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 thymopoietin pentapeptide (TP5) on experimental tumors: I. TP5 relieves immunosuppression in tumor-bearing mice

The allogeneic and syngeneic immune responses of tumor-bearing mice (C57BL/6 mice bearing 3LL and DBA mice bearing P815) were evaluated by the cytotoxic lymphocyte precursor unit (CLP-U) and MLC. In general, tumor-bearing mice showed slightly enhanced immune responses 4 days after tumor inoculation. This enhanced immune response rapidly declined and about 7–10 days after tumor inoculation, both allogeneic and syngeneic responses were markedly lower than normal. Mice treated with TP5, starting 2 weeks before tumor inoculation, retained normal or enhanced allogeneic and syngeneic responses up to 3 weeks after tumor inoculation. When this tumor-induced suppressive effect was studied in cell transfer experiments, spleen cells from tumor-bearing mice enhanced the growth of tumors in syngeneic recipients whereas spleen cells from TP5-treated mice inhibited the growth of tumors in syngeneic recipients. Moreover, the spleen cells from TP5-treated mice also showed enhanced cytotoxic activity against tumor cells in vitro. These findings suggest that the tumors, after a transient stimulatory phase, induced immune suppressive mechanisms in the hosts' immune defenses. Treatment with TP5 prevented the development of these immune suppressive effects and spleen cells from TP5-treated tumor-bearing mice inhibited tumor growth in freshly tumor-inoculated recipients.     

Immunologic significance of nonspecific suppressor cells in spleens of tumor-bearing mice.

Spleen cells from mice bearing a progressively growing syngeneic tumor failed to respond to stimulation with mitogens in vitro. This lack of reactivity was due to the presence of nylon wool-adherent cells in the population that could inhibit the mitogen response of normal lymphocytes. Paradoxically, at times when strong suppressor cell activity could be detected in tumor-bearing mice, the animals responded normally to in vivo immunization with sheep erythrocytes and allogeneic tumors, and to in vitro sensitization with allogeneic tumor cells. Regression of a highly antigenic syngeneic tumor also was unaffected by the presence of these suppressor cells. Thus, the occurrence of nonspecific suppressor cells in the spleens of tumor-bearing mice did not influence the overall immunologic competence of these animals.     

Studies on the specificity of in vitro-induced lymphocytotoxicity to methylcholanthrene-induced fibrosarcoma cell lines

Cytotoxic effector lymphocytes were induced by in vitro immunization of lymph node and spleen cells from CS7B16(H2^b) and Balb/c(H2^d) mice to syngeneic or allogeneic methylcholanthrene-induced fibrosarcoma (MCAF) cell lines. The T cell-dependent cytotoxicity was specific to target cell lines to which the lymphocytes were immunized in vitro. Normal fibroblasts as stimulator cells did not induce lymphocytotoxicity to syngeneic MCAF cells or to normal syngeneic fibroblasts. The results indicate that the in vitro-immunized lymphocytes recognize individual specific tumor-associated antigens of the MCAF cells. In experiments in which the lymphocytes were immunized in vitro to allogeneic MCAF cells, cytotoxic reactions to alloantigens, but not to tumor-associated antigens, were detected. Incubation with phytohemagglutinin (PHA) during the sensitization period modified the specificity of the cell-mediated lysis of MCAF cells: Allogeneic as well as syngeneic target cells were destroyed by these effector cells. PHA induced a nonspecific cytotoxic effect which increased the specific lysis of target cells. The cytotoxicity of the in vitro-immunized lymphocytes was inhibited by incubation with membrane protein preparations from the syngeneic MCAF cell lines. In contrast to the specificity of the cytotoxic effect to the different syngeneic cell lines, the membrane extract of one individual syngeneic MCAF cell line was able to inhibit the lymphocytotoxicity to all other syngeneic cell lines. Membrane protein preparations from allogeneic MCAF cells or from normal syngeneic fibroblasts were not inhibitory. The in vitro-immunized cytotoxic lymphocytes did not impair the tumor growth in vivo as could be demonstrated by passive transfer of the lymphocytes in a Winn assay.     

