Insensitivity of a ricin-resistant mutant of Chinese hamster ovary cells to fusion induced by Newcastle disease virus.

The simian virus 40 (sv40) tumor antigen (T-antigen) and tumor-specific transplantation antigen (TSTA) have been partially purified and studied to clarify their relationship. The T-antigen and the TSTA were partially purified from nuclei of SV AL/N cells, and SV40-transformed mouse embryo fibroblast line, by precipitation with ammonium sulfate and chromatography on DEAE- and DNA-cellulose. The T-antigen was assayed by complement fixation, and the TSTA was assayed by its ability to immunize mice against SV40-containing ascites tumor cells. When T-antigen- and TSTA-containing preparations were sedimented through sucrose gradients, each antigen had a major peak of activity at a sedimentation coefficient of 6.7 and minor peaks in other regions. Antiserum against T-antigen (from tumor-bearing hamsters) immunoprecipitated the TSTA activity. A preparation of T-antigen from human SV80 cells, which exhibited only one protein band after sodium dodecylsulfate-polyacrylamide gel electrophoresis, had TSTA activity when as little as 0.6 microgram of protein per mouse was used for immunization. These experiments demonstrate that the T-antigen, the product of the SV40 early A gene is capable of inducing specific immunity against transplantation of SV40-transformed tumor cells in mice.     

SV40 T antigen acts as a minor histocompatibility antigen of SV40 T antigen tolerant transgenic mice

The ability of normal mice to mount an SV40 T antigen-specific cytolytic T lymphocytes response when immunized in vivo with splenocytes from the SV40 T antigen transgenic 427-line mice and restimulated in vitro with SV40-transformed fibroblasts, or when immunized with SV40 and restimulated with 427-line splenocytes, was analyzed. Both immunization schemes resulted in an SV40 T antigen-specific immune response, indicating the presence of SV40 T antigen-positive cells in the spleens of these transgenic mice. Normal mice engrafted with skin from 427 donors showed no rejection of the graft. Thus, SV40 T antigen in transgenic 427-line mice is expressed on an undefined cell type in the spleen and acts as a tissue-specific minor histocompatibility antigen.     

Antibody response to simian virus 40 tumor antigen in nude mice reconstituted with T cells.

Athymic BALB/c nude mice (nu/nu) fail to generate circulating antibodies to simian virus 40 (SV40) tumor (T) antigen when immunized with SV40-transformed mouse cells or with T antigen positive somatic cell hybrids derived from SV40-transformed human and normal mouse parental cells. However, normal BALB/c mice readily produce antibodies to SV40 T antigen. When nude mice were reconstituted with normal syngeneic T lymphocytes from spleen or thymus source, the humoral immune responsiveness to SV40 T antigen was restored.     

Studies on the specificity of in vitro induced lymphocytotoxicity to SV40-transformed fibroblasts.

Cytotoxic effector lymphocytes were induced by in vitro immunization of lymph node and spleen cells from AKR-mice (H-2k) and from BALB/c-mice (H-2d) to syngeneic SV40-transformed fibroblasts. The T cell-dependent cytotoxicity was specific for target cells expressing the same H2-specificity as the immunizing cells. Nontransformed fibroblasts as stimulator cells did not induce efficient cytotoxicity to transformed or nontransformed target cells. Incubation with phytohemagglutinin during the sensitization period modified the specificity of the T cell-mediated lysis of syngeneic SV40-transformed fibroblasts: allogeneic as well as syngeneic target cells were destroyed by these effector cells. However, the polyclonal stimulant activates preferentially cytotoxicity to H2-matched target cells. The in vitro generation of cytotoxic effector cells was restricted to living SV40-transformed fibroblasts as immunizing cells; it was not possible to immunize lymphocytes in the presence of membrane proteins prepared from the SV40-transformed cells. The cytotoxicity of the in vitro immunized lymphocytes was inhibited by incubation with membrane protein preparations from syngeneic or allogeneic SV40-transformed fibroblasts.     

