Induction of tumor-specific in vivo protective immunity by immunization with tumor antigen-pulsed antigen-presenting cells

The present study investigates the role of APC in inducing tumor-specific in vivo protective immunity. Thy-1+ cell-depleted, Mac-1+ cell-enriched fraction of normal BALB/c spleen cells were used as a source of APC. These APC were cultured in vitro with the membrane fraction isolated from CSA1M fibrosarcoma derived from BALB/c strain. The administration of such APC into naive BALB/c mice generated the capacity of these animals to reject the subsequently challenged viable CSA1M tumor cells. Although the induction of anti-CSA1M in vivo protective immunity required three consecutive immunizations with more than 10(5) APC which had been pulsed in vitro with 200 to 300 micrograms protein of CSA1M membrane fraction, the immunity was induced irrespective of whether APC were administered via s.c., i.v., or i.p. route. This immunity was tumor-specific, inasmuch as the inoculation of CSA1M or Meth A fibrosarcoma membrane component-pulsed APC resulted in the selective immunity against the challenge with homologous types of tumor cells. The CSA1M-specific in vivo protective immunity was also induced by injecting APC pulsed with solubilized CSA1M membrane components. Moreover, it was demonstrated that the efficiency for inducing anti-CSA1M immunity was much higher in the utilization of tumor Ag-pulsed APC than in the immunization with tumor Ag emulsified in CFA. These results indicate the critical role of APC in generating tumor rejection immunity in vivo and this model presents a novel approach to induce tumor-specific immunity without using tumor cells themselves.     

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.     

Tumor-immunotherapy with the use of tumor-antigen-pulsed antigen-presenting cells

Summary Our previous study demonstrated that the administration of antigen-presenting cells (APC) pulsed with tumor cell membrane fraction to naive syngeneic mice results in effective induction of tumor-specific protective immunity in vivo. The present study examined whether tumor-antigen-pulsed APC can produce the inhibitory effect on the growth of tumor cells when administered to tumor-bearing hosts. Naive BALB/c mice were inoculated with viable tumor cells. Five days later, these mice started to receive the relevant tumor-antigen-pulsed APC at 3- to 4-day intervals. The administration of tumor-antigenpulsed APC induced the rejection or growth inhibition of a growing tumor in approximately half of the recipient mice. Moreover, it was demonstrated that tumor-specific immunity was induced in such tumor-regressed mice. These results indicate that tumor-antigen-pulsed APC are effectively applicable to the tumor-specific immunotherapy.This work was supported by Special Project Research-Cancer Bioscience from the Ministry of Education, Science and Culture, Japan     

The role of suppressor T cells in BCNU-mediated rejection of a syngeneic tumor

The present investigation was initiated to determine the mechanism by which 1,3-bis(2-chloro-ethyl)-1-nitrosourea (BCNU) treatment of tumor-bearing mice results in a high percentage of surviving mice which are resistant to subsequent homologous tumor challenge. Spleen cells from C57BL/6 mice bearing the syngeneic LSA ascites tumor failed to demonstrate significant tumor-specific cytotoxic T lymphocyte (CTL) activity when stimulated in vitro with irradiated tumor cells. This lack of CTL activity correlated with the presence and high activity of two types of CTL-regulatory suppressor T cells (Ts), tumor-specific Thy-1+, Lyt-1-2+ and tumor-nonspecific Thy-1+, Lyt-1+2+ cells, as demonstrated by a double-positive selection technique. In contrast, spleen cells from BCNU-treated tumor-bearing mice generated high tumor-specific CTL activity when stimulated in vitro with irradiated tumor cells. This CTL activity correlated with the lack of demonstrable tumor-specific Ts and greatly diminished tumor-nonspecific Ts activity. The tumor-specific helper activity of Thy-1+, Lyt-1+,2- cells was found to be similar in both BCNU-treated and untreated tumor-bearing mice. BCNU-treated mice that survived a primary LSA tumor challenge (referred to as BCNU-cured mice) resisted subsequent challenge with the homologous (LSA) but not with a heterologous syngeneic tumor (EL-4). However, rejection of a secondary challenge with LSA tumor by BCNU-cured mice was inhibited by adoptive transfer of spleen cells from either normal mice or mice bearing LSA tumors. Furthermore, LSA tumor cells that failed to evoke tumor-specific CTL activity in normal mice could induce high CTL activity in BCNU-cured mice. The present study suggests that, in addition to its direct tumoricidal activity, BCNU inhibits the induction of tumor-specific Ts, thereby explaining why a high percentage of mice survive a primary syngeneic tumor challenge after treatment with BCNU, and also resist subsequent rechallenge with the homologous tumor.     

