Evidence for free and metabolically stable p53 protein in nuclear subfractions of simian virus 40-transformed cells.

To determine functional subcellular loci of p53, a cellular protein associated with cellular transformation, we analyzed the nucleoplasmic, chromatin, and nuclear matrix fractions from normal mouse 3T3 cells, from methylcholanthren-transformed mouse (MethA) cells, and from various simian virus 40 (SV40)-transformed cells for the presence of p53. In 3T3 and MethA cells, p53 was present in all nuclear subfractions, suggesting an association of p53 with different structural components of the nucleus. In 3T3 cells, p53 was rapidly turned over, whereas in MethA cells, p53 was metabolically stable. In SV40-transformed cells, p53 complexed to large tumor antigen (large T) was found in the nucleoplasmic and nuclear matrix fractions, as described previously (M. Staufenbiel and W. Deppert, Cell 33:173-181, 1983). In addition, however, metabolically stable p53 not complexed to large T (free p53) was also found in the chromatin and nuclear matrix fractions of these cells. This free p53 did not arise by dissociation of large T-p53 complexes, suggesting that stabilization of p53 in SV40-transformed cells can also occur by means other than formation of a complex with large T.     

Structural prerequisites of simian virus 40 large T antigen for the maintenance of cell transformation.

We have investigated the functional roles of two structural subsets of simian virus 40 (SV40) large T antigen, namely homo-oligomers and complexes with the host cellular p53 protein, for the transformed phenotype. We examined T antigen produced in cells transformed by temperature-sensitive SV40 large T mutants: heat-sensitive or unrestricted SV40 tsA58-transformed rat cells and unrestricted tsA1499 transformants. In both unrestricted cell lines, T antigen was temperature-sensitive only for the formation of fast sedimenting homo-oligomers. Corresponding to our recent observations obtained with tsA1499-infected monkey cells, in tsA1499 transformants large T was competent to form stable T-p53 complexes independently of the temperature. However, T antigen coded for by tsA58, which is heat-sensitive for binding to p53, occurred in stable complexes with this protein in unrestricted tsA58 transformants under all conditions. Furthermore, in both unrestricted transformants T-p53 complexes arise in the absence of homo-oligomers of T antigen. In conclusion, T antigen homo-oligomers are not involved in cell transformation, whereas T-p53 complexes may be involved in the maintenance of this phenotype.     

Interactions between SV40 T antigen and DNA polymerase alpha

Simian virus 40 large T antigen is the only viral protein required for SV40 DNA synthesis in vivo and in vitro. This complex protein recruits the cellular DNA replication apparatus to the SV40 origin and provides a good model for the initiation of cellular DNA replication. The interaction between SV40 large T antigen (TAg) and DNA polymerase alpha has been shown previously to be inhibited by murine p53, the nuclear protein product of a cellular anti-oncogene. The murine p53 protein will inhibit SV40 replication both in vivo and in vitro. Using monoclonal antibodies to TAg, p53, and polymerase alpha, we developed immunoassays to measure the complexes formed between TAg and polymerase alpha and between TAg and p53. The assays allowed us to detect the TAg-polymerase alpha and TAg-p53 complexes in lytically infected and transformed cells. The amount of TAg complexed to p53 was far lower in infected cells than in transformed cells. We used a large range of monoclonal antibodies to different sites on T antigen and found that antibodies that inhibited the formation of the TAg-polymerase alpha complex also inhibited the formation of the TAg-p53 complex. Finally, we found that the tsA58 and 5080 point mutations in TAg, previously shown to inhibit the binding of TAg to p53, also inhibit its binding to polymerase alpha. Together these results emphasize the specificity and functional importance of the TAg-polymerase alpha complex. The disruption of this interaction by the cellular anti-oncogene p53 provides an interesting model for the normal action of p53 and the effects of its removal on the regulation of cellular DNA synthesis.     

MDM2 is a target of simian virus 40 in cellular transformation and during lytic infection.

