Postoperative administration of interleukin-12 significantly enhances the anti-tumor immune response of MBT-2 bladder cancer bearing mice

This study, using the MBT-2 murine bladder tumor model, mainly investigated the role of interleukin-12 (IL-12) in the specific antitumor immune response of a tumor-bearing host when systemically administrated after surgery. Day 17 tumor-bearing mice (D17TBM) along with non-tumor bearing naive mice were treated with daily intraperitoneal (i.p.) injection of IL-12 (0.25 microg/mouse) from day 18 to day 24 for a total of 7 doses. Their splenocytes were obtained on Day 31 for natural killer cells (NK), lymphokine activated killer cells (LAK) and cytotoxic T lymphocyte (CTL) activity assay and lymphocyte subsets phenotypic analysis. The tumor suppression effect of systemic IL-12 administration was evaluated based on the tumor outgrowth of the higher number of tumor cells rechallenged 24 hours after resectioning of the primary tumor. After evaluation on Day 31, the result of in vitro cytotoxicity assay revealed that systemic administration of IL-12 mainly enhanced the splenic LAK and CTL activities in non-tumor-primed naive mice, and the NK activity in tumor-primed D17TBM, respectively. However, in vivo administration of IL-12 with or without IL-2 failed to upgrade the proportions of either CD4+ CD44+ or CD8+ CD44+ T cells subsets in the spleens and regional inguinal lymph nodes (LNs) of both the D17TBM and naive mice. However, the splenic CD8+ CD44+ T-cell subset in the IL-12-treated D17TBM increased prominently after further culturing in the presence of IL-2 400 units/ml plus IL-12 25 ng/ml for 4 days. The fact that systemic administration of IL-12 significantly suppressed the outgrowth of Day-18 challenged tumor cells, especially in D17TBM, clearly indicates that the established specific antitumor immunity in tumor-primed D17TBM was efficiently augmented. From the results of this study, we conclude that, after surgical resection of a primary tumor, systemic administration of IL-12 can be an effective adjuvant therapy because it demonstrates a significant augmentation effect on the tumor-specific immune response in the tumor-primed host.     

Tumor-bearing mice exhibit a progressive increase in tumor antigen-presenting cell function and a reciprocal decrease in tumor antigen-responsive CD4+ T cell activity.

Splenic CD4+ T cells from BALB/c mice bearing a syngeneic tumor (CSA1M) 2 to 3 wk after the inoculation with CSA1M cells produced IL-2 and macrophage-activating factor upon in vitro cultures. This lymphokine production was achieved without stimulation of these T cells with exogenous stimulating tumor Ag. However, elimination of APC from spleen cells resulted in almost complete abrogation of the capacity of CD4+ T cells to produce IL-2/macrophage-activating factor. The lymphokine production was regained when APC from CSA1M-bearing mice were added back to cultures. APC from normal or another syngeneic tumor (Meth A)-bearing mice failed to regain the lymphokine production. These observations demonstrated that the lymphokines were produced by CD4+ T cells from CSA1M-bearing hosts through their collaboration with APC binding CSA1M tumor Ag in the tumor-bearing state. The lymphokine-producing capacity of whole spleen cells from tumor-bearing mice reached the maximal level around 2 to 3 wk after tumor implantation but gradually decreased with the progress of tumor-bearing stages. Importantly, tumor-bearing stage-related changes were observed in a different fashion in the capacities of anti-CSA1M CD4+ T cells vs CSA1M tumor Ag-binding APC. The capacity of APC increased with the progress of tumor-bearing stages as demonstrated by the stimulation of CSA1M-immunized T cells with APC from different CSA1M-bearing stages. In contrast, the reactivity of anti-CSA1M T cells to APC from a given CSA1M-bearing stage decreased with the tumor-bearing stage. These results demonstrate a stage-related increase tumor Ag-binding APC function, as well as a reciprocal reduction in tumor Ag-responsive CD4+ T cell activity.     

IL-4-transduced tumor cell vaccine induces immunoregulatory type 2 CD8 T lymphocytes that cure lung metastases upon adoptive transfer.

