Antigenic structure of simian virus 40 large tumor antigen and association with cellular protein p53 on the surfaces of simian virus 40-infected and -transformed cells

Binding and Internalization of Iron Oxide Nanoparticles Targeted to Nuclear Oncoprotein

A targeted nanoconjugate is being developed for non-invasive detection of gene expression in cells expressing the JC virus oncoprotein, T-antigen, which has been associated with medulloblastoma and other cancers. JC virus T-antigen localizes predominantly to the nucleus via a classical monopartite nuclear localization signal (NLS). An antibody fragment which recognizes JC virus T-antigen was attached to cross-linked dextran coated iron oxide nanoparticles. Radiolabeled conjugates were added to mouse medulloblastoma cells expressing the target T-antigen to test their ability to bind to tumor cells and be internalized by the cells. All conjugates containing targeting antibody bound to cells and were internalized, with increasing levels over time. There was no difference in cell binding or internalization among conjugates containing 2, 4, 6 or 8 antibody fragments per nanoparticle. Conjugates with only nonspecific antibody on nanoparticles, or unconjugated nonspecific antibody, had significantly lower total binding and internalization than conjugates with targeting antibody. Unconjugated targeting antibody had equivalent or lower cell uptake compared with targeted nanoparticle conjugates. Specificity of uptake was demonstrated by >80% reduction of nanoconjugate uptake in the presence of 100 fold excess of unconjugated antibody. The presence of a membrane translocation peptide (Tat) on the nanoparticles in addition to targeting antibody did not improve nanoconjugate internalization over the internalization caused by the antibody alone. This antibody nanoconjugate demonstrates feasibility of targeting a nuclear protein and suggests that a minimum number of antibody fragments per nanoparticle are sufficient for achieving binding specificity and efficient uptake into living cells.

Differential effects of the simian virus 40 early genes on mammary epithelial cell growth, morphology, and gene expression

To study the effect of SV40 T-antigen in mammary epithelial cells, a rat beta-casein promoter-driven SV40 early-region construct was stably introduced into the clonal mouse mammary epithelial cell line HC11. With the expression of the viral T-antigens under the control of a hormone-inducible promoter, it was possible to dissociate the effects of different levels of T-antigen expression on cell growth, morphology, and gene expression. Following hormonal induction, a rapid but transient induction of T-antigen was observed, followed by a delayed induction of H4 histone mRNA. In T-antigen-positive HC11 cells cultured in the absence of EGF, the expression of basal levels of T-antigen (in the absence of hormonal induction) led to a decreased doubling time and an increased cell density. In the presence of EGF, T-antigen expression resulted additionally in an altered cell morphology. Despite the effects of T-antigen on cell growth and gene expression, the cells were unable to form colonies in soft agar and were nontumorigenic when transplanted into cleared mammary fat pads. They were, however, weakly tumorigenic in nude mice. Relatively high levels of p53 protein synthesis were observed in both the transfected HC11 cells and the parental COMMA-D cells, as compared to 3T3E fibroblasts and another mammary epithelial cell line. The HC11 and COMMA-D cells synthesized approximately equal levels of wild-type and mutated p53 proteins as defined by their reactivities with monoclonal antibodies PAb246 and PAb240, respectively. Interactions between excess p53 and T-antigen may, in part, explain the failure of these cells to display a completely transformed phenotype.

Insulin-induced mitogenesis associated with transformation by the SV40 large T antigen

Simian virus 40 (SV40) large T antigen-transformed cells typically show a markedly reduced serum requirement for growth and the inability to growth arrest and differentiate. An SV40 large T antigen-transformed 3T3 T cell line, CSV3-1, that can growth arrest and differentiate into adipocytes with high efficiency has, however, recently been described (Scott et al: Proc. Natl. Acad. Sci. U.S.A. 86:1652-1656, 1989; Estervig et al: J. Virol. 63:2718-2725, 1989; J. Cell. Physiol. 142:552-558, 1990). The results of the current studies using these cells show that whereas quiescent 3T3 T cells show no mitogenic response to insulin, quiescent CSV3-1 cells show a highly significant insulin-induced mitogenic responsiveness in the absence of other added growth factors. Maximum mitogenesis was observed at an insulin concentration of 1 microgram/ml, which induced 40-70% of the cells to undergo DNA synthesis within 48 hours. The half maximum response was achieved with 1-10 ng/ml of insulin. Insulin's mitogenic effect on CSV3-1 cells was evident under several different culture conditions that induce quiescence and was not mediated by any detectable autocrine growth factors that might make CSV3-1 cells competent to respond to insulin. In CSV3-1 cells insulin appears to act on its own receptor rather than on the IGF-1 receptor, because at comparable dosages IGF-1 is 10- to 100-fold less effective than insulin. Insulin also is shown to be a mitogen for another SV40-transformed cell line, CSV3-35, which can be growth arrested; in contrast insulin has no mitogenic effect on two control cell lines that are stably transfected with pSV2neo, a plasmid containing SV40 early promoter/enhancer but lacking large T antigen gene: These results suggest a significant relationship between SV40 T antigen-associated transformation and the expression of mitogenic responsiveness to insulin.