Activation of dendritic cells that cross-present tumor-derived antigen licenses CD8+ CTL to cause tumor eradication

The fate of naive CD8(+) T cells is determined by the environment in which they encounter MHC class I presented peptide Ags. The manner in which tumor Ags are presented is a longstanding matter of debate. Ag presentation might be mediated by tumor cells in tumor draining lymph nodes or via cross-presentation by professional APC. Either pathway is insufficient to elicit protective antitumor immunity. We now demonstrate using a syngeneic mouse tumor model, expressing an Ag derived from the early region 1A of human adenovirus type 5, that the inadequate nature of the antitumor CTL response is not due to direct Ag presentation by the tumor cells, but results from presentation of tumor-derived Ag by nonactivated CD11c(+) APC. Although this event results in division of naive CTL in tumor draining lymph nodes, it does not establish a productive immune response. Treatment of tumor-bearing mice with dendritic cell-stimulating agonistic anti-CD40 mAb resulted in systemic efflux of CTL with robust effector function capable to eradicate established tumors. For efficacy of anti-CD40 treatment, CD40 ligation of host APC is required because adoptive transfer of CD40-proficient tumor-specific TCR transgenic CTL into CD40-deficient tumor-bearing mice did not lead to productive antitumor immunity after CD40 triggering in vivo. CpG and detoxified LPS (MPL) acted similarly as agonistic anti-CD40 mAb with respect to CD8(+) CTL efflux and tumor eradication. Together these results indicate that dendritic cells, depending on their activation state, orchestrate the outcome of CTL-mediated immunity against tumors, leading either to an ineffective immune response or potent antitumor immunity.     

The generation of tumor-specific in vivo protective immunity in the tumor mass from mice rendered tolerant to tumor antigens

Summary C3H/He mice were inoculated i.v. with 10⁶ heavily X-irradiated syngeneic X5563 plasmacytoma cells 3 times at 4 day intervals. When these mice received an appropriate immunization procedure consisting of i. d. inoculation of viable tumor cells plus the surgical resection of the tumor which enables i.v. nonpresensitized mice to produce anti-X5563 immunity, they failed to develop tumor-specific immunity. This was demonstrated by the abrogation in potential of spleen and lymph node cells to generate in vivo protective immunity. In contrast, the tumor mass from X5563 tumor-bearing mice which had received the i.v. presensitization contained comparable anti-X5563 tumor neutralizing activity to that obtained from the tumor mass from nonpresensitized, X5563 tumor-bearing mice. Such an in vivo protective immunity was revealed to be mediated by tumor-specific T cells. These results demonstrate the differential generation and antitumor capability of tumor infiltrating T cells and T cells in lymphoid organs from mice which are in the tumor-specific tolerant state. The results are discussed in the context of potential utilization of tumor infiltrating in vivo protective T cells to enhance the local tumor-specific immunity in tumor-specific tolerant mice.This work was supported by Special Project Research-Cancer Bioscience from the Ministry of Education, Science and Culture     

Invariant chain alters the malignant phenotype of MHC class II+ tumor cells.

