Simian virus 40 large T antigen and two independent T-antigen segments sensitize cells to apoptosis following genotoxic damage.

The simian virus 40 (SV40) large tumor (T) antigen is sufficient to transform cells in cultures and induce tumors in experimental animals. Transformation of primary cells in cultures requires both overcoming growth arrest by stimulating the cell cycle and blocking cell death activities presumably activated by oncogene-mediated hyperproliferation signals. The study presented here examined the ability of specific regions and activities of T antigen to modulate apoptosis in cells treated with the genotoxic agent 5-fluorouracil (5-FU). The results showed that the expression of full-length T antigen rendered rat embryo fibroblasts (REF) sensitive to 5-FU-induced apoptosis. Thus, neither the p53-binding region nor the Bcl-2 homology region of T antigen was sufficient to prevent cell death induced by the DNA-damaging agent. T-antigen-mediated sensitization occurred independently of retinoblastoma protein or p53 and p300 binding. An N-terminal segment containing the first 127 T-antigen amino acids (T1-127) was sufficient to sensitize cells. A C-terminal segment consisting of T-antigen amino acids 251 to 708 (T251-708) also sensitized cells to 5-FU-induced apoptosis. This sensitization did not occur when T251-708 was targeted to the nucleus by inclusion of the SV40 nuclear localization signal. The introduction of mutations into the T-antigen J domain resulted in mutation-specific and variable inhibition of apoptosis. This result suggested that either the structural or the functional integrity of the J domain is required to sensitize cells to apoptosis. Treatment of REF or REF expressing full-length T antigen, an N-terminal segment, or T251-708 resulted in increased expression of the p53-responsive MDM2 gene; apoptosis occurred through a p53-dependent pathway, as p53-null cells expressing these T antigens were resistant to 5-FU-induced apoptosis. Possible mechanisms involved in sensitizing cells to a p53-dependent apoptosis pathway in spite of the ability of T antigen to bind and inactivate the transcriptional transactivating activity of p53 are discussed.

Role of CTL host responses and their implication for tumorigenicity testing and the use of tumour cells as vaccine substrate.

Viral oncogenes, mutated cellular oncogenes, or other adventitious agents that might contaminate vaccine preparations on inoculation of the host will encounter a T cell-mediated immune response which will play a determining role in the progression of neoplastic events or replication of contaminating viral agents. Using SV40 T antigen tumour systems as a model we discuss the regions of the oncoprotein that have an impact on tumourigenicity and the role of CD8 T lymphocyte immune responses in eliminating potential tumour cells. In addition, we discuss measures that counteract T cell immune responses to abrogate T cell-mediated immunosurveillance.

Mice with spontaneous pancreatic cancer naturally develop MUC-1-specific CTLs that eradicate tumors when adoptively transferred.

Pancreatic cancer is a highly aggressive, treatment refractory cancer and is the fourth leading cause of death in the United States. In humans, 90% of pancreatic adenocarcinomas overexpress altered forms of a tumor-specific Ag, mucin 1 (MUC1; an epithelial mucin glycoprotein), which is a potential target for immunotherapy. We have established a clinically relevant animal model for pancreatic cancer by developing a double transgenic mouse model (called MET) that expresses human MUC1 as self molecule and develops spontaneous tumors of the pancreas. These mice exhibit acinar cell dysplasia at birth, which progresses to microadenomas and acinar cell carcinomas. The tumors express large amounts of underglycosylated MUC1 similar to humans. Tumor-bearing MET mice develop low affinity MUC1-specific CTLs that have no effect on the spontaneously occurring pancreatic tumors in vivo. However, adoptive transfer of these CTLs was able to completely eradicate MUC1-expressing injectable tumors in MUC1 transgenic mice, and these mice developed long-term immunity. These CTLs were MHC class I restricted and recognized peptide epitopes in the immunodominant tandem repeat region of MUC1. The MET mice appropriately mimic the human condition and are an excellent model with which to elucidate the native immune responses that develop during tumor progression and to develop effective antitumor vaccine strategies.

Transactivation of a ribosomal gene by simian virus 40 large-T antigen requires at least three activities of the protein.