Only a minor fraction of plasma membrane-associated large T antigen in simian virus 40-transformed mouse tumor cells (mKSA) is exposed on the cell surface

The bulk of simian virus 40 (SV40) large T antigen in SV40-infected and -transformed cells localizes within the cell nucleus, while a minor fraction specifically associates with the plasma membrane (PM) and is exposed on the cell surface. PM-associated large T seems to span the lipid bilayer but, on the other hand, does not display typical features of a transmembrane protein. To further characterize the postulated transmembrane orientation of large T, we asked whether all large T molecules associated with the plasma membrane indeed are exposed on the cell surface. We compared the amount of cell surface-exposed large T, determined on living cells by a sensitive 3H-protein A-binding assay and by external immunoprecipitation, with that of total PM-associated large T extracted from isolated PM. We demonstrate that in mKSA cells (SV40-transformed BALB/c mouse fibroblasts), total PM-associated large T accounted for a substantial portion (ca. 2%) of total cellular large T. However, only 0.1 to 0.2% of it could be detected on the cell surface. Thus, only a minor fraction of PM-associated large T (less than 10%) is exposed on the surface of these cells. Interior PM-associated large T is stably associated with the plasma membrane, while the small fraction of surface-exposed large T is rapidly released from the cell surface.

SV40 T-antigen as a dual oncogene: structure and function of the plasma membrane-associated population

SV40 T-antigen (T-ag) is localized in both the nucleus (nT-ag) and plasma membrane (pmT-ag) of cells and provides multiple functions necessary for cell transformation. The pmT-ag population is structurally very similar to the nT-ag. Transport to the cell surface is by an unknown mechanism that does not involve the secretory pathway. The disposition of T-ag in the membrane exposes both the amino and the carboxyl terminus on the exterior of the cell. Nuclear-transport-defective mutants of T-ag can transform established cells in culture, but not primary cells, suggesting that non-nuclear forms of T-ag may mediate some transformation-related process(es). A non-cytolytic protein extraction technique utilizing 1-butanol solubilized from SV40-transformed cells a multimeric complex composed of pmT-ag and at least five cellular proteins ranging in size from 35,000 (35K) to 60K M. Both amino- and carboxylterminal T-ag-specific monoclonal antibodies co-precipitated T-ag and the 35-60K Mr proteins, but antibodies against the internal portion of T-ag precipitated only uncomplexed T-ag. The growth state of the cells markedly influenced the expression of the T-ag-containing surface complexes; more complexes were recovered from actively dividing cells than from confluent cell cultures, and suspension cells yielded more complexes than cells on a substratum. The complex exhibited a highly dynamic association with the cell membrane, as demonstrated by pulse-chase analysis. The characteristics of growth-dependent expression and rapid turnover rate suggest a functional role for the membrane complex. The identities of the cellular proteins in the complex with pmT-ag are unknown, although one member (56K) is recognized by p53-specific monoclonal antibodies.