T lymphocytes usually recognize endogenously encoded Ag in the context of MHC class I molecules, whereas exogenous Ag is usually presented by MHC class II molecules. In vitro studies in model systems suggest that presentation of endogenous Ag by class II molecules is inhibited by the association of class II with its invariant chain (Ii). In the present study we test this hypothesis in an in vivo system in which endogenously encoded tumor peptides are presented by tumor cell MHC class II molecules. In this system, transfection of syngeneic MHC class II genes (Aak and Abk) into a highly malignant, Ii negative, mouse tumor (SaI sarcoma) produces an immunogenic tumor (SaI/Ak) that is rejected by the autologous host. The class II+ transfectants also effectively immunize autologous A/J mice against a subsequent challenge of wild-type class II- tumor cells. We have hypothesized that the SaI/Ak transfectants induce protective immunity because they function as APC for endogenously synthesized tumor peptides, and thereby stimulate tumor-specific Th cells, by-passing the need for professional APC. To test the role of Ii as an inhibitor of presentation of endogenous peptides, SaI/Ak tumor cells were supertransfected with Ii gene (SaI/Ak/Ii cells), and the tumorigenicity of the resulting cells determined. Nine SaI/Ak/Ii clones were tested, and their malignancy compared with that of SaI/Ak and SaI cells. Seven of the nine class II+/Ii+ tumor cells are more malignant than class II+/Ii- tumor cells in autologous A/J mice. Expression of Ii therefore restores the malignant phenotype, presumably by preventing presentation of endogenously synthesized tumor peptides. Ii therefore regulates Ag presentation and can be a critical parameter for in vivo tumor immunity.     

Potent tumor-specific protection ignited by adoptively transferred CD4+ T cells

Administration of anti-CD25 mAb before an aggressive murine breast tumor inoculation provoked effective antitumor immunity. Compared with CD4(+) T cells purified from anti-CD25 mAb-pretreated mice that did not reject tumor, CD4(+) T cells purified from anti-CD25 mAb-pretreated mice that rejected tumor stimulated by dendritic cells (DCs) produced more IFN-gamma and IL-2, and less IL-17 in vitro, and ignited protective antitumor immunity in vivo in an adoptive transfer model. Tumor Ag-loaded DCs activated naive CD8(+) T cells in the presence of these CD4(+) T cells in vitro. Tumor Ag and adoptively transferred CD4(+) T cells were both required for inducing a long-term tumor-specific IFN-gamma-producing cellular response and potent protective antitumor activity. Although adoptively transferred CD4(+) T cells ignited effective tumor-specific antitumor immunity in wild-type mice, they failed to do so in endogenous NK cell-depleted, Gr-1(+) cell-depleted, CD40(-/-), CD11c(+) DC-depleted, B cell(-/-), CD8(+) T cell-depleted, or IFN-gamma(-/-) mice. Collectively, the data suggest that adoptively transferred CD4(+) T cells orchestrate both endogenous innate and adaptive immunity to generate effective tumor-specific long-term protective antitumor immunity. The data also demonstrate the pivotal role of endogenous DCs in the tumor-specific protection ignited by adoptively transferred CD4(+) T cells. Thus, these findings highlight the importance of adoptively transferred CD4(+) T cells, as well as host immune components, in generating effective tumor-specific long-term antitumor activity.     

The influence of cyclophosphamide on antitumor immunity in mice bearing late-stage tumors

Spleen cells from mice bearing late-stage methylcholanthrene-induced tumor did not show any tumor activity when mixed with tumor cells in Winn's assay. Treatment of these mice with cyclophosphamide (CY) induced a tumor-inhibitory activity in spleen, occurring on day 7 after treatment, reaching its maximum on day 11 and disappearing by day 21. This antitumor activity could not be induced in control, tumor-free or T-deficient tumor-bearing mice. CY-induced tumor-inhibitory activity was immunologically specific, and mediated by Thy-1⁺, L3T4^–, Ly-2⁺ cells. Contrary to spleen cells from untreated tumor-bearing mice, spleen cells from CY-treated tumor-bearing mice did not suppress the antitumor activity of immune spleen cells in Winn's assay. However, in contrast to immune spleen cells, CY-induced tumor-inhibitory cells did not manifest antitumor activity when transferred systemically (i. v.) into T-cell-deficient tumor-bearing mice. Even more, spleen cells from CY-pretreated mice, harvested 7–15 days after the drug administration, partially suppressed the antitumor activity of concomitantly transferred spleen cells from specifically immune mice. Nevertheless, CY-pretreated mice manifested concomitant immunity, i.e. these mice exhibited higher resistance to a second inoculum of the same tumor than did nontreated mice or even mice with excised primary tumor.     