Production of specific macrophage activating factor by lymphocytes from tumor-bearing mice.

Lymphocytes from C57BL mice bearing a syngeneic UV-induced fibrosarcoma (UV-112) produced macrophage activating fatcor (MAF) when cultured with UV-112 cells in vitro. This MAF rendered normal C57BL macrophages cytotoxic in vitro to UV-112 cells. MAF production and lymphocyte-mediated cytotoxicity were detected in the early stages of tumor growth, but were absent in mice bearing large tumors. This eclipsed reatcivity was specific for the growing tumor. Lymphocytes from mice bearing a large UV-112 tumor were still able to produce MAF in response to B16 melanoma to which they had been preimmunized. In all instances, the MAF produced was specific in that it rendered syngeneic macrophages cytotoxic against only the tumor used for immunization.     

The requirement of Ia-positive accessory cells for the induction of tumor-specific cytotoxic T lymphocytes in vitro

The mechanism for the induction of cytotoxic T cells specific for tumor-associated antigens was studied by using fractionated responder T cells, tumor cells, and accessory cells in vitro. The tumor-specific cytotoxic T cells were induced by culturing immunized spleen cells with the tumor cells in vitro for 5 days. Nylon-column-purified T cells alone did not induce cytotoxic T cells upon culture with tumor cells, but the addition of normal spleen cells as accessory cells did successfully induce the cytotoxic T cells, suggesting that the presence of accessory cells is required for the activation of tumor-specific cytotoxic T cells in vitro. The accessory function was associated with spleen cell populations adhering to a plastic dish, a Sephadex G-10 column or a nylon wool column, and was sensitive to anti-Ia serum and C treatment, but was resistant to anti-Ig serum or anti-Thy 1 serum and C treatment, suggesting that the accessory cells are Ia-positive macrophages. Not only syngeneic but also allogeneic macrophages had the accessory function and the allogeneic macrophages were also Ia positive. These results suggest that Ia-positive macrophages play a crucial role in the induction of tumor-specific cytotoxic T cells in vitro. The possible role of Ia-positive accessory cells in the induction of tumor-specific cytotoxic T cells is discussed from the standpoint of cellular interactions.     

Cell-mediated immune response to syngeneic ultraviolet-induced tumors. II. The properties and antigenic specificities of cytotoxic T lymphocytes generated in vitro following removal from syngeneic tumor-immunized mice.

The immune responses of C3Hf mice to syngeneic fibrosarcomas induced with either ultraviolet light or methychlolanthrene (MCA) were measured in vitro by the ability of cytotoxic lymphocytes (CTL) from immunized animals to kill ⁵¹Cr-labeled tumor targets in a 6-hr assay. The CTL were generated by the in vitro culturing of draining popliteal lymph node (DLN) cells derived from animals that were footpad immunized 8 days previously. It was determined that CTL activity could be generated using DLN from both normal (uv tumorresistant) and uv-exposed (uv tumor-susceptible) C3H mice. The kinetics of CTL generation between these two groups, however, was different in that the lymphocytes from normal animals appeared to differentiate into CTL faster than the lymphocytes from the uv-irradiated mice. The in vitro generation of CTL activity was found to be extremely radiosensitive and was also inhibited by the presence of viable tumor cells within the cell culture. Once generated, it was observed that the CTL were extremely insensitive to the effects of gamma irradiation. It was also established that the CTL is a T lymphocyte that appears to be Ia^?. The CTL derived from mice immunized to syngeneic uv- or MCA-induced tumors were capable of expressing cross-reactive non-MHC-restricted killing of multiple tumor targets. Cold cell inhibition experiments confirmed the presence of cross-reactive determinants on various tumors and also established the presence within a single CTL preparation of effector cells with specificity for both the unique tumor specific transplantation antigens as well as the common (cross-reactive) tumor-associated antigens.     

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.     

