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.     

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. 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.     

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.     

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.     

Surface markers on the T cells that regulate cytotoxic T-cell responses

Regulatory T cells can be obtained from primary mixed lymphocyte cultures of CBA spleen cells responding to BALB/c stimulators. At day 3 of culture, T cells are generated which can either help or suppress the generation of cytotoxic T cells in a second primary MLC culture. The regulatory activity observed depends on the conditions employed in the assay system allowing independent assay of different functional cell types which coexist in the cultures. Both the helper activity and the suppressor activity are mediated by differentiated antigen-specific T cells whose function is radioresistant. The Ly phenotype of these regulatory cells was tested. At day 3 of the first-step culture, the phenotype of the helper cells is Ly 1.1⁺ Ly 2.1^–, whereas the inhibitory cells are Ly 1.1⁺ Ly 2.1⁺. At day 5 of MLC culture, suppressor activity and helper activity are also observed. However, at this point, a suppressor cell which is Ly 1.1^– Ly 2.1⁺ represents the major inhibitory activity. It is not clear whether this change in suppressor cell phenotype as a function of time in culture represents one differentiation pathway or cells derived from two different precursor cells. The Ly phenotype of helper or cytotoxic T cells did not change as a function of time in culture. In day 5 first-step cells, the cytotoxic cells were typed as Ly 1.1⁺ 2.1⁺, whereas the inhibitory cells present in aliquots of the same treated cell population expressed the Ly 1.1^– Ly 2.1⁺ phenotype. Taken together, these observations show that the antigen-specific suppressor cells and helper cells which regulate the generation of cytotoxicity, and the cytotoxic cells themselves represent physically distinct subclasses of T cells.     

Tumor-specific CD4+ T cells develop cytotoxic activity and eliminate virus-induced tumor cells in the absence of regulatory T cells

The important role of tumor-specific cytotoxic CD8⁺ T cells is well defined in the immune control of the tumors, but the role of effector CD4⁺ T cells is poorly understood. In the current research, we have used a murine retrovirus-induced tumor cell line of C57BL/6 mouse origin, namely FBL-3 cells, as a model to study basic mechanisms of immunological control and escape during tumor formation. This study shows that tumor-specific CD4⁺ T cells are able to protect against virus-induced tumor cells. We show here that there is an expansion of tumor-specific CD4⁺ T cells producing cytokines and cytotoxic molecule granzyme B (GzmB) in the early phase of tumor growth. Importantly, we demonstrate that in vivo depletion of regulatory T cells (Tregs) and CD8⁺ T cells in FBL-3-bearing DEREG transgenic mice augments IL-2 and GzmB production by CD4⁺ T cells and increases FV-specific CD4⁺ T-cell effector and cytotoxic responses leading to the complete tumor regression. Therefore, the capacity to reject tumor acquired by tumor-reactive CD4⁺ T cells largely depends on the direct suppressive activity of Tregs. We suggest that a cytotoxic CD4⁺ T-cell immune response may be induced to enhance resistance against oncovirus-associated tumors.     

Cell-mediated immunity to Friend virus-induced leukemia. III. Characteristics of secondary cell-mediated cytotoxic response.

By employing the 125IUdR release cytotoxicity assay, we have been able to measure the primary and secondary cell-mediated cytotoxic response of C57BL/6 mice to FBL-3 cells, a syngeneic Friend virus-induced leukemia. It was found that the secondary cell-mediated cytotoxic response occurred more rapidly after challenge (within 3 days) than the primary response, and the levels of reactivity were considerably higher. As in the primary response, the secondary cytotoxic reactivity of spleen cells was T cell dependent, being eliminated by pretreatment with anti-theta antibody plus complement. However, the secondary reactivity of pertioneal exudate (PE) cells was not entirely T-cell dependent. The specificity of the secondary cytotoxic response was analyzed by primary or secondary immunization with various tumor cells and by testing of cytotoxic lymphocytes against a variety of target cells. When spleen cells were used for testing, only tumor cells induced by Friend, Moloney, or Rauscher (FMR) leukemia viruses could produce secondary cell-mediated cytotoxic responses against FBL-3 cells. This correlated well with the specificity observed in the in vivo tumor transplantation protection studies. Similarly, spleen cells immune to FBL-3 had appreciable cytotoxicity against tumor cells induced by FMR viruses. The FBL-3 immune mice also gave significant protection against the challenge of FMR leukemias. When PE cells were used for testing, they gave higher levels of cytotoxicity against tumor cells induced by FMR viruses, but also gave less, but appreciable, cytotoxicity against non-FMR tumors. The latter reactivity might be related to the antigens induced by the murine endogenous type C viruses.     

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.     

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.     