Simian virus 40 large-T antigen transactivates the ribosomal genes which are transcribed by RNA polymerase (pol I), as well as genes that are dependent on either pol II or pol III. This report identifies regions and activities of T antigen that are required to transactivate a pol I-dependent rat ribosomal gene promoter. By using the rat ribosomal gene (rDNA) promoter linked to a chloramphenicol acetyltransferase gene, we show that at least three separable T-antigen regions are necessary to achieve wild-type levels of transactivation of rDNA in transiently transfected monkey cells. One activity depends on the region of T antigen shared with small-t antigen (T/t common region). A second activity maps to amino acids 109 to 626 and is highly sensitive to mutational inactivation. Complementation analyses suggest that at least one activity in this region is independent of and must be in cis with the activity within the T/t common region. In addition, a functional nuclear localization signal is required for maximal T-antigen-mediated transactivation of rat rDNA. The three activities work in concert to override cellular species-specific controls and transactivate the rat ribosomal gene promoter. Finally, we provide evidence that although the tumor suppressor protein Rb has been shown to repress a pol I-dependent promoter, transactivation of the rat rDNA promoter does not depend on T antigen's ability to bind the tumor suppressor product Rb.

Cytotoxic T lymphocyte recognition sequences as markers for distinguishing among tumour antigens encoded by SV40, BKV and JCV.

Simian virus 40 (SV40) has been shown to be associated with a number of human tumours. Two other human papova viruses, BKV and JCV, infect humans at a relatively high frequency and are activated upon immune suppression. The T antigens of both of these viruses share considerable homologies with the transforming protein T antigen of SV40. We have used SV40 T antigen specific cytotoxic T lymphocyte (CTL) clones to discriminate among the T antigens of SV40, BKV and JCV. These CTL clones directed to four distinct CTL epitopes serve as specific probes and can differentiate subtle alterations or deletions in the CTL epitopes relative to SV40 T antigen. Using this strategy, we have been able to authenticate three SV40 viruses isolated from humans as all four distinct CTL epitopes in the T antigens encoded by these three SV40 human isolates (SVCPC, SVMEN, and SVPML-1) were found to be identical to prototype SV40. We have further identified a 198 amino acid deletion T antigen variant of SVCPC. The finding of a deletion mutant in the SVCPC virus population suggests that the cellular immune response may play a role in the selection of antigenic loss variants.

Two regions of simian virus 40 large T-antigen independently extend the life span of primary C57BL/6 mouse embryo fibroblasts and cooperate in immortalization.

Expression of the SV40 large T-antigen allows primary cells to escape senescence and thereby become immortalized. Immortalization occurs in two steps, extension of life span and acquisition of unlimited cell division potential. By following the increase in expression of a senescence-associated marker with increased cell passage, we show that C57Bl/6 mouse embryo fibroblast (B6MEF) cultures senesce by passage 4. Thus, the development of colonies from cultures transfected with T-antigen expressing constructs indicates extension of life span. Two T-antigen regions independently extended the life span of B6MEF. Expression of either a T-antigen consisting of amino acids 1-147 (T1-147) or a T-antigen consisting of amino acids 251-708 (T251-708) resulted in colony development. However, the colonies expressing these truncated T-antigens could not be expanded into cell lines efficiently. In contrast, coexpression of T1-147 and T251-708 produced colonies that could be expanded into cell lines as efficiently as could colonies expressing full-length T-antigen. Thus, the two regions of T-antigen contain analogous activities that are sufficient to extend cell life span; they cooperate to immortalize primary B6MEF; and they act in trans, indicating that the functions involved are independent.

A simian virus 40 large T-antigen segment containing amino acids 1 to 127 and expressed under the control of the rat elastase-1 promoter produces pancreatic acinar carcinomas in transgenic mice.

The simian virus 40 large T antigen induces tumors in a wide variety of tissues in transgenic mice, the precise tissues depending on the tissue specificity of the upstream region controlling T-antigen expression. Expression of mutant T antigens that contain a subset of the protein's activities restricts the spectrum of tumors induced. Others showed previously that expression of a mutant large T antigen containing the N-terminal 121 amino acids (T1-121) under control of the lymphotropic papovavirus promoter resulted in slow-growing choroid plexus tumors, whereas full-length T antigen under the same promoter induced rapidly growing CPR tumors, T-cell lymphomas, and B-cell lymphomas. In those instances, the alteration in tumor induction or progression correlated with inability of the mutant large T antigen to bind the tumor suppressor p53. In the study reported here, we investigated the capacity of an N-terminal T antigen segment (T1-127) expressed in conjunction with small t antigen under control of the rat elastase-1 (E1) promoter to induce pancreatic tumors. The results show that pancreases of transgenic mice expressing T1-127 and small t antigen display acinar cell dysplasia at birth that progresses to neoplasia. The average age to death in these mice is within the range reported for transgenic mice expressing full-length T antigen under control of the E1 promoter. These results indicate that sequestering p53 by binding is not required for the development of rapidly growing acinar cell carcinomas. In addition, we provide evidence that small t antigen is unlikely to be required. Finally, we show that the p53 protein in acinar cell carcinomas is wild type in conformation.

