Expression and thermal stability of simian virus 40 tumor-specific transplantation antigen and tumor antigen in wild type- and tsA mutant-transformed cells

Immortalized phenotype and the presence of active oncogenes correlate with the capacity of culture cells to induce reactivation of DNA synthesis in macrophage nuclei in heterokaryons

Several types of culture cells with limited life span (rat embryo fibroblasts, rat chondrocytes and mouse premacrophages) were found to be unable to induce the reactivation of DNA synthesis in the nuclei of non-dividing differentiated cells (mouse peritoneal resident macrophages) in heterokaryons. By contrast, malignant HeLa cells have this ability. In heterokaryons formed by fusion of mouse macrophages with HE239 cells (Syrian hamster fibroblasts transformed with a ts mutant of the SV40 virus), DNA synthesis in macrophage nuclei is reactivated only at the permissive temperature (33 degrees C), at which viral T antigen is stable. Immortalization of rat chondrocytes by transfection with p53 gene enables to induce DNA synthesis in macrophage nuclei upon fusion. All the evidence indicates that the function of immortalizing oncogenes is necessary for the resumption of the DNA synthesis in macrophage nuclei in heterokaryons.

In vivo induction of tumor-specific immunity by glycolipid extracts of SV40-transformed cells

Glycolipid extracts were prepared from various Syrian golden hamster cell lines, either SV40-transformed or spontaneously transformed. To detect possible SV40-TSTA activity of the glycolipid preparations, normal hamsters were inoculated with different glycolipid extracts and were subsequently challenged with an SV40 tumor-cell line. Significant immunoprotection against SV40 tumor challenge was induced with glycolipids obtained from SV40-transformed cell lines. This was expressed as complete tumor rejection or as a decrease in tumor growth rate, when compared to controls. No protective effects were induced with glycolipid extracts from spontaneously transformed cells. Results suggest that tumor-specific glycolipids synthesized in cells transformed by SV40 virus could act as tumor transplantation antigens responsible for specific tumor rejection in syngeneic hosts.

Surface proteins of simian-virus-40-transformed cells

Mammalian cells transformed in tissue culture by SV40 were shown to contain, in addition to the SV40-coded 94,000 d large T antigen and the 20,000 d small t antigen, a approximately 56,000 d cellular protein, which specifically precipitates with sera of animals bearing SV40-induced tumor(s) (tumor or T serum). We investigated the presence of these three proteins at the surface of logarithmically growing SV40-transformed cloned mouse cells, after metabolic labelling with [35S]-methionine for 3 h. The 56,000 d protein was found to be susceptible to digestion by trypsin under conditions which did not disrupt the cells, while no small t antigen was found to be digested. Both the 56,000 d cellular protein and the SV40 large T antigen were susceptible to lactoperoxidase-catalyzed iodination from the outside of intact cells. Trypsin treatment removed both the iodinated 56,000 d protein and the iodinated SV40 large T antigen. These experiments indicated that (a certain amount of) the 56,000 d protein and a relatively small amount of the large T antigen (which is present mainly in the nucleus) are present on the cell surface. The results confirm and extend independent experiments using subcellular fractionation techniques (Luborsky and Chandrasekaran, 1980; Soule and Butel, 1979). After heat treatment (at 50 degrees C for 30 min) of the whole-cell extract the 56,000 d cellular protein was precipitated by the tumor serum in the absence of precipitation of SV40 large T antigen. This result showed that the 56,000 d protein is more (thermo)stable (in the whole-cell extract) than the SV40 large T antigen, and also indicated that the tumor serum employed had antibodies against the 56,000 d cellular antigen. The heat-treated whole-cell extract of Sv40-transformed mouse cells was able to immunize and fully protect mice against a lethal tumorigenic dose of SV40-transformed cells. These results suggest the need for further experiments to characterize the chemical and immunologic properties of the 56,000 d protein.

Simian virus 40 gene A regulation of cellular DNA synthesis. II. In nonpermissive cells

The stimulation of host macromolecular synthesis and induction into the cell cycle of serum-deprived G0-G1-arrested mouse embryo fibroblasts were examined after infection of resting cells with wild-type simian virus 40 or with viral mutants affecting T antigen (tsA58) or small t antigen (dl884). At various times after virus infection, cell cultures were analyzed for DNA synthesis by autoradiography and flow microfluorimetry. Whereas mock-infected cultured remained quiescent and displayed either a 2N DNA content (80%) or a 4N DNA content (15%), mouse cells infected with wild-type simian virus 40, tsA58 at 33 degrees C, or dl884 were induced into active cell cycling at approximately 18 h postinfection. Although dl884-infected mouse cells were induced to cycle initially at the same rate as wild type-infected cells, they became arrested earlier after infection and also failed to reach the saturation densities of wild-type simian virus 40-infected cells. Infection with dl884 also failed to induce loss of cytoplasmic actin cables in the majority of the infected cell population. Mouse cells infected with tsA58 and maintained at 39.5 degrees C showed a transient burst of DNA synthesis as reflected by changes in cell DNA content and an increase in the number of labeled nuclei during the first 24 h postinfection; however, after the abortive stimulation of DNA synthesis at 39.5 degrees C shift experiments demonstrated that host DNA replication was regulated by a functional A gene product. It is concluded that both products of the early region of simian virus 40 DNA play a complementary role in recruiting and maintaining simian virus 40-infected cells in the cell cycle.

