Emergence of virus escape mutants after immunization with epitope vaccine

BALB/c and C57BL/6J mice were immunized with recombinant vaccines consisting of lymphocytic choriomeningitis virus CD8+ T-lymphocyte epitopes and a carrier protein. During challenge infection with WE strain lymphocytic choriomeningitis virus, mutants with alterations in distinct amino acid residues of the epitopic nonapeptides appeared and multiplied. Splenocytes from WE-infected BALB/c mice lysed cells coated with the WE-type epitope; lysis was considerably less effective when the epitopic nonapeptide with which the syngeneic cells had been sensitized was the mutated form. Neither target was lysed by splenocytes from BALB/c mice infected with the variant virus. Mutants were not detected in F1 hybrid mice immunized with two viral epitopes that were restricted by class I molecules of both parents.

Species- and tissue-specific expression of the C-terminal alternatively spliced form of the tumor suppressor p53

Alternative splicing of the p53 transcript which so far has been demonstrated only in the murine system has been proposed as a general regulatory mechanism for the generation of functionally different p53 proteins. We analyzed by RT-PCR the pattern of p53 mRNAs within the region spanning exons 10 and 11 of the p53 gene in 13 different tissues from two independent mouse strains, in 10 different rat tissues and in six different human tissues. PCR products of the expected sizes, corresponding to the normally spliced and the alternatively spliced p53 mRNAs, were detected in mice. Alternatively spliced mRNA was found at approximately 25-20% the level of the normally spliced p53 mRNA in most tissues analyzed. In spleen and kidney the proportion of alternatively spliced p53 mRNA was much lower. Surprisingly, examination of p53 mRNAs isolated from 10 different rat tissues and six human tissues within the same region of the p53 gene showed only products of normal size. Although a potential homologous alternative 3' splice site within intron 10 of the human p53 gene is present in the genomic sequence of human p53, the expected corresponding alternatively spliced p53 mRNA was undetectable. These findings imply that the generation of functionally different forms of p53 by alternative splicing of p53 transcripts is a species-specific event, possibly indicating species-specific mechanisms for regulating p53 activities.

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.

Negative feedback regulation of wild-type p53 biosynthesis

When growth-arrested mouse fibroblasts re-entered the cell-cycle, the rise in tumour suppressor p53 mRNA level markedly preceded the rise in expression of the p53 protein. Furthermore, gamma-irradiation of such cells led to a rapid increase in p53 protein biosynthesis even in the presence of the transcription inhibitor actinomycin D. Both findings strongly suggest that p53 biosynthesis in these cells is regulated at the translational level. We present evidence for an autoregulatory control of p53 expression by a negative feed-back loop: p53 mRNA has a predicted tendency to form a stable stem-loop structure that involves the 5'-untranslated region (5'-UTR) plus some 280 nucleotides of the coding sequence. p53 binds tightly to the 5'-UTR region and inhibits the translation of its own mRNA, most likely mediated by the p53-intrinsic RNA re-annealing activity. The inhibition of p53 biosynthesis requires wild-type p53, as it is not observed with MethA mutant p53, p53-catalysed translational inhibition is selective; it might be restricted to p53 mRNA and a few other mRNAs that are able to form extensive stem-loop structures. Release from negative feed-back regulation of p53 biosynthesis, e.g. after damage-induced nuclear transport of p53, might provide a means for rapidly increasing p53 protein levels when p53 is required to act as a cell-cycle checkpoint determinant after DNA damage.

Cell-specific transcriptional activation of the mdm2-gene by ectopically expressed wild-type form of a temperature-sensitive mutant p53

