Cell-mediated immunity to friend virus-induced leukemia. IV. In vitro generation of primary and secondary cell-mediated cytotoxic responses.

Primary and secondary cell-mediated cytotoxic responses to FBL-3 cells, a syngeneic Friend virus-induced leukemia in C57BL/6 mice, could be generated by in vitro techniques as tested by the 125IUdR release assay. The specificity of the cytotoxic reactions appeared to be directed against the Friend type-specific antigen and the FMR (Friend, Moloney, Rauscher) antigen which were also the major antigens for transplantation immunity to FBL-3. In comparison to the primary cytotoxic response, the secondary cytotoxic response was accelerated (detected at an earlier time after sensitization), enhanced (gave much higher levels of cytotoxicity), was also longer lasting, and could be induced by a wide dose range of tumor cells. The secondary response could only be induced with lymphocytes obtained from regressors that were resistant to FBL-3 challenge; lymphocytes from mice with progressive tumor growth had no detectable secondary response. It was found that both induction phase and the effector phase of cytotoxic responses were T cell dependent. The characteristics of these reactions were thus very similar to those obtained with in vivo immunization or challenge, providing a good correlation with in vivo tumor immunity.     

Cell-mediated immunity to Friend virus-induced leukemia. II. Characteristics of primary cell-mediated cytotoxic response.

The primary cell-mediated cytotoxic response to a Friend virus-induced leukemia, FBL-3, in C57BL/6 mice was measured by the 125IUdR release assay. Intraperitoneal (i.p.) inoculation of 1 x 10(1) FBL-3 cells produced progressive tumor growth (progressors); subcutaneous (s.c.) inoculation of as many as 5 x 10(6) FBL-3 cells produced only transient tumor growth (regressors), and these mice would subsequently resist i.p. challenge of FBL-3 cells at 3 days after s.c. inoculation. The kinetics of the primary cell-mediated cytotoxic response of regressors was biphasic. Significant cytotoxicity could be detected at 3 to 5 days after s.c. inoculation of 5 x 10(6) FBL-3 cells peaked at days 10 to 14, declined to a very low level or became undetectable around days 20 to 30; then the reactivity reappeared and persisted at least up to 60 days. In progressors, the kinetics of the cell-mediated cytotoxic response was similar to the regressors, but the reactivity was much lower. The cytotoxic response was found to be T cell dependent, during both the first peak (days 10 to 14) and the second peak (days 40 to 60). In adoptive transfer experiments, lymphocytes from regressors gave 90% protection against i.p. challenge of FBL-3; lymphocytes from progressors only gave 40% protection.     

Studies of the mechanisms for the induction of in vivo tumor immunity. I. Induction of primary and secondary cell-mediated cytotoxic responses by adoptive transfer of lymphocytes.

Cell-mediated immunity to FBL-3, a syngeneic Friend virus-induced leukemia in C57BL/6 mice, could be adoptively transferred. Characteristic primary and secondary cytotoxic responses could be induced by adoptive transfer of normal and presensitized lymphocytes, respectively. In vivo tumor immunity could also be produced by adoptive transfer of presensitized lymphocytes. Both the primary and secondary cell-mediated cytotoxic reactions were T-cell dependent. The specificity of these reactions was primarily directed against F (Friend) type-specific antigen and FMR (Friend, Moloney, Rauscher) common antigen. The cytotoxic responses produced by adoptive transfer experiments gave better correlation to in vivo tumor immunity than those generated by in vitro mixed lymphocyte tumor cell culture reactions.     

Regulation of the In Vitro Secondary Cell-Mediated Cytotoxic Response against Syngeneic FBL-3 Leukemia by Macrophages

Depletion of macrophages from immune spleen cells by treatment with carbonyl iron and magnet or by in vivo treatment with carrageenan enhanced the in vitro secondary cell-mediated cytotoxic response against a syngeneic Friend virus-induced leukemia, FBL-3 cells of C57BL/6 mice. However, further depletion of macrophages by passing the carbonyl iron-treated immune spleen cells through a nylon wool column abrogated the cytotoxic response. The addition of splenic macrophage-enriched preparations from either FBL-3-immune or normal mice suppressed the cytotoxic response of immune spleen cells treated with carbonyl iron and magnet. This suppressive effect of splenic macrophages presented a marked contrast with the enhancing effect of normal peritoneal macrophages on the same cell-mediated cytotoxic response, indicating regulation of the generation of killer T cells against a syngeneic tumor by functionally distinct macrophages. The suppressed cell-mediated cytotoxic response against FBL-3 cells by immune spleen cells was augmented by the addition of indomethacin to the culture medium, and this augmentation with indomethacin was greatly decreased by depletion of phagocytic cells from the immune spleen by treatment with carbonyl iron and magnet. The mechanisms of regulation of the cell-mediated cytotoxic response with soluble factors released from macrophages are discussed.     

