, but cells permanently transformed by SV40 still exhibit the temperature-sensitive phenotype.     

Potassium transport in normal and transformed mouse 3T3 cells

The components of unidirectional K influx and efflux have been investigated in the 3T3 cell and the SV40 transformed 3T3 cell in exponential and stationary growth phase. Over the cell densities used for transport experiments the 3T3 cell goes from exponential growth to density dependent inhibition of growth (4 × 10⁴ to 4 × 10⁵ cell cm^?2) whereas the SV40 3T3 maintains exponential or near exponential growth (4 × 10⁴ to 1 × 10⁶ cell cm^?2). In agreement with previous observations, volume per cell and mg protein per cell decrease with increasing cell density. Thus, transport measurements have been expressed on a per volume basis. Total unidirectional K influx and efflux in the 3T3 cell is approximately double that of the SV40 3T3 cell at all cell densities investigated. Both cell types have similar volumes initially and show similar decreases with increasing cell density. Thus, in this clone of the 3T3 cell SV40 transformation specifically decreases unidirectional K flux. The magnitude of the total K flux does not change substantially for either cell line during transition from sparse to dense cultures. However, the components of the K transport undergo distinct changes. Both cell lines possess a ouabain sensitive component of K influx, presumably representing the active inward K pump. Both also possess components of K influx and efflux sensitive to furosemide. The data suggest this component represents a one-for-one K exchange mechanism. The fraction of K influx mediated by the ouabain sensitive component is reduced to one half its value when exponential versus density inhibited 3T3 cells are compared (63% versus 31% of total influx). No comparable drop occurs in the SV40 3T3 cell at equivalent cell densities (64% versus 56% of total influx). Thus, the pump mediated component of K influx would appear to be correlated with growth. In contrast, the furosemide sensitive component represents approximately 20% of the total unidirectional K influx and efflux in both cell lines in sparse culture. At high cell densities, where growth inhibition occurs in the 3T3 cell but not the SV40 3T3, the furosemide sensitive component doubles in both cell lines. Thus, the apparent K-K exchange mechanism is density dependent rather than growth dependent.     

Variation in the appearance of SV40 tumor antigen in transformed cells

Five types of variation in the appearance of SV40 T antigen have been observed by immunofluorescence in wild-type and tsD^*101 transformed BALB and Swiss/3T3 cells: (1) clones having more than 95% uniformly stained nuclei; (2) clones having variable stained nuclei; (3) clones having T-negative nuclei at the periphery at 39 °C, but not at 33 °C; (4) D101 cells having T-negative nuclei at 39 °C, but not at 33 °C, during growth and after saturation; and (5) wild type cells having T-negative nuclei after confluence at both 33 and 39 °C. This fifth type of variation may involve an immuno-specificity change in the T antigen molecule. Any models proposed for the regulation of SV40 T antigen in transformed cells will have to explain these variations.     

Direct Isolation and Characterization of “Flat” SV40-transformed Cells

UNDER standard culture conditions cells of the permanent mouse embryo line BALB/c-3T3 cease to divide when cell to cell contact is made and thus are characterized as sensitive to density dependent inhibition of growth. A loss of this aspect of growth control is commonly used as a selective means for recovering SV40-transformants because such transformed cells continue to divide in conditions in which nontransformed cells remain confined to the monolayer¹. SV40-transformants selected by their ability to overgrow the monolayer commonly attain population densities ten to fifteen times greater than nontransformed cells, although viral transformants of low saturation density termed “flat revertants” may be obtained from transformed clonal lines by negative selection with 5-fluoro-2-deoxyuridine², or by passage on cell layers fixed with glutar aldehyde³.     