Suppressor factor from tumor-allosensitized spleen cells--its effect on in vitro proliferation of tumor cells and in vivo skin allograft survival

C57BL/6 mice are sensitized ip with allogeneic P-815 mastocytoma cells. Fifteen days later the spleen cells of the sensitized mice are used in the production of suppressor factor or treated with mitomycin and used as suppressor cells. Sensitized spleen cells incubated with the specific alloantigen (DBA/2 m-treated spleen cells) release suppressor factor (SF)² which inhibits cell proliferation in mixed lymphocyte culture (MLC) as well as the in vitro generation of cytotoxic cells (CML). SF is most effective when added eary during MLC. SF also inhibits mitogen responsiveness of normal spleen cells. In addition to inhibiting lymphocyte function in vitro, suppressor cells as well as SF inhibit the in vitro proliferation of tumor cells. This inhibition is specific for the tumor to which the suppressor cells are induced. The inhibition of tumor cell proliferation is not due to the presence of cytotoxic cells in the spleen of the tumor-allosensitized mice. Suppressor cells from neonatal mice do not inhibit the in vitro proliferation of tumor cells. SF injected iv into C57BL/6 mice decreases the mixed lymphocyte reactivity of the host spleen cells and decreases the ability of the host to reject skin allografts. We interpret these data to suggest that tumor-allosensitized spleen cells, and the SF they produce, not only affect lymphocyte function but also inhibit tumor cell proliferation. This dual effect of suppressor cells could be an important part of the immune surveillance against tumors.     

Identification and cytotoxic reactivity of inflammatory cells recovered from progressing or regressing syngeneic UV-induced murine tumors.

Most tumors induced in C3H mice by ultraviolet (UV) light are immunologically rejected by normal syngeneic recipients, but will grow progressively in immunosuppressed mice and in mice treated with UV light. In this study we compared the composition and cytotoxic activity of the inflammatory cell infiltrate from tumors transplanted into syngeneic UV-irradiated or unirradiated mice. Tumor fragments were implanted in either normal (regressor) or UV-treated (progressor) mice, and removed on various days after implantation and mechanically dissociated. The cells were examined by immunofluorescence for theta and immunoglobulin markers, stained for morphologic examination, and tested for cytotoxicity against the tumor. No significant differences were noted in numbers of macrophages, granulocytes, or B cells recovered from progressing or regressing tumors on day 6, the time of greatest activity. However, the numbers of T cells recovered from tumor fragments implanted in normal mice was approximately 3-fold that recovered from tumor fragments implanted in UV-treated mice. Lymphocytes recovered from regressing tumor fragments were specifically cytotoxic for that tumor in a microcytotoxicity test; those from progressing tumor fragments were not cytotoxic.     

Tumoricidal responses in vitro of peritoneal macrophages from conventionally housed and germ-free nude mice

Peritoneal macrophages from untreated nude mice were nonspecifically cytotoxic to tumor cells in vitro and were more responsive to chemotactic stimuli than macrophages from normal mice or from phenotypically normal littermates of nude mice. Tumoricidal and chemotactic responses of activated macrophages from nude mice were quantitatively comparable to responses of macrophages from BCG-infected normal mice. Peritoneal macrophages from germ-free nude mice, however, were not tumoricidal in vitro. These observations suggest that environmental stimuli, rather than thymic deficiency per se, induced activated macrophages in nude mice.     

Participation of three lymphoid cell types in the in vitro activation of cell-mediated immunity to a syngeneic gross virus-induced lymphoma in rats.