Adding an Rb-binding site to an N-terminally truncated simian virus 40 T antigen restores growth to high cell density, and the T common region in trans provides anchorage-independent growth and rapid growth in low serum concentrations.

The simian virus 40 large T antigen is sufficient to confer on cells multiple transformed cell growth characteristics, including growth to a high cell density, rapid growth in medium containing low serum concentrations, and anchorage-independent growth. We showed previously that distinct regions of the protein were involved in conferring these properties and that removal of the first 127 amino acids of T antigen abrogated all three activities. At least three large-T-antigen transformation-related activities have been localized to that region: binding of the tumor suppressor gene product Rb and two independent activities contained within the common region shared by large T and small t antigens. The experiments described here were directed toward determining whether these were the only activities from the N terminus that were needed. To do so we reintroduced an Rb-binding region into the N-terminally truncated T antigen (T128-708) and examined the growth properties of cells immortalized by it in the presence and absence of small t antigen, which can provide the T-common-region transformation-related activities in trans. We show that an Rb-binding region consisting of amino acids 101 to 118, when introduced into a heterologous site in T128-708, is capable of physically binding Rb and that binding is sufficient for cells expressing the protein to acquire the ability to grow to a high saturation density. However, in low-serum medium, the growth rate of the cells and maximal cell density are reduced relative to those of wild-type-T-antigen-expressing cells, and the cells cannot divide without anchorage. This result suggests that although Rb binding is sufficient in the context of T128-708 to confer growth to a high density, one or more other N-terminally located T-antigen activities are needed for cells to acquire the additional growth properties. Small t antigen in trans supplied those activities. These results indicate that the T-common-region activities and Rb binding are the only activities from the T-antigen N terminus needed to restore full transforming activity to the N-terminally truncated T antigen.

p300 family members associate with the carboxyl terminus of simian virus 40 large tumor antigen.

Several cellular polypeptides critical for growth regulation interact with DNA tumor virus oncoproteins. p400 is a cellular protein which binds to the adenovirus E1A oncoprotein(s). The biological function of p400 is not yet known, but it is structurally and immunologically closely related to p300 and CREB-binding protein, two known E1A-binding transcription adapters. Like p300, p400 is a phosphoprotein that binds to the simian virus 40 large tumor antigen (T). In anti-T coimmunoprecipitation experiments, staggered deletions spanning the amino-terminal 250 amino acids of T did not abrogate T binding to either p400 or p300. A T species composed of residues 251 to 708 bound both p400 and p300, while a T species defective in p53 binding was unable to bind either detectably. Anti-p53 immunoprecipitates prepared from cells containing wild-type T also contained p400 and p300. Hence, both p400 and p300 can bind (directly or indirectly) to a carboxyl-terminal fragment of T which contains its p53 binding domain. Since the p53 binding domain of T contributes to its immortalizing and transforming activities, T-p400 and/or T-p300 interactions may participate in these functions.

Induction and persistence of a cytotoxic T lymphocyte (CTL) response against a herpes simplex virus-specific CTL epitope expressed in a cellular protein.