Vaccinations with tumor cells engineered to produce IL-4 prolonged survival and cured 30% of mice bearing pulmonary metastases, an effect abrogated by in vivo depletion of T cells. Vaccination induced type 2 T cell polarization in both CD4 and CD8 T lymphocyte subsets. We focused on the antitumor activity exerted by type 2 CD8+ T cells (Tc2) activated by IL-4 tumor cell vaccination. Tc2 lymphocytes lacked in vitro tumor cytotoxicity, but released IL-4 upon stimulation with tumor cells, as shown by limiting dilution analysis of the frequencies of tumor-specific pCTL and of CD8 cells producing the cytokine. In vivo fresh purified CD8+ T lymphocytes from IL-4-vaccinated mice eliminated 80-100% of lung metastases when transferred into tumor-bearing mice. CD8+ lymphocytes from IL-4-vaccinated IFN-gamma knockout (KO), but not from IL-4 KO, mice cured lung metastases, thus indicating that IL-4 produced by Tc2 cells was instrumental for tumor rejection. The antitumor effect of adoptively transferred Tc2 lymphocytes needed host CD8 T cells and AsGM1 leukocyte populations, and partially granulocytes. These data indicate that Tc2 CD8+ T cells exert immunoregulatory functions and induce tumor rejection through the cooperation of bystander lymphoid effector cells. Tumor eradication is thus not restricted to a type 1 response, but can also be mediated by a type 2 biased T cell response.     

Mice bearing late-stage tumors have normal functional systemic T cell responses in vitro and in vivo

Immune suppression in tumor-bearing hosts is considered to be one factor causally associated with the growth of antigenic tumors. Support for this hypothesis has come from reports that spleen T cells in tumor-bearing mice are deficient in either priming or effector phase functions. We have reexamined this hypothesis in detail using multiple murine tumor models, including transplantable adenocarcinoma, melanoma, sarcoma, and thymoma, and also a transgenic model of spontaneous breast carcinoma. In both in vitro and in vivo assays of T cell function (proliferation, cytokine production, induction of CD8+ alloreactive CTL, and development of anti-keyhole limpet hemocyanin CD4+ T cells, rejection of allogeneic or syngeneic regressor tumors, respectively) we show that mice bearing sizable tumor burdens are not systemically suppressed and do not have diminished T cell functions. Therefore, if immune suppression is a causal function in the growth of antigenic tumor, the basis for escape from immune destruction is likely to be dependent upon tumor-induced T cell dysfunction at the site of tumor growth.     

Identification of tumor-infiltrating macrophages as the killers of tumor cells after immunization in a rat model system.

Immunization can prevent tumor growth, but the effector cells directly responsible for tumor cell killing in immunized hosts remain undetermined. The present study compares tumor grafts that progress in naive syngeneic rats with the same grafts that completely regress in hosts preimmunized with an immunogenic cell variant. The progressive tumors contain only a few macrophages that remain at the periphery of the tumor without direct contact with the cancer cells. These macrophages do not kill tumor cells in vitro. In contrast, tumors grafted in immunized hosts and examined at the beginning of tumor regression show a dramatic infiltration with mature macrophages, many of them in direct contact with the cancer cells. These macrophages are strongly cytotoxic for the tumor cells in vitro. In contrast to macrophages, tumor-associated lymphocytes are not directly cytotoxic to the tumor cells, even when obtained from tumor-immune rats. However, CD4(+) and CD8(+) T cells prepared from the regressing tumors induce tumoricidal activity in splenic macrophages from normal or tumor-bearing rats and in macrophages that infiltrate progressive tumors. These results strongly suggest that the main tumoricidal effector cells in preimmunized rats are macrophages that have been activated by adjacent tumor-immune lymphocytes.     