Quantitative analysis of cell surface-associated SV40 large T antigen using a newly developed 3H-protein A binding assay

We have established a sensitive assay for the quantitative determination of large T antigen determinants on the surface of living simian virus 40 (SV40)-transformed cells (mKSA). Cells in suspension culture were incubated with monoclonal antibodies specific for large T antigen (KT3, directed against the carboxyterminus of large T antigen, and PAb 108, directed against an aminoterminal determinant on large T antigen). After incubation with secondary antibody (rabbit anti-mouse IgG), followed by incubation with 3H-protein A, the cells were sequentially extracted first with the nonionic detergent NP-40, followed by ultrasonication and extraction with the zwitterionic detergent Empigen BB. NP-40 solubilized large T antigen associated with NP-40-soluble constituents of the plasma membrane, whereas Empigen BB solubilized the plasma membrane lamina-associated subclass of large T antigen (U. Klockmann and W. Deppert, 1983, EMBO J., 7, 1151-1157). The amount of cell surface-bound 3H-protein A in the NP-40 and Empigen BB extracts was determined by liquid scintillation counting. In agreement with earlier reports, cell surface large T antigen was mainly found in association with the plasma membrane lamina (PML). Since the specific activity of 3H-protein A was known, it was possible to calculate the number of surface-bound 3H-protein A molecules, and thus to estimate the average number of surface-exposed amino- and carboxyterminal determinants of large T antigen per cell. KT3 recognized about 450-900 carboxyterminal determinants, while PAb 108 bound to about 1200-2400 aminoterminal determinants on the surface of a single mKSA cell. The cellular protein p53 also was detected on the surface of mKSA cells and was found to be present in amounts comparable to cell surface large T antigen.

Solubilization of SV40 plasma-membrane-associated large tumor antigen using single-phase concentrations of 1-butanol

The nature of the interaction of the simian virus 40 (SV40) transforming protein, large tumor antigen (T-ag), with the plasma membrane of transformed cells is not well understood. We report here that SV40 plasma-membrane-associated large tumor antigen (pmT-ag) can be solubilized by using single-phase concentrations of 1-butanol. Purified plasma membranes from SV40-transformed mouse cells yielded T-ag when treated with 2.5% butanol; solubilization of T-ag from the purified membranes in butanol was temperature dependent, with approximately 10-fold more T-ag extracted at 37 degrees C than at 22 degrees C; and application of 2.5% butanol to mKSA cells after cellular surface proteins had been radiolabeled with 125I resulted in the release of iodinated T-ag. Butanol-extracted pmT-ag coprecipitated with p53 and several cellular proteins ranging in size from 35 to 60 kDa. One cellular component migrated at a mobility similar to that of tubulin (56 kDa), and a monoclonal antibody against the alpha subunit of tubulin coprecipitated T-ag. Immunoblotting of proteins immunoprecipitated with monoclonal antibodies against T-ag or p53 from butanol extracts with a monoclonal antibody against the beta subunit of tubulin revealed specific coprecipitation of tubulin with T-ag and p53. This suggests that complexes composed of tubulin, T-ag, and p53 exist in butanol extracts. Control experiments eliminated the possibility of an artifactual association of tubulin with T-ag and p53 induced by butanol. Two-dimensional gel analyses revealed that 2.5% butanol at 37 degrees C extracted a subset of membrane-associated proteins and some cytosolic proteins, as well as a number of proteins that were not soluble in either high salt or detergent. Thus, the butanol extraction conditions employed in this study recovered a species of pmT-ag that appears to complex with tubulin. As butanol reportedly is less deleterious to native protein structures than other agents, including high salts and detergents, this extraction procedure may be useful for studying the structure and function of other membrane-associated proteins.

Autoimmune expression of a cytoplasmic protein p60 in mice bearing metastasizing SV40-transformed tumors

In STU mice bearing metastasizing SV40-transformed 51A-232B-M tumors, an immune response against a cellular 60kDa protein (p60) developed in about 50% of the tumor-bearing animals, in addition to the response against SV40 large T-antigen and cellular protein p53. The anti-p60 auto-immune response could be observed as early as 11 days after tumor challenge and was strictly linked with metastatic spread but was not a prerequisite for metastasis. Anti-p60 antibodies could not be detected in sera of animals bearing metastasizing Rous-sarcoma virus-transformed or methylcholanthrene-induced tumors, or in sera from human cancer patients with clinically confirmed metastatic spread. The anti-p60 auto-antibodies showed a broad cross-reactivity against components of similar size in a great number of cell lines of various species and in normal mouse tissue. The p60 auto-antigen is a cytoplasmic protein which is neither phosphorylated nor glycosylated in vivo. Immunoblotting performed with fresh cell lysates under non-reducing conditions using tumor-bearer sera revealed a diffuse p60 double band, but under reducing conditions only one sharp p60 band was observed. The reaction of p60 with anti-p60 auto-antibodies could be completely blocked by pre-treatment of fresh cell lysates with N-ethylmaleimide or p-chloromercuriphenyl sulfonate, or by oxidation in air prior to immunoblotting, indicating that the anti-p60 autoimmune response was directed against an epitope sensitive to SH-group-blocking reagents. Immunofluorescence studies with tumor-bearer sera showed only a very weak cytoplasmic fluorescence, possibly due to the nature of the p60 SH-groups in situ being masked. Immunoprecipitates with monoclonal antibodies against SV40 large T-antigen and p53 obtained from fresh cell lysates of SV40-transformed tumor cells contained no associated p60 auto-antigen. The p60 auto-antigen was purified from tumor cell homogenates with an enrichment factor of about 2,000; its iso-electric point is at pH 6.8. Determination of the biological half-life of p60 yielded a value of about 28 hr. The p60 auto-antibodies in pools of tumor-bearer sera taken at day 40 after tumor challenge all belonged to the IgG1 subclass.