CD8+ cytotoxic T-lymphocytes recognize small epitope peptides in association with MHC class I molecules expressed on the cell surface. In this study, we have determined whether an 8 amino acid viral CTL epitope, when expressed in a cellular protein, can be appropriately processed, presented, and recognized by the corresponding epitope-specific CTL and whether it is capable of inducing a CTL response in vivo. An H-2Kb-restricted CTL epitope from herpes simplex virus type 1 (HSV-1) glycoprotein B (gB epitope, residues 498-505) was cloned into the mouse dihydrofolate reductase protein (DHFR) at amino acid position 87. The recombinant DHFRs were expressed in vaccinia virus recombinants. To distinguish the recombinant DHFR proteins from the endogenous DHFR, an antibody epitope, recognized by monoclonal antibody PAb 901 and derived from simian virus 40 (SV40) T antigen was tagged to the C-termini of recombinant DHFR proteins. In vivo expression of recombinant DHFR was demonstrated by immunoprecipitation with the monoclonal antibody PAb 901. The H-2b cells infected with recombinant vaccinia virus expressing the recombinant DHFR were specifically lysed by gB epitope-specific CTL. Furthermore, the recombinant DHFR was functional in inducing a long lasting HSV gB epitope-specific CTL response upon immunization of C57BL/6 (B6) mice. These results indicate that a viral epitope expressed in a cellular protein can be efficiently processed, presented, and recognized by epitope-specific CTL and show that cellular proteins expressing CTL epitopes can be used for induction of CD8+ T lymphocyte responses.

Identification of a variable region at the carboxy terminus of SV40 large T-antigen.

The entire early regions of three human isolates of simian virus 40 (SV40), as well as two laboratory strains recovered from monkeys, were sequenced. The early coding region of each isolate contains a number of nucleotide differences when compared to the reference strain SV40-776. These differences result in some changes in the predicted amino acid sequence of the unique region of small t-antigen and in the carboxy (C) terminus of large T-antigen. The amino acid sequence of the remainder of large T-antigen was absolutely conserved among all isolates. Thus, SV40 large T-antigen contains a variable domain at the C-terminal end of the molecule.

Cytotoxic T lymphocyte escape variants, induced mutations, and synthetic peptides define a dominant H-2Kb-restricted determinant in simian virus 40 tumor antigen.

Immunization of C57BL/6 mice with syngeneic cells transformed by simian virus 40 large T antigen (SV40 T ag) induces the generation of T antigen-specific cytotoxic T lymphocytes (CTL) which are restricted by the major histocompatibility class I antigens H-2Db and H-2Kb. Previous studies have shown that the H-2Db-restricted CTL response is directed to at least three distinct epitopes (I, II/III, and V) in the SV40 T antigen which have been precisely mapped using deletion mutagenesis and overlapping synthetic peptides. Although in vivo the CTL response to SV40 T antigen is dominated by the H-2Kb class I antigen, the precise location of the H-2Kb-restricted epitope(s) was not known, and whether there was multiplicity of H-2Kb-restricted epitopes remained unclear. In this study, we have defined the minimal recognition epitope for the SV40-specific H-2Kb-restricted CTL clone Y-4 as T antigen residues 404-411 by using T antigen deletion and point mutants and synthetic peptides. DNA sequence analysis of the region encoding residues 404-411 from the T antigens expressed in three independently isolated CTL clone Y-4 escape variants identified inactivating mutations capable of abrogating CTL recognition. Estimation of CTL precursor (CTLp) frequencies by limiting dilution analysis revealed that CTLp specific for epitope IV represent a large percentage of the total CTL response elicited by the intact T antigen in H-2b mice. Immunization of B6 mice with cells expressing a T antigen derivative deleted of residues 404-411 revealed that site IV represents the only immunodominant H-2Kb-restricted epitope within T antigen.

A novel translational regulation function for the simian virus 40 large-T antigen gene.

Cells use the interferon-induced, double-stranded-RNA-dependent protein kinase PKR as a defense against virus infections. Upon activation, PKR phosphorylates and thereby inactivates the protein synthesis initiation factor eIF-2, resulting in the cessation of protein synthesis. Viruses have evolved various strategies to counteract this cellular defense. In this paper, we show that simian virus 40 (SV40) large-T antigen can antagonize the translational inhibitory effect resulting from the activation of PKR in virus-infected cells. Unlike the situation with other virus-host cell interactions, SV40 large-T antigen does not block the activation of PKR, suggesting that SV40 counteracts the cellular antiviral response mediated by PKR at a step downstream of PKR activation. Mutational analysis of large-T antigen indicates that a domain located between amino acids 400 and 600 of large-T antigen is responsible for this function. These results define a novel translational regulatory function for the SV40 large-T antigen.

Simian virus 40 large T antigen contains two independent activities that cooperate with a ras oncogene to transform rat embryo fibroblasts.