Characterization of a progressive tumor from C3H fibroblasts transformed in vitro with SV40 virus. Immunoresistance in vivo correlates with phenotypic loss of H-2Kk

Cultured SV40-transformed fibroblasts from C3H mice (SV-C3H) were "adapted" to in vivo growth by serial passage through sublethally irradiated, syngeneic recipients. After four in vivo passages, a population of cells was obtained (V4) that was weakly oncogenic in nonirradiated mice. Cells isolated from large V4 tumors (V5) were found to be highly oncogenic, producing lethal tumors at doses of less than 10(3) cells. V5 is insensitive to SV40-specific transplantation immunity in syngeneic animals but can be rejected completely by H-2 allogeneic mice. In vitro studies revealed that although V4 and the parent SV-C3H cells can induce SV40-specific cytotoxic T cells (CTL) in vitro and are lysed by these CTL, V5 does neither. The failure of V5 to interact with CTL was traced to the loss of H-2Kk antigen expression on these cells. The correlation between H-2Kk loss and immunoresistance in vivo suggests a central role for the cytotoxic T cell in in vivo tumor elimination in this system.     

Demonstration of multiple antigenic sites of the SV40 transplantation rejection antigen by using cytotoxic T lymphocyte clones

Multiple antigenic sites on the simian virus 40 (SV40) tumor-specific transplantation antigen (TSTA) were detected by the use of cytotoxic T lymphocyte (CTL) clones isolated from continuous cultures of SV40-specific CTL (H-2b). Two independently derived clones, K11 and K19, specific for the SV40 TSTA in association with H-2Db, each recognized a different antigenic determinant of the SV40 TSTA. This conclusion was based on the observation that a human papovavirus BK virus (BKV) transformed cell line, which possesses a T antigen serologically cross-reactive with that of SV40, was lysed by a heterogeneous population of SV40-immune lymphocytes and by clone K19 but not by K11. Therefore, these CTL clones must recognize two different antigenic determinants of the SV40 TSTA:K19 recognizes a cross-reactive determinant of the SV40 and BKV TSTA, whereas K11 is reactive against an SV40-specific determinant.     

Simian virus 40 large-T-antigen-specific rejection of mKSA tumor cells in BALB/c mice is critically dependent on both strictly tumor-associated, tumor-specific CD8(+) cytotoxic T lymphocytes and CD4(+) T helper cells

Protective immunity of BALB/c mice immunized with simian virus 40 (SV40) large T antigen (TAg) against SV40-transformed, TAg-expressing mKSA tumor cells is critically dependent on both CD8(+) and CD4(+) T lymphocytes. By depleting mice of T-cell subsets at different times before and after tumor challenge, we found that at all times, CD4(+) and CD8(+) cells both were equally important in establishing and maintaining a protective immune response. CD4(+) cells do not contribute to tumor eradication by directly lysing mKSA cells. However, CD4(+) lymphocytes provide help to CD8(+) cells to proliferate and to mature into fully active cytotoxic T lymphocytes (CTL). Depletion of CD4(+) cells by a single injection of CD4-specific monoclonal antibody at any time from directly before injection of the vaccinating antigen to up to 7 days after tumor challenge inhibited the generation of cytolytic CD8(+) lymphocytes. T helper cells in this system secrete the typical Th-1 cytokines interleukin 2 (IL-2) and gamma interferon. Because in this system TAg-specific CD8(+) cells secrete only minute amounts of IL-2, it appears that T helper cells provide these cytokines for CD8(+) T cells. Moreover, this helper effect of CD4(+) T cells in mKSA tumor rejection in BALB/c mice does not simply improve the activity of TAg-specific CD8(+) CTL but actually enables them to mature into cytolytic effector cells. Beyond this activity, the presence of T helper cells is necessary even in the late phase of tumor cell rejection in order to maintain protective immunity. However, despite the support of CD4(+) T helper cells, the tumor-specific CTL response is so weak that only at the site of tumor cell inoculation and not in the spleen or in the regional lymph nodes can TAg-specific CTL be detected.     