Generation from tumor-bearing mice of lymphocytes with in vivo therapeutic efficacy

Systemic transfer of sensitized lymphocytes can effectively mediate the regression of established tumors. However, virtually all prior experimental applications of this approach have utilized lymphocytes from animals that have been immunized to reject tumor challenge. A similar source of cells is not available in the human. With the use of a weakly immunogenic murine tumor, MCA 105, we demonstrate here that following in vitro sensitization (IVS) with viable tumor cells and interleukin 2, the nontherapeutic lymphoid cells from mice bearing a progressively growing tumor acquired antitumor reactivity capable of mediating the regression of established pulmonary metastases. Although the IVS system induced nonspecific lymphokine-activated killer-like cytotoxic activity from lymphoid cells of normal as well as tumor-bearing mice, therapeutically active cells could only be generated from cultures initiated with lymphoid cells from tumor-bearing animals, indicating that the IVS was a secondary in vitro immune response. Without other treatment, the IVS cells could mediate antitumor effects. However, low doses of exogenous interleukin 2 administration could enhance their therapeutic efficacy. By in vivo T cell subset depletion with monoclonal antibodies, the primary effector cells were identified as belonging to cytotoxic/suppressor T cell lineage expressing the Lyt-2 phenotype. In addition, these therapeutic effector cells could be further expanded in numbers in vitro with continuous stimulation by tumor cells in the presence of interleukin 2. Compared to the number of cells initiating the culture, as many as 126 times the number of cells were obtained after 9 days of IVS followed by in vitro expansion for an additional 5 days. Studies on the kinetics of the occurrence of the pre-effector lymphocytes during tumor growth revealed that they were readily obtained from draining lymph nodes of mice with a broad range of tumor burdens as well as durations of tumor growth. The ability to generate and expand, in vitro, therapeutically active lymphocytes from tumor-bearing hosts has important implications for cellular therapy of human cancers.     

Effector phenotypes and mechanisms of antitumor immune reactivity of tumor-immunized and tumor-bearing mice in two syngeneic tumors.

By using two different syngeneic tumors, Meth A sarcoma and RL male 1 lymphoma of BALB/c origin, the present study was designed to investigate the subset(s) of T cells mediating in vivo antitumor immune responses and some of the effector mechanisms of in vivo protective immunity in BALB/c mice immunized against tumor or bearing tumor. Spleen cells from the mice immunized against Meth A tumor or bearing Meth A tumor inhibited the growth of Meth A tumor in the Winn assay. In the Meth A-immunized mice, L3T4+ (CD4+) cells played a major role in mediating the inhibitory activity against Meth A tumor growth, whereas in the Meth A-bearing mice, the antitumor protective immunity was mediated by both L3T4+ and Lyt-2+ (CD8+) cells. Spleen cells from the Meth A-immunized or Meth A-bearing mice were not able to generate cytotoxic T lymphocytes (CTL) directed against Meth A tumor after the in vitro restimulation of spleen cells with mitomycin C (MMC)-treated Meth A cells, while fresh spleen cells from the Meth A-immunized or Meth A-bearing mice were able to induce the strong delayed-type hypersensitivity (DTH) responses to Meth A tumor. The DTH response to Meth A tumor was mediated by L3T4+ cells in the Meth A-immunized mice and by both L3T4+ and Lyt-2+ cells in the Meth A-bearing mice. In the similar experiments performed in the RL male 1 lymphoma, the antitumor activity in spleen cells from the RL male 1-immunized or RL male 1-bearing mice depended on Lyt-2+ but not L3T4+ cells in the Winn assay. When spleen cells from the RL male 1-immunized or RL male 1-bearing mice were cultured with MMC-treated RL male 1 cells for 5 days, an appreciable CTL response to RL male 1 tumor was induced. These results suggest that the nature of tumor and/or tumor antigens determines which T cell subset is required to exhibit the protective immunity against tumor and thus the different effector mechanisms could be induced in the different tumor models. Furthermore, these data support the conclusion that antitumor T cell responses are affected by the immune state of host to tumor.     

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.     

T and B lymphocyte migration into syngeneic tumors.

