The augmentation of tumor-specific immunity using haptenic muramyl dipeptide (MDP) derivatives

Summary A new haptenic compound, a muramyl dipeptide (MDP) derivative (designated as L4-MDP-ONB) cross-reactive with Bacillus Calmette Guerin (BCG) was synthesized. The cross-reactivity of L4-MDP hapten to BCG was demonstrated from the following evidence; (a) lymph node cells from BCG-primed C3H/HeN mice exhibited appreciable L4-MDP-specific proliferative responses to the in vitro stimulation of L4-MDP-modified syngeneic cells (L4-MDP-self); (b) inoculation of L4-MDP-self into footpads of BCG-primed C3H/HeN mice elicited ample delayed type-hypersensitivity (DTH) responses in vivo as measured by footpad swelling; and (c) BCG-primed mice contained L4-MDP-reactive helper T cell activity which functions to augment the generation of effector T cell responses to cell surface antigens. This crossreactivity between L4-MDP hapten and BCG as measured by the helper T cell activity was applied to enhanced induction of tumor-specific immunity. When BCG-primed C3H/HeN mice were immunized with L4-MDP-modified syngeneic X5563 tumor cells, these mice could generate augmented tumor-specific in vivo protective (tumor neutralizing) immunity as well as in vitro cytotoxic T cell responses. These results indicate the effectiveness of L4-MDP hapten in augmenting tumor-specific immunity. The present approach is discussed in the context of potential advantages of this new hapten for its future application to clinical tumor systems.     

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     

Studies on the recovery from tolerance to tumor antigens

Summary The present study investigates the potential of bone marrow cells from mice tolerant to tumor antigens to repopulate tumor-specific effector T cells. C3H/He mice were inoculated i.v. with 10⁶ 10000 R X-irradiated syngeneic X5563 plasmacytoma tumor cells three times at 4-day intervals. This regimen abrogated the ability of spleen cells from these mice to develop anti-X5563 cytotoxic and in vivo protective (tumor-neutralizing) T cell-mediated immunity as induced by i.d. inoculation of viable X5563 cells followed by surgical resection of the tumor. Since such suppression was induced in a tumor-specific way, this represented a state of antitumor tolerance. When bone marrow cells from normal or X5563-tolerant mice were transferred i.v. into 950 R X-irradiated syngeneic C3H/He mice, both groups of recipient mice generated anti-X5563 tumor immunity over a similar time course and to almost the same degree. Anti-X5563 tumor immunity induced in (C3H/He×C57BL/6) F1 mice which had been transferred with bone marrow cells from normal or X5563-tolerant C3H/He mice were mediated by T cells expressing the Ly phenotype of C3H/He, but not of C57BL/6, excluding the possibility that the antitumor effector cells were derived from recipient mice. It was also demonstrated that C3H/He mice which had been reconstituted with normal marrow were rendered tolerant when the tolerance regimen was started 7 weeks, but not 1 week after the bone marrow reconstitution. These results indicate that bone marrow cells from antitumor tolerant mice are not rendered tolerant to the tumor but can provide the potential to repopulate antitumor CTL and in vivo protective effector T cells.This work was supported by the Special Project Cancer-Bioscience from the Ministry of Education, Science and Culture, Japan Abbreviations used: MHC, major histocompatibility complex; CTL, cytotoxic T lymphocytes; TNP, trinitrophenyl; C, complement; TNBS; trinitrobenzene sulfonate; MMC, mitomycin C     

The augmentation of tumor-specific immunity using haptenic muramyl dipeptide (MDP) derivatives