Suppression of hamster lymphocyte reactivity to simian virus 40 tumor surface antigens by spleen cells from pregnant hamsters

SV40-transformed tumor cells in hamsters have been found to have cell surface antigens cross-reactive with antigens temporally expressed on fetal tissues. Adoptive transfer assays performed in this laboratory have shown that peritoneal exudate cells from 10-day primiparous hamsters are cytotoxic to SV40-transformed sarcoma cells (WF5-1) carrying fetal antigen, whereas peritoneal exudate cells from multiparous hamsters are less cytotoxic. This suggests a suppressor activity might be present during subsequent pregnancies that reduces the responsiveness of lymphocytes from pregnant hamsters to stimulation by fetal antigens on tumor cells. Using a lymphocyte transformation assay, spleen cells from pregnant hamsters were found to be incapable of responding to preparations of either hamster fetal tissue or SV40-transformed cells. However, a suppressor component can be demonstrated in spleen cell populations of both primi- and multiparous hamsters during pregnancy that is capable of reducing the response of lymphocytes sensitized against SV40 tumor-associated antigens. The degree of suppression is proportional to the ratio of responder cells to spleen cells from pregnant animals. These results suggest there is a subpopulation of spleen cells involved in immunoregulation during pregnancy that has the ability to suppress the reactivity of lymphocytes sensitized against SV40-associated oncofetal antigens.     

Cell-mediated immune reaction against BK virus-transformed cells

Summary Syngeneic or allogeneic cells transformed by BK virus (BKV) were used to immunize C57BL/6J mice. After in vitro stimulation, lymphocytes prepared from the spleens of immunized mice were used in in vitro cytotoxicity tests. The results of these tests revealed the presence of a cell surface antigen, presumably corresponding to the viral transplantation antigen, common to all tested BKV- and SV40-transformed cell lines of C57BL/6J origin. An allogeneic cell line transformed by BKV also contained the same antigen. Immunization, i.e., in vivo priming, did not require syngeneic transformed cells, whereas cytolysis was only observed when the virus-specific antigen on target cells was associated with the same H2 haplotype as was expressed by effector cells. An additional unidentified antigen was shared by some of the BKV-transformed cell lines and cell lines transformed by simian adenovirus SA7.     

Comparison of simian virus 40 large T antigen recombinant protein and DNA immunization in the induction of protective immunity from experimental pulmonary metastasis

In this report we examine the ability of a recombinant tumor antigen preparation to prevent the establishment of experimental pulmonary metastasis. Baculovirus-derived recombinant simian virus 40 (SV40) large tumor antigen (T-Ag) was injected into BALB/c mice followed by challenge with an intravenous injection of syngeneic SV40-transformed tumorigenic cells. The experimental murine pulmonary metastasis model allows for the accurate measurement of metastatic lessions in the lungs at various times after the challenge, using computer-assisted video image analysis. Following challenge, lung metastasis and survival data for the groups of mice were obtained. Animals immunized with recombinant SV40 T-Ag showed no detectable sign of lung metastasis and survived for more than 120 days after challenge. Antibodies specific for SV40 T-Ag were detected in the serum of immunized mice by enzyme-linked immunosorbent assay. Splenocytes obtained from mice immunized with recombinant SV40 T-Ag did not lyse syngeneic tumor cells, indicating that no cytotoxic T lymphocyte response was induced. Control mice developed extensive lung metastasis and succumbed to lethal tumor within 4 weeks after challenge. These data indicate that immunization with the recombinant SV40␣T-Ag induces protective, T-Ag-specific immunity in an experimental pulmonary tumor metastasis model. Received: 20 August 1998 / Accepted: 25 November 1998     

An early event in murine cytomegalovirus replication inhibits presentation of cellular antigens to cytotoxic T lymphocytes.