The migration of splenic T and B lymphocytes into syngeneic tumors undergoing immunologic rejection was investigates. Spleen cells were obtained from normal BALC/c mice or BALB/c mice bearing tumors induced by murine sarcoma virus (MSV). Either whole spleen cells or immunoabsorbent purified T and B cells were radiolabeled with sodium chromate-51 and injected i.v. into normal or MSV inducted-tumor bearing syngeneic recipients. Twenty-four hours later the recipient mice were sacrificed and radioactivity was assessed for tumor, contralateral normal muscle, the lymph nodes draining the tumor and contralateral draining lymph nodes, peripheral lymph nodes, spleen, and liver. Both T and B lymphocytes from either normal or MSV tumor-bearing animals show greatly increased migration into the tumor when compared with normal muscle. Migration of T cells from both normal and MSV tumor bearers was 30 times that of migration to normal muscle. B cells from tumor-bearing mice, on the other hand, localized in the tumor itself only 50% as frequently as did B cells from normal animals. In addition, T cells from MSV tumor bearers were found in the highest proportion in the lymph node draining the tumor site. We conclude that T and B lymphocytes from either normal or tumor-bearing mice migrate to a syngeneic tumor undergoing immunologic rejection. In contrast, the migration of both T and B cells from tumor-bearing animals was decreased to the peripheral lymph nodes at the time of maximum tumor growth.     

Tumor-induced CD11b+Gr-1+ myeloid cells suppress T cell sensitization in tumor-draining lymph nodes

Suppression of tumor-specific T cell sensitization is a predominant mechanism of tumor escape. To identify tumor-induced suppressor cells, we transferred spleen cells from mice bearing progressive MCA205 sarcoma into sublethally irradiated mice. These mice were then inoculated subdermally with tumor cells to stimulate T cell response in the tumor-draining lymph-node (TDLN). Tumor progression induced splenomegaly with a dramatic increase (22.1%) in CD11b(+)Gr-1(+) myeloid-derived suppressor cells (MDSC) compared with 2.6% of that in normal mice. Analyses of therapeutic effects by the adoptive immunotherapy revealed that the transfer of spleen cells from tumor-bearing mice severely inhibited the generation of tumor-immune T cells in the TDLN. We further identified MDSC to be the dominant suppressor cells. However, cells of identical phenotype from normal spleens lacked the suppressive effects. The suppression was independent of CD4(+)CD25(+) regulatory T cells. Intracellular IFN-gamma staining revealed that the transfer of MDSC resulted in a decrease in numbers of tumor-specific CD4(+) and CD8(+) T cells. Transfer of MDSC from MCA207 tumor-bearing mice also suppressed the MCA205 immune response indicating a lack of immunologic specificity. Further analyses demonstrated that MDSC inhibited T cell activation that was triggered either by anti-CD3 mAb or by tumor cells. However, MDSC did not suppress the function of immune T cells in vivo at the effector phase. Our data provide the first evidence that the systemic transfer of MDSC inhibited and interfered with the sensitization of tumor-specific T cell responses in the TDLN.     

CD4-deficient mice have reduced levels of memory cytotoxic T lymphocytes after immunization and show diminished resistance to subsequent virus challenge.

Although primary antiviral CD8+ cytotoxic T lymphocytes (CTL) can be induced in mice depleted of CD4+ T cells, the role of CD4+ T lymphocytes in the generation and maintenance of antiviral memory CTL is uncertain. This question, and the consequences upon vaccine-mediated protection, were investigated in transgenic CD4 knockout (CD4ko) mice, which lack CD4+ T lymphocytes. Infection of immunocompetent C57BL/6 mice with lymphocytic choriomeningitis virus (LCMV), or with recombinant vaccinia viruses bearing appropriate LCMV sequences, induces long-lasting protective immunity, mediated mainly by antiviral CD8+ CTL. Here we report two important findings. First, LCMV-specific CD8+ memory CTL are maintained at considerably lower levels in CD4ko mice than in normal C57BL/6J mice; we demonstrate a reduction in precursor CTL evident as soon as 30 days postimmunization and declining, by day 120, to levels 1 to 2 log units below those in normal mice. Thus, CD4+ T cells appear to be important to the generation and maintenance of their CD8+ counterparts. Second, this reduction has an important biological consequence; compared with immunocompetent mice, CD4ko mice immunized with vaccinia virus recombinants expressing nucleoprotein or glycoprotein of LCMV are less effectively protected from subsequent LCMV challenge. Thus, this study underscores the potential importance of CD4+ T lymphocytes in generation of appropriate levels of CD(8+)-cell-mediated immunoprotective memory and has implications for vaccine efficacy in individuals with immune defects in which CD4 levels may be reduced, such as AIDS.     