Cells transformed by a wide variety of agents express higher abundance levels of some cellular RNA species

A cDNA-cloned library was prepared from mRNA synthesized by SV40-transformed mouse cells. Eleven cDNA clones were selected based on their ability to hybridize higher levels of mRNA in SV40-transformed 3T3 cells than in 3T3 cells. These cDNA clones were employed to screen the steady-state levels of cytoplasmic RNAs in a wide variety of viral (SV40, polyoma, adenovirus, and Rous sarcoma virus) and nonviral (methylcholanthrene, embryonal carcinoma) transformed cell lines. Two of the cDNA clones—A17 and 104—detected greater than 40–100-fold higher levels of mRNA in all the transformed cell lines tested when compared to nontransformed cells (3T3, C3HEF). The levels of mRNA complementary to these two cDNAs were regulated in a temperature-sensitive fashion (87–100-fold) in both SV40tsA- and RSV ts-src-transformed murine cell lines. These two cDNA clones detected greater than 100-fold, higher levels of complementary RNA derived from SV40 tumor tissue than in normal mouse liver. RNA species complementary to cDNA clones A17 or 104 were not detected in either actively growing nontransformed cells or in serum-stimulated 3T3 cells. The abundance levels of mRNAs detected by these two cDNA clones appear to be regulated 100-fold or greater by the transformed state, independent of the transforming agent. The higher levels of these RNA species detected in transformed mouse cells appear not to be solely regulated by the state of growth of nontransformed cells.     

Regulatory mutants of simian virus 40: constructed mutants with base substitutions at the origin of DNA replication.

Mutants of simian virus 40 (SV40) with base substitutions at or near the origin of replication of the viral genome have been constructed by bisulfite mutagenesis at the BglI restriction site of SV40 DNA, followed by transfection of cells with the BglI-resistant (BglI^r) DNA so generated. Based on plaque morphology at different temperatures, the resulting BglI^r mutants could be classified into four-groups. Class I mutants (designated ar for “altered restriction”) were indistinguishable from wild-type SV40; class II mutants (designated shp for “sharp plaque”) produced small, sharp-edged plaques; class III mutants (designated sp for “small plaque”) produced small plaques at 32 °C, 37 °C and 40 °C; and class IV mutants (designated cs for “cold sensitive”) produced small plaques at 32 °C and wild-type plaques at 37 °C and 40 °C. That the altered plaque morphology of sp and cs mutants was related to mutation at the BglI restriction site was demonstrated by co-reversion to wild-type of the plaque phenotype and BglI sensitivity. The nucleotide sequence around the original BglI site was determined in the DNA from one mutant of each class. In each case a different base-pair substitution was found, at a site outside sequences coding for SV40 proteins. When rates of replication of mutant DNAs were measured during productive infection, ar mutant DNA was synthesized at a rate comparable to that of wild-type SV40 DNA, shp mutant DNA was made at a rate exceeding that of wild-type, sp mutant DNA was synthesized at a lower rate than that of wild type. and cs mutant DNA synthesis was reduced at 32 °C, but about the same as the wild-type rate at 40 °C. These patterns of mutant DNA synthesis were unaltered in cells co-infected with mutant and wild-type virus, i.e. the defects in DNA synthesis were not trans-complementable. We conclude that the defective mutants have single base-pair changes in a cis element that determines the rate of viral DNA replication, presumably within the origin signal itself.     

Transfer of SV40 temperature-sensitive early gene into human epidermal keratinocytes by the recombinant adenovirus vector

Summary We constructed a recombinant adenovirus vector that contained the origin-defective SV40 early gene, coding temperature-sensitive T antigen. This vector transferred the SV40 early gene into human epidermal keratinocytes with high efficiency. T antigen conferred the ability of keratinocytes to grow with limited differentiation in the presence of serum and high calcium concentration at the permissive temperature (34°C), although normal keratinocytes were induced to differentiate and stop growing under the same conditions. The serum/Ca⁺⁺-resistant cells did not proliferate at the nonpermissive temperature (40°C), indicating that they depended on T antigen for their proliferation. The temperaturesensitive T antigen dissociated from the tumor suppressor gene products, p53, at 40°C. The serum/Ca⁺⁺-resistant cells still had the ability to proceed to terminal differentiation when injected into SCID mice as cultured keratinocytes. However, they did not form an apparent basal layer. This indicated that the tissue remodeling process in the serum/Ca⁺⁺-resistant keratinocytes was abnormal. All of these epidermoid cysts disappeared within 8 wk and no tumor developed for 6 mo. We consider that ΔE1/SVtsT is a useful tool to examine multistep carcinogenesis of human epithelial cells in vitro.     