Cytomegalovirus (CMV) infection of simian virus 40 (SV40)-immune mice inhibits priming of SV40-specific helper and cytotoxic T lymphocytes (CTL) in vivo (A. E. Campbell, J. S. Slater, and W. S. Futch, Virology 173:268-275, 1989; J. S. Slater, W. S. Futch, V. J. Cavanaugh and A. E. Campbell, Virology 185:132-139, 1991). We now demonstrate that murine CMV (MCMV) infection of SV40-transformed macrophages and fibroblasts prevents presentation of SV40 T antigen to SV40-specific CTL. MCMV-infected macrophages failed to stimulate SV40-immune CTL precursors in vitro. In addition, MCMV-infected, SV40-transformed macrophage and fibroblast target cells lost their susceptibility to lysis by major histocompatibility complex class I-restricted, SV40-specific CTL clones. MCMV infection did not alter the synthesis of SV40 T antigen in the target cells. MCMV early gene expression was required for inhibition of SV40 T-antigen presentation; immediate-early gene expression was insufficient for this effect. Early viral gene expression also resulted in significant reduction of H-2K and H-2D molecules on the surface of MCMV-infected fibroblasts. However, this reduction occurred independently from suppression of antigen presentation to CTL. The same target cells which were resistant to lysis by SV40 CTL were susceptible to lysis by MCMV-specific CTL. MCMV early gene products therefore interfere with the processing and/or presentation of SV40 T-antigen determinants to CTL independent of alterations in the major histocompatibility complex.     

Studies of Nondefective Adenovirus 2-Simian Virus 40 Hybrid Viruses VIII. Association of Simian Virus 40 Transplantation Antigen with a Specific Region of the Early Viral Genome

Two of the five nondefective adenovirus 2 (Ad2)-simian virus 40 (SV40) hybrids induce SV40 transplantation resistance in immunized hamsters. These two hybrids, Ad2(+)ND(2) and Ad2(+)ND(4), contain 32 and 43% of the SV40 genome, respectively. The pattern of induction of SV40 transplantation antigen (TSTA) by the various hybrids differentiates TSTA from both SV40 U and T antigens. Since the SV40 RNA induced by both these hybrids is early SV40 RNA, these findings confirm that TSTA is an early SV40 function. By combining available data on SV40 antigen induction by these hybrids with electron microscopy heteroduplex mapping studies, the DNA segment responsible for the induction of SV40 TSTA can be inferred to lie in the region between 0.17 and 0.43 SV40 units from the site on the SV40 chromosome cleaved by E. coli R(1) restriction endonuclease.     

Induction of SV40-related transplantation immunity in mice by BK virus-transformed cells.

The reactivity of tumor-specific transplantation antigens (TSTAs) induced by SV40 and BK virus (BKV) was studied in Balb/Ccr mice with SV40-transformed tumor cells (mKSA-4AC). The mice, which had received BKV-transformed mouse or hamster cells, were highly resistant to the challenge with mKSA-4AC. The mKSA-rejected animals, however, were as susceptible as non-immunized ones to the subsequent challenge with Moloney sarcoma virus (Kirsten)-transformed cells. The result shows that BKV-transformed cells have a TSTA immunologically related closely to that induced by SV40.     

Active specific immunotherapy with extracted tumor-specific transplantation antigen, cyclophosphamide, and adoptive transfer of tumor-specific cytotoxic T-cell clones

An L3T4-, Lyt2+ tumor-specific, cloned T-lymphocyte cell line (RTT-2) was isolated from a spleen cell population harvested from C3H/HeJ mice, following in vivo immunization against a syngeneic MCA-induced fibrosarcoma (MCA-F) and in vitro restimulation with 1-butanol-extracted, isoelectrophoretically purified MCA-F tumor-specific transplantation antigen (TSTA). RTT-2 required exposure to homotypic-extracted MCA-F TSTA in combination with low-dose IL-2 to maintain its specific cytotoxic activity in vitro. In vivo local adoptive transfer of RTT-2 caused specific neutralization of homotypic MCA-F, but not heterotypic MCA-D, tumor cells. Systemic in vivo transfer of RTT-2 alone augmented host resistance. In combination with a triple regimen of weekly doses of purified TSTA (1 microgram SC) and a single ip injection of CY (20 mg/kg), adoptive transfer of RTT-2 cells (1 X 10(7)) retarded the neoplastic outgrowth in and prolonged the survival of primary hosts bearing 3-, 7-, and 14-day established MCA-F tumors. In a spontaneous pulmonary metastasis model following amputation of a tumor-bearing limb, the triple regimen of TSTA/CY/RTT-2 markedly reduced the number of lung colonies. Thus RTT-2, which displays specific tumoricidal activity in vitro and in vivo, may afford a suitable tool to dissect T-cell receptors recognizing tumor markers on 1-butanol-extracted, MCA-F TSTA.     