Phosphopeptide analyses of the simian virus 40 (SV40) large tumor antigen (LT) in SV40-transformed rat cells, as well as in SV40 lytically infected monkey cells, showed that gel-purified LT that was not complexed to p53 (free LT) and p53-complexed LT differed substantially in their phosphorylation patterns. Most significantly, p53-complexed LT contained phosphopeptides not found in free LT. We show that these additional phosphopeptides were derived from MDM2, a cellular antagonist of p53, which coprecipitated with the p53-LT complexes, probably in a trimeric LT-p53-MDM2 complex. MDM2 also quantitatively bound the free p53 in SV40-transformed cells. Free LT, in contrast, was not found in complex with MDM2, indicating a specific targeting of the MDM2 protein by SV40. This specificity is underscored by significantly different phosphorylation patterns of the MDM2 proteins in normal and SV40-transformed cells. Furthermore, the MDM2 protein, like p53, becomes metabolically stabilized in SV40-transformed cells. This suggests the possibility that the specific targeting of MDM2 by SV40 is aimed at preventing MDM2-directed proteasomal degradation of p53 in SV40-infected and -transformed cells, thereby leading to metabolic stabilization of p53 in these cells.     

Identification of the p53 protein domain involved in formation of the simian virus 40 large T-antigen-p53 protein complex.

An expression vector utilizing the enhancer and promoter region of the simian virus 40 (SV40) DNA regulating a murine p53 cDNA clone was constructed. The vector produced murine p53 protein in monkey cells identified by five different monoclonal antibodies, three of which were specific for the murine form of p53. The murine p53 produced in monkey cells formed an oligomeric protein complex with the SV40 large tumor antigen. A large number of deletion mutations, in-frame linker insertion mutations, and linker insertion mutations resulting in a frameshift mutation were constructed in the cDNA coding portion of the p53 protein expression vector. The wild-type and mutant p53 cDNA vectors were expressed in monkey cells producing the SV40 large T antigen. The conformation and levels of p53 protein and its ability to form protein complexes with the SV40 T antigen were determined by using five different monoclonal antibodies with quite distinct epitope recognition sites. Insertion mutations between amino acid residues 123 and 215 (of a total of 390 amino acids) eliminated the ability of murine p53 to bind to the SV40 large T antigen. Deletion (at amino acids 11 through 33) and insertion mutations (amino acids 222 through 344) located on either side of this T-antigen-binding protein domain produced a murine p53 protein that bound to the SV40 large T antigen. The same five insertion mutations that failed to bind with the SV40 large T antigen also failed to react with a specific monoclonal antibody, PAb246. In contrast, six additional deletion and insertion mutations that produced p53 protein that did bind with T antigen were each recognized by PAb246. The proposed epitope for PAb246 has been mapped adjacent (amino acids 88 through 109) to the T-antigen-binding domain (amino acids 123 through 215) localized by the mutations mapped in this study. Finally, some insertion mutations that produced a protein that failed to bind to the SV40 T antigen appeared to have an enhanced ability to complex with a 68-kilodalton cellular protein in monkey cells.     

Simian virus 40 large T antigen induces or activates a protein kinase which phosphorylates the transformation-associated protein p53.

The cellular phosphoprotein p53 is presumably involved in simian virus 40 (SV40)-induced transformation. We have monitored changes in the state of phosphorylation of p53 from normal versus SV40-infected or -transformed cells. In normal cells, p 53 was hardly phosphorylated. Upon infection or transformation, a quantitative and qualitative increase in p53 phosphorylation was observed as revealed by two-dimensional phosphopeptide analysis. This increase was dependent on a functional large T antigen. In rat cells, enhanced phosphorylation of p53 resulted in conversion to a second, electrophoretically distinct form. In cells transformed with transformation-defective mutants, phosphorylation of p53 was reduced and conversion to form 2 was inefficient. These data suggest (i) that SV40 large T antigen induces or activates a protein kinase, one substrate of which is p53, (ii) that transformation-defective mutants are impaired in kinase induction, and (iii) that either a certain phosphorylation state of p53 or the SV40-induced kinase is critical for efficient transformation.     

Monoclonal antibodies displaying a novel species specificity for the primate transformation-related protein, p53

SV40 large T antigen associates with a cellular phosphoprotein, p53, in virus-transformed cells. We have raised three new monoclonal antibodies, PAb1101, PAb1102 and PAb1103, to this cellular protein, derived from SV40-transformed human fibroblasts. These define at least two non-overlapping determinants on human p53 that are in different areas of the molecule from those recognised by previously available antibodies. Unlike those antibodies, PAb1102 and PAb1103 do not react with rodent p53. PAb1101 reacts far more weakly with rodent p53 than with primate p53. All three antibodies show a preference for binding to the large T-associated form of p53, an effect that is particularly marked with PAb1102. The novel specificity of these antibodies allows further probing of the nature and function of the large T/p53 complex in human cells.     