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.     

The TLR-7 agonist, imiquimod, enhances dendritic cell survival and promotes tumor antigen-specific T cell priming: relation to central nervous system antitumor immunity

Immunotherapy represents an appealing option to specifically target CNS tumors using the immune system. In this report, we tested whether adjunctive treatment with the TLR-7 agonist imiquimod could augment antitumor immune responsiveness in CNS tumor-bearing mice treated with human gp100 + tyrosine-related protein-2 melanoma-associated Ag peptide-pulsed dendritic cell (DC) vaccination. Treatment of mice with 5% imiquimod resulted in synergistic reduction in CNS tumor growth compared with melanoma-associated Ag-pulsed DC vaccination alone. Continuous imiquimod administration in CNS tumor-bearing mice, however, was associated with the appearance of robust innate immune cell infiltration and hemorrhage into the brain and the tumor. To understand the immunological mechanisms by which imiquimod augmented antitumor immunity, we tested whether imiquimod treatment enhanced DC function or the priming of tumor-specific CD8+ T cells in vivo. With bioluminescent, in vivo imaging, we determined that imiquimod dramatically enhanced both the persistence and trafficking of DCs into the draining lymph nodes after vaccination. We additionally demonstrated that imiquimod administration significantly increased the accumulation of tumor-specific CD8+ T cells in the spleen and draining lymph nodes after DC vaccination. The results suggest that imiquimod positively influences DC trafficking and the priming of tumor-specific CD8+ T cells. However, inflammatory responses induced in the brain by TLR signaling must also take into account the local microenvironment in the context of antitumor immunity to induce clinical benefit. Nevertheless, immunotherapeutic targeting of malignant CNS tumors may be enhanced by the administration of the innate immune response modifier imiquimod.     

The augmentation of tumor-specific immunity by virus help

Summary The role of vaccinia virus-reactive helper T cells (Th) in augmenting in vivo generation of antitumor protective immunity and the Ly phenotype mediating the enhanced in vivo tumor immunity were investigated. C3H/HeN mice were inoculated i.p. with viable vaccinia virus to generate vaccinia virus-reactive Th activity. The mice were subsequently immunized i.p. with virus-infected syngeneic X5563 and MH134 tumor cells, and spleen cells from these mice were tested for in vivo tumor neutralizing activity. Immunization of virus-primed mice with virus-uninfected tumor cells and of virus-unprimed mice with virus-infected tumor cells failed to result in in vivo protective immunity. In contrast, spleen cells from mice immunized with virus-infected tumor cells subsequent to virus-priming exhibited potent tumor-specific neutralizing activities. Such an augmented generation of in vivo protective immunity was accompanied by enhanced induction of tumor-specific cytotoxic T lymphocyte (CTL) and antibody activities in X5563 and MH134 tumor systems, respectively. However, analysis of the effector cell type responsible for in vivo tumor neutralization revealed that enhanced in vivo immunity was mediated by Lyt-1⁺2^– T cells in both tumor systems. Moreover, the Lyt-1⁺2^– T cells exerted their function in vivo under conditions in which anti-X5563 tumor-specific CTL or anti-MH134 tumor-specific antibody activity was not detected in recipient mice. These results indicate that augmenting the generation of a tumor-specific Lyt-1⁺2^– T cell population is essential for enhanced tumor-specific immunity in vivo.This work was supported by Special Project Research-Cancer Bioscience from the Ministry of Education, Science and Culture     