Summary Preinduction of potent haptenic muramyl dipeptide (MDP)-reactive helper T cell activity and subsequent immunization with MDP hapten-coupled syngeneic tumor cells resulted in enhanced induction of tumor-specific immunity through T-T cell collaboration between anti-MDP hapten helper T cells and tumor-specific effector T cells. The present study establishes two types of tumor-specific immunotherapy protocols utilizing helper T cells against MDP hapten cross-reactive with Bacillus Calmette Guérin (BCG). In the first model, naive normal C3H/He mice or mice in which MDP hapten-reactive helper T cells had been generated by BCG-sensitization were inoculated i.d. with syngeneic X5563 tumor cells. When both groups of mice were allowed to generate MDP hapten-modified tumor cells in the tumor mass in situ by intratumoral injection of MDP hapten, an appreciable number of growing tumors in the BCG-presensitized but not in the unsensitized group were observed to regress. In the second model, a growing X5563 tumor mass was removed by the surgical resection 9 days after the tumor implantation. Approximately 90% of C3H/He mice receiving such treatment died from tumor metastasis by about 30 days after the tumor resection. However, immunization of mice with MDP hapten-coupled X5563 tumor cells subsequent to the tumor resection resulted in an increased survival rate. Such protection from the tumor metastasis was appreciably stronger when compared to the protection obtained by immunization with MDP hapten-uncoupled tumor cells. The mice surviving in both models were also demonstrated to retain X5563 tumor-specific immunity. These results indicate that the presentation of MDP hapten-modified tumor cells to BCG-sensitized recipients results in potent tumor-specific immunity which contributes to the regression of the primary tumor or inhibition of metastatic tumor growth.This work was supported by a Grant-in-Aid for the Special Project Cancer Bioscience from the Ministry of Education, Science and Culture, Japan     

The role of tumor-specific Lyt-1+2- T cells in eradicating tumor cells in vivo. I. Lyt-1+2- T cells do not necessarily require recruitment of host's cytotoxic T cell precursors for implementation of in vivo immunity

The present study determines the Ly phenotype of T cells mediating tumor cell rejection in vivo and investigates some of cellular mechanisms involved in the in vivo protective immunity. C3H/HeN mice were immunized to syngeneic X5563 plasmacytoma by intradermal (i.d.) inoculation of viable X5563 tumor cells, followed by the surgical resection of the tumor. Spleen cells from these immune mice were fractionated by treatment with anti-Lyt antibodies plus complement, and each Lyt subpopulation was tested for the reconstituting potential of in vivo protective immunity in syngeneic T cell-depleted mice (B cell mice). When C3H/HeN B cell mice were adoptively transferred with Lyt-1-2+ T cells from the above tumor-immunized mice, these B cell mice exhibited an appreciable cytotoxic T lymphocyte (CTL) response to the X5563 tumor, whereas they failed to resist the i.d. challenge of X5563 tumor cells. In contrast, the adoptive transfer of Lyt-1+2- anti-X5563 immune T cells into B cell mice produced complete protection against the subsequent tumor cell challenge. Although no CTL or antibody response against X5563 tumors was detected in the above tumor-resistant B cell mice, these mice were able to retain Lyt-1+2- T cell-mediated delayed-type hypersensitivity (DTH) responses to the X5563 tumor. These results indicate that Lyt-1+2- T cells depleted of the Lyt-2+ T cell subpopulation containing CTL or CTL precursors are effective in in vivo protective immunity, and that these Lyt-1+2- T cells implement their in vivo anti-tumor activity without inducing CTL or antibody responses. The mechanism(s) by which Lyt-1+2- T cells function in vivo for the implementation of tumor-specific immunity is discussed in the context of DTH responses to the tumor-associated antigens and its related Lyt-1+2- T cell-mediated lymphokine production.     

Establishment of a tumor-specific immunotherapy model utilizing TNP-reactive helper T cell activity and its application to the autochthonous tumor system