Thermal sensitivity of specific transplantation antigens of the tumor-cell membrane]

Study of temperature-sensitivity of the tumour specific transplantation antigen (TSTA) on the cell membrane of SV40-induced tumours and spontaneous hepatoma of inbred Syrian hamsters, as well as in the monkey cells infected in vitro with SV40 virus (ts-mutant) demonstrated high thermolability of TSTA. Heating such cells at 56 degrees C for 30-60 min led to complete loss of their immunogenic activity. Moreover, in the animals immunized with heated tumour cells the test-tumour cell growth was regularly enhanced.     

Evidence for the involvement of cytolytic macrophages in rejection of SV40-induced tumors

The potential role of cytolytic macrophages in in vivo resistance to tumors induced by simian virus 40 (SV40) was evaluated in two experimental systems. First, a cell line produced by sequential in vivo passage of SV40-transformed fibroblasts through syngeneic C3H/HeJ mice was found to develop both increased neoplastic character and resistance to macrophage-mediated lysis, suggesting in vivo selection pressure against the macrophage-sensitive phenotype. In the second approach, SV40-transformed cells from C3H.OL mice, a strain that fails to produce SV40-specific cytolytic T lymphocytes (CTL), were cloned, and the cloned cells were tested for susceptibility to macrophage cytolysis in vitro. Two clones SV-COL-E8 and SV-COL-F5, which represent the extremes of macrophage susceptibility and resistance, respectively, were tested for progressive growth in syngeneic C3H.OL recipients. Progression in vivo was found to correlate with resistance to macrophage cytolysis in vitro. Other in vitro measures of the neoplastic phenotype, cell division rate and anchorage-independent growth, did not predict the relative abilities of clones E8 and F5 to form tumors. Likewise, the cells were indistinguishable in their sensitivity to cytolysis by allogeneic CTL and by natural killer cells. Finally, the presence of activated macrophages in the peritoneum of mice rejecting a challenge of syngeneic SV40-transformed cells was confirmed in both CTL responder and nonresponder strains. These studies suggest that cytolytic macrophages are indeed generated during rejection of SV40-induced mouse tumors and that, in the absence of an effective anti-SV40 CTL response, resistance of the transformed cell to macrophage-mediated cytolysis can be a determining factor in in vivo tumor growth.     

H-2 antigen requirements in the in vitro induction of SV40-specific cytotoxic T lymphocytes

T cytotoxic cells generated to syngeneic SV40 virus transformants lyse only SV40 target cells that are syngeneic at the H-2 locus. In contrast, SV40-specific tumor transplantation immunity shows no requirements for syngeneic H-2. Inoculation of allogeneic or even xenogeneic transformants will confer immunity to a challenge of syngeneic SV40 tumor cells. The experiments described here represent an attempt to reconcile these apparently conflicting observations. In our hands, generation of SV40-specific T cytotoxic cells in vitro requires both in vivo priming and secondary in vitro sensitization. We have found that priming for a secondary syngeneic-restricted response requires only that the cell employed be SV40 transformed. That is, priming may be accomplished with syngeneic, allogeneic, or xenogeneic SV40 transformants. Thus, the apparent lack of H-2 restriction in vivo immunity does not eliminate a role for the H-2-restricted cytotoxic T cell in tumor transplantation immunity.     

The role of gamma interferon in DNA vaccine-induced tumor immunity targeting simian virus 40 large tumor antigen

The central role of CD4+ T lymphocytes in mediating DNA vaccine-induced tumor immunity against the viral oncoprotein simian virus 40 (SV40) large tumor antigen (Tag) has previously been described by our laboratory. In the present study, we extend our previous findings by examining the roles of IFN-γ and Th1-associated effector cells within the context of DNA immunization in a murine model of pulmonary metastasis. Immunization of BALB/c mice with plasmid DNA encoding SV40 Tag (pCMV-Tag) generated IFN-γ-secreting T lymphocytes that produced this cytokine upon in vitro stimulation with mKSA tumor cells. The role of IFN-γ as a mediator of protection against mKSA tumor development was assessed via in vivo IFN-γ neutralization, and these experiments demonstrated a requirement for this cytokine in the induction immune phase. Neutralization of IFN-γ was associated with a reduction in Th1 cytokine-producing CD4+ and CD8+ splenocytes, as assessed by flow cytometry analysis, and provided further evidence for the role of CD4+ T lymphocytes as drivers of the cellular immune response. Depletion of NK cells and CD8+ T lymphocytes demonstrated the expendability of these cell types individually, but showed a requirement for a resident cytotoxic cell population within the immune effector phase. Our findings demonstrate the importance of IFN-γ in the induction of protective immunity stimulated by pCMV-Tag DNA-based vaccine and help to clarify the general mechanisms by which DNA vaccines trigger immunity to tumor cells.     