Amplification and rearrangement of integrated SV40 DNA sequences accompany the selection of anchorage-independent transformed mouse cells

Clones of SV40 tsA mutant-transformed mouse embryo cells with a temperature-independent transformed growth phenotype were derived from a parental line with a temperature-dependent growth phenotype, using the selective pressure of anchorage independent growth in agar at 40 degrees C. The parental J78 clone contained a complex tandem structure of integrated SV40 DNA within two cellular DNA fragments of 10 and 14 kb, generated by Bgl II digestion. The new clonal derivatives, in addition to an altered growth phenotype, displayed additional high molecular weight sites of SV40 DNA integration. A marked structural similarity among integration sites suggested that the new sites may have arisen by duplication and translocation of an original integration structure, or via an unequal crossover event. The rearrangement of viral DNA sequences appears to be specifically associated with the emergence of temperature-independent clones, since the isolation of new clones under nonselective conditions, that is, growth in semi-solid medium at 33 degrees C, was not accompanied by modification in cellular sequences containing SV40 DNA.

Subcellular distribution of simian virus 40 T antigen species in various cell lines: the 56K protein

The subcellular distribution of SV40 anti-T serum-specific species was examined in SV40-transformed, T-antigen-positive tissue culture cell lines of rat and of AL/N and BALB/c mouse origin. Cells were labelled with [35S]methionine. The cytoplasm, nuclear and membrane fractions were obtained, and their radioimmunoprecipitates analyzed by gel electrophoresis. Tests were performed to determine the purity of these subcellular fractions, and negligible cross-contamination was found. The cytoplasm fractions lacked detectable anti-T serum reactivity. Large amounts of both large T antigen and a 56K protein were always present together both in the nuclear fractions and, in a somewhat lesser amount, in the plasma membrane fractions of all cell lines examined. Analysis of density gradient sedimentation profiles of the immunoprecipitates of whole-cell extracts indicated these species were associated in some fashion, probably with each other. The activity of the 56K protein may be associated with its presence on the cell surface where, either alone or acting together with the large T antigen, it might provide the surface activity responsible for tumor-specific surface and/or transplantation antigen activities.

Serological detection of a polyoma-tumor-associated membrane antigen

Syngeneic antisera raised against three polyoma tumors, SEYF-a SESO and SEWE, of strain ABY, A and ASW origin, respectively, contain antibodies directed against multiple specificities. One specificity is cross-reactive for the three polyoma tumors, but appears to be absent from a large variety of other tumors tested. Other, more "public" antigens are shared with a variety of other tumors of viral or non-viral origin. Five different public specificities of this type have been demonstrated and to some extent defined. Since the SEWE ascites tumor, with the shortest passage history, is much less liable to induce antibodies against the public specificities than the long-passaged SEYF-a and SESO, it is likely that the corresponding antigenic determinants arise as a result of passenger virus pick-up during continued passage, or are due to secondary cytogenetic changes.

Simian virus 40 gene A regulation of cellular DNA synthesis. I. In permissive cells

The kinetics of host cellular DNA stimulation by simian virus 40 (SV40) tsA58 infection was studied by flow microfluorometry and autoradiography in two types of productively infected monkey kidney cells (AGMK, secondary passage, and the TC-7 cell line). Prior to infection, the cell populations were maintained predominantly in G0-G1 hase of the cell cycle by low (0.25%) serum concentration. Infection of TC-7 or AGMK cells by wild-type SV40, viable deletion mutant dl890, or by SV40 tsA58 at 33 degrees C induced cells through S phase after which they were blocked with a 4N DNA content in the G2 phase. The infection of TC-7 cells by tsA58 at 41 degrees C, which was a nonpermissive temperature for viral DNA replication, induced a round of cell DNA synthesis in approximately 30% of the cell population. These cells proceeded through S phase but then re-entered the G1 resting state. In contrast, infection of AGMK cells by tsA58 at 41 degrees C induced DNA synthesis in approximately 50% of the cells, but this population remained blocked in the G2 phase. These results indicate that the mitogenic effect of the A gene product upon cellular DNA is more heat resistant than its regulating activity on viral DNA synthesis and that the extent of induction of cell DNA synthesis by the A gene product may be influenced by the host cell.