Modulation of p53 protein expression during cellular transformation with simian virus 40.

We analyzed the relation of metabolic stabilization of the p53 protein during cellular transformation by simian virus 40 (SV40) to (i) expression of the transformed phenotype and (ii) expression of the large tumor antigen (large T). Analysis of SV40-tsA28-mutant-transformed rat cells (tsA28.3 cells) showed that both p53 complexed to large T and free p53 (W. Deppert and M. Haug, Mol. Cell. Biol. 6:2233-2240, 1986) were metabolically stable when the cells were cultured at 32 degrees C and expressed large T and the transformed phenotype. At the nonpermissive temperature (39 degrees C), large-T expression is shut off in these cells and they revert to the normal phenotype. In such cells, p53 was metabolically unstable, like p53 in untransformed cells. To determine whether metabolic stabilization of p53 is directly controlled by large T, we next analyzed the metabolic stability of complexed and free p53 in SV40 abortively infected normal BALB/c mouse 3T3 cells. We found that neither p53 in complex with large T nor free p53 was metabolically stable. However, both forms of p53 were stabilized in SV40-transformed cells which had been developed in parallel from SV40 abortively infected cultures. Our results indicate that neither formation of a complex of p53 with large T nor large-T expression as such is sufficient for a significant metabolic stabilization of p53. Therefore, we suggest that metabolic stabilization of p53 during cellular transformation with SV40 is mediated by a cellular process and probably is the consequence of the large-T-induced transformed phenotype.     

Complex formation of simian virus 40 large T antigen with cellular protein p53

We investigated the formation of native complexes between simian virus 40 large T antigen and the cellular protein p53 (T-p53) by using simian virus 40 tsA58-transformed mouse fibroblasts (tsA58 F2b). We observed that newly synthesized p53 bound to all structural subclasses of large T antigen detectable on sucrose density gradients. This led to various intermediates of T-p53 complexes which converted within 2 h into typical mature aggregates. The final levels of stable T-p53 complexes seemed to be determined by p53 rather than by large T antigen.     

Excess wild-type p53 blocks initiation and maintenance of simian virus 40 transformation.

Wild-type (wt) murine p53 has been tested for its ability to block and reverse the transforming effects of simian virus 40 (SV40) large T antigen. Established and precrisis mouse cells overexpressing exogenously introduced wt p53 became resistant to SV40 transformation. The introduction of excess wt p53 into SV40-transformed precrisis cells reverted their transformed phenotype. However, the phenotype of SV40-transformed established cells was not reverted by excess wt p53. We conclude that an antioncogenic action of wt p53 is exerted during SV40 transformation and that in precrisis cells, the antitransforming action of wt p53 can be exerted both at initiation and during the maintenance of transformation.     

cis-active elements from mouse chromosomal DNA suppress simian virus 40 DNA replication.

Simian virus 40 (SV40)-containing DNA was rescued after the fusion of SV40-transformed VLM cells with permissive COS1 monkey cells and cloned, and prototype plasmid clones were characterized. A 2-kilobase mouse DNA fragment fused with the rescued SV40 DNA, and derived from mouse DNA flanking the single insert of SV40 DNA in VLM cells, was sequenced. Insertion of the intact rescued mouse sequence, or two nonoverlapping fragments of it, into wild-type SV40 plasmid DNA suppressed replication of the plasmid in TC7 monkey cells, although the plasmids expressed replication-competent T antigen. Rat cells were transformed with linearized wild-type SV40 plasmid DNA with or without fragments of the mouse DNA in cis. Although all of the rat cell lines expressed approximately equal amounts of T antigen and p53, transformants carrying SV40 DNA linked to either of the same two replication suppressor fragments produced significantly less free SV40 DNA after fusion with permissive cells than those transformed by SV40 DNA without a cellular insert or with a cellular insert lacking suppressor activity. The results suggest that two independent segments of cellular DNA act in cis to suppress SV40 replication in vivo, either as a plasmid or integrated in chromosomal DNA.     