Intraocular tumor antigen drains specifically to submandibular lymph nodes, resulting in an abortive cytotoxic T cell reaction

Ocular immune privilege is considered essential in the protection against sight-threatening immune responses, as illustrated by the ability of the ocular environment to permit the growth of tumors that are rejected when implanted at other sites. Although several studies indicate that soluble Ag can drain directly into the spleen when injected into the anterior chamber, the primary site of intraocular tumor Ag presentation to tumor-specific CTLs has not been studied. To gain a better understanding of the mechanism involved in ocular immune privilege, we examined to which lymphoid organs anterior chamber tumor Ags primarily drain. Our data show that intraocular tumor Ag drains exclusively to the submandibular lymph nodes, resulting in activation of tumor-specific CTLs, whereas no Ag drainage was found in spleen. However, these tumor-specific CTLs do not distribute systemically and, as a consequence, intraocular tumor growth is unhampered. A similar lack of CTL efficacy has been observed in mice bearing s.c. tumors, which is converted to a systemic tumoricidal CTL response by administration of agonistic anti-CD40 mAb. In contrast, systemic anti-CD40 treatment of eye tumor-bearing mice did not result in mobilizing tumor-specific CTLs or tumor eradication. Together, these results show that intraocular tumor Ag drains to regional lymph nodes for activation of tumor-specific CTLs. However, the induced tumor-specific immunity is insufficient for tumor clearance, even combined with otherwise highly effective immune intervention protocols.     

Enhanced production of IL-6 in tumor-bearing mice and determination of cells responsible for its augmented production

IL-6 is a cytokine secreted in normal individuals by monocytes, fibroblasts, and endothelial cells. We have found increased levels of IL-6 in the sera from MH134 hepatoma- and CSA1M fibrosarcoma-bearing mice. Concerning the capacity of these tumor cells themselves to produce IL-6 in vitro, they exhibited the distinct contrast, i.e., the MH134 tumor cells produced high levels of IL-6 whereas the CSA1M generated a marginal level of IL-6. It was, however, demonstrated that appreciably enhanced IL-6 production was observed in spleen cell culture supernatants from both types of tumor-bearing mice when compared to those obtained from normal mice. More importantly, in contrast to the production of IL-6 by non-T cell compartment of normal spleen cells, enhanced IL-6 production of spleen cells from tumor-bearing mice was ascribed to T cell compartment. Analysis of T cell phenotype has revealed that enhanced IL-6 production was mediated predominantly by Lyt-2+ but not by L3T4+ T cell subset. Thus, these results indicate that increased circulating IL-6 is elicited in the tumor-bearing state and that irrespective of the potential of tumor cells themselves to produce IL-6, T cells, especially Lyt-2+ T cells from tumor-bearing mice are responsible for such a high level of IL-6 production.     

Augmented induction of tumor-specific resistance by priming with Mycobacterium tuberculosis (TBC) and subsequent immunization with PPD-coupled syngeneic tumor cells

The present study investigates the augmenting effect of tuberculin- (PPD) reactive amplifier T cells on the induction of syngeneic tumor immunity. PPD-reactive helper (amplifier) T cell activity was generated in C3H/HeJ mice by appropriate immunization with heat-killed Mycobacterium (Tbc). Immunization of these Tbc-primed mice with PPD-coupled syngeneic X5563 tumor cells led to augmented generation of in vivo tumor-neutralizing activity contingent on the presence of PPD-reactive amplifier T cell activity. Splenic T cells from these mice exhibited potent tumor-neutralizing activity using Winn's assay, whereas spleen cells from mice not primed with Tbc before PPD-X5563 immunization failed to neutralize viable X5563 tumor cells. After establishing that the neutralizing activity was tumor specific and mediated by T cells, the applicability of this augmentation of tumor-specific immunity to an immunotherapy model was explored. Immunization with PPD-X5563 in the early stages of the tumor-bearing state induced potent anti-tumor activity sufficient to reject the growing tumor. Pretreatment of mice with cyclophosphamide or light x-irradiation (250 R), procedures that eliminate suppressor cell activity nonspecifically, before priming with Tbc further potentiated the anti-tumor activity under these conditions. Thus, the present study elucidates the augmenting effect of PPD-reactive amplifier T cells in the induction of tumor-specific immunity and provides an effective method of immunotherapy in tumor-bearing animals.     