Integration of Friend murine leukemia virus into both alleles of the p53 oncogene in an erythroleukemic cell line

The Friend virus-transformed erythroleukemic cell line DP16-9B4 has undergone a complex rearrangement of the p53 oncogene and lacks any detectable expression of the p53 protein. We report here characterization of both p53 alleles in this cell line and identify independent integrations of Friend murine leukemia virus sequences into the coding region of both alleles.

Fine mapping two distinct antigenic sites on simian virus 40 (SV40) T antigen reactive with SV40-specific cytotoxic T-cell clones by using SV40 deletion mutants

The existence of two distinct antigenic sites at the surface of simian virus 40 (SV40)-transformed H-2b cells has been previously demonstrated (A. E. Campbell, L. F. Foley, and S. S. Tevethia, J. Immunol. 130:490-492, 1983) by using two independently isolated SV40-specific cytotoxic T-lymphocyte (CTL) clones, K11 and K19. We identified amino acids in the amino-terminal half of SV40 T antigen that are essential for the recognition of antigenic sites by these CTL clones by using H-2b cells transformed by mutants that produce T antigen truncated from the amino-terminal or carboxy-terminal end or carrying overlapping internal deletions in the amino-terminal regions of SV40 T antigen. The results show that CTL clone K11 failed to recognize and lyse target cells missing SV40 T-antigen amino acids 189 to 211, whereas CTL clone K19 lysed these cells. The cell lines missing SV40 T-antigen amino acids 220 to 223 and 220 to 228 were not lysed by CTL clone K19 but were susceptible to lysis by CTL clone K11. Two other cell lines missing amino acids 189 to 223 and 189 to 228 of SV40 T antigen were not lysed by either of the CTL clones but were lysed by SV40-specific bulk-culture CTL if sufficient amounts of relevant restriction elements were expressed at the cell surface. The SV40 T-antigen amino acids critical for the recognition of an antigenic site by CTL clone K11 were identified to be 193 to 211; 220 to 223 were identified as critical for recognition by CTL clone K19. The deletion of these amino acids from the T antigen resulted in the loss of antigenic sites specific for CTL clones K11 and K19.

The cellular secretory pathway is not utilized for biosynthesis, modification, or intracellular transport of the simian virus 40 large tumor antigen

Unlike most proteins, which are localized within a single subcellular compartment in the eucaryotic cell, the simian virus 40 (SV40) large tumor antigen (T-ag) is associated with both the nucleus and the plasma membrane. Current knowledge of protein processing would predict a role for the secretory pathway in the biosynthesis and transport of at least a subpopulation of T-ag to account for certain of its chemical modifications and for its ability to reach the cell surface. We have examined this prediction by using in vitro translation and translocation experiments. Preliminary experiments established that translation of T-ag was detectable with as little as 0.1 microgram of the total cytoplasmic RNA from SV40-infected cells. Therefore, by using a 100-fold excess of this RNA, the sensitivity of the assays was above the limits necessary to detect the theoretical fraction of RNA equivalent to the subpopulation of plasma-membrane-associated T-ag (2 to 5% of total T-ag). In contrast to a control rotavirus glycoprotein, the electrophoretic mobility of T-ag was not changed by the addition of microsomal vesicles to the in vitro translation mixture. Furthermore, T-ag did not undergo translocation in the presence of microsomal vesicles, as evidenced by its sensitivity to trypsin treatment and its absence in the purified vesicles. Identical results were obtained with either cytoplasmic RNA from SV40-infected cells or SV40 early RNA transcribed in vitro from a recombinant plasmid containing the SP6 promoter. SV40 early mRNA in infected cells was detected in association with free, but not with membrane-bound, polyribosomes. Finally, monensin, an inhibitor of Golgi function, failed to specifically prevent either glycosylation or cell surface expression of T-ag, although it did depress overall protein synthesis in TC-7 cells. We conclude from these observations that the constituent organelles of the secretory pathway are not involved in the biosynthesis, modification, or intracellular transport of T-ag. The initial step in the pathway of T-ag biosynthesis appears to be translation on free cytoplasmic polyribosomes. With the exclusion of the secretory pathway, we suggest that T-ag glycosylation, palmitylation, and transport to the plasma membrane are accomplished by previously unrecognized cellular mechanisms.