Isolation and characterization of a heat-inducible simian virus 40 mutant.

We have isolated a new type of temperature-sensitive mutant of simian virus 40 (SV40) that is capable of productive infection in permissive cells but not of maintenance of viral DNA integration in transformed cells at the conditional temperature. Virus development is induced when cells transformed by this mutant are shifted to temperatures above 39 degrees C, but is not induced below this temperature. The plaque-purified, temperature-sensitive mutant virus confers heat inducibility to new host cells, indicating that the conditional function is a property of the viral genome. Unlike previously described temperature-sensitive SV40 mutants, in (ts)-1501 is capable of productive infection in permissive cells at the conditional temperature. The morphology, growth, and oncogenicity of in (ts)-1501-transformed cells at 37 degrees C are similar to those of cell lines transformed by wild-type SV40. HK10-c2(in(ts)-1501), a cloned cell line, transformed at 37 degrees C by the mutant virus, exhibits a transient increase in DNA synthesis before cell death at the conditional temperature. Many properties of in(ts)-1501 are analogous to those of the heat-inducible mutants of bacteriophages in which a heat-inactivated protein is responsible for the stable integration of the prophage in the bacterial chromosome.     

Biosynthesis of plasma membrane components by SV40-virus-transformed 3T3 mouse cells temperature sensitive for expression of some transformed cell properties

We have studied the plasma membranes of an SV40-transformed 3T3 cell line temperature sensitive for the transformed growth phenotype (ts H6-15 cells), and have found that they vary little as a function of temperature of cultivation. Analysis by polyacrylamide gel electrophoresis was performed on plasma membranes prepared from ts H6-15 cell cultured at the permissive (32 °C) and non-permissive (39 °C) temperatures and radioactively-labelled in several ways. No significant differences were seen when the electrophoretic patterns of polypeptides of the plasma membranes of ts H6-15 cells, grown through 3–4 generations in medium containing radioactive leucine (32 °C and 39 °C temperatures) were compared. Plasma membranes derived from cells similarly grown in medium with radioactive glucosamine indicated that extensive alterations in the intrinsic glycopeptides occurred in association with alteration in growth phenotype. A shift towards decreased synthesis of large molecular weight (? 100 000–160 000) glycopeptides occurred in cells grown at the temperature of non-transformed growtn (39 °C). A decrease in amount of a 1200 000 molecular weight glycopeptide at 39 °C was the most prominent of these alterations.We have studied the surface exposure of polypeptides and glycopeptides of intact cells grown at 32 and 39 °C, using lactoperoxidase-catalyzed iodination, NaBH₄ reduction of galactose oxidase-treated cells, and metabolic-labelling with glucosamine of trypsin-sensitive molecules. We found no major qualitative differences between whole cell extracts or between plasma membrane preparations of cells cultivated at the permissive and non-permissive temperatures. Of special interest was the observation that the formation and surface exposure of a trypsin-sensitive, 240 000 molecular weight polypeptide appeared not to be ts in ts H6-15 cells. The significance of these observations will be discussed.     

A selective temperature-sensitive defect in viral RNA expression in cells infected with a ts transformation mutant of murine sarcoma virus