Abrogation of tumorigenicity by MHC class II antigen expression requires the cytoplasmic domain of the class II molecule

Transfection of syngeneic MHC class II genes into the lethal mouse SaI tumor abrogates the malignancy of the tumor in the autologous host, and protects the host against subsequent challenges with the wild type class II- tumor. We have hypothesized that the transfectants induce protective immunity by functioning as APC for tumor peptides, and stimulating tumor-specific Th cells. Recent in vitro studies suggest that Ag presentation by class II-restricted APC requires the cytoplasmic domain of the class II molecule, and may involve intracellular signaling via the cytoplasmic domain. To determine if the class II cytoplasmic domain is required for enhanced tumor-specific immunity, SaI mouse sarcoma cells were transfected with syngeneic Aak and Abk genes with truncated cytoplasmic domains. These transfectants are as malignant as wild type class II- SaI cells in autologous A/J mice. Stimulation of tumor-specific immunity by class II+ tumor cells is therefore dependent on the class II cytoplasmic region, and may involve intracellular signaling events.     

An extract of seeds fromAeginetia indica L., a parasitic plant,induces potent antigen-specific antitumor immunity in Meth A-bearing BALB/c mice

Summary The antitumor activity of an extract of seeds fromAeginetia indica L., a parasitic plant, was investigated. BALB/c mice, inoculated i.p. 1 × 10⁵ syngeneic Meth A tumor cells, were administered 2.5 mg/kgA. indica extract i.p. every 2 days from day 0. The untreated mice died of an ascitic form of tumor growth within 21 days, whereas all the treated mice completely recovered from tumor challenge without any side-effects. The extract did not exert direct cytotoxic activity against Meth A in vitro. Mice that survived after the first challenge as a result ofA. indica treatment overcame the rechallenge with homologous Meth A without additional administration of the extract. On the other hand, those mice could not survive after rechallenge with Meth 1 tumor cells, which were also established in BALB/c mice but were different in antigenicity from Meth A, suggesting the development of antigen-specific concomitant immunity in theA. indica-cured mice. In the induction phase of antitumor resistance in this system, CD4⁺ T cells appeared to be the main contributors, since in vivo administration of anti-CD4 mAb completely abolished such resistance. In contrast, anti-CD8 mAb administration did not influence the effect ofA. indica. The importance of CD4⁺ T cells in antitumor immunity was again clarified by Winn assay; that is, spleen and lymph node cells depleted of CD4⁺ T cells in vitro prior to assay abolished antitumor activity on co-grafted Meth A tumor cells in vivo.     

γ-Irradiation facilitates the expression of adoptive immunity against established tumors by eliminating suppressor T cells

It was found that sublethal (550 rad) whole-body gamma-irradiation of mice bearing established immunogenic tumors enabled tumor-sensitized spleen cells infused intravenously 1 h later to cause complete tumor regression in all mice. In contrast, gamma-irradiation alone caused only a temporary halt in tumor growth, and immune cells gave practically no therapeutic effect at all. This result was obtained with the SA1 sarcoma, Meth A fibrosarcoma, P815 mastocytoma, and P388 lymphoma. Additional experiments with the Meth A fibrosarcoma revealed that the spleen cells from tumor-immune donors that caused tumor regression in gamma-irradiated recipients were T cells, as evidenced by their functional elimination by treatment with anti-Thy-1.2 antibody and complement. It was shown next that adoptive T-cell-mediated regression of tumors in gamma-irradiated recipients was inhibited by an intravenous infusion of spleen cells from donors with established tumors, but not by spleen cells from normal donors. The spleen cells that suppressed the expression of adoptive immunity were functionally eliminated by treatment with anti-Thy-1.2 antibody and complement. Moreover, they were destroyed by exposing the tumor-bearing donors to 500 rad of gamma-radiation 24 h before harvesting their spleen cells. The results are consistent with the interpretation that gamma-radiation facilitates the expression of adoptive T-cell-mediated immunity against established tumors by eliminating a population of tumor-induced suppressor T cells from the tumor-bearing recipient.     