CD8 is needed for development of cytotoxic T cells but not helper T cells.

A mutant mouse strain without CD8 (Lyt-2 and Lyt-3) expression on the cell surface has been generated by disrupting the Lyt-2 gene using embryonic stem cell technology. In these mice, CD8+ T lymphocytes are not present in peripheral lymphoid organs, but the CD4+ T lymphocyte population seems to be unaltered. Cytotoxic response of T lymphocytes from these mice against alloantigens and viral antigens is dramatically decreased. Proliferative response against alloantigens and in vivo help to B lymphocytes, however, are not affected. These data suggest that CD8 is necessary for the maturation and positive selection of class I MHC restricted cytotoxic T lymphocytes but is not required on any of the intermediate thymocyte populations (CD8+CD4-TcR- or CD4+CD8+TcRlow) during the development of functional class II MHC restricted helper T cells.     

Turning on/off tumor-specific CTL response during progressive tumor growth

Therapeutic vaccinations used to induce CTLs and treat firmly established tumors are generally ineffective. To understand the mechanisms underlying the failure of therapeutic vaccinations, we investigated the fate of tumor-specific CD8+ T cells in tumor-bearing mice with or without vaccinations. Our data demonstrate that tumor-specific CD8+ T cells are activated at the early stage of tumor growth, tumor-specific CTL response reaches a maximal level during progressive tumor growth, and tumor-specific CD8+ T cells lose cytolytic function at the late stage of tumor growth. The early stage therapeutic vaccination induces efficient antitumor activity by amplifying the CTL response, whereas the late-stage therapeutic vaccination is invalid due to tumor-induced dysfunction of CD8+ T cells. However, at the late stage, tumor-specific CD8+ T cells are still present in the periphery. These tumor-specific CD8+ T cells lose cytolytic activity, but retain IFN-gamma secretion function. In contrast to in vitro cultured tumor cells, in vivo growing tumor cells are more resistant to tumor-specific CTL killing, despite an increase of tumor Ag gene expression. Both tumor-induced CD8+ T cell dysfunction at the late stage and immune evasion developed by in vivo growing tumor cells contribute to an eventual inefficacy of therapeutic vaccinations. Our study suggests that it is important to design a vaccination regimen according to the stages of tumor growth and the functional states of tumor-specific CD8+ T cells.     

Local T helper cell signals by lymphocytes infiltrating intraocular tumors.

Tumor-infiltrating lymphocytes from mice bearing minor histoincompatible tumor cells in the anterior chamber (AC) or subconjunctival (SCon) space of the eye have been shown to contain large numbers of tumor-specific precursor cytotoxic T cells. Because SCon tumors eventually acquire directly cytotoxic, tumor-specific T cells and are rejected by their hosts and because AC tumors never acquire cytotoxic effector cells and are not rejected, we have examined tumor-infiltrating lymphocytes from both types of ocular tumors for the capacity to secrete lymphokines in response to in vitro stimulation with tumor cells. The results indicate that T "helper" cells were able to infiltrate both SCon and AC tumors. In the former, T cells capable of secreting IL-2 and IL-4 were found whereas in the latter only IL-2-secreting T cells were detected. These findings implicate a defect in local delivery of appropriate T cell help as the reason why AC tumors are not rejected. The failure of AC tumor-bearing mice to destroy their tumors correlates not only with defective delivery of local help but with a systemic inability to produce tumor-specific T cells that can secrete IL-2 and IL-4. Because these mice also generate down-regulatory T cells that suppress the expression of tumor-specific delayed hypersensitivity, they appear to have an immunologically mediated block in T helper cell differentiation which renders them unable to generate either T helper 1 or T helper 2 cells. This immunologic abnormality is discussed in terms of tumor rejection and the phenomenon of immunologic privilege.     

Mechanisms of tumor-induced immunosuppression: evidence for contact-dependent T cell suppression by monocytes.