W/Fu rats inoculated with the syngeneic Gross-virus induced lymphoma, (C58NT)D, had transient lymphocyte-mediated specific cytotoxicity against the tumor cells at 7–15 days after tumor injection. Spleen cells 40 days after immunization (spleen 40) were unreactive by a direct 4-hr ⁵¹Cr release assay, but activity appeared after in vitro culture of these spleen eclls by themselves for 18–24 hr. The nature of the cells involved in the activation of cytotoxicity and the characteristics of the effector cells themselves were studied. Significant differences were seen in the cell types involved in the activation phase and the effector phase. Activation appeared to require the cooperation of three cell types. Induction of activity was lost by treatment of cells with ATS plus complement, by passage over an EAC-column, or by treatment with carbonyl iron. Thus, T cells, CRL and macrophages were necessary for full activation of cytotoxicity in spleen 40. In contrast, after activation, only CRL seemed to be required for cytotoxicity, and treatment wih ATS or carbonyl iron had little effect. The effector cell detected after in vitro activation was quite distinct from that seen in the direct cytotoxicity assay with spleen cells at 10 days after tumor cell inoculation. The early, direct cytotoxic reactivity was dependent on T cells, being eliminated by treatment with ATS and complement but not by EAC columns or carbonyl iron. It appears therefore that the in vitro activation is a separate mechanism for cytotoxicity against tumor cells, rather than a simple recovery of T cells from in vivo inhibition.     

Subpopulations of human T lymphocytes. II. Effect of thymopoietin, corticosteroids, and irradiation.

Lymphoid cells from normal SJL/J mice gave high proliferative responses but failed to develop cytotoxic activity to γ-irradiated cells from syngeneic transplantable reticulum cell sarcomas (X-RCS). In spite of a vigorous in vivo proliferative response to X-RCS, cytotoxic activity was never generated to detectable levels in vivo. After repeated injections of X-RCS, spleen and, to a lesser degree, lymph node cells acquired the ability to give moderate secondary cytotoxic responses in vitro upon co-culture with X-RCS. This immunity was T-cell mediated and specific for RCS although it did not distinguish between different transplantable RCS lines. SJL/J mice also developed resistance to RCS growth after injection of X-RCS, which showed a transient RCS-line-specific component. (SJL/J × C₅₇B1/6)F₁ mice showed 60% less RCS growth than did SJL/J mice, and their lymphoid cells gave slightly lower proliferative responses than did cells from SJL/J mice, whereas (SJL/J × BALB/c)F₁ mice showed little tumor growth, and their spleen cells proliferated only minimally to X-RCS. B10.S mice allowed moderate RCS growth. Cytotoxic activity was generated in co-cultures with X-RCS of immunized F₁ spleen cells even after a single immunization in vivo but not in cultures of normal F₁ cells with X-RCS.     

Intracellular localization of anti-tumor immune RNA.

Syngeneic spleen cells from normal, non-immune Fischer 344/N rats and allogeneic spleen cells from normal Wistar-Furth rats became cytotoxic, in vitro, to chemically induced Fischer rat sarcoma (MC3-R) target cells following incubation with xenogeneic Immune RNA (I-RNA) extracted from spleens of guinea pigs immunized with MC3-R tumor cells. I-RNA extracted from intact spleen cells or from the cytoplasmic fraction of spleen cells were equally active. RNA extracted from isolated spleen cell nuclei was inactive, as were all RNA fractions from spleen cells of nonspecifically immunized guinea pigs. Syngeneic I-RNA extracted from intact spleen cells or the cytoplasmic fraction of cells from spleens of Fischer rats bearing growing MC3-R transplants mediated cytotoxic reactions against MC3-R target cells when incubated with normal Fischer rat spleen cells. RNA from the nuclei of spleen cells of rats bearing MC3-R tumors was considerably less active. All RNA fractions from spleen cells of normal non-immune Fischer rats were inactive. The immunologically active component of xenogeneic and Syngeneic I-RNA, therefore, were found to be localized in the cytoplasm of specifically sensitized lymphoid cells.     

Concanavalin A-mediated in vitro activation of lymphocytes primed against syngeneic SV40-induced tumor-associated antigens in mice into secondary effector cells capable of specifically preventing tumor growth.