The temperature-sensitive mutant p53 tsp53val135 (tsp53) displays a mutant phenotype at 38 degrees C, but assumes properties of a wild-type (wt) p53 at 32 degrees C. We analysed the cellular responses of two cell lines which ectopically overexpress tsp53, and dramatically differ in their responses to tsp53 expressed at 32 degrees C. Clone 6 (cl6) cells [precrisis rat embryo fibroblasts transformed by tsp53val135 and an activated ras oncogene at 38 degrees C (Michalovitz et al., 1990. Cell 62, 671-680) stop to grow and arrest mainly in the G1 phase of the cell cycle, whereas MethAp53ts cells [BALB/c mouse MethA tumor cells, transfected with the same tsp53 encoding vector as cl6 cells (Otto and Deppert, 1993. Oncogene 8, 2591-2603)] do not growth arrest at 32 degrees C. Both cell lines expressed similar amounts of tsp53, which was mainly cytoplasmic at 38 degrees C and mainly nuclear at 32 degrees C. At 32 degrees C, both cell lines contained similar amounts of waf1/cip1 mRNA. However, the amount of mdm2 mRNA in MethAp53ts cells was considerably higher compared to that in cl6 cells. The different transcriptional regulation of the mdm2-gene in cl6 and MethAp53ts cells at 32 degrees C indicated that the tsp53 proteins in these cells were functionally different. This assumption was supported by our finding that at 32 degrees C phosphorylation of the tsp53 in these cells was markedly different. We conclude that the cellular environment is an important determinant of p53 function.

Antiviral protective immunity induced by major histocompatibility complex class I molecule-restricted viral T-lymphocyte epitopes inserted in various positions in immunologically self and nonself proteins

Injection into mice of chimeric proteins consisting of a portion of either the simian virus 40 large tumor antigen or nonstructural protein 1 of influenza A virus or of the murine tumor suppressor p53 on one hand and T-cell epitopes of lymphocytic choriomeningitis virus on the other resulted in antiviral protective immunity, which was independent of the epitopes' position in the protein and the same whether the latter was immunologically nonself or self. Mice of different haplotypes were protected when the corresponding class I molecule-restricted epitopes had been inserted close to each other in one carrier protein.

Suppression of tumorigenicity of breast cancer cells by transfer of human chromosome 17 does not require transferred BRCA1 and p53 genes

A number of candidate tumor suppressor genes located on the human chromosome 17 are thought to have a role to play in the development of breast cancer. In addition to the p53 gene on 17p13.1 and the BRCA1 gene mapped to 17q12-21, other chromosomal regions for tumor suppressor genes have been suggested to exist on 17p13.3 and both the central and the distal parts of 17q, although definitive functional proof of their involvement in breast cancer tumorigenesis is still lacking. In this report we show that microcell transfer of a human chromosome 17 into wild-type p53 breast cancer cells CAL51 results in loss of tumorigenicity and anchorage-independent growth, changes in cell morphology and a reduction of cell growth rates of the neo-selected microcell hybrids. In the hybrid cells, which express the p53 wild-type protein, only the p- and the distal parts of the q arm of donor chromosome 17 are transferred. Thus, our results provide functional evidence for the presence of one or more tumor suppressor gene(s) on chromosome 17, which are distinct from the p53 and the BRCA1 genes.

p53 and mdm2 are expressed independently during cellular proliferation

We analysed p53 expression during proliferation of serum stimulated Swiss mouse 3T3 cells and of concanavalin A stimulated mouse spleen lymphocytes and correlated it to rate of DNA synthesis and to expression of PCNA. We also analysed mdm2 gene expression, as rising p53 levels during proliferation might require MDM2 protein expression to functionally antagonize p53 mediated growth inhibition. p53 protein synthesis closely paralleled DNA synthesis and PCNA expression, suggesting a direct involvement of p53 in cellular DNA synthesis. mdm2 expression in 3T3 cells could not be correlated with p53 expression and DNA synthesis and was not detected at all in stimulated lymphocytes. We conclude that p53 and mdm2 expression during proliferation are not functionally related and that mdm2 expression is not required for proliferation.