trans-activation of cellular and viral promoters by a transforming nonkaryophilic simian virus 40 large T antigen

We used the chloramphenicol acetyl transferase (CAT) transient expression system to study the transactivating ability of a simian virus 40 (SV40) mutant that was unable to transport and localize large T antigen into the nucleus and which retained the competence to transform established cell lines. The effect of the SV40 wild type and the SV40 mutant for the large T antigen was tested in both mouse and simian cells on a series of plasmids in which the CAT gene was regulated by one of the following promoters: SV40 early and late, herpes simplex virus thymidine kinase, chicken alpha 2(I) collagen, mouse H-2Kk. Our results indicated that both the SV40 wild type and the cytoplasmic mutant for the large T antigen regulated transcription from any promoter tested, suggesting that the trans-activation by SV40 does not require the nuclear localization of the 100,000-molecular-weight large T-antigen protein.

Fluctuation of simian virus 40 (SV40) super T-antigen expression in tumors induced by SV40-transformed mouse mammary epithelial cells

Higher-molecular-weight forms of the simian virus 40 (SV40) large tumor antigen (T-Ag), designated super T-Ag, are commonly found in SV40-transformed rodent cells. We examined the potential role of super T-Ag in neoplastic progression by using a series of clonal SV40-transformed mouse mammary epithelial cell lines. We confirmed an association between the presence of super T-Ag and cellular anchorage-independent growth in methylcellulose. However, tumorigenicity in nude mice did not correlate with the expression of super T-Ag. In the tumors that developed in nude mice, super T-Ag expression fluctuated almost randomly. Cell surface iodination showed that super T-Ag molecules were transported to the epithelial cell surface. The biological functions of super T-Ag remain obscure, but it is clear that it is not important for tumorigenicity by SV40-transformed mouse mammary epithelial cells. Super T-Ag may be most important as a marker of genomic rearrangements by the resident viral genes in transformed cells.

Biochemical properties of a transforming nonkaryophilic T antigen of SV40

We reconstructed into wt SV40 DNA a previously described deletion of the A gene, eliminating amino acids 110 through 152 of the large T (L. Fischer-Fantuzzi and C. Vesco (1985) Proc. Natl. Acad. Sci. USA 82, 1891-1895); the gene product of the new recombinant pACTSV2, like the previous product, has a cytoplasmic instead of a nuclear localization and efficiently transforms NIH3T3 cells. Three main functions of this nonkaryophilic large T (NKLT) were examined, and the results obtained were the following: the NKLT does not bind to the SV40 origin DNA under conditions where the normal large T shows specific binding; the NKLT has conserved the ability to form high molecular weight aggregates; the NKLT becomes phosphorylated in vivo at only two residues: serine 639 and threonine 701. This indicates that the NH2-terminal phosphorylation of the large T is unnecessary for established-cell transformation. In addition, this and previous evidence (K. H. Scheidtmann et al. (1984) J. Virol. 50, 636-640) suggest that the lack of phosphorylation in serines 106, 676, 677, and 679 may constitute a characteristic of the large T molecules with extranuclear localization.