The role of B cells in the establishment of T cell response in mice infected with an intracellular bacteria, Listeria monocytogenes.

To clarify the role of B cells in the establishment of T cell response against intracellular bacteria, B-cell-deficient (muMT-/-) mice were infected with an intracellular bacteria, Listeria monocytogenes, and T cell response against the bacteria was analyzed. On day 6 of primary Listeria infection, spleen T cells of the muMT-/- mice showed significantly lower levels of proliferative response and IFN-gamma production than those of normal infected mice after in vitro stimulation with listerial antigen. Even in the secondary Listeria infection after immunization with viable bacteria, spleen T cells of the muMT-/- mice proliferated and produced IFN-gamma against listerial antigen at significantly lower levels than those of normal immunized mice. These results demonstrate participation of B cells in priming of Listeria-specific T cells in vivo. However, B cells failed to present Listeria antigen to Listeria-specific T cells in vitro unless Listeria antigen was solubilized. Furthermore, transfer of immune serum from Listeria-infected normal mice failed to enhance the Listeria-specific T cell response of muMT-/- mice. The results indicate that B cells support the T cell response against intracellular bacteria through a mechanism other than their Ig production or antigen presentation function.     

Antigenic and Immunogenic Characteristics of Nuclear and Membrane-Associated Simian Virus 40 Tumor Antigen

Antisera were prepared in syngeneic hosts against subcellular fractions of simian virus 40 (SV40)-transformed cells (MoalphaPM, MoalphaNuc), glutaraldehydefixed SV40-transformed cells (HaalphaH-50-G, MoalphaVLM-G), and electrophoretically purified denatured SV40 tumor antigen (T-ag) (RaalphaT). Immune sera were also collected from animals bearing tumors induced by SV40-transformed cells (HaalphaT, MoalphaT, HAF) and from SV40-immunized animals that had rejected a transplant of SV40-transformed cells (HaalphaS, MoalphaS). Immunological reagents prepared against cell surface (MoalphaPM, HaalphaS, MoalphaS, HaalphaH-50-G, MoalphaVLM-G) reacted exclusively with the surface of SV40-transformed cells by indirect immunofluorescence or protein A surface antigen radioimmunoassay. Immunological reagents prepared against the nuclear fraction (MoalphaNuc) or whole-cell determinants (HaalphaT, MoalphaT, HAF, RaalphaT) reacted with both the nuclei and surface of SV40-transformed or -infected cells. All reagents were capable of immunoprecipitating 96,000-molecular weight large T-ag from solubilized whole cell extracts of SV40-transformed cells. The exclusive surface reactivity of HaalphaS exhibited in immunofluorescence tests was abolished by solubilization of subcellular fractions, which then allowed immunoprecipitation of T-ag by HaalphaS from both nuclear and plasma membrane preparations. Specificity was established by the fact that all T-reactive reagents failed to react in serological tests against chemically transformed mouse cells, and sera from mice bearing transplants chemically transformed mouse cells (MoalphaDMBA-2) failed to react with SV40-transformed mouse or hamster cells. Reagents demonstrating positive surface immunofluorescence and protein A radioimmunoassay reactions against SV40-transformed cells were capable of blocking the surface binding of RaalphaT to SV40-transformed cells in a double-antibody surface antigen radioimmunoassay. This blocking ability demonstrated directly that a component specificity of each surface-reactive reagent is directed against SV40 T-ag. A model is presented which postulates that the differential detection of T-ag by the various serological reagents is a reflection of immunogenic and antigenic differences between T-ag polypeptides localized in nuclei and plasma membranes.