CD8+ T lymphocyte-mediated antiviral immunity in mice as a result of injection of recombinant viral proteins

A major portion of the nucleoprotein (amino acids 67 through 300) and the glycoprotein-2 of lymphocytic choriomeningitis (LCM) virus were synthesized by using recombinant technology and were injected together with SDS twice in portions of 5 micrograms into BALB/c mice. As evidenced by diminished replication of LCM challenge virus, both proteins induced antiviral immunity, which was comparable in extent with the immunity caused by infection with LCM vaccinia recombinant viruses. Primed LCM-viral CTLs could not be demonstrated in these mice by culturing splenocytes in the presence of LCM virus, and Abs appeared slowly and in low quantities; but, after injection of large infectious doses, CTLs appeared faster and in higher numbers than in mice not previously treated with viral proteins. Depletion of CD8+ cells, but not of CD4+ cells, by treatment of mice with mAb abolished the antiviral immunity, demonstrating that protection was mediated by CD8+ T lymphocytes. Absence of CD4+ T lymphocytes before and during the period of immunization did not measurably affect the animals' antiviral immune status, indicating that activation of the CD8+ T lymphocytes was not dependent on help by CD4+ cells.

CD8+ T lymphocyte-mediated antiviral immunity in mice as a result of injection of recombinant viral proteins

A major portion of the nucleoprotein (amino acids 67 through 300) and the glycoprotein-2 of lymphocytic choriomeningitis (LCM) virus were synthesized by using recombinant technology and were injected together with SDS twice in portions of 5 micrograms into BALB/c mice. As evidenced by diminished replication of LCM challenge virus, both proteins induced antiviral immunity, which was comparable in extent with the immunity caused by infection with LCM vaccinia recombinant viruses. Primed LCM-viral CTLs could not be demonstrated in these mice by culturing splenocytes in the presence of LCM virus, and Abs appeared slowly and in low quantities; but, after injection of large infectious doses, CTLs appeared faster and in higher numbers than in mice not previously treated with viral proteins. Depletion of CD8+ cells, but not of CD4+ cells, by treatment of mice with mAb abolished the antiviral immunity, demonstrating that protection was mediated by CD8+ T lymphocytes. Absence of CD4+ T lymphocytes before and during the period of immunization did not measurably affect the animals' antiviral immune status, indicating that activation of the CD8+ T lymphocytes was not dependent on help by CD4+ cells.

Immortalization of BALB/c mouse embryo fibroblasts alters SV40 large T-antigen interactions with the tumor suppressor p53 and results in a reduced SV40 transformation-efficiency

In order to analyse the immortalizing and transforming potential of simian virus 40 (SV40), we compared the transformation efficiencies of SV40 in primary and in established BALB/c mouse fibroblasts. Five independently isolated clones of freshly immortalized normal fibroblasts (FTE cells) were established from precrisis BALB/c mouse embryo fibroblasts (pMEF cells) according to the protocol for establishing 3T3 cells (Todaro & Green, 1963). These cells expressed a wild-type p53 and were indistinguishable in all parameters analysed from original 3T3 cells kept in our laboratory. Using abortive infection to control gene dosage, followed by selection of transformed cells by cloning in soft agar, SV40 was able to transform primary cells with a much higher efficiency than 3T3 or FTE cells. Analysis of this unexpected result revealed that the different transformation efficiencies of SV40 in primary and established cells correlated with an altered cellular response to SV40 infection regarding metabolic stabilization of p53 complexed to large T during abortive infection. Whereas p53 in pMEF cells became stabilized upon abortive infection with SV40, p53 in 3T3 and FTE cells remained unstable. Our results strongly favour the hypothesis that metabolic stabilization and the ensuing higher levels of p53 in abortively infected cells enhance the transforming competence of large T.

The yin and yang of p53 in cellular proliferation

The tumor suppressor p53 is a key element in preserving the stability of the genetic information of vertebrates. In response to DNA damage, PSS induces a growth arrest thus allowing time for DNA repair to occur. However, p53 seems to exert additional functions in cellular proliferation, amongst them a so far unidentified role in the progression of cells through the cell cycle and in differentiation processes. Modulation of p53 activities, by regulating p53 interactions with different target genes and cellular protein partners through the cellular environment might explain the diversity of p53 functions in cellular growth control.