Subcellular Localization of simian virus 40 large tumor antigen

The distribution of simian virus 40 large tumor antigen in subcellular fractions from simian virus 40-transformed hamster (H-50) and mouse (VLM) cells and from simian virus 40-infected monkey cells was determined. Solubilized [(35)S]-methionine- or (32)P(i)-labeled surface membrane and nuclear fractions were prepared, immunoprecipitated with hamster anti-T serum, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Tumor antigen with an apparent molecular weight of approximately 96,000 was detected in both subcellular fractions. Minor components of approximately 68,000 and approximately 56,000 with anti-T reactivity which labeled with [(35)S]methionine were also detected in both fractions from H-50 cells, as were components of approximately 140,000 and approximately 56,000 from VLM cells. The 56,000 component appeared to be greatly reduced in (32)P(i)-labeled surface membrane fractions. Normal cells or cells transformed with a heterologous agent, such as polyoma virus or a chemical carcinogen, lacked immunoprecipitable tumor antigen. Cell fractionation was monitored by [(3)H]thymidine labeling, NADH-diaphorase activity, and Na(+)-K(+)-dependent ATPase activity. These analyses revealed only trace contamination of surface membranes by nuclei, extremely low levels of nuclear rupture during homogenization, and an approximate 10-fold enrichment of surface membrane. Reconstruction experiments demonstrated that soluble tumor antigen failed to associate or copurify with surface membranes during fractionation procedures. These results indicate the presence of a protein in the plasma membrane of cells transformed or infected by simian virus 40 that is immunologically indistinguishable from nuclear tumor antigen.

Relationship between T-antigen and tumor-specific transplantation antigen in simian virus 40-transformed cells

The simian virus 40 (sv40) tumor antigen (T-antigen) and tumor-specific transplantation antigen (TSTA) have been partially purified and studied to clarify their relationship. The T-antigen and the TSTA were partially purified from nuclei of SV AL/N cells, and SV40-transformed mouse embryo fibroblast line, by precipitation with ammonium sulfate and chromatography on DEAE- and DNA-cellulose. The T-antigen was assayed by complement fixation, and the TSTA was assayed by its ability to immunize mice against SV40-containing ascites tumor cells. When T-antigen- and TSTA-containing preparations were sedimented through sucrose gradients, each antigen had a major peak of activity at a sedimentation coefficient of 6.7 and minor peaks in other regions. Antiserum against T-antigen (from tumor-bearing hamsters) immunoprecipitated the TSTA activity. A preparation of T-antigen from human SV80 cells, which exhibited only one protein band after sodium dodecylsulfate-polyacrylamide gel electrophoresis, had TSTA activity when as little as 0.6 microgram of protein per mouse was used for immunization. These experiments demonstrate that the T-antigen, the product of the SV40 early A gene is capable of inducing specific immunity against transplantation of SV40-transformed tumor cells in mice.

Tumor-specific transplantation antigen: use of the Ad2+ND1 hybrid virus to identify the protein responsible for simian virus 40 tumor rejection and its genetic origin

Cells transformed by simian virus 40 (SV40) possess a tumor-specific transplantation antigen (TSTA) that has the property of immunizing animals against syngeneic tumor challenge. We find that the early SV40 DNA segment present in the human adenovirus 2 (Ad2)-SV40 hybrid, Ad2+ND1, is sufficient to induce this SV40-specific TSTA in BALB/c mice. Moreover, studies on the intracellular distribution of TSTA activity in Ad2+ND1-infected cells, as determined by the ability of various subcellular fractions to immunize mice against syngeneic tumor challenge, have suggested a correlation between this biological activity and the presence of the SV40-specific 28,000Mr protein in coded by this hybrid virus. Both the TSTA activity and the 28,000 Mr protein are found in the plasma membrane fraction and in the perinuclear region of infected cells but are virtually undetectable in the cytoplasmic fraction. Using a hamster antitumor antiserum that can specifically immunoprecipitate the 28,000 Mr protein, we are able to demonstrate a loss of TSTA activity concomitant with the removal of this SV40-coded protein. Thus, it appears that antigenic determinants responsible for SV40-specific tumor rejection in mice are contained within the 28,000 Mr protein coded for by the early SV40 DNA segment that extends from 0.17 to 0.28 map unit.

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.

The genome of simian virus 40

The nucleotide sequence of SV40 DNA was determined, and the sequence was correlated with known genes of the virus and with the structure of viral messenger RNA's. There is a limited overlap of the coding regions for structural proteins and a complex pattern of leader sequences at the 5' end of late messenger RNA. The sequence of the early region is consistent with recent proposals that the large early polypeptide of SV40 is encoded in noncontinguous segments of DNA.

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.