Simian virus 40 origin DNA-binding domain on large T antigen

Fifty variant forms of simian virus 40 (SV40) large T antigen bearing point, multiple point, deletion, or termination mutations within a region of the protein thought to be involved in DNA binding were tested for their ability to bind to SV40 origin DNA. A number of the mutant large T species including some with point mutations were unable to bind, whereas many were wild type in this activity. The clustering of the mutations that are defective in origin DNA binding both reported here and by others suggests a DNA-binding domain on large T maps between residues 139 and approximately 220, with a particularly sensitive sequence between amino acids 147 and 166. The results indicate that the domain is involved in binding to both site I and site II on SV40 DNA, but it remains unclear whether it is responsible for binding to cellular DNA. Since all the mutants retain the ability to transform Rat-1 cells, we conclude that the ability of large T to bind to SV40 origin DNA is not a prerequisite for its transforming activity.

Evidence for transmembrane orientation of acylated simian virus 40 large T antigen

In mKSA cells (a simian virus 40-transformed BALB/c mouse tumor cell line), plasma membrane-associated large T antigen (large T) is found in two subfractions of the plasma membrane; a minor amount of large T is recovered from the Nonidet P-40 (NP-40)-soluble plasma membrane fraction, whereas the majority is tightly bound to a substructure of the plasma membrane, the plasma membrane lamina (PML). Only PML-associated large T is fatty acid acylated (U. Klockmann and W. Deppert, EMBO J. 2:1151-1157, 1983). We have analyzed whether these two forms of plasma membrane-associated large T might differ in features like cell surface expression or metabolic stability. In addition, we have asked whether one of the two large Ts might represent the hypothetic, large T-related protein T* (D. F. Mark and P. Berg, Cold Spring Harbor Symp. Quant. Biol. 44:55-62, 1979). We show that in mKSA cells grown in suspension culture, large T associated with the PML is also exposed on the cell surface. This form of large T, therefore, exhibits properties of a transmembrane protein. Large T in the NP-40-soluble plasma membrane fraction could not be labeled with radioiodine on the cell surface and, for this reason, does not seem to be oriented towards the cell surface. In contrast, when mKSA cells were grown on substratum (culture dish), we found that in these cells both NP-40-soluble large T as well as large T anchored in the PML could be cell surface iodinated. We also have analyzed the plasma membrane association of surface T antigen in mKSA cells grown in a mouse as ascites tumor. In tumor cells, only PML-bound large T is cell surface associated. We conclude that differences in extractibility of cell surface-associated large T most likely depend on cell shape and are not an artifact of cell culture. Both NP-40-soluble and PML-bound large Ts are associated with the plasma membrane in a metabolically stable fashion. Neither of the two large Ts represents T*.

Abrogation of simian virus 40 DNA-mediated transformation of primary C57BL/6 mouse embryo fibroblasts by exposure to a simian virus 40-specific cytotoxic T-lymphocyte clone

Primary mouse embryo fibroblasts of C57BL/6 origin (B6/MEF) were transformed in vitro by transfection with simian virus 40 (SV40) DNA. The transformation frequency was markedly reduced if the SV40 DNA-transfected cultures were briefly exposed to K11 cells, an SV40-specific clone of cytotoxic T lymphocytes. This abrogation of SV40 transformation in vitro by cytotoxic T-lymphocyte clone K11 was specific, since transformation of B6/MEF cells by adenovirus type 5 DNA was not affected. The approach described here should serve as an ideal model of dissecting immunological events during in vivo tumorigenesis.

Surface T-antigen expression in simian virus 40-transformed mouse cells: correlation with cell growth rate

Cell growth control appears to be drastically altered as a consequence of transformation. Because the cell surface appears to have a role in modulating cell growth and simian virus 40 (SV40)-transformed cells express large T antigen (T-Ag) in the plasma membrane, we investigated whether surface T-Ag expression varies according to cell growth rate. Different growth states were obtained by various combinations of seeding density, serum concentration, and temperature, and cell cycle distributions were determined by flow microcytofluorometry. Actively dividing SV40-transformed mouse cell cultures were consistently found to express higher levels of surface T-Ag and T-Ag/p53 complex than cultures in which cells were mostly resting. In addition, the T-Ag/p53 complex disappeared from the surface of tsA7-transformed cells cultured under restrictive conditions known to induce complete growth arrest (39.5 degrees C), although the surface complex did not disappear from other tsA transformants able to keep cycling at 39.5 degrees C. These results suggest that surface SV40 T-Ag or surface T-Ag/p53 complex, or both, are involved in determining the growth characteristics of SV40-transformed cells.