Spleen cells from BALB/c mice immunized against a syngeneic SV40-induced tumor, mKSA, prevented specifically the growth of the corresponding tumor in the tumor cell neutralization assay following preincubation for 5 days with mitogenic concentrations of concanavalin A. This reactivity was shown to be T cell dependent, independent of remaining concanavalin A, and was detected at least up to 60 days following in vivo antigenic immunization. A similar reactivity was obtained with mitogenic concentrations of phytohemagglutinin but not with the B-cell mitogen lypopolysaccharide. Since this reactivity was indistinguishable from that obtained upon in vitro secondary antigenic stimulation with SV40-transformed cells, it is suggested that activation of precytotoxic cells against a syngeneic tumor by concanavalin A into cytotoxic cells may be mediated by the same or similar receptors triggered by the stimulating tumor-associated antigens.     

Synergy between spleen cells and bone marrow cells in mixed lymphocyte culture-induced cytotoxicity: Requirement for macrophages in the induction of synergy

Synergistic interaction between isogeneic spleen cells and bone marrow cells were induced during the in vitro generation of cytotoxic effector cells against alloantigens. The observed synergy occurs during the early sensitization period and not at the effector phase of cytotoxicity. The cytotoxic effector cells appear to be T cells provided by spleen cells. The synergizing cells are Thy-1-negative subpopulations of bone marrow cells have light to moderate densities on BSA gradient, and appear to interact with splenic T cells only in the presence of macrophages.     

Suppressor T cells induced by soluble immune complexes can adoptively transfer inhibition of cytophilic antibody receptors on macrophages.

Immune complexes (soluble antigens of L1210 and antibody to L1210) when given to allogeneic C3H mice generated suppressor cells that inhibited receptors for cytophilic antibody on macrophages. Thymocytes or nylon-nonadherent splenic T cells (4 × 10⁷) from immune-complex-treated mice transferred this suppressive activity when injected into normal syngeneic mice. Maximal suppression of macrophages occurred 4 to 6 days after transfer. In contrast, even 5 × 10⁷ nylon-adherent, non-T spleen cells from immune-complex-treated (“suppressed”) mice failed to induce macrophage suppression in the syngeneic recipients. When T-cell-depleted “B” mice were used as recipients, neither thymocytes nor splenic T cells from suppressed mice were able to transfer suppressive activity. However, the admixture of 2 × 10⁷ normal syngeneic thymocytes with 4 × 10⁷ thymocytes from suppressed mice restored the latter's ability to elicit suppression of macrophages in T-cell-deprived recipients. Peritoneal monocytes from recipients of suppressor thymocytes (to L1210) could not attach cytophilic antibody to L1210 but could attach cytophilic antibody to EL-4 and sheep erythrocytes. Thus, suppressor T cells induced by immune complexes can transfer immunologically specific macrophage suppression (inhibition of cytophilic antibody receptors) to syngeneic recipients. The suppressor cells required the cooperation of normal T cells, suggesting either recruitment of suppressor cells from, or a helper effect by, the normal T cells, in order to produce their effect.     

Isolated soluble fractions from the murine B16 melanoma induce primary in vitro syngeneic antitumor responses

Summary This paper extends our previous studies, which documented our ability to isolate immunogenic entities from nonimmunogenic or weakly immunogenic tumors.B16 melanoma cells failed, in our in vitro experimental system, to induce anti-B16 cytotoxic responses in spleen cells derived from normal syngeneic C57BL/6 mice. The B16 melanoma cellular homogenate was fractionated on an Ultrogel AcA 34 column, and the various fractions were tested for their ability to induce anti-B16 cytotoxic responses under the same conditions as those used for intact B16, the nonimmungenic tumor cells. Certain fractions, some of them with relatively low protein concentrations, induced anti-B16 cytotoxic responses in spleen cells of normal C57BL/6 mice, whereas others, some of them with relatively high protein concentrations, failed to induce such responses. One fraction (Fr.), designated Fr. 5/6, was examined in detail. It was found that in normal syngeneic spleen cells this fraction induced effector cells that efficiently killed (at various E : T ratios) the relevant B16 target cells and RBL5 syngeneic tumor cells, but not the YAC allogeneic tumor cells or C57BL/6 lymphoblasts. Furthermore, an excess of unlabeled B16 cells most efficiently blocked the ability of these anti-B16 effector cells to kill radiolabeled B16 target cells. RBL5 tumor cells, YAC tumor cells, or C57BL/6 lymphoblasts failed to block these effector cells efficiently. A significant fraction of the effector cells induced with Fr. 5/6 was characterized as thymus-derived cells (Thy-1⁺, Thy-2⁺3⁺ cells). It was suggested that another fraction of the cellular population was natural killer cells, which cytolyzed the RBL5 target cells. Various theoretical and practical aspects of these findings are discussed.     