Characterization of the autoregulation of simian virus 40 gene A

Cells infected by tsA mutants of simian virus 40 (SV40) overproduce early RNA. Overproduction results from failure of the temperature-sensitive A protein (T antigen) to inhibit early transcription. The amount of early RNA in the cytoplasm, determined quantitatively from the kinetics of hybridization to labeled complementary SV40 DNA, was elevated at both permissive (32 degrees C) and nonpermissive (41 degrees C) temperatures in all the early mutants tested (tsA7, -30, -58, and -209), but not in the late mutant tsB4. The amount of early RNA in a culture maintained at 32 degrees C for 72 h and then shifted to 41 degrees C was maximum when each cell was infected initially with at least one plaque-forming unit of tsA58. Azidocytidine (2'-deoxy-2'-azidocytidine), which inhibits initiation of DNA synthesis, did not cause overproduction of early RNA in cells infected with wild-type SV40, showing that the effect seen with tsA mutants is not due to interference with initiation of DNA synthesis per se. In parallel infections at 41 degrees C, the amount of early RNA per copy of viral DNA was as much as 2,000 times greater with tsA58 than with wild-type SV40, even though there was no replication of the tsA58 DNA. Synthesis of late RNA could not be detected during the first 20 h of an infection by either virus at 32 degrees C, indicating that late and early transcription are under different control. In three cell lines transformed by tsA mutants, the amount of early RNA increased moderately after a shift from 32 to 41 degrees C, whereas with homologous cells transformed by wild-type virus, the amount of early RNA decreased, indicating that the A protein may be able to repress transcription of integrated SV40 DNA. All the observations are consistent with a simple model in which the binding of A protein at the origin of replication blocks either binding of RNA polymerase to the early promoter or its progress through the early gene(s).

Immunological selection of tumour cells which have lost SV40 antigen expression

In an already tumorigenic spontaneously transformed mouse cell, after further transformation by SV40, the virus-specific antigenic function becomes dominant. By transplantation into syngeneic mice SV40 antigen negative revertant tumour cells can be selected out.

The early region of SV40 DNA may have more than one gene

The nucleotide sequence of 70 base pairs (bp) around 0.545 map units (Alu I C and B junction) of the genome from the single Eco RI cleavage site within SV40 DNA is presented. The mRNA transcribed from the early strand template from this stretch contains two copies of the nonsense triplet UAA in each of the three reading frames. Thus at least 25% of the early region of SV40 DNA does not code for the SV40 "A" protein, and the viral contribution to events in the lytic cycle and transformation may be more complex than is generally appreciated.

Expression of tumor-specific transplantation antigen in cell lines transformed by wild-type of tsA mutant simian virus 40

The simian virus 40-induced tumor-specific surface antigen(s) (TSSA) and tumor-specific transplantation antigen(s) (TSTA)were detected in cells transformed by wild-type or temperature-sensitive mutant simian virus 40 by an antibody-mediated cytolytic assay for TSSA and an immunization test for TSTA. Cells transformed by tsA mutants, which lose their transformed phenotype when grown at nonpermissive temperatures, nonetheless do express TSSA and TSTA as well as T-antigen at both temperatures.

Biological and biochemical studies of cells transformed by simian virus 40 temperature-sensitive gene A mutants and A mutant revertants

The growth properties of hamster cells transformed by wild-type Simian virus 40 (SV40), by early SV40 temperature-sensitive mutants of the A complementation group, and by spontaneous revertants of these mutants were studied. All of the tsA mutant-transformed cells were temperature sensitive in their ability to form clones in soft agar and on monolayers of normal cells except for CHLA-30L1, which was not temperature sensitive in the latter property. All cells transformed by stable revertants of well-characterized tsA mutants possessed certain growth properties in common with wild-type-transformed cells at both temperatures. Virus rescued from tsA transformants including CHLA30L1 was temperature sensitive for viral DNA replication, whereas that rescued from revertant and wild-type transformants was not thermolabile in this regard. T antigen present in crude extracts of tsA-transformed cells including CHLA30L1, grown at 33 degreeC, was temperature sensitive by in vitro immunoassay, whereas that from wild-type-transformed cells was relatively stable. T antigen from revertant transformants was more stable than the tsA protein. Partially purified T antigen from revertant-transformed cells was nearly as stable as wild-type antigen in its ability to bind DNA after heating at 44 degrees C, whereas T antigen from tsA30 mutant-transformed cells was relatively thermolabile. These results further indicate that T antigen is a product of the SV40 A gene. Significantly more T antigen was found in extracts of CHLA30L1 grown to high density at the nonpermissive temperature than in any other tsA-transformed cell similarly grown. This is consistent with the suggestion that the amount of T antigen synthesized in CHLA30L1 is large enoughto allow partial expression of the transformed phenotype at the restrictive temperature. Alternatively, the increase in T antigen concentration may be secondary to one or more genetic alterations that independently affect the transformed phenotype of these cells.