BACKGROUND: The progressive growth of tumors in mice is accompanied by down-regulation of specific T cell responses. The factors involved in this suppression are not completely understood. Here, we have developed a model to examine the role of host immune effector cells in the inhibition of T cell function. In this model, progressive growth of a colon carcinoma line, CT26, is accompanied by loss of T cell response to alloantigens in both cytolytic and proliferation assays. MATERIALS AND METHODS: The CT26 tumor was inoculated into BALB/c syngeneic mice. Tumor growth, cytolytic T cell responses, lymphocyte proliferation, and flow cytometric analysis was performed in tumor-bearing animals 7 or 28 days after tumor inoculation. RESULTS: Spleen cells from tumor-bearing mice were found to suppress the proliferative response of spleen cells from normal mice to alloantigens. Examination of the spleen cell population by FACS analysis revealed an increase in the percentage of monocytes as defined by expression of CD11b, the Mac-1 antigen. Removal of the Mac-1-positive cells from the tumor-bearing hosts spleen relieved suppression of the tumor-bearing mouse spleen cell proliferative response to alloantigens, and addition of the Mac-1-positive enriched cells suppressed proliferation of normal T cells in response to alloantigens. Cell contact was required for this inhibition. CONCLUSIONS: Tumor induction of suppressive monocytes plays an important role in the general immunosuppression noted in animals bearing CT26 tumors. Identification of the mechanisms responsible for this effect and reversal of tumor-induced macrophage suppression may facilitate efforts to develop effective immunotherapy for malignancy.     

Analysis of splenic Gr-1int immature myeloid cells in tumor-bearing mice.

It is known that the number of ImC, expressing myeloid markers, CD11b and Gr-1, increase with tumor growth and ImC play a role in the escape of tumor cells from immunosurveillance in tumor-bearing mice and cancer patients. However, the mechanisms by which ImC suppress immune responses in tumor-bearing mice have not been completely elucidated. In the present study, we investigated the function of splenic ImC freshly isolated from tumor-bearing mice and splenic ImC differentiated in vitro by GM-CSF. Freshly isolated splenic ImC were divided into two groups depending on Gr-1 expression, Gr-1 high (Gr-1hi) and intermediate (Gr-1int). Freshly isolated splenic Gr-1int ImC, but not Gr-1hi ImC, from tumor-bearing mice reduced production of IFN-gamma in CD8+ T cells, but neither splenic Gr-1int ImC nor Gr-1hi ImC isolated from naive mice did. Both Gr-1int and Gr-1hi ImC differentiated in vitro by GM-CSF inhibited production of IFN-gamma in both CD8+ and CD4+ T cells. In addition, the differentiated Gr-1int ImC, one-third of which were CD11c+F4/80+ cells, and their culture supernatants suppressed proliferative responses of T cells stimulated by CD3 ligation, but the differentiated Gr-1hi ImC and their culture supernatants did not. These results suggest that Gr-1int ImC are altered to immune-suppressive cells in tumor circumstances and that they are differentiated by GM-CSF progressively into CD11c+F4/80+ cells with further suppressive activity against T cells.     

Tumor-associated myeloid cells can be activated in vitro and in vivo to mediate antitumor effects

Tumor growth is often accompanied by the accumulation of myeloid cells in the tumors and lymphoid organs. These cells can suppress T cell immunity, thereby posing an obstacle to T cell-targeted cancer immunotherapy. In this study, we tested the possibility of activating tumor-associated myeloid cells to mediate antitumor effects. Using the peritoneal model of B16 melanoma, we show that peritoneal cells (PEC) in tumor-bearing mice (TBM) had reduced ability to secrete nitric oxide (NO) following in vitro stimulation with interferon gamma and lipopolysaccharide, as compared to PEC from control mice. This reduced function of PEC was accompanied by the influx of CD11b(+) Gr-1(+) myeloid cells to the peritoneal cavity. Nonadherent PEC were responsible for most of the NO production in TBM, whereas in na?ve mice NO was mainly secreted by adherent CD11b(+) F4/80(+) macrophages. Sorted CD11b(+) Gr-1(-) monocytic and CD11b(+) Gr-1(+) granulocytic PEC from TBM had a reduced ability to secrete NO following in vitro stimulation (compared to na?ve PEC), but effectively suppressed proliferation of tumor cells in vitro. In vivo, treatment of mice bearing established peritoneal B16 tumors with anti-CD40 and CpG resulted in activation of tumor-associated PEC, reduction in local tumor burden and prolongation of mouse survival. Inhibition of NO did not abrogate the antitumor effects of stimulated myeloid cells. Taken together, the results indicate that in tumor-bearing hosts, tumor-associated myeloid cells can be activated to mediate antitumor effects.     