Cellular interactions in lymphocyte proliferation: effect of syngeneic and xenogeneic macrophages.

Secondary cell-mediated responses to ectromelia virus infection were studied using an in vitro system. Lymphoid “responder” cells from mice which had recovered from intravenous primary infection at various times prior to sacrifice, were cultured with syngeneic, virus-infected macrophages or spleen cells as “stimulator” cells at 39 °C, a temperature which prevented the virus from exerting cytopathic effects against responder cells. This restrictive temperature and medium with 2-mercaptoethanol at 10^?4M often gave viable cell yields of more than 100% of the original responder cells over 4 days of culture. Preliminary experiments showed that spleen cells from primed mice, cultured with syngeneic, infected spleen cells from normal mice gave the most powerful secondary cytotoxic cell responses as measured by ⁵¹Cr release from virusinfected H-2-compatible target cells. The cytotoxic cells were sensitive to anti-θ and complement treatment and lysed H-2-compatible, virus-infected target cells much more efficiently than infected, allogeneic target cells, thus indicating that they were T cells. Some activity against uninfected H-2-compatible target cells was also generated, but this was largely independent of the presence of virus-induced antigen, (i.e. infected stimulator cells were unnecessary) and therefore seemed to be a consequence of the cultural conditions. Cold target competition showed that this activity was the responsibility of a T cell subset separate from the virus-specific cytotoxic T cells. The peak of cytotoxic activity against virus-infected targets occurred at 4 days of culture and DNA synthesis was maximal on day 3. The concentration of cytotoxic T cells at the peak was eight-fold higher than at the peak of the splenic primary response in vivo, Memory T cells (precursors of secondary cytotoxic T cells) appeared in spleen within 12–14 days of primary infection in vivo, reached a plateau at 5–6 weeks and persisted for at least 16 months. Spleen cells appeared partly refractory to secondary stimulation in vitro at 8–10 days post-priming. This did not seem to be due to cellular migration from spleen to lymph nodes or peritoneal cavity, but its cause was not determined. Primary responses in vitro were not detectable under conditions optimal for secondary responses, thus suggesting a major quantitative, or qualitative difference between virgin and memory T cells.     

Kinetics of the reactivity of subpopulations of spleen cells of mice bearing virus-induced mammary tumors to syngeneic antigenic extracts in vitro

Summary This study was designed to investigate the nature of lymphocyte reactivity to soluble tumor antigens with respect to the kinetics of the reactivity, the responding cell type, and the role of accessory cells, within a syngeneic system. BALB/c mice were inoculated with 1×10⁶ viable cells of sygeneic MTV-induced mammary tumors. Assessment of proliferative activity of spleen cells of these animals by DNA synthesis (³H-thymidine incorporation in vitro) indicated a biphasic response to stimulation by 200 g of a syngeneic perchloric acid (PCA)-soluble extract (AMMT) of the tumor over a 25-day period, with peak activities at days 13 and 19 post inoculation. The response was predominantly T-cell-mediated. Splenic macrophage population rose from less than 2% of total spleen cells by day 25 without any appreciable change in the T or B cell population. Depletion of spleen cells of macrophages abolished the first peak activity (at day 13) but significantly enhanced the second (at day 19). Reconstitution of the depleted cells with macrophages prepared from peritoneal exudates of tumor-bearing or normal mice restored the responses to undepleted values, thus indicating an accessory role for macrophages in these responses. These results provide new data which should contribute to a better understanding of the tumor-host relationship.