Monoclonal antibody analysis of simian virus 40 small t-antigen expression in infected and transformed cells.

The monoclonal antibody PAb280 binds to small t antigen but not to large T antigen. Its binding site within the unique region of small t antigen was localized by studying its reaction with simian virus 40 mutants, other papovaviruses, and bacterial expression vectors coding for fragments of small t antigen. The antibody was used to define the cellular location of small t antigen by immunocytochemistry and by immunoprecipitation of subcellular extracts of infected cells. PAb280 reacts strongly with a cytoplasmic form of small t antigen that appears to be associated with the cytoskeleton and is not detected by antibodies directed to the common N terminus of small t and large T antigens. Immunoperoxidase staining of cells infected by the simian virus 40 defective strain SV402 with PAb280 and other anti-T antibodies demonstrated that this virus produced an N-terminal fragment of large T antigen as well as small t antigen. In cells infected by the virus, this fragment was located in the cell nucleus but was very unstable. These results suggest that the activity of the SV402 virus in transformation assays may not be entirely due to the action of small t antigen alone.     

Identification and initial characterization of a new low-molecular-weight virus-encoded T antigen in a line of simian virus 40-transformed cells.

SV80 cells, a simian virus 40 (SV40)-transformed derivative of a strain of human fibroblasts, synthesize an 8-kilodalton anti-T reactive polypeptide in addition to large T and small t antigens. Although not observed during lytic infection carried out under a variety of conditions, an anti-T reactive molecule which comigrated with the SV80 8-kilodalton protein during sodium dodecyl sulfate-polyacrylamide gel electrophoresis was synthesized by one of five other SV40-transformed cell lines studied. The SV40 8-kilodalton protein was present in lysates of cells exposed to a brief pulse of radioactive methionine and did not accumulate during an extended chase period. This polypeptide could not by generated by mixing an unlabeled extract of SV80 cells with a labeled extract of infected monkey cells. The 8-kilodalton molecule reacts with antibody raised against homogeneous large T antigen, is present only in the cytoplasm, is not complexed with T, lacks DNA-binding properties, and is not phosphorylated. This protein could be translated in a cell-free system programmed by SV40-specific mRNA. At least two messenger species (approximately 19S and approximately 22S) directed its synthesis. Tryptic peptide analysis of [35S]methionine-labeled proteins demonstrated that the 8-kilodalton protein contains all eight of the common T/t peptides and one additional peptide not present in the maps of t or T. It lacks both of the t-unique peptides. The organization of the integrated viral sequences which encode this molecule was determined by restriction endonuclease analysis. In particular, SV80 cells contain at least two integrated SV40 genomes which are oriented in tandem, with an intervening cellular sequence..     

Cooperation of simian virus 40 large and small T antigens in metabolic stabilization of tumor suppressor p53 during cellular transformation.

Metabolic stabilization of the tumor suppressor p53 is a key event in cellular transformation by simian virus 40 (SV40). Expression of the SV40 large tumor antigen (large T) is necessary but not sufficient for this process, as metabolic stabilization of p53 complexed to large T in abortively SV40-infected cells strictly depends on the cellular systems analyzed (F. Tiemann and W. Deppert, J. Virol. 68:2869-2878, 1994). Comparative analyses of various cells differing in metabolic stabilization of p53 upon abortive infection with SV40 revealed that metabolic stabilization of p53 closely correlated with expression of the SV40 small t antigen (small t) in these cells: 3T3 cells do not express small t and do not stabilize p53 upon infection with wild-type SV40. However, ectopic expression of small t in 3T3 cells provided these cells with the capacity to stabilize p53 upon SV40 infection. Conversely, precrisis mouse embryo cells express small t and mediate metabolic stabilization of p53 upon infection with wild-type SV40. Infection of these cells with an SV40 small-t deletion mutant did not lead to metabolic stabilization of p53. Small-t expression and metabolic stabilization of p53 correlated with an enhanced transformation efficiency by SV40, supporting the conclusion that at least part of the documented helper effect of small t in SV40 transformation is its ability to promote metabolic stabilization of p53 complexed to large T.     

Characterization of different tumor antigens present in cells transformed by simian virus 40.