Preinduction of potent hapten-reactive helper T cell activity and subsequent immunization with hapten-coupled syngeneic tumor cells result in enhanced induction of tumor-specific immunity through T-T cell collaboration between anti-hapten helper T cells and tumor-specific effector T cells. On the basis of this augmenting mechanism, a tumor-specific immunotherapy protocol was established in which a growing tumor regresses by utilizing a potent trinitrophenyl (TNP)-helper T cell activity. C3H/He mice were allowed to generate the amplified (more potent) TNP-helper T cell activity by skin painting with trinitrochlorobenzene (TNCB) after pretreatment with cyclophosphamide. Five weeks later, the mice were inoculated intradermally with syngeneic transplantable X5563 tumor cells. When TNCB was injected into X5563 tumor mass, an appreciable number of growing tumors, in the only group of C3H/He mice in which the amplified TNP-helper T cell activity had been generated were observed to regress (regressor mice). These regressor mice were shown to have acquired tumor-specific T cell-mediated immunity. Such immunity was more potent than that acquired in mice whose tumor was simply removed by surgical resection. These results indicate that in situ TNP haptenation of the tumor cells in TNP-primed mice can induce the enhanced tumor-specific immunity leading to the regression of a growing tumor. Most importantly, the present study further investigates the applicability of this TNP immunotherapy protocol to an autochthonous tumor system. The results demonstrate that an appreciable percent of growing methylcholanthrene-induced autochthonous tumors regressed by the above TNP immunotherapy protocol. Thus, the present model provides an effective maneuver for tumor-specific immunotherapy in syngeneic transplantable as well as autochthonous tumor systems.     

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.     

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     

Additional evidence for the augmented induction of tumor-specific resistance in vaccinia virus-primed mice by immunization with vaccinia virus-modulated syngeneic tumor cells

The augmenting effect of vaccinia virus infection of tumor cells on induction of tumor-specific resistance was examined in mice. C3H/HeN mice were primed intraperitoneally (ip) with live vaccinia virus after whole-body irradiation with 250 rad of X-rays. Three weeks later the mice were immunized ip 3 times at weekly intervals with syngeneic murine hepatoma MH134 or spontaneous myeloma X5563 which had been infected in vitro with vaccinia virus and subsequently irradiated with 7000 rad of X-rays. One week after the third immunization, the mice were challenged with 1 X 10(5) viable cells of MH134 or X5563 ip or 1 X 10(6) tumor cells intradermally (id). On ip challenge with viable MH134 cells all mice that had not been pretreated died within 3 weeks due to ascites tumor out-growth, whereas all mice that had been vaccinia virus-primed and immunized with vaccinia virus-infected MH134 cells survived. On ip challenge with X5563 cells, the percentage survival of vaccinia virus-primed and vaccinia virus-modified tumor-immunized mice was 80%. On id challenge with MH134 and X5563 tumor cells, in un-treated mice tumors grew to more than 5 mm in diameter within 3 weeks, whereas 90% and 60%, respectively, of the mice that had been vaccinia virus-primed and immunized with vaccinia virus-infected tumor cells showed no tumor out-growth. Pretreatment by only immunization with vaccinia virus-infected cells or vaccinia virus-priming and immunization with virus non-infected tumor cells were not effective for preventing induction of tumor-resistance to either ip or id challenge with MH134 or X5563 tumor cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of tumor-specific Lyt-1+2− T cells in eradicating tumor cells in vivo

Summary The present study investigates some of mechanisms for tumor-specific Lyt-1⁺2^– T cell-mediated tumor cell eradication in vivo through analyses of tumor specificity in the afferent tumor recognition and efferent rejection phases. When C3H/He mice which had acquired immunity against syngeneic MH134 hepatoma were challenged with other syngeneic X5563 plasmacytoma cells, these mice failed to exhibit any inhibitory effect on the growth of X5563 tumor cells. However, the inoculation of X5563 tumor cells into the MH134-immune C3H/He mice together with the MH134 tumor cells resulted in appreciable growth inhibition of antigenically distinct (bystander) X5563 tumor cells. Although the growth of X5563 cells was inhibited in an antigen-nonspecific way in mice immunized to antigenically unrelated tumor cells (bystander effect), the activation of Lyt-1⁺2^– T cells leading to this effect was strictly antigen-specific. Such a bystander growth inhibition also required the admixed inoculation of the bystander (X5563) and specific target (MH134) tumor cells into a single site in mice immunized against the relevant MH134 tumor cells. Furthermore, the results demonstrated that Lyt-1⁺2^– T cells specific to MH134 tumor cells were responsible for mediating the growth inhibition of antigenically irrelevant (bystander) and relevant tumor cells. These results are discussed in the context of cellular and molecular mechanisms involved in the Lyt-1⁺2^– T cell-initiated bystander phenomenon.This work was supported by Special Project Research-Cancer Bioscience from the Ministry of Education, Science and Culture     