Stabilization of the tumor suppressor p53 during cellular transformation by simian virus 40: influence of viral and cellular factors and biological consequences

To understand the process and biological significance of metabolic stabilization of p53 during simian virus 40 (SV40)-induced cellular transformation, we analyzed cellular and viral parameters involved in this process. We demonstrate that neither large T expression as such nor the cellular phenotype (normal versus transformed) markedly influence the stability of p53 complexed to large T in SV40 abortively infected BALB/c mouse fibroblasts. In contrast, metabolic stabilization of p53 is an active cellular event, specifically induced by SV40. The ability of SV40 to induce a cellular response leading to stabilization of p53 complexed to large T is independent from the cellular phenotype and greatly varies between different cells. However, metabolic stability was conferred only to p53 in complex with large T, whereas the free p53 in these cells remained metabolically unstable. Comparative analyses of cellular transformation in various cells differing in stability of p53 complexed to large T upon abortive infection with SV40 revealed a strong correlation between the ability of SV40 to induce metabolic stabilization and its transformation efficiency. Our data suggest that metabolic stabilization and the ensuing enhanced levels of p53 are important for initiation and/or maintenance of SV40 transformation.

Independent expression of the transforming amino-terminal domain of SV40 large I antigen from an alternatively spliced third SV40 early mRNA

We found that simian virus 40 (SV40), in addition to the SV40 early proteins large T antigen (large T) and small antigen (small t), codes for a third early protein with a molecular weight of 17 kDa. This protein (17kT) is expressed from an alternatively spliced third SV40 early mRNA, using a splice donor site at position 4425 and a splice acceptor site at position 3679 of the SV40 genome. The 17kT protein consists of 135 amino acids. Of these, 131 correspond to the amino-terminus of large T, while the four carboxy-terminal amino acids are unique and encoded by a different reading frame. 17kT mRNA, and the corresponding protein, were found in all SV40 transformed cells analyzed, as well as in SV40 infected cells. Transfection of a cDNA expression vector encoding the 17kT protein into rat F111 fibroblasts induced phenotypic transformation of these cells. The expression of the transforming amino-terminal domain of large T as an independent 17kT protein might provide a means for individually regulating the various functions associated with this domain.

Upregulation of mdm-2 expression in Meth A tumor cells tolerating wild-type p53

Overexpression of mouse wild-type p53 (wt p53) in mouse Meth A tumor cells after transfection of wt p53 encoding vectors induced a strong growth-inhibitory response. Cells of only few of randomly selected surviving colonies contained and expressed the transfected wt p53 specific DNA. Despite expressing authentic wt p53, such cells (MethAp53wt) exhibited a similar phenotype as the parental Meth A cells. These cells overexpressed the mdm-2 (mouse double minute-2) gene, both at the RNA and at the protein level. Recently, the MDM-2 protein has been identified as a cellular target of p53, which can abolish its tumor suppressor activity. We, therefore, suggest that MDM-2 has mitigated the growth-inhibitory effect of wt p53 in MethAp53wt cells. Upregulation of mdm-2 expression in MethAp53wt cells was mediated by wt p53, as analysis of Meth A cells carrying a tsp53 (p53Val135) revealed a strict dependence of mdm-2 upregulation upon wt p53 expression. Our results propose that a balanced ratio of MDM-2 and p53 will allow cells to tolerate a limited expression of wt p53. This tolerance is not mediated by a direct inactivation of wt p53 via complex formation with MDM-2, as the majority of both MDM-2 and wt p53 in MethAp53wt cells was not complexed to each other.

Immunization of mice with the N-terminal (1-272) fragment of simian virus 40 large T antigen (without adjuvants) specifically primes cytotoxic T lymphocytes