In addition to large T and small t antigens, cells transformed by simian virus 40 (SV40) commonly contain other proteins which specifically immunoprecipitate with SV40 anti-T serum and which are not detected in untransformed cells. The additional tumor antigens (T-Ags) fall into two groups: those having a close structural relationship with normal SV40 T-Ags, and those unrelated to large T and small t. The latter are probably nonviral T-Ags (NVT-Ags). The NVT-Ags comprise a family of proteins of molecular weight 50,000-55,000. Fingerprint analysis shows that NVT-Ags have few if any peptides in common with large T or small t, and that they lack the amino terminal tryptic peptide and the peptides unique to small t. NVT-Ags from different species have different fingerprints, but those isolated from different transformants of the same cell line are identical. The size of NVT is unaltered in cells transformed by mutants of SV40 with deletions in the region 0.60-0.55 map units. The mRNA for NVT does not hybridize to SV40 DNA. The other forms of T-Ag isolated from transformed cells fall into three classes: shortened forms of large T (truncated large T); multiple species of T-Ag with molecular weights very similar to, but distinct from, those of normal large T (large T doublets and triplets); and elongated forms of large T (super T). These proteins all contain the normal amino terminus of SV40 T-Ags, and the truncated forms of large T lack peptides from the carboxy terminal half of large T. One species of super T (molecular weight 130,000) contains only those methionine tryptic peptides present in normal large T, although it may contain some peptides in more than one copy.     

Requirement for the simian virus 40 small tumor antigen in tumorigenesis in transgenic mice.

To examine the role of simian virus 40 (SV40) large T and small t antigens in tumorigenesis in animals, we generated transgenic mice which expressed either both the SV40 large T and small t antigens or the SV40 large T antigen alone under the control of the mouse mammary tumor virus long terminal repeat. The mouse mammary tumor virus long terminal repeat directs the expression of transgenes in ductal epithelial cells of several organs, including the mammary gland, lung, and kidney, and in lymphoid cells. The mice which expressed both the T and t tumor antigens developed lung and kidney adenocarcinomas, while those which expressed large T alone did not. Both types of mice developed malignant lymphomas with similar frequencies and latency periods. Our results show that the SV40 small t antigen cooperates with the large T antigen in inducing tumors in slowly dividing epithelial cells in the lung and kidney.     

The sequences between 0.59 and 0.54 map units on SV40 DNA code for the unique region of small t antigen.

To demonstrate directly that the carboxy terminal portion of simian virus 40 (SV40) small t is encoded by a sequence of nucleotides from the region between 0.59-0.54 map units on SV40 DNA, we characterized the putative shortened forms or fragments of small t produced by mutants of SV40 (dl 884, dl 885, dl 890) with deletions in this region of the genome. Attempts to isolate the putative fragments of small t from mutant-infected cells, or from cell-free systems primed with mRNA from mutant-infected cells, resulted in only low yields of the fragments. Experiments using purified SV40 mRNA in low background cell-free systems, in which large T and small t could be detected without immunoprecipitation, suggested that these low yields were accounted for by reduced amounts of mRNA coding for the shortened forms of small t present in the mutant-infected cells. Larger amounts of putative fragments of small t were produced by translation of deletion mutant cRNA (complementary RNA synthesized in vitro using purified deletion mutant DNA and E. coli RNA polymerase). Fingerprint analysis of the proteins produced showed that they contain most, if not all, of the methionine peptides common to small t and large T. Furthermore, the fragments of small t produced in response to dl 884 and dl 890 lack two methionine peptides that are present in small t but not in large T. These data provide direct evidence that the region between 0.59-0.54 map units on SV40 DNA codes for polypeptide sequences that are unique to small t, and establishes that the nucleotide sequences from the region between 0.59-0.54 map units are both a coding sequence (for small t) and an intervening sequence (for large T).     

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.     

Failure of simian virus 40 small t antigen to disorganize actin cables in nonpermissive cell lines.

Mouse C3H 10T1/2 cell lines expressing the simian virus 40 (SV40) small t antigen were obtained by cotransfection of pSV2neo and plasmids which encode small t. Cell lines derived from two plasmids which encode small t in the absence of stable deletion fragments of the large T antigen were morphologically normal and grew to slightly higher saturation densities in low serum than control cell lines. Unexpectedly, the clones had highly organized actin cables, as did parental 10T1/2 cells infected with wild-type SV40. These observations and comparisons of rat F111 cells infected with either polyomavirus or SV40 suggest that the SV40 small t antigen does not directly affect cytoskeletal organization.     