The mechanism of tumor growth inhibition by tumor-specific Lyt-1+2-T cells. I. Antitumor effect of Lyt-1+2-T cells depends on the existence of adherent cells

In the present study we establish an assay system of tumor growth inhibition with the use of a diffusion chamber and investigate the mechanism by which tumor-specific Lyt-1+2-T cells exhibit their inhibiting effect on tumor cell growth. When a diffusion chamber containing X5563 plasmacytoma cells together with normal syngeneic C3H/HeN spleen cells was implanted in the peritoneal cavity of C3H/HeN mice, these tumor cells continued to proliferate at least 7 to 9 days. In contrast, spleen cells from C3H/HeN mice that had acquired X5563-specific immunity by intradermal (i.d.) inoculation of viable tumor cells, followed by surgical resection of the tumor, exhibited an appreciable inhibitory effect on the growth of X5563 tumor cells admixed in the chamber. This antitumor effect was mediated by Lyt-1+2-T cells and was tumor-specific, because the growth of X5563 or another syngeneic MH134 hepatoma cells was inhibited by spleen cells from C3H/HeN mice immunized to the respective tumor cell types. Most important, these tumor-specific Lyt-1+2-T cells lost their antitumor activity by depleting an adherent cell population contained in spleen cells, indicating that adherent cells are required for the Lyt-1+2-T cell-mediated antitumor effect. This was substantiated by the fact that immune spleen cells depleted of adherent cells could regain their tumor-inhibiting effect when normal spleen cells were added back as an adherent cell source, or more directly by adding back a splenic or peritoneal resident adherent cell population. These results indicate that tumor-specific Lyt-1+2-T cells mediate the tumor growth inhibition and that their antitumor effect depends on the coexistence of an adherent cell population.     

The augmentation of tumor-specific immunity using haptenic muramyl dipeptide (MDP) derivatives

Summary A previous paper has demonstrated that enhanced tumor-specific immunity could be induced by priming mice with Bacillus Calmette Guerin (BCG) and subsequently immunizing them with syngeneic tumor cells modified with BCG-cross-reactive muramyl dipeptide (MDP) hapten [15]. The present study establishes a tumorspecific immunotherapy protocol for a murine chronic leukemia based on the above T-T cell collaboration between antitumor effector T cells and anti-MDP hapten helper T cells induced by BCG priming. BALB/c mice which had been primed to BCG were injected intravenously (i.v.) with viable, syngeneic BCL1 leukemia cells. One week later, these mice were immunized intraperitoneally (i.p.) with unmodified or MDP hapten-modified, 10,000 R X-irradiated BCL1 cells, followed by 4 booster immunizations at 5-day intervals. The administration of unmodified BCL1 tumor cells into BCG-primed mice failed to prevent them from tumor death due to the persistent growth of preinjected BCL1 cells. In contrast, the immunization of BCG-primed, BCL1 leukemia-cell-bearing mice with MDP-modified BCL1 cells resulted in a high growth inhibition of leukemia cells and protection of these mice from death by leukemia. It was also revealed that potent tumorspecific, T-cell-mediated immunity was generated in mice which survived in this immunotherapy model. Thus, these results indicate that administration of MDP hapten-modified, syngeneic leukemia cells into leukemia-bearing mice which have been primed with BCG results in potent tumor-specific, T-cell-mediated immunity attributable to preventing the growth of disseminated leukemic cells.This work was supported by a Grant-in-Aid for the Special Project Cancer-Bioscience from the Ministry of Education, Science, and Culture, Japan Abbreviations used: TATA, tumor-associated transplantation antigens; MDP, muramyl dipeptide; MTP, muramyl tripeptide; BCG, Bacillus Calmette Guerin     