Recruitment and activation of tumor-specific immune T cells in situ. CD8+ cells predominate the secondary response in sponge matrices and exert both delayed-type hypersensitivity-like and cytotoxic T lymphocyte activity

This study analyzes the involvement of CD4+ and CD8+ T cells in a secondary cellular immune response to the highly metastatic murine lymphoma ESb in situ. This tumor line expresses tumor-associated transplantation Ag which can induce protective immunity in vivo and specific CTL in vitro. In tumor-immune mice the injection of a tumor vaccine (x-irradiated ESb tumor cells) into s.c. implanted vascularized sponges resulted in the generation of a specific secondary immune response characterized by massive leukocyte recruitment and generation of strong CTL activity at the restimulation site. During the antitumor immune response the CD4+:CD8+ T cell ratio decreased significantly and specifically in the restimulated sponges. Depletion of CD8+ but not CD4+ T cells from the tumor immune mice before restimulation significantly reduced the delayed-type hypersensitivity-like response and totally blocked the generation of tumor-specific CTL activity in situ. Only a minority of the CD8+ immune T cells which predominated the secondary response in situ expressed IL-2R and lymph node homing receptors as detected by the mAb MEL-14.     

Regualtion of the immune response to tumor antigens. I. Immunosuppressor cells in tumor-bearing hosts.

A/Jax mice were rendered immune to the syngeneic and transplantable methylcholanthrene-induced Sarcoma 1509a by the surgical removal of the tumor 7 days after implantation; subsequent injection i.v. transfer of 10(7) to 10(8) washed thymus or spleen cells of tumor-bearing animals (TBA) to immune animals significantly inhibited the rejection of the tumor; this suppressive effect was entirely abolished by the treatment of these lymphocytes with anti-theta serum or anti-thymocyte serum (ATS) and complement before adoptive transfer. On the other hand, an equal number of thymus or spleen cells of normal animals or of animals bearing an unrelated tumor had no suppressive effect. Treatment of normal syngeneic animals with ATS after tumor cell inoculation or splenectomy of TBA resulted in the suppression of the tumor growth. The serum of TBA had no effect on tumor growth in immune syngeneic mice. Together these results suggest that TBA possess immunosuppressor T cells regulating negatively their immune response to the tumor.     

Reversal of CD8+ T cell ignorance and induction of anti-tumor immunity by peptide-pulsed APC

In the present report, we have studied the potential of naive and activated effector CD8(+) T cells to function as anti-tumor T cells to a solid tumor using OVA-specific T cells from TCR-transgenic OT-I mice. Adoptive transfer of naive OT-I T cells into tumor-bearing syngeneic mice did not inhibit tumor cell growth. The adoptively transferred OT-I T cells did not proliferate in lymphoid tissue of tumor-bearing mice and were not anergized by the tumor. In contrast, adoptive transfer of preactivated OT-I CTL inhibited tumor growth in a dose-dependent manner, indicating that E.G7 was susceptible to immune effector cells. Importantly, naive OT-I T cells proliferated and elicited an anti-tumor response if they were adoptively transferred into normal or CD4-deficient mice that were then vaccinated with GM-CSF-induced bone marrow-derived OVA-pulsed APC. Collectively, these data indicate that even though naive tumor-specific T cells are present at a relatively high fraction they remain ignorant of the tumor and demonstrate that a CD8-mediated anti-tumor response can be induced by Ag-pulsed APC without CD4 T cell help.