Characterization of a 54K dalton cellular SV40 tumor antigen present in SV40-transformed cells and uninfected embryonal carcinoma cells.

SV40 infection or transformation of murine cells stimulated the production of a 54K dalton protein that was specifically immunoprecipitated, along with SV40 large T and small t antigens, with sera from mice or hamsters bearing SV40-induced tumors. The same SV40 anti-T sera immunoprecipitated a 54K dalton protein from two different, uninfected murine embryonal carcinoma cell lines. These 54K proteins from SV40-transformed mouse cells and the uninfected embryonal carcinomas cells had identical partial peptide maps which were completely different from the partial peptide map of SV40 large T antigen. An Ad2+ND4-transformed hamster cell line also expressed a 54K protein that was specifically immunoprecipitated by SV40 T sera. The partial peptide maps of the mouse and hamster 54K protein were different, showing the host cell species specificity of these proteins. The 54K hamster protein was also unrelated to the Ad2+ND4 SV40 T antigen. Analogous proteins immunoprecipitated by SV40 T sera, ranging in molecular weight from 44K to 60K, were detected in human and monkey SV40-infected or -transformed cells. A wide variety of sera from hamsters and mice bearing SV40-induced tumors immunoprecipitated the 54K protein of SV40-transformed cells and murine embryonal carcinoma cells. Antibody produced by somatic cell hybrids between a B cell and a myeloma cell (hybridoma) against SV40 large T antigen also immunoprecipitated the 54K protein in virus-infected and -transformed cells, but did not do so in the embryonal carcinoma cell lines. We conclude that SV40 infection or transformation of mouse cells stimulates the synthesis or enhances the stability of a 54K protein. This protein appears to be associated with SV40 T antigen in SV40-infected and -transformed cells, and is co-immunoprecipitated by hybridomas sera to SV40 large T antigen. The 54K protein either shares antigenic determinants with SV40 T antigen or is itself immunogenic when in association with SV40 large T antigen. The protein varies with host cell species, and analogous proteins were observed in hamster, monkey and human cells. The role of this protein in transformation is unclear at present.     

Regulation of simian virus 40 gene expression in Xenopus laevis oocytes.

Expression of the simian virus 40 (SV40) early and late regions was examined in Xenopus laevis oocytes microinjected with viral DNA. In contrast to the situation in monkey cells, both late-strand-specific (L-strand) RNA and early-strand-specific (E-strand) RNA could be detected as early as 2 h after injection. At all time points tested thereafter, L-strand RNA was synthesized in excess over E-strand RNA. Significantly greater quantities of L-strand, relative to E-strand, RNA were detected over a 100-fold range of DNA concentrations injected. Analysis of the subcellular distribution of [35S]methionine-labeled viral proteins revealed that while the majority of the VP-1 and all detectable small t antigen were found in the oocyte cytoplasm, most of the large T antigen was located in the oocyte nucleus. The presence of the large T antigen in the nucleus led us to investigate whether this viral product influences the relative synthesis of late or early RNA in the oocyte as it does in infected monkey cells. Microinjection of either mutant C6 SV40 DNA, which encodes a large T antigen unable to bind specifically to viral regulatory sequences, or deleted viral DNA lacking part of the large T antigen coding sequences yielded ratios of L-strand to E-strand RNA that were similar to those observed with wild-type SV40 DNA. Taken together, these observations suggest that the regulation of SV40 RNA synthesis in X. laevis oocytes occurs by a fundamentally different mechanism than that observed in infected monkey cells. This notion was further supported by the observation that the major 5' ends of L-strand RNA synthesized in oocytes were different from those detected in infected cells. Furthermore, only a subset of those L-strand RNAs were polyadenylated.     

Purification and functional properties of simian virus 40 large and small T antigens overproduced in insect cells.