Induction of T-cell-mediated immunity against MethA fibrosarcoma by intratumoral injections of a bacillus Calmette-Guérin nucleic acid fraction

Summary MY-1, which consists of DNA and RNA extracted and purified from bacillus Calmette-Guérin (BCG), has been shown to have strong antitumor activity against various experimental tumors. To examine the role of T cells in the antitumor mechanism of MY-1, the effect of MY-1 injection on the development of tumor-specific immunity against MethA fibrosarcoma was investigated. MY-1 injections inhibited tumor growth less effectively in T-cell-deficient nude mice than in normal BALB/c mice. MethA tumor growth was suppressed after inoculation with L3T4-positive lymphocytes from tumor-bearing mice treated with MY-1. MethA-specific delayed-type hypersensitivity was also detected in tumor-bearing mice treated with MY-1. Immunohistochemical analyses showed that many L3T4-positive and a few Lyt2-positive cells infiltrated the regressing tumors. These results indicate that intratumoral MY-1 injections induce a MethA-specific, L3T4-positive cell-mediated, delayed-type hypersensitivity, which is necessary for the tumor regression.     

A modified tyrosinase-related protein 2 epitope generates high-affinity tumor-specific T cells but does not mediate therapeutic efficacy in an intradermal tumor model

The generation of tumor-specific T cells is hampered by the presentation of poorly immunogenic tumor-specific epitopes by the tumor. Here, we demonstrate that, although CD8+ T cells specific for the self/tumor Ag tyrosinase-related protein 2 (TRP2) are readily detected in tumor-bearing hosts, vaccination of either tumor-bearing or naive mice with an epitope derived from TRP2 fails to generate significant numbers of tetramer-staining TRP2-specific T cells or antitumor immunity. We identified an altered peptide epitope, called deltaV, which elicits T cell responses that are cross-reactive to the wild-type TRP2 epitope. Immunization with deltaV generates T cells with increased affinity for TRP2 compared with immunization with the wild-type TRP2 epitope, although TRP2 immunization often generates a greater number of TRP2-specific T cells based on intracellular IFN-gamma analysis. Despite generating higher affinity responses, deltaV immunization alone fails to provide any greater therapeutic efficacy against tumor growth than TRP2 immunization. This lack of tumor protection is most likely a result of both the deletion of high affinity and functional tolerance induction of lower affinity TRP2-specific T cells. Our data contribute to a growing literature demonstrating the ability of variant peptide epitopes to generate higher affinity T cell responses against tumor-specific Ags. However, consistent with most clinical data, simple generation of higher affinity T cells is insufficient to mediate tumor immunity.     

Tumor-specific idiotype vaccines. II. Analysis of the tumor-related network response induced by the tumor and by internal image antigens (Ab2 beta)

In this study the tumor-specific immuneresponse induced by irradiated tumor cells (L1210/GZL) and by anti-idiotype antibodies was analyzed. The anti-idiotype antibodies (Ab2) were made against the paratope of a monoclonal antitumor antibody (11C1) that recognizes a tumor-associated antigen which cross-reacts with the mouse mammary tumor virus-encoded envelope glycoprotein 52. Two Ab2, 2F10 and 3A4, induced idiotypes expressed by the monoclonal antitumor antibodies 11C1 and 2B2. Cytotoxic T cells, generated by immunization with irradiated tumor cells, lyse 2F10 and 3A4 hybridoma cells. Furthermore, immunization with Ab2 induces tumor-specific cytotoxic T lymphocytes. The frequency of tumor-reactive cytotoxic T lymphocyte was found to be similar in mice immunized with Ab2 or irradiated tumor cells when examined at the precursor level. However, only 2F10 induces protective immunity against the growth of L1210/GZL tumor cells. The depletion of a L3T4+ T cell population from 2F10 immune mice was found to increase the effectiveness of transferred T cells to induce inhibition of tumor growth. The inability of 3A4 to induce antitumor immunity could be correlated with the presence of a population of Lyt2+ regulatory T cells. Collectively, these results demonstrate the existence of a regulatory network controlling the expression of effective tumor immunity. Our results demonstrate that selection of binding site-related Ab2 may not be a sufficient criteria for the development of an idiotype vaccine. A better understanding of the regulatory interactions induced by anti-idiotypes is needed for the design of effective antitumor immunotherapy.     