Analysis of a large-T-antigen variant expressed in simian virus 40-transformed mouse cell line mKS-A.

Earlier reports had suggested that the large T antigen expressed in simian virus 40 (SV40)-transformed mKS-A cells may be replication defective. Our experiments support these earlier observations showing that the mKS-A T antigen has a reduced DNA-unwinding activity in vitro. To investigate the molecular basis for this defect, we have isolated from an mKS-A genomic library an EMBL-3 bacteriophage clone carrying in its insert a full-length SV40 DNA element that most likely encodes the expressed T-antigen variant. DNA sequencing revealed only one nonconservative amino acid exchange, Asp to Asn at residue 636. Surprisingly, when a plasmid clone carrying the mKS-A T-antigen-coding sequence was transfected into monkey cells, we found that it replicated quite efficiently, probably suggesting that a high nuclear concentration of the variant T-antigen form compensates for the partial biochemical defect. However, a high nuclear concentration of T antigen was also found in mKS-A T-antigen-transformed mouse cells, yet a fusion of these cells to permissive monkey cells failed to induce in situ replication and excision of integrated SV40 DNA. We discuss possible reasons for the different behavior of T antigen in monkey cells and in mouse cells and suggest that one possibility for the replication-negative phenotype in transformed cells may be related to the fact that T antigen forms a tight complex with the cellular p53 protein in mouse cells but not in monkey cells.     

Study of the Functional Activities Concomitantly Retained by the 115,000 Mr Super T Antigen, an Evolutionary Variant of Simian Virus 40 Large T Antigen Expressed in Transformed Rat Cells

Simian virus 40 (SV40) transformed V 11 F 1 clone 1 subclone 7 rat cells (subclone 7) do not synthesize normal-size large T antigen (M(r), 90,000); instead, they produce a 115,000 M(r) super T antigen (115K super T antigen). This super T antigen is SV40 virus coded, and its synthesis results from rearrangement and amplification of integrated viral DNA sequences in subclone 7 (May et al., Nucleic Acids Res. 9:4111-4128, 1981). In this study the functional activities of 115K super T antigen were compared with the functional activities of SV40 large T antigen. Transfection experiments were performed with (i) cosmid SVE 5 Kb and plasmid pSVsT, both containing the super T antigen gene and (ii) plasmids pSV1 and pSV40, both containing the large T antigen gene. Transfection of pSVsT DNA or SVE 5 Kb DNA into secondary cultures of rat kidney cells induced the formation of transformed cell foci with an efficiency that was about 50% of the efficiency of pSV1 DNA or pSV40 DNA. Concomitant with the transforming activity, two other activities were also retained by super T antigen, namely, the ability to enhance the level of host cellular protein p53 and the capacity to bind to p53. In contrast, pSVsT and SVE 5 Kb DNAs were markedly deficient in the capacity to support tsA58 DNA replication in CV1-P cells at a nonpermissive temperature (41 degrees C), as shown by cotransfection experiments. The yield of virus produced in these experiments was 400-fold less than the yield obtained in parallel experiments with pSV40 or pSV1. However, SVE 5 Kb and pSVsT have a functional SV40 replication origin, as shown by their efficient replication in COS 1 cells which provided functional large T antigen. Super T antigen also possesses a specific affinity for sequences of SV40 viral origin. Our results suggest that under certain conditions, evolutionary changes in T antigen take place and that these changes could be restricted to the phenotypic requirement of maintaining a structure that is able to induce cell transformation, to form a complex with p53, and to enhance the cellular level of p53. Therefore, there appears to be a close relationship among the activities of T antigen involved in transforming cells, in binding to p53, and in enhancing the p53 cellular level. Moreover, this set of activities appears to be separable from the replicative ability of T antigen, based on the observation that 115K super T antigen is markedly defective for initiating viral DNA synthesis.     

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.     

Simian virus 40 can overcome the antiproliferative effect of wild-type p53 in the absence of stable large T antigen-p53 binding.