The simian virus 40 large T antigen immortalizes growing primary cells in culture. In addition, this viral oncoprotein cooperates with an activated ras protein to produce dense foci on monolayers of rat embryo fibroblasts (REF). The relationship between independent immortalization and cooperative transformation with ras has not been defined. Previously, two regions of T antigen were shown to contain immortalization activities. An N-terminal fragment consisting of amino acids 1 to 147 immortalizes rodent cells (L. Sompayrac and K. J. Danna, Virology 181:412-415, 1991). Loss-of-function analysis indicated that immortalization depended on integrity of the T-antigen segments containing amino acids 351 to 450 and 533 to 626 (T. D. Kierstead and M. J. Tevethia, J. Virol. 67:1817-1829, 1993). The experiments described here were directed toward determining whether these same T-antigen regions were sufficient for cooperation with ras. Initially, constructs that produce T antigens containing amino acids 176 to 708 (T176-708) or 1 to 147 were tested in a ras cooperation assay. Both polypeptides cooperated with ras to produce dense foci on monolayers of primary REF. These results showed that T antigen contains two separate ras cooperation activities. In order to determine the N-terminal limit of the ras cooperation activity contained within the T176-708 polypeptide, a series of constructs designed to produce fusion proteins containing T-antigen segments beginning at residues 251, 301, 337, 351, 371, 401, 451, 501, 551, 601, and 651 was generated. Each of these constructs was tested for the capacity to cooperate with ras to produce dense foci on REF monolayers. The results indicated that a polypeptide containing T-antigen amino acids 251 to 708 (T251-708) was sufficient to cooperate with ras, whereas the more extensively truncated products were not. The abilities of the N-terminally truncated T antigens to bind p53 were examined in p53-deficient cells infected with a recombinant vaccinia virus expressing a phenotypically wild-type mouse p53. The results showed that polypeptides containing T-antigen amino acids 251 to 708, 301 to 708, 337 to 708, or 351 to 708 retained p53-binding capacity. The introduction into the T251-708 polypeptide of deletions that either prevented p53 binding (dl434-444) or did not prevent p53 binding (dl400) abrogated ras cooperation. These results indicated that although p53 binding may be necessary for ras cooperation, an additional, as-yet-undefined activity contained within the T251-708 polypeptide is needed.

Protein-protein interactions between human cytomegalovirus IE2-580aa and pUL84 in lytically infected cells.

The human cytomegalovirus immediate-early protein IE2-580aa (ppUL122a) activates transcription of viral and cellular genes and represses its own transcription through sequence-specific binding to the major immediate-early promoter. In lytically infected cells, IE2-580aa interacts with a 75-kDa viral protein (p75), an early protein that is also synthesized at late times after infection. Here we show that p75 is the product of the UL84 gene. Its association with IE2-580aa in infected cells suggests that pUL84 is involved in transcription control.

The human cytomegalovirus 86-kilodalton immediate-early 2 protein: synthesis as a precursor polypeptide and interaction with a 75-kilodalton protein of probable viral origin.

The immediate-early 2 (IE2) 86-kDa polypeptide, a major immediate-early gene product of human cytomegalovirus, regulates transcription both positively and negatively. We report two new properties of the IE2 86-kDa polypeptide in infected cells. Immunoprecipitation of infected cell proteins from human embryonic lung cells by antipeptide or monoclonal antibodies specific for IE2 epitopes revealed three closely migrating polypeptide species. The slowest, p86, behaved as expected for the mature 86-kDa IE2 polypeptide. The middle species, p80, was immunoprecipitated from denatured as well as native samples and labeled to steady state rapidly. Pulse-chase analysis demonstrated directly that p80 was a metabolic precursor to p86. The fastest-migrating species, p75, was not detected by probing blots of the immunoprecipitated proteins with IE2-specific antisera; p75 was not precipitated from denatured protein samples; and the products of partial proteolysis of p75 were distinct from those of p86. These properties established p75 as an unrelated coprecipitated polypeptide complexed with p86. The p75 proteins coprecipitated from cells infected with two different strains of human cytomegalovirus, AD169 and Towne, had different mobilities. p75 was detected as early as 6 h and as late as 72 h after infection, but it was not synthesized in cells released from a cycloheximide block. Thus, it is likely that p75 is an early viral protein.

Simian virus 40 T antigen as a carrier for the expression of cytotoxic T-lymphocyte recognition epitopes.