Immunization of C57BL/6 (B6) mice (H-2b) with the "large tumor antigen" (T-Ag) of simian virus 40 (SV40) in its soluble form without adjuvants primed CD8+ cytotoxic T lymphocytes (CTL) in vivo. CD8+ CTL primed in vivo by this non-structural 708-amino acid (aa) viral protein, and specifically restimulated in vitro, lysed H-2b target cells, either transfected with an SV40 T-Ag-encoding vector, or transformed by SV40 infection. H-2b RMA-S transfectants expressing the complete 708 aa T-Ag (which fail to transport peptides through the endoplasmic reticulum membranes) were not lysed. CTL were also efficiently primed in vivo by injection of the N-terminal 272 aa fragment of the T-Ag. Hence, this fragment contains the structure(s) required for a soluble protein to enter the "endogenous" class I-restricted antigen processing and presentation pathway for CD8+ CTL activation. In soluble form, the complete T-Ag or the N-terminal T-Ag fragment sensitized in vitro RBL5 cells for lysis by T-Ag-specific CTL lines and clones. This in vitro sensitization was blocked by brefeldin A. In contrast, specific recognition of RBL5 cells pulsed in vitro with synthetic, immunogenic nonapeptides (derived from N-terminal T-Ag epitopes) by CTL lines was insensitive to brefeldin A. Hence, T-Ag and its 272-aa N-terminal fragment can enter the "endogenous" processing pathway and prime CD8+ CTL in vivo and in vitro.

Wild-type p53 in cellular-transformation - a reassessment

We found that a mouse p53 cDNA clone (pP53-5; Jenkins et al, Nature 312: 651-654, 1984), which previously was characterized as encoding mutant p53 protein, in fact represents wild-type mouse p53 cDNA, as we were able to demonstrate that the mutations described represented sequencing artefacts (compressions). Such sequencing artefacts were also observed with a p53 cDNA isolated from mouse T3T3 cells, encoding a mutant p53 with an Arg-Cys exchange at position 270, and could be resolved by sequencing of the opposite DNA strands. As pP53-5 had been successfully used in cellular immortalization and transformation assays (Jenkins et al, Nature 312: 651-654, 1984; Nature 317: 816-818, 1985), our results suggest that wild-type p53 under certain circumstances can induce transformation. This finding is relevant to the recent findings of overexpressed wild-type p53 in human tumors.

In vitro expansion distorts the detectable pattern of specific recognition of in vivo primed cytotoxic T lymphocyte populations

Injection of the 708-amino-acid (aa) viral protein "large tumor antigen" (T-Ag) of simian virus 40 (SV40) or its N-terminal 272-aa fragment into C57BL/6 (B6) mice (H-2b) primed CD8+ cytotoxic T lymphocytes (CTL) in vivo. Surprisingly, injection of this nonstructural viral protein (or its N-terminal fragment) in soluble form (without adjuvants) was as efficient in priming CD8+ CTL in vivo as the infection of B6 mice with the virus SV40. CTL activated in vivo by immunization with T-Ag proteins or SV40 infection specifically lysed syngeneic RBL5 cells transfected with a T-Ag-encoding vector; these RBL5/M7 transfectants efficiently presented N- and C-terminal T-Ag epitopes in association with H-2 class I restriction elements. N- and C-terminal T-Ag epitopes were recognized by CTL primed in vivo by immunization with the complete T-Ag protein or by infection with SV40, and (as expected) only N-terminal T-Ag epitopes were recognized by CTL primed in vivo by the soluble N-terminal T-Ag fragment. In CD8+ CTL populations primed in vivo by immunization with the complete T-Ag protein or by SV40 infection and restimulated in vitro with RBL5/M7 transfectants in a mixed tumor cell-lymphocyte culture (MTLC), CTL with specificity for C-terminal T-Ag epitopes were selectively expanded in vitro for months. Hence, the in vitro expansion of CTL population with heterogenous recognition specificities can dramatically distort the picture of its specific recognition repertoire primed in vivo.

Analysis of simian virus 40 small t antigen-induced progression of rat F111 cells minimally transformed by large T antigen

Minimal transformants of rat F111 fibroblasts were established after infection with the large T antigen (large T)-encoding retroviral expression vector pZIPTEX (M. Brown, M. McCormack, K. Zinn, M. Farrell, I. Bikel, and D. Livingston, J. Virol. 60:290-293, 1986). Coexpression of small t antigen (small t) in these cells efficiently led to their progression toward a significantly enhanced transformed phenotype. Small t forms a complex with phosphatase 2A and thereby might influence cellular phosphorylation processes, including the phosphorylation of large T. Since phosphorylation can modulate the transforming activity of large T, we asked whether the phosphorylation status of large T in minimally transformed cells might differ from that of large T in maximally transformed FR(wt648) cells and whether it might be altered by coexpression of small t. We found the phosphate turnover on large T in minimally transformed cells significantly different from that in fully transformed cells. This resulted in underphosphorylation of large T in minimally transformed cells at phosphorylation sites previously shown to be involved in the regulation of the transforming activity of large T. However, coexpression of small t in the minimally transformed cells did not alter the phosphate turnover on large T during progression; i.e., it did not induce a change in the steady-state phosphorylation of large T. This suggests that the helper function of small t during the progression of these cells was not mediated by modulating phosphatase 2A activity toward large T.