Studies of the mechanisms for the induction of in vivo tumor immunity. IV. Enhancement of the in vitro generation of secondary cell-mediated cytotoxic response by normal peritoneal macrophages and their culture supernatants.

The effect of macrophages on the induction of the cell-mediated cytotoxicity against a leukemia in a syngeneic system was investigated. The addition of exogenous peritoneal cells from normal C57BL/6 MIce enhanced the in vitro secondary cell-mediated cytotoxic response of both spleen and lymph node cells as responding cells against syngeneic FBL-3 leukemia. Peritoneal phagocytic macrophages seemed to be responsible for the enhancement. No inhibitory effect was demonstrated by the addition of peritoneal macrophages at a concentration as high as 20%, whereas the primary cytotoxic allograft response was significantly suppressed. In the present studies, there was no absolute restriction of macrophage-T cell interaction by an H-2 barrier. Supernatants of peritoneal macrophage cultures also enhanced this cell-mediated cytotoxic response. There was no difference between the effects of syngeneic or allogeneic peritoneal macrophage culture supernatants.     

Cell-mediated immunity to Friend virus-induced leukemia. I. Modification of 125IUdR release cytotoxicity assay for use with suspension target cells.

Cell-mediated cytotoxic reactivity of C57BL/6 mice against syngeneic FBL-3 cells, a Friend virus-induced leukemia, was measured by the 125IUdR release assay with tumor target cells in suspension. The tests could be performed either with Linbro tissue culture plates(16-mm wells) or with Microtest II plates (6-mm wells). The former could only be harvested manually; the latter could be harvested mechanically by an automatic harvesting apparatus which permitted larger scale tests. With either plate, it was found that careful preparation of the target cells and of the attacker cells has important effects on the results obtained. When performed under optimal test conditions, the 125IUdR assay can be used as a very simple, objective, and reproducible assay for testing cell-mediated cytotoxicity.     

Studies of the mechanisms for the induction of in vivo tumor immunity. VI. Induction of specific and nonspecific cell-mediated immunity in tumor-bearing hosts and its correlation with transplantation tumor immunity

Studies were performed to determine the development of cell-mediated cytotoxic response at tumor site in C57BL/6 mice bearing progressively growing FBL-3 ascites leukemia. The effectors isolated from tumor ascites are found to be highly cytotoxic for leukemic target cells. The levels of cytotoxicity obtained with effectors isolated from tumor site are generally higher than those obtained with immune mice. This cytotoxicity is both specific and nonspecific. The specific cytotoxicity against tumor-associated antigen is mainly mediated by T cells and the nonspecific cytotoxicity against unrelated tumor cells is mediated largely by macrophages. The T-cell-enriched preparation did not give significant natural killer activity. When testing the ability of these effectors to produce in vivo immunity against the challenge of FBL-3, it was found that only T cells could confer the transplantation-type immunity, but the immunity was transient. The macrophage-enriched preparation isolated from tumor ascites failed to give in vivo protection. These findings indicate that in FBL-3 system, mice with progressively growing tumors are able to develop immune response against tumor cells. However, this immunity is probably interfered with by a suppressor factor(s) or suppressor cells which restrict their activity to eliminate the tumor cells effectively.     

Mechanisms of leukemogenesis. I. Generation of autoreactive lymphocytes in response to a murine leukemia virus.

Examined in this paper is the capacity of 334C murine leukemia virus (MuLV) to stimulate the generation of virus-specific cytotoxic effector cells in mice of the C57BL/6 strain that are relatively resistant to Friend, Moloney, and Rauscher (FMR) MuLV-induced leukemia, and in BALB/c mice that are relatively susceptible to leukemia induced by FMR MuLV. Generation of cytotoxicity requires in vivo administration of the virus followed by in vitro culture of lymphoid cells from virus-injected animals. Lymphoid cells from MuLV-resistant C57BL/6 donors develop high levels of specific cytotoxicity after secondary in vitro stimulation with syngeneic MuLV-induced tumor cells. Cells derived from these same donors, cultured in the absence of MuLV-induced tumor cells, fail to exhibit cytotoxicity. Secondary in vitro stimulation of lymphocytes from MuLV-susceptible BALB/c animals results not only in generation of cytotoxic reactivity against syngeneic MuLV-induced tumor cells but also induces apparently autoreactive effector cells capable of lysing other H-2d tumor cells as well as normal peritoneal cells bearing H-2d antigens. Moreover, generation of cytotoxicity by BALB/c lymphocytes occurs whether or not MuLV-induced tumor cells are included in the secondary culture system.     