We investigated the nature of the defect in the temperature-sensitive mutant of Moloney murine sarcoma virus (Mo-MuSV), termed ts110. This mutant has a temperature-sensitive defect in a function required for maintenance of the transformed state. A nonproducer cell clone, 6m2, infected with ts110 expresses P85 and P58 at 33°C, the transformed temperature, but only P58 is detected at the restrictive temperature of 39°C. Shift-up (33°C → 39°C) and in vitro experiments have established that P85 is not thermolabile for immunoprecipitation. Previous temperature-shift experiments (39°C → 33°C) have shown that P85 synthesis resumes after a 2–3 hr lag period. Temperature shifts (39°C → 33°C) performed in the presence of actinomycin D prevented the synthesis of P85, whereas P58 synthesis did not decline for 5 hr, suggesting that P58 and P85 are translated from different mRNAs. The shift-up experiments also indicated that, once made, the RNA coding for P85 can function at the restrictive temperature for several hours. MuSV-ts110-infected cells superinfected with Mo-MuLV produced a ts110 MuSV-MuLV mixture. Sucrose gradient analysis of virus subunit RNAs revealed a ～28S and a ～35S peak. Electrophoresis of the ～28S poly(A)-containing RNA from ts110 virus in methyl mercuric hydroxide gels resolved two RNAs with estimated sizes of 1.9 × 10⁶ and 1.6 × 10⁶ daltons, both smaller than the wild type MuSV-349 genomic RNA (2.2 × 10⁶ daltons). RNA in the ～28S size class from virus preparations harvested at 33°C was found to translate from P85 and P58, whereas, the ～35S RNA yielded helper virus Pr63^gag. In contrast, virus harvested at 39°C was deficient in P85 coding RNA only. Peptide mapping experiments indicate that P85 contains P23 sequences, a candidate Moloney mouse sarcoma virus src gene product. Taken together, these results suggest that two virus-specific RNAs are present in ts 110-infected 6m2 cells and rescued ts110 pseudotype virions at 33°C, one coding for P85, whose expression can be interfered with by shifting the culture to 39°C; the other coding for P58, whose expression is unaffected by temperature shifts. P85 is a candidate gag-src fusion protein, while P58 contains gag sequences only.     

Expression of the SV40-transformed phenotype in hybrids between conditional and wild-type transformants

The nature of two different SV40-transformed cell lines which are temperature sensitive (ts) for the expression of the transformed phenotype has been analysed by somatic cell hybridization. Ts 23A cells are temperature sensitive in their ability to grow in medium containing low serum; in hybrids between these cells and a standard SV40-transformed BALB/c 3T3 cell line, the mutation seems to be dominant, at least for some parameters. One hundred percent of the hybrid clones have a very low efficiency of plating in medium containing 1% serum, but only 50% of them show growth inhibition in mass culture under the same conditions. Ts H615 cells revert to a normal phenotype at 39 °C for most parameters of transformation. The mutation appears to be recessive, as the hybrids generally behave like transformed cells at 39 °C. However, the expression of this mutation is not completely suppressed, since DNA synthesis after confluence shows some degree of inhibition in the hybrids at 39 °C. A considerable variation in the behavior of individual hybrid clones and in the degree of inhibition of some parameters has been observed and is discussed in terms of possible mechanism(s) of transformation.     

Defect in translation of poliovirus RNA at the restrictive temperature.

Translation of the RNA of LSc type 1 poliovirus was examined in vivo at the restrictive temperature (39 °C). During the first two hours of infection at 39 °C the levels of viral polyribosomes were 50% lower than at 35 °C (permissive temperature). During the third hour of infection at 39 °C, only 4 to 10% of the control levels of polyribosomes were observed. Three experiments indicate that the elongation of viral peptides was not occurring properly at 39 °C. First, cultures incubated at 39 °C during the third hour of infection with both [³⁵S]methionine and [³H]uridine exhibit a fourfold increase in the ratio of viral protein/viral RNA in the polyribosome region of sucrose gradients in comparison to controls kept at 35 °C. However, at both temperatures the relative size distribution of polyribosomes was similar. Second, the ratios of released protein/nascent protein after 90-second and 5-minute pulses with [³⁵S]methionine indicate that elongation of peptide chains was inhibited at 39 °C. Third, when initiation of synthesis of viral protein was blocked with 150 mM-NaCl, the polyribosomes disaggregated four to five times more rapidly at 35 °C than at 39 °C. The data indicate that translation of viral RNA is inhibited at the restrictive temperature because of a reduced rate of elongation of viral proteins. The reduced rate of peptide chain elongation at 39 °C was fully reversible when cultures were shifted to 35 °C in the presence of 150 mm-NaCl. The latter finding indicates a conformational change in viral protein at 39 °C.     

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.