In simian virus 40 (SV40)-transformed cells, a tight complex is formed between the viral large T antigen (large T) and p53. It has been proposed that this complex interferes with the antiproliferative activity of p53. This notion was tested in primary rat fibroblasts by assessing the ability of SV40-mediated transformation to be spared from the inhibitory effect of wild-type (wt) p53. The data indicate that relative to transformation induced by myc plus ras, SV40-plus-ras-mediated focus formation was indeed much less suppressed by p53 plasmids. A majority of the resultant cell lines made a p53 protein with properties characteristic of a wt conformation. Furthermore, cell lines expressing stably both SV40 large T and a temperature-sensitive p53 mutant continued to proliferate at a temperature at which this p53 assumes wt-like properties and normally causes a growth arrest. Surprisingly, at least partial resistance to the growth-inhibitory effect of wt p53 was also evident when transformation was mediated by an SV40 deletion mutant, encoding a large T which does not bind p53 detectably. In addition to supporting the idea that SV40 can overcome the growth-restrictive activity of wt p53, these findings strongly suggest that at least part of this effect does not require a stable association between p53 and large T.     

Primate's p53 inhibits SV40 DNA replication in vitro

Previous reports indicated that rodent p53 inhibits simian virus 40 (SV40) DNA replication in vitro as well as in vivo while that from primate cells does not (1-4). Here we report the evidence that p53 of primate origin also inhibits SV40 DNA replication in vitro. p53-SV40 large tumor antigen (T antigen) complex purified from SV40 infected COS-1 cells had little replication activity and inhibited SV40 DNA replication in vitro. These results suggest that inhibition of SV40 DNA replication by p53 should be regarded as general property of the protein and does not determine the mode of species specific replication of SV40 DNA.     

Relationship of phosphorylation to the oligomerization of SV40 T antigen and its association with p53

The potential significance of the phosphorylation of SV40 large T antigen for oligomers and complexes with the cellular protein p53 was investigated. We observed that T antigen oligomers remain stable after enzymatic dephosphorylation by alkaline phosphatase up to 80%. Separate analysis of free and p53-bound T antigen revealed a considerably lower phosphorylation of the p53-bound subclass. Therefore, a simple correlation between the overall phosphorylation of T antigen and the formation of oligomers and T-p53 complexes is highly unlikely.     

Wild-type p53 is not a negative regulator of simian virus 40 DNA replication in infected monkey cells.

To analyze the proposed growth-inhibitory function of wild-type p53, we compared simian virus 40 (SV40) DNA replication in primary rhesus monkey kidney (PRK) cells, which express wild-type p53, and in the established rhesus monkey kidney cell line LLC-MK2, which expresses a mutated p53 that does not complex with large T antigen. SV40 DNA replication proceeded identically in both cell types during the course of infection. Endogenously expressed wild-type p53 thus does not negatively modulate SV40 DNA replication in vivo. We suggest that inhibition of SV40 DNA replication by wild-type p53 in in vitro replication assays is due to grossly elevated ratios of p53 to large T antigen, thus depleting the replication-competent free large T antigen in the assay mixtures by complex formation. In contrast, the ratio of p53 to large T antigen in in vivo replication is low, leaving the majority of large T antigen in a free, replication-competent state.     

N18-RE-105 cells: differentiation and activation of p53 in response to glutamate and adriamycin is blocked by SV40 large T antigen tsA58

Process extension was induced in cells of the N18-RE-105 neuroblastoma-retinal hybrid line by toxic agents, including glutamate and the p53-inducing anticancer agents adriamycin and etoposide. Both adriamycin and glutamate activated p53 as measured by a plasmid transfection assay. It was therefore hypothesized that SV40 large T antigen, which binds p53, would interfere with cellular differentiation. To test this hypothesis, the temperature-sensitive form of SV40 large T was transduced into N18-RE-105 cells by retroviral infection. SV40 large T-infected cells became de-differentiated, grew in tightly-packed colonies, lost expression of neurofilament, and lost the ability to differentiate in response to glutamate and adriamycin. The de-differentiating effect of SV40 large T antigen may be due to binding and inactivation of cellular proteins, such as p53, p107, p130, p300, and retinoblastoma protein, which are important in cellular growth and differentiation. It is suggested that p53 may play a role in cellular differentiation, perhaps under unusual circumstances involving stress or cytotoxicity. Received: 29 April 1997 / Accepted: 18 June 1997