Studies of the mechanisms for the induction of in vivo tumor immunity. V. A comparison of the generation of the primary cell-mediated cytotoxic response using in vitro mixed-lymphocyte--tumor cell culture and an in vivo technique

In vivo immunization of C57BL/6 mice with FBL-3, a syngeneic Friend-virus-induced leukemia, can induce a specific, T-cell-mediated cytotoxic response, as measured by the ¹²⁵IUdR release assay. In vitro it was difficult to generate an analogous, primary cytotoxic response, using a normal spleen responder population. After modification of the splenic responders by adding normal peritoneal cells, this modified population then had the capacity to mount a primary cytotoxic response in the mixed-lymphocyte-tumor cell culture reaction to FBL-3. We have characterized the effector population as well as the helper (peritoneal) cells which were responsible for elevating the cytolytic response to FBL-3. The results indicate that there are at least two populations of cells which are essential for inducing a primary cell-mediated cytotoxic response. First, the effectors which are directly responsible for mediating the cytotoxic reactions and are derived from radiosensitive T cells and second, a helper cell population which is radioresistant and has the characteristics of macrophages.     

In vitro reactivity of splenic lymphocytes from normal and UV-irradiated mice against syngeneic UV-induced tumors.

Skin tumors induced in mice by chronic ultraviolet (UV) irradiation are highly antigenic and are frequently immunologically rejected upon transplantation to normal syngeneic recipients. In this study we characterized this immune response with an in vitro microcytotoxicity test. Cytotoxic activity was present in the spleen cells of mice given a single injection of syngeneic UV-induced fibrosarcoma cells. After removal of adherent spleen cells, the remaining splenic lymphocytes were specifically cytotoxic for the immunizing tumor and showed no cross-reactivity with other syngeneic UV-induced or methylcholanthrene-induced tumors of similar histologic type. The level of cell-mediated reactivity against UV-induced tumors was quite high compared to that obtained with syngeneic tumors induced by methylcholanthrene, and the cytotoxicity was attributable to a population of theta antigen-bearing lymphocytes. With this in vitro test, we compared the response of normal mice, which reject a syngeneic tumor challenge, with that of UV-irradiated mice, in which the syngeneic UV-induced tumors grow progressively. After tumor cell inoculation, lymphocytes form the unirradiated (regressor) mice showed a high degree of cytotoxicity that reached a maximum level 8 days after injection. In contrast, no reactivity could be detected in the spleens of tumor-challenged UV-irradiated (progressor) mice.     

Studies of H-2 restriction in cell-mediated cytotoxicity and transplantation immunity to Leukemia-associated antigens.

H-2 dependency of T cell-mediated cytotoxicity and transplantation immunity to leukemia-associated antigens has been investigated. Through the use of a 20-hr 125IUdR release assay, it was found that the induction of T cell-mediated cytotoxicity against Friend virus-induced leukemias of different H-2 haplotype orgins could be produced by immunization with both syngeneic and allogeneic tumor cells; the effector cells that were generated by syngeneic immunization could also provide effective killing of allogeneic tumor cells, although the killing of allogeneic targets might require a longer incubation time (20 to 40 hr). Furthermore, in vivo transplantation immunity against Friend virus-induced leukemias also was induced by immunization with both syngeneic and allogeneic tumors and syngeneic immunization could induce specific protection against the challenge with a-logeneic tumor in x-irradiated hosts. These findings clearly indicate that, both at the sensitizing phase and effector phase of the immune response, there is no strict H-2 dependency for T cell-mediated cytotoxicity or in in vivo transplantation imunity to leukemia-associated antigens.     

Characterization of the blastogenic and cytotoxic responses of normal mice to ecotropic C-type viral gp71.