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.

Structural requirements for simian virus 40 replication and virion maturation

The nuclear matrix plays an important role in simian virus 40 (SV40) DNA replication in vivo, since functional replication complexes containing large T and replicating SV40 minichromosomes are anchored to this structure (R. Schirmbeck and W. Deppert, J. Virol. 65:2578-2588, 1991). In the present study, we have analyzed the course of events leading from nuclear matrix-associated replicating SV40 minichromosomes to fully replicated minichromosomes and, further, to their encapsidation into mature SV40 virions. Pulse-chase experiments revealed that newly replicated SV40 minichromosomes accumulated at the nuclear matrix and were directly encapsidated into DNase-resistant SV40 virions at this nuclear structure. Alternatively, a small fraction of newly replicated minichromosomes left the nuclear matrix to associate with the cellular chromatin. During the course of infection, progeny virions continuously were released from the nuclear matrix to the cellular chromatin and into the cytoplasm-nucleoplasm. The bulk of SV40 progeny virions, however, remained at the nuclear matrix until virus-induced cell lysis.

Specific and complex interactions of murine p53 with DNA

Biologically active mutant p53 from Balb/c mouse tumor cells (Meth A) was analysed for its specific interaction with DNA. Restricted phage lambda DNA, representing DNA of high complexity with regard to sequence and secondary structure, was used to probe for such an activity in a target-bound DNA-binding assay, using doubly immunopurified p53. A single lambda DNA fragment was specifically retained with very high affinity (KD = 10(-10) M). Specific DNA binding was shown to be an intrinsic property of p53, as it could be blocked with p53-specific monoclonal antibodies PAb122 and PAb421. The characteristics of the DNA binding of p53 to this lambda DNA fragment, as well as the structural properties of this fragment, suggested the possibility that p53 might be able to interact with nuclear matrix attachment region (MAR) DNA. Indeed, established genomic MAR elements were specifically bound by Meth A p53, whereas no binding was observed to an AT-rich control DNA. The interaction of p53 with MAR elements in vitro is compatible with the idea that p53 in vivo is involved in the regulation of replication and/or expression of cellular DNA. Complex DNA interactions were not restricted to mutant p53 from Meth A cells. Mutant p53 of a different conformational phenotype (PAb246+ 'wild-type' as opposed to PAb246- 'mutant' for p53 from Meth A cells) from minimally transformed T3T3 cells, as well as genotypic wild-type p53 expressed by a recombinant baculovirus in insect cells, exhibited similar DNA-binding properties.

Selection against large T-antigen expression in cells transformed by lymphotropic papova virus

Large T-antigen (T-Ag) in hamster cells transformed by the lymphotropic papova virus (LPV) exhibits similar properties as the T-Ag of simian virus 40 (SV40) with regard to its interaction with cellular targets. However, in contrast to SV40-transformed cells, LPV-transformed cells in cell culture select against high expression of LPV T-Ag. Southern analysis revealed that this selection process was accompanied by drastic changes at the DNA level, involving the loss of most of the integrated viral DNA copies. These changes probably were responsible for an approximately 100-fold downregulation of LPV T-Ag transcription. To elucidate the biological significance of this phenomenon, we studied the effects of the expression of LPV and SV40 T-Ag, respectively, in a variety of cells. Our data suggest that LPV T-Ag, like SV40 T-Ag, acts as an immortalizing and transforming protein. However, in contrast to SV40 T-Ag, high-level expression of LPV T-Ag seems to be detrimental to the establishment and maintenance of LPV-transformed cells in vitro.