Antigen-specific helper T cells recognize determinants encoded in the H-2D region of the H-2 gene complex

Observations have frequently been interpreted as showing that the helper T cells which collaborate with alloantigen-specific cytotoxic T-cell precursors can only recognize antigens encoded in the I region of the H-2 gene complex. An experimental system is described here that allows analysis of the recognition repertoire of these helper cells. CBA helper T-cell precursors can be primed in vitro to antigens encoded in the H-2 ^b gene complex. These helpers can then be tested for the existence of a subset of helper cells which recognize antigens encoded in the D region of H-2 ^b haplotype. CBA thymocytes were used as a source of cytotoxic T-cell precursors that respond poorly in the absence of exogeneous helper activity. The source of alloantigen was varied by using irradiated spleen cells from various (BALB/c × recombinant)F₁ hybrid mice as stimulator cells. When the stimulator cell bears BALB/c determinants recognized by the cytotoxic T-cell precursor and also bears only the D region antigens of the H-2 ^b haplotype, an anti-BALB/c cytotoxic response is generated only if the anti-H-2^b helper population contains cells able to recognize H-2D^b. A positive cytotoxic response was obtained, indicating that helper cells are not limited to recognition of I region antigens and can efficiently recognize antigens encoded in the D region of the H-2 gene complex. This was confirmed by the demonstration of helpers specific for H-2D^d. We were unable to detect any evidence for Ia-restricted recognition of the H-2D alloantigens, suggesting that, as for cytotoxic T lymphocytes (CTL), helper cell recognition of class I alloantigens is an unrestricted event.     

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.     

The cell-mediated immune response to ectromelia virus infection. I. Kinetics and characteristics of the primary effector T cell response in vivo.

The cell-mediated immune (CMI) response to ectromelia virus infection in mice was studied. Virus doses from 4 × 10² up to 5 × 10⁴ PFU of an attenuated strain inoculated intravenously (iv) all induced cytotoxic T cell responses in the spleen as measured in a ⁵¹Cr release assay using virus-infected target cells. Higher virus doses gave larger responses. There was little variation between individual animals, and mice ranging in age from 4–22 weeks gave similar responses. Following iv infection, virus grew logarithmically in spleen for 2 days, then titers declined to undetectable levels by day 5. The peak of the virus-specific cytotoxic T cell response occurred at 5–6 days post-infection, as determined by calculation of effector units based on a linear log-log relationship between killer cells added and targets lysed. T cells responsible for virus clearance in vivo gave similar kinetics, suggesting the possibility that both functions are mediated by the same T cell subset. Two other categories of cytotoxic activity were also generated at low levels in the spleen during ectromelia infection or during infection with a bacterium, Listeria monocytogenes. These activities were significantly sensitive to anti-δ and complement treatment, suggesting T cell dependence, but participation of other mechanisms has not been rigorously excluded. One category lysed allogenic target cells and reached a peak at 4 days post-infection. The other lysed H-2-compatible cells, syngeneic embryo cells, and some syngeneic tumor cells but not syngeneic macrophages, and was present at similar low levels through days 1–4. These different kinetics and evidence from “cold” target competition experiments suggested that the total cytotoxic activity of immune spleen cell populations was a composite of the activities of separate cellular subsets (probably mainly T cells), killing of any one target cell type being the responsibility of a subset with receptors at least partly specific for antigens on that target cell.     

Antigen-driven T cell clones can proliferate in vivo, eradicate disseminated leukemia, and provide specific immunologic memory

The aim of the current study was to determine the ability of antigen-driven cloned helper cell independent cytotoxic T lymphocytes (HITc) to proliferate and to survive in vivo and to mediate tumor therapy. The HITc clone utilized (denoted 1.B6) was specifically cytolytic to FBL-3, a syngeneic Friend virus-induced murine leukemia. Activation in vitro (48 hr) with FBL-3 induced secretion of interleukin 2 (IL 2), expression of IL 2 receptors (IL 2R), and in vitro proliferation. These cells could be "rested" for several weeks without stimulation, which resulted in reduced expression of IL 2R; however, restimulation with antigen resulted in reinduction of IL 2R and proliferation. The ability of cloned HITc to proliferate and to survive in vivo was examined in cyclophosphamide (CY) pretreated donor mice congenic for the Thy-1 gene. Adoptively transferred cloned HITc could be found in large numbers, and were widely distributed in vivo 1 wk after transfer. In tumor therapy, 1.B6 cells when injected into a site of tumor (i.p.) and used as an adjunct to CY were effective against disseminated FBL-3. In this circumstance, cloned 1.B6 cells could be recovered from cured mice 125 days after transfer and were shown to specifically lyse tumor and proliferate in vitro in response to FBL-3. Thus as an adjunct to CY, tumor-specific cloned HITc are capable of eradicating disseminated leukemia, persisting long-term in vivo, and providing specific immunologic memory.     