Vaccination with membrane-associated idiotype provides greater and more prolonged protection of animals from tumor challenge than the soluble form of idiotype

The purpose of this work was to compare the efficacy of immunizing mice with a soluble vs a cell-associated form of a tumor Ag. A murine B cell tumor (2C3), which displays an Id on its cell surface, grows progressively and gives rise to Id-negative tumor variants in nonimmunized animals. We previously reported that the tumor variants arise as a consequence of Id-specific T cell suppression of the Id+ tumor. The Id-specific effector T cells are CD4+, CD8-. Based upon these findings vaccination protocols have been designed and tested to determine whether the expansion of tumor-specific effector T cells would eliminate the Id+ tumors and prevent the subsequent generation of Id- tumor variants in vivo. MHC-restricted T cells typically recognize soluble Ag subsequent to modification by an APC, and APC may ultimately express a processed form of the Ag that is different from that expressed on the surface of the tumor cells. Based upon this assumption, the efficacy of immunizing mice with cell-associated 2C3 Id was compared to immunization with a soluble form of the same Id. Mice were immunized with either irradiated 2C3 cells or syngeneic spleen cells to which 2C3 protein was covalently linked. These immunization protocols provided a complete and lasting protection against a tumor challenge of up to 1 x 10(6) tumor cells. In contrast, most mice hyperimmunized with a soluble form of the Id did not survive this level of tumor challenge in spite of the production of significant levels of anti-Id antibodies. Mice immunized with the soluble form of the Id, which did survive, produced slowly progressing tumors expressing a 1000-fold less of the marker Id. These results illustrate the importance of understanding and properly exploiting a host's natural response to a tumor-specific Ag when designing effective immunization protocols for cancer therapy.     

Recombinant cholera toxin B subunit activates dendritic cells and enhances antitumor immunity

Activation of dendritic cells (DC) is crucial for priming of cytotoxic T lymphocytes (CTL), which have a critical role in tumor immunity, and it is considered that adjuvants are necessary for activation of DC and for enhancement of cellular immunity. In this study, we examined an adjuvant capacity of recombinant cholera toxin B subunit (rCTB), which is non-toxic subunit of cholera toxin, on maturation of murine splenic DC. After the in vitro incubation of DC with rCTB, the expression of MHC class II and B7-2 on DC was upregulated and the secretion of IL-12 from DC was enhanced. In addition, larger DC with longer dendrites were observed. These data suggest that rCTB induced DC maturation. Subsequently, we examined the induction of tumor immunity by rCTB-treated DC by employing Meth A tumor cells in mice. Pretreatment with subcutaneous injection of rCTB-treated DC pulsed with Meth A tumor lysate inhibited the growth of the tumor cells depending on the number of DC. Moreover, intratumoral injection of rCTB-treated DC pulsed with tumor lysate had therapeutic effect against established Meth A tumor. Immunization with DC activated by rCTB and the tumor lysate increased number of CTL precursor recognizing Meth A tumor. The antitumor immune response was significantly inhibited in CD8+ T cell-depleted mice, although substantial antitumor effect was observed in CD4+ T cell-depleted mice. These results indicated that rCTB acts as an adjuvant to enhance antitumor immunity through DC maturation and that CD8+ T cells play a dominant role in the tumor immunity. Being considered to be safe, rCTB may be useful as an effective adjuvant to raise immunity for a tumor in clinical application.