Simian virus 40 (SV40) large T antigen can immortalize a wide variety of mammalian cells in culture. We have taken advantage of this property of T antigen to use it as a carrier for the expression of cytotoxic T-lymphocyte (CTL) recognition epitopes. DNA sequences corresponding to an H-2Db-restricted SV40 T-antigen site I (amino acids 205 to 215) were translocated into SV40 T-antigen DNA at codon positions 350 and 650 containing EcoRI linkers. An H-2Kb-restricted herpes simplex virus glycoprotein B epitope (amino acids 498 to 505) was also expressed in SV40 T antigen at positions 350 and 650. Primary C57BL/6 mouse kidney cells were immortalized by transfection with the recombinant and wild-type T-antigen DNA. Clonal isolates of cells expressing chimeric T antigens were shown to be specifically susceptible to lysis by CTL clones directed to SV40 T-antigen site I and herpes simplex virus glycoprotein B epitopes, indicating that CTL epitopes restricted by two different elements can be processed, presented, and recognized by the epitope-specific CTL clones. Our results suggest that SV40 T antigen can be used as a carrier protein to express a wide variety of CTL epitopes.

Association of p53 binding and immortalization of primary C57BL/6 mouse embryo fibroblasts by using simian virus 40 T-antigen mutants bearing internal overlapping deletion mutations.

To more precisely map the immortalization and p53 binding domains of T antigen, a large series of overlapping deletion mutations were created between codons 251 to 651 by utilizing a combination of Bal 31 deletion and oligonucleotide-directed mutagenesis. Immortalization assay results indicated that amino acids (aa) 252 to 350, 400, and 451 to 532 could be removed without seriously compromising immortalization, although the appearance of immortal colonies was delayed in some cases. Western immunoblotting experiments indicated that the p53 binding capacities of T antigen produced by mutants missing aa 252 to 300, 301 to 350, 400, or 451 to 532 were only slightly reduced relative to that of wild-type T antigen. Within the limits of this deletion analysis, the immortalization and p53 binding domains appear to be colinear and, in fact, may represent two aspects of the same domain. This deletion analysis eliminates the entire zinc finger domain (aa 302 to 320), a small portion of the leucine-rich region (aa 345 to 350), and a large portion of the ATP binding domain (aa 451 to 528) as participants in p53 binding or in the immortalization process. The results also show that removal of T antigen amino acids within the region 451 to 532 appears to alter the capacity of newly synthesized but not older T antigen and p53 molecules to form complexes.

Cytotoxic T lymphocytes (CTL) against a transforming gene product select for transformed cells with point mutations within sequences encoding CTL recognition epitopes.

The 94-kD large tumor (T) antigen specified by simian virus 40 (SV40) is sufficient to induce cell transformation. T antigen contains four H-2Db-restricted cytotoxic T lymphocyte (CTL) recognition epitopes that are targets for CTL clones Y-1, Y-2, Y-3, and Y-5. These epitopes have been mapped to T antigen amino acids 207-215 (site I), 223-231 (sites II and III), and 489-497 (site V), respectively. Antigenic site loss variant cells that had lost one or more CTL recognition epitopes were previously selected by coculturing SV40-transformed H-2Db cells with the site-specific Db-restricted CTL clones. The genetic bases for T antigen CTL recognition epitope loss from the variant cells were identified by DNA amplification and direct sequencing of epitope-coding regions from variant cell DNAs. Cells selected for resistance to CTL clone Y-1 (K-1; K-1,4,5; K-3,1) carry deleted SV40 genomes lacking site I, II, and III coding sequences. Point mutations present within the site II/III coding region of Y-2-/Y-3-resistant cell lines specify the substitution of asparagine for lysine as T antigen amino acid 228 (K-2) or phenylalanine for tyrosine at position 230 (K-3). Point mutations identified within independently selected Y-5 resistant populations (K-5 and K-1,4,5) direct the substitution of isoleucine for asparagine at position 496 (K-5) or the substitution of phenylalanine for isoleucine at position 491 (K-1,4,5) of T antigen. Each substitution causes loss of the relevant CTL recognition epitope, apparently by compromising CTL T cell receptor recognition. These experiments identify specific amino acid changes within a transforming protein that facilitate transformed cell escape from site-specific CTL clones while allowing maintenance of cellular transformation. This experimental model system provides unique opportunities for studying mechanisms of transformed cell escape from active immunosurveillance in vivo, and for analysis of differential host immune responses to wild-type and mutant cell-transforming proteins.