Spleen cells from normal (B6C3)F1 mice demonstrated natural cytotoxic reactivity mediated by a "null" cell population which, in part, had immunologic specificity for the major envelope glycoprotein (gp71) of the endogenous ecotropic murine leukemia virus. In contrast, the cytotoxic reactivity reflected in spleen cells of NIH Swiss nude mice apparently had no immunologic specificity. A significant level of blastogenic response could be generated in vitro by using normal (B6C3)F1 and AKR spleen cells in the presence of gp71. This reactivity was highly type specific. Moreover, using normal spleen cells from (B6C3)F1, both secondary blastogenic responses and cytotoxic T cell responses could be induced in vitro with purified soluble viral gp71. These findings extend further our previous studies on the existence of a natural immune response in normal mice to their endogenous MuLV by providing in vitro evidence for the expression of cell-mediated response in addition to the humoral response and that at least two effector cell types are operable in the cell-mediated phase.     

Low density of Thy 1 antigen on mouse effector cells mediating natural cytotoxicity against tumor cells.

Mouse effector cells mediating natural cell-mediated cytotoxicity against tumor cells were found to contain a low density of Thy 1 antigen. Treatment of nude spleen cells, or spleen cells from mice in which natural reactivity was boosted, with anti-Thy 1.2 plus complement resulted in a substantial decrease in cytotoxicity. The spontaneous cytotoxic reactivity of young, thymus-bearing mice was resistant to such treatment, but repeated exposure to anti-Thy 1.2 plus complement did cause a decrease in lytic activity. By use of congenic anti-Thy 1.2 and effector cells from mice congenic for Thy 1, the effects of the treatment were shown to be specific for Thy 1.2 antigen.     

The immune response to Moloney murine leukemia virus-induced tumors: induction of cytolytic T lymphocytes specific for both viral and tumor-associated antigens

The specificity of CTL generated against tumors induced by murine leukemia viruses (MuLV) has been reported to parallel the expression of two serologically defined tumor cell surface antigens--the cross-reactive FMR antigen expressed on the surface of tumors induced by Friend, Moloney, and Rauscher MuLV, and the Gross cell surface antigen (GCSA) expressed on tumors induced by AKV/Gross MuLV. We examined the specificity of CTL generated against MuLV-induced tumors and identified two distinct patterns of reactivity. The first follows the traditional pattern of FMR vs GCSA reactivity as assessed on a panel of established MuLV-induced lymphomas. However, CTL exhibiting this pattern of reactivity are incapable of lysing MuLV-infected fibroblasts. CTL exhibiting the second pattern of reactivity are capable of lysing MuLV-induced lymphomas as well as MuLV-infected fibroblasts. In addition, these CTL exhibit extensive cross-reactivity between lymphomas and fibroblasts infected by both groups of MuLV. Our results suggest that CTL exhibiting the traditional FMR vs GCSA pattern of reactivity are directed against a tumor-associated antigen and not against virus-encoded antigens, and that CTL directed against MuLV-encoded antigens demonstrate extensive cross-reactivity, including the ability to lyse AKV-infected cells.     

Generation of cytotoxic T lymphocytes during coxsackievirus B-3 infection. I. Model and viral specificity1.

The production of cytotoxic cells in the spleen of adult male BALB/c mice infected with Coxsackievirus B-3 has been examined.An in vitro 51Cr release assay was used to measure cytotoxic activity against virus-infected and uninfected neonatal sygeneic fibroblasts. Cytotoxicity of immune spleen cells against virus-infected targets was detected on the 3rd day after infection, reached a peak on day 7, and then declined to low levels by days 12 and 14. Spleen cells obtained 3 and 5 days after infection also exerted cytotoxicity against uninfected fibroblasts, but by the 7th day there was little or no reactivity against uninfected target cells, although activity against infected fibroblasts was maximal at this time. Reciprocal assays performed by using Coxsackie and vaccinia viruses provided evidence of virus specificity of the cytotoxic reaction. When spleen cells were obtained 7 days after infection, the Coxsackievirus-immune population was not cytotoxic for vaccinia-infected fibroblasts, and the vaccinia-immune population was not cytotoxic for Coxsackievirus-infected targets, although each immune cell preparation caused significant lysis of fibroblasts infected with the homologous virus. Additional studies showed that primary mouse or hyperimmune rabbit anti-Coxsackieviral serum could not block immune spleen cell cytotoxicity or induce complement-mediated lysis of infected targets. The findings indicate that Coxsackievirus infection results in surface membrane alterations, but no evidence was obtained that antiviral antibody could react with the infected cells.     