Suppression of in vivo tumor formation induced by simian virus 40-transformed cells in mice receiving antiidiotypic antibodies

This study characterizes four private idiotypes (Id) associated with monoclonal antibodies (mAb) to simian virus 40 (SV40) tumor antigen (T-Ag), and to a cellular protein, p53. Anti-Id recognized Id determinants associated with the antibody-combining site. BALB/c mice receiving a pool of anti-Id directed against mAb recognizing distinct amino and carboxyl terminal epitopes of T-Ag before receiving a tumorigenic dose of SV40-transformed cells showed suppression of tumor formation. Serum obtained from these mice before tumor challenge contained anti-anti-Id that failed to bind T-Ag. These data support the potential role of regulatory idiotopes in tumor immunity.

Surface T-antigen expression in simian virus 40-transformed mouse cells: correlation with cell growth rate

Cell growth control appears to be drastically altered as a consequence of transformation. Because the cell surface appears to have a role in modulating cell growth and simian virus 40 (SV40)-transformed cells express large T antigen (T-Ag) in the plasma membrane, we investigated whether surface T-Ag expression varies according to cell growth rate. Different growth states were obtained by various combinations of seeding density, serum concentration, and temperature, and cell cycle distributions were determined by flow microcytofluorometry. Actively dividing SV40-transformed mouse cell cultures were consistently found to express higher levels of surface T-Ag and T-Ag/p53 complex than cultures in which cells were mostly resting. In addition, the T-Ag/p53 complex disappeared from the surface of tsA7-transformed cells cultured under restrictive conditions known to induce complete growth arrest (39.5 degrees C), although the surface complex did not disappear from other tsA transformants able to keep cycling at 39.5 degrees C. These results suggest that surface SV40 T-Ag or surface T-Ag/p53 complex, or both, are involved in determining the growth characteristics of SV40-transformed cells.

Modification of simian virus 40 large tumor antigen by glycosylation

The SV40-encoded transforming protein, large tumor antigen (T-ag), is multifunctional. Chemical modifications of the T-ag polypeptide may be important for its multifunctional capacity. T-ag is additionally modified by glycosylation. T-ag was metabolically labeled in SV40-infected cells with tritiated galactose or glucosamine, but not with mannose or fucose. The identity of glycosylated T-ag was established by immunoprecipitation with a variety of T-ag-specific antisera, including monoclonal antibodies. Incorporation of labeled sugar into T-ag was inhibited in the presence of excess unlabeled sugars, but not in the presence of excess unlabeled amino acids. Labeled monosaccharides could be preferentially removed from T-ag with a mixture of glycosidic enzymes. In addition, galactose was removed from purified T-ag by acid hydrolysis and identified as such by thin-layer chromatography. T-ag oligosaccharides were resistant to treatment with EndoH, and glycosylation was not inhibited by tunicamycin. Together, these data strongly suggest that T-ag is glycosylated. Several characteristics, including lack of mannose labeling, EndoH resistance, and tunicamycin resistance, suggest that T-ag is not an N-linked glycoprotein. Rather, these properties are more consistent with the identification of T-ag as an O-linked glycoprotein.

Plasma membrane orientation of simian virus 40 T antigen in three transformed cell lines mapped with monoclonal antibodies

Simian virus 40 large T antigen transforms cells from several species. Recent studies show that it is present on the cell surface. As in other tumor virus systems, this may be important for transformation. We have used a radioimmunoassay to map antigenic determinants on living and formaldehyde-fixed transformed cells with six different monoclonal antibodies to T antigen. Nonrelevant monoclonal antibodies of the same subclasses served as controls. With the transformed mouse line SVT2, antibody PAb 101, which reacts with the C-terminal region of T antigen, and PAb 1700, which is directed against an internal region of T, reacted with both formaldehyde-fixed and living cells. Antibodies PAb 402 (C terminus) and 419 (N terminus) reacted only with living cells, their determinants being destroyed upon formaldehyde fixation. Antibodies PAb 405 (C terminus) and 100 (internal) fail to react on either fixed or living cells. Similar results were obtained on the simian virus 40-transformed human line SV80 and the fixed hamster line CHLwt23, although all antibodies failed to react with living CHLwt23 cells. The data suggest that T antigen is inserted into the plasma membrane of transformed cells in a specific, nonrandom manner, with the C and N termini exposed on the cell surface and the midportion either buried in the lipid bilayer, hidden by the tertiary structure of T antigen, or masked by a post-translational modification such as fatty acid acylation.