Selective protection of murine thymic helper T cells from glucocorticosteroid inhibition by macrophage-derived mediators

We investigated the in vitro effects of dexamethasone (DEX) on the functional capacities of virgin murine T cells cultured in the absence and presence of adjuvant-stimulated macrophages or factors derived from them. Immunologically mature thymocytes, isolated on the basis of their inability to bind peanut agglutinin (PNA^? thymocytes), were used as virgin T cells. Treatment of PNA^? thymocytes with DEX for 24 hr in vitro eliminated their subsequent capacity to function as helper cells for primary humoral responses, to proliferate when stimulated by plant mitogens or allogeneic cells, or to generate T-cell-mediated cytotoxic responses. However, when PNA^? thymocytes were pretreated with DEX in combination with either adjuvant-activated macrophages or their culture supernatants, which contained Interleukin 1, the capacity of the T cells to subsequently express helper activity was preserved. The macrophage products, however, did not prevent DEX from inhibiting the capacities of PNA^? thymocytes to proliferate in response to plant mitogens or alloantigens or to generate cytotoxic effector cells; thus, protection was selective. The data indicate that, prior to activation, helper T cells are distinguished by their capacity to become steroid resistant in response to macrophage products. Although T-cell proliferative and cytotoxic responses have been reported to be protected from DEX inhibition by Interleukin 2, our results suggest that macrophages prevent steroid effects on virgin helper T cells by Interleukin-1-dependent mechanisms that do not involve Interleukin 2. While we have not delineated the biochemical pathways of protection, we show that the acquisition of DEX resistance by helper T cells cannot be attributed to the polyclonal induction of helper activity by macrophage factors.     

Synergistic cytolytic activity by combined populations of peritoneal T lymphocytes and macrophages during the L5178Y cell tumor-dormant state in DBA/2 mice

It was previously reported that the establishment of the L5178Y cell tumor-dormant state in DBA/2 mice is mediated principally by a peritoneal cytolytic T-cell response that reaches peak levels 4 days after L5178Y cell challenge, lyses more than 99% but less than 100% of peritoneal L5178Y cells, and gradually wanes to background levels by 40–70 days postchallenge (DPC). At this time the majority of mice are clinically normal, and contain a relatively small number of L5178Y cells in the peritoneal cavity. During the tumor-dormant state, mice that harbor more than 10⁴ L5178Y cells contain peritoneal macrophage-mediated cytolytic activity. We report here that tumor-dormant mice that contain fewer than 10⁴ peritoneal L5178Y cells also produce cytolytic activity in vitro, but that it is synergistic, in that the cytolytic activity of adherent (AD) peritoneal cells (PEC) and nonadherent (NAD) PEC cultured together is greater than the additive lysis produced by these cell populations when cultured separately. This synergistic cytolytic activity is: (1) effector cell density dependent, (2) dependent on the tumor-dormant status of the NAD and AD PEC donor mice, (3) protracted in its kinetics during a 48-hr in vitro assay, and (4) dependent on an interaction between NAD T cells and AD phagocytic macrophages. The consistent detection of this in vitro-assayed cytolytic activity in PEC of tumor-dormant mice which harbor small endogenous tumor burdens suggests that it reflects an in vivo cytotoxic effector mechanism involved in the long-term maintenance of the tumor-dormant state.     

Cellular origin of cytotoxic effectors and secondary educated lymphocytes in human mixed leukocyte reaction

Human lymphocytes sensitized in vitro during a mixed leucocyte reaction (MLR) against an allogeneic-stimulating cell respond by blast transformation and generation of specific cytotoxic effector cells. Both proliferation and cytotoxicity are maximum on Days 6 and 7 of culture. On Day 14, no more dividing cells or cytotoxic cells are detected in such primary cultures. Restimulation by the specific priming cell triggers a secondary proliferative response and rapid reappearance of specific cytotoxic effector cells. The velocity sedimentation cell separation method which separates cells according to their size was applied to human lymphocytes sensitized in vitro during an MLR on Day 7 of culture. Blast cells were separated from nondividing small lymphocytes. It was shown that: (1) cytotoxic effectors generated at the peak of a primary response are exclusively present in the isolated blast population; (2) highly cytotoxic secondary effector cells are induced to reappear mainly from the blast-derived population upon restimulation; and (3) secondary educated proliferative cells mainly derive from the blast population. Conversely, the blast-depleted small lymphocyte population is operationally depleted of cells able to respond by proliferation to the priming cell while responding normally against third party control cells. HLA-D region specificity of the secondary proliferative response is suggested.     