The insect baculovirus Autographa californica nuclear polyhedrosis virus was used as an expression vector for the simian virus 40 (SV40) small t (t) and large T (T) antigens. Spodoptera frugiperda (SF9) cells infected with recombinant viruses encoding these proteins produced approximately 1 to 2 micrograms of t and up to 30 micrograms of T per 3 X 10(6) cells. The former was highly soluble after Nonidet P-40 extraction of the infected cells, unlike its Escherichia coli-produced counterpart. Both SF9-produced proteins were of authentic size and could be readily immunoprecipitated by specific antibodies. Single-step immunoaffinity chromatography was used to purify the two proteins to near homogeneity, with yields averaging 70% in each case. Experiments to test the biological activity of the baculovirus SV40 proteins showed that SF9 t was capable of associating with two of the cellular proteins reported to bind to t in SV40-infected mammalian cells. Moreover, SF9 T had ATPase activity comparable to that of T produced in monkey cells, exhibited helicase activity and SV40 origin-specific DNA binding, and was active in the SV40 DNA replication assay in vitro. Thus, the SV40 T antigens produced in insect cells can be used in future studies of their biochemical roles in vitro and in vivo.     

The abnormal location of cytoplasmic SV40 large T is not caused by failure to bind to DNA or to p53.

We have examined the large T encoded by an SV40 mutant, d10, which fails to localize to the nucleus. The DNA sequence of the mutant predicts the alteration of Lys 128----Thr within the sequence 127 Lys Lys Lys Arg Lys 131 of large T. The results show that d10 large T is capable of binding to SV40 DNA, to cellular DNA and to the cellular phosphoprotein p53 as well as wild-type large T. These data suggest that the cytoplasmic location of d10 large T is not due to an inability of the protein to be retained within the nucleus, but argues instead that the protein fails to reach the nucleus because it contains a defective nuclear location signal.     

Changes in gene expression and protein phosphorylation in murine cells, transformed or abortively infected with wild type and mutant simian virus 40

The mechanism of SV40-induced cellular transformation was investigated by two-dimensional gel analysis of 35S- and 32P-labeled proteins of various cells. These included rat and mouse cells, either transformed or abortively infected by SV40 wild type, small t deletion mutants, and a large T temperature-sensitive mutant. Synthesis, turnover, or (de)phosphorylation of multiple protein spots was found to be reproducibly and quantitatively influenced by the transformed and/or infected status. Several of these alterations were attributable to the biological activity of either large T or small t antigen. Most changes in 35S-labeled proteins corresponded to a decreased intensity of the gel spots in transformed cells, while hyperphosphorylated proteins were more common than hypophosphorylated ones. About half of the polypeptide alterations in 35S-and 32P-labeled SV40-transformed rat cells, including a set of 35S-labeled small t-dependent changes were shared by Rous sarcoma virus-transformed cells. In contrast, small t-dependent (de)phosphorylation was rarely detected. Phosphoamino acid analysis of selected phosphoprotein spots of rat cells and alkaline hydrolysis of whole two-dimensional gels did not reveal any evidence for increased tyrosine-specific phosphorylation after SV40-induced transformation. Abortively infected mouse cells showed many protein alterations, also observed in stably transformed cells. However, the latter cells contained additional changes, also affecting several phosphoproteins and possibly related to the establishment of transformation. These findings are discussed in relation to the biological functions, known or presumed, for SV40 large T and small t antigens during transformation.     

Cyclic AMP specifically blocks proliferation of rat 3T3 cells transformed by polyomavirus.

Elevated exogenous and intracellular levels of cyclic AMP could totally block proliferation of polyomavirus (PyV) transformants derived from rat 3T3 cells without affecting proliferation of normal cells or simian virus 40 (SV40)-induced transformants. Concanavalin A (ConA) had the opposite effect; it could totally block proliferation of both normal cells and SV40 transformants but reduced proliferation of PyV transformants only twofold. Adenylate cyclase was threefold less active in membranes of PyV transformants, and the number of ConA receptors was similar to that of normal cells. Proliferating PyV transformants contained threefold less cyclic AMP than did proliferating SV40 transformants. The sensitivity to cyclic AMP did not correlate with the degree of transformation: cells transformed by Rous sarcoma virus and tumor cells derived from SV40 transformants were not sensitive to cyclic AMP. The differential effect of cyclic AMP and ConA on proliferation was probably due to the activity of an intact middle t protein. The presence of both large T and small t together with middle t was also required for cyclic AMP sensitivity.