Distinct proliferative T cell clonotypes are generated in response to a murine retrovirus-induced syngeneic T cell leukemia: viral gp70 antigen-specific MT4+ clones and Lyt-2+ cytolytic clones which recognize a tumor-specific cell surface antigen

After immunization of B6 mice with the syngeneic retrovirus-induced T cell leukemia/lymphoma FBL-3, two major tumor-specific proliferative T cell clonotypes were derived. T cell clones derived from long-term lines propagated by in vitro culture with irradiated tumor cells and syngeneic spleen cells were exclusively of the Lyt-2+ phenotype. Such clones were cytolytic, retained their proliferative phenotype indefinitely when expanded by repeated cycles of reactivation and rest, and recognized a tumor-specific cell surface antigen in association with class I MHC molecules. This tumor cell antigen was not present on nontransformed virus-infected cells. Class II MHC-restricted MT4+ clones specific for the viral antigen gp70 were derived from lymph node T cells of FBL-3 tumor-immune mice only by in vitro culture with purified Friend virus in the presence of syngeneic splenic APC. Once derived, however, such clones could be stimulated in the presence of FBL-3 tumor cells and syngeneic spleen cells, demonstrating the reprocessing of tumor-derived gp70 antigen by APC in the spleen cell population. In contrast, no reprocessing of the tumor cell surface antigen by splenic APC for presentation to the class I MHC-restricted T cell clones could be demonstrated. Evidence is presented that FBL-3 T leukemia/lymphoma cells function as APC for Lyt-2+ class I MHC-restricted clones, and that no concomitant recognition of Ia molecules is required to activate these clones. Both Lyt-2+ and MT4+ clones were induced to proliferate in the presence of exogenous IL2 alone, but this stimulus failed to result in significant release of immune interferon. In contrast, antigen stimulation of both clones resulted in proliferation as well as significant immune interferon release. Immune interferon production is not required for the generation of MHC-restricted cell-mediated cytolytic function.     

Cell-mediated immune response to syngeneic UV induced tumors: I. The presence of tumor associated macrophages and their possible role in the in Vitro generation of cytotoxic lymphocytes

A primary in vitro sensitization system employing a chromium release assay was utilized to investigate reactivity of murine spleen cells toward syngeneic ultraviolet (uv) light induced fibrosarcomas. These tumors are immunologically rejected in vivo when implanted into normal syngeneic mice but grow progressivly when implanted into syngeneic mice that had previously been irradiated with subcarcinogenic levels of uv light. Following appropriate sensitization, spleen cells from both normal and uv irradiated mice are capable of developing cytotoxic lymphocytes in vitro against the uv induced tumors. It was subsequently discovered that in situ uv induced tumors all contained macrophages of host origin that became demonstrable only after enzymatic dissociation of the tumor tissue. These macrophages were immunologically active in vitro as their presence in the stimulator cell population was necessary to achieve an optimum anti-tumor cytotoxic response following in vitro sensitization. Anti-tumor reactivity generated by mixing spleen cells and tumor cells in the absence of tumor derived macrophages could be greatly enhanced by the addition of normal syngeneic peritoneal macrophages. When in vitro anti-tumor reactivity of spleen cells from normal and uv treated mice was compared under these conditions we again found no significant difference in the magnitude of the responses. In addition, the cytotoxic cells generated in response to uv induced tumors appeared to be highly cross reactive with respect to their killing potential. Cross reactive killing was observed between all uv induced tumors tested as well as with a syngeneic benz[a]pyrene (BP) induced fibrosarcoma. No cytotoxicity was observed against normal syngeneic PEC's even through these cells were shown to be susceptible to lysis by anti-H-2^k effector cells. It was concluded that: (a) A significant number of host-derived macrophages are present in uv tumor tissue. (b) These macrophages are important for the in vitro generation of tumor specific cytotoxicity. (c) Spleen cells from uv treated mice are capable of recognizing and responding against uv tumor associated antigens in vitro. Cytotoxic effector cells generated in response to uv induced tumors appear to have specificity for tumor associated antigens (TAA) present on all uv tumors tested as well as a syngeneic BP induced tumor. The relationship between in vivo and in vitro reactivity against uv tumors is discussed.     