Adoptive chemoimmunotherapy of a syngeneic murine lymphoma with long-term lymphoid cell lines expanded in T cell growth factor

Summary Recently techniques have been developed for the long-term growth of cytotoxic T-lymphoid cells in vitro with T cell growth factor (TCGF). We have investigated the use of these in vitro-expanded T cells for the immunotherapy of a disseminated syngeneic murine FBL-3 lymphoma. In this model, mice with disseminated tumor were treated on day 5 with 180 mg cytoxan/kg and then 5 h later were given lymphoid cells IP. In vivo-immunized lymphocytes resulted in significantly improved survival in three of three experiments, curing 52% of 38 animals, compared with treatment with cytoxan alone (0 of 31 cured) or cytoxan plus unimmunized cells (0 of 40 cured) (P<0.0005). In vivo-immunized lymphocytes were re-exposed to FBL-3 tumor in vitro for 5 days in complete medium (CM) or lectin-free TCGF (LF-TCGF). Both groups showed significantly improved survival in six of six experiments. Cytoxan cured 17% of 66 animals, while cytoxan plus normal lymphocytes after IVS cured 6% of 47 animals. In vivo-immunized cells resensitized in vitro to FBL-3 in CM or LF-TCGF cured 82% of 50 animals (P<0.001) and 72% of 61 animals (P<0.001), respectively. Cells from in vivo- and in vitro-sensitized lymphocytes exhibited no cytotoxicity in our in vitro ⁵¹Cr-release assay; expansion of these cells resulted in significant specific lysis of fresh FBL-3 targets. Adoptive transfer of immune lymphocytes resensitized to FBL-3 tumor in vitro and expanded in LF-TCGF conferred a significant survival benefit (P<0.001, curing 7 of 27 animals) compared with all controls. These expanded cells were then continuously grown in LF-TCGF for 2 1/2 months. Again, in vivo-immunized lymphocytes resensitized to FBL-3 tumor and expanded in LF-TCGF for 2 1/2 months cured 56% of the animals with disseminated tumor, significantly prolonging survival over that recorded in any control group (P<0.0002). Irradiation of these same cells totally abolished their efficacy. Clones were generated from IVS and continuously grown in LF-TCGF. Two of these clones were very cytotoxic for fresh FBL-3 (>4,000 lytic units/10⁶ cells). When adoptively transferred to mice in this chemoimmunotherapy model these cytotoxic clones significantly enhanced survival over that recorded following treatment with cytoxan alone (P<0.00001), though prolongation of survival was small. Implications of these results for application of these techniques to other less antigenic tumors and human cancers are discussed.     

Macrophage Functional Heterogeneity in the <Emphasis Type="Italic">in vitro</Emphasis> Induced Immune Response

RNA from antigenically stimulated peritoneal macrophages is immunogenic in vitro^1–4. The studies of Fishman and Adler^5–6 suggest that the peritoneal macrophage population consists of at least three functionally distinct subpopulations. Although most peritoneal macrophages act as scavenger cells⁷, a second population—possibly less than one cell per 1,000—consists of cells that produce but do not necessarily secrete antibody^8,9 and respond to antigen by synthesizing informational RNA. On transfer to normal lymphoid cells, this RNA elicits IgM antibody with the allotypic specificity of the macrophage donor¹⁰. A third type of macrophage gives rise to the RNA-antigen complex responsible for the in vitro synthesis of IgG antibody with the allotypic specificity of the lymphocyte donor¹⁰.     

Defective T helper activity in the spleen of BALB/c mice immune to a syngeneic fibrosarcoma

Summary BALB/c mice were immunized with the syngeneic 3-methylcholanthrene-induced fibrosarcoma CA-2 by the growth and excision method. When lymphoid cells from different organs of these tumor-free mice were tested in a direct ⁵¹Cr-release assay, peritoneal exudate cells but not spleen cells displayed specific cytotoxicity against the syngeneic tumor target. A cytotoxic response could be obtained by tumor-immune spleen cells when cultured in a mixed lymphocyte tumor cell culture (MLTC) at high but not low density although at the same effector/stimulator ratio. Lack of cytotoxic activity in low density MLTC was not due to an impairment of cytotoxic precursors since cytotoxicity was rescued by adding exogenous interleukin-2 in experimental conditions in which no lymphokine-activated killer cells could develop relevant anti-CA-2 lysis. When low density MLTC were supplemented with either 800 R-irradiated cells or nonirradiated, negatively selected Lyt 1⁺ cells from the same immune mice, induction of a cytotoxic response against CA-2 occurred and interleukin-2 production became detectable. Additional studies indicated that spleen cells of CA-2-immune mice were also impaired in their ability to provide help to syngeneic thymocytes for the generation of cytotoxic T lymphocytes against C57BL/6J alloantigens. Dilution effect of helper cells due to immunization procedures was excluded since spleen cells of mice immunized against another BALB/c tumor, the YC8 lymphoma, or against DBA/2 minor histocompatibility antigens provided good help to thymocytes against the same alloantigens. These results indicate that tumor-immune animals may also have selective T helper defects in an important lymphoid organ like spleen.