Adoptively transferred antigen-specific T cells can be grown and maintained in large numbers in vivo for extended periods of time by intermittent restimulation with specific antigen plus IL-2

The aim of the current study was to determine whether cultured tumor Ag-specific T cells could be induced to grow and maintained functional in large numbers in vivo by intermittent restimulation in vivo with specific Ag plus IL-2. T cells derived from spleens of B6 mice (Thy-1.2) immune to FBL-3, a Friend virus-induced leukemia, were activated by in vitro stimulation with irradiated FBL-3 and expanded by culture for 14 days with low concentrations of IL-2. The resultant FBL-3-specific T cell lines were adoptively transferred into cyclophosphamide pretreated congenic hosts (B6/Thy-1.1), and restimulated every 14 days by an injection of irradiated FBL-3 plus a 7-day course of IL-2. Donor T cells residing in the host were identified and quantified by use of antibody to the Thy-1.2 allele. The results confirmed that stimulation with FBL-3 on the day of transfer (day 0) plus IL-2 on days 0 to 6 induced rapid growth of donor T cells to approximately an 11-fold increase in total donor T cell number recoverable from host ascites and spleen by day 7. However, prolonging the course of IL-2 administration to 35 days did not maintain the number or the specific cytolytic function of donor T cells. By contrast, intermittent restimulation with specific Ag plus IL-2 induced intermittent regrowth of donor T cells in vivo, maintained the number of donor T cells in vivo at greater than the number input for longer than 1 mo, and allowed detection of substantially augmented donor T cell-mediated specific antitumor function over that period of time.     

Identification of a gag-encoded cytotoxic T-lymphocyte epitope from FBL-3 leukemia shared by Friend, Moloney, and Rauscher murine leukemia virus-induced tumors.

FBL-3 is a highly immunogenic murine leukemia of C57BL/6 origin induced by Friend murine leukemia virus (MuLV). Immunization of C57BL/6 mice with FBL-3 readily elicits CD8+ cytotoxic T lymphocytes (CTL) capable of lysing FBL-3 as well as syngeneic leukemias induced by Moloney and Rauscher MuLV. The aim of this current study was to identify the immunogenic epitope(s) recognized by the FBL-3-specific CD8+ CTL. A series of FBL-3-specific CD8+ CTL clones were generated from C57BL/6 mice immunized to FBL-3. The majority of CTL clones (32 of 38) were specific for F-MuLV gag-encoded antigen. By using a series of recombinant vaccinia viruses expressing full-length and truncated F-MuLV gag genes, the antigenic epitope recognized by the FBL-3 gag-specific CTL clones, as well as by bulk-cultured CTL from spleens of mice immune to FBL-3, was localized to the leader sequence of gPr80gag protein. The precise amino acid sequence of the CTL epitope in the leader sequence was identified as CCLCLTVFL (positions 85-93) by examining lysis of targets incubated with a series of synthetic leader sequence peptides. No evidence of other CTL epitopes in the gPr80gag or Pr65gag core virion structural polyproteins was found. The identity of CCLCLTVFL as the target peptide was validated by showing that immunization with the peptide elicited CTL that lysed FBL-3. The CTL elicited by the Gag peptide also specifically lysed syngeneic leukemia cells induced by Moloney and Rauscher MuLV (MBL-2 and RBL-5). The transmembrane peptide was shown to be the major gag-encoded antigenic epitope recognized by bulk-cultured CTL derived from C57BL/6 mice immunized to MBL-2 or RBL-5. Thus, the CTL epitope of FBL-3 is localized to the transmembrane anchor domain of the nonstructural Gag polyprotein and is shared by leukemia/lymphoma cell lines induced by Friend, Moloney, and Rauscher MuLV.     

Chemoimmunotherapeutic effect of cyclophosphamide on the highly metastatic MAT 13762 tumor

Summary We have observed that cyclophosphamide (CY) treatment of 13762 mammary adenocarcinoma tumor-bearing rats was found to cause tumor regression. Tumor-bearing animals cured with three low doses of CY were partially immune against IV and SC challenge with a high dose of 13762 cells. This immune protection mechanism in CY-cured animals appears to be a T (Ig^–) cell-mediated response. Irradiated rats reconstituted with CY-cured animal spleen cells were also partially protected against IV and SC challenge with 13762 cells, whereas irradiated rats reconstituted with CY-control animal spleen cells were not. In vitro primary and secondary cell-mediated cytotoxic activity of CY-cured spleen cells against target 13762 cells was low. The possible relevance of this tumor-model study is in the understanding of CY-induced tumor immune response and its role in preventing metastases or perhaps recurrent tumor growth.