Anti-idiotype responses abrogate anti-CD4–induced tolerance to a tumor-specific antigen and promote systemic tumor immunity

Purpose: Immunologic-based cancer treatment modalities represent an active area of investigation. Included in these strategies are passive administration of monoclonal antibodies which recognize tumor-associated antigens and active vaccination with identified tumor antigens. However, several problems associated with these types of treatment strategies have been identified. Methods: In this report, we address certain issues by employing a murine model for experimental pulmonary metastasis and a tumor antigen vaccination strategy that induces complete tumor immunity in this system. Utilizing this model, we attempt to address issues related to unresponsiveness to tumor antigen immunization induced by passive administration of a rat monoclonal anti-CD4 and the induction of anti-idiotype responses to a passively administered monoclonal antibody and the effects on the induction of tumor immunity. Results: The results presented indicate that passive administration of rat monoclonal anti-CD4 exhibits immunosuppressive effects that inhibit the production of antibodies to the tumor antigen immunization and abolishes tumor immunity. Repeated administration of the rat monoclonal anti-CD4 results in an anti-idiotype response that can abrogate unresponsiveness to tumor antigen immunization and promote systemic tumor immunity. Conclusions: The data examine a number of potential problems associated with immunologic-based treatments for cancer. These problems include the potential for tolerance to the tumor antigen and establishing an immunocompromised state where immunization with a tumor antigen failed to generate tumor immunity. Approaches to eliminate tolerant T cells by targeting anti-CD4 via anti-idiotype responses that could be generated in vivo without CD4⁺ T cells allowed for recovery of nontolerant T cells, and an antibody response to the tumor antigen that results in tumor immunity.Abbreviations CTL Cytotoxic T lymphocyte - FITC Fluorescein isothiocyanate - OD Optical density - PBS Phosphate-buffered saline - SV40 Simian virus 40     

Type II collagen-induced murine arthritis. I. Induction and perpetuation of arthritis require synergy between humoral and cell-mediated immunity

Immunization of DBA/1 mice with type II collagen resulted in typical and progressive arthritis, which is associated with the production of high titer of anti-collagen antibody and the induction of cell-mediated immunity as exemplified by delayed type hypersensitivity response as well as lymphokine production. In contrast, administration of heat-denatured collagen into DBA/1 mice failed to induce the arthritis. These mice produced only marginal antibody, whereas they developed comparable cell-mediated immunity to that induced by immunization with native collagen, and therefore the inoculation of heat-denatured collagen provided the regimen capable of inducing preferentially cell-mediated immunity without the generation of high level of antibody. Inasmuch as administration of antibody induced only marginal and transient joint swelling not associated with typical histologic lesion, the synergistic effect of humoral and cell-mediated immunities was investigated using antibody preparation and the regimen to induce selectively cell-mediated immunity. The results demonstrate that administration of antibody into DBA/1 mice pre-sensitized with heat-denatured collagen resulted in potent and progressive arthritis. Such synergy was further confirmed by the induction of arthritis in T cell-depleted DBA/1 mice that had been adoptively transferred with antibody and lymphoid cells from heat-denatured collagen-sensitized mice. Moreover, it was revealed that the nature of cells capable of transferring cell-mediated immunity was of Thy-1+ and L3T4+ Lyt-2-. These results indicate that anti-collagen antibody and L3T4+ T cell-mediated cellular immunity are crucially required for the perpetuated development of type II collagen-induced arthritis.     

Cellular interactions and the role of interleukin 2 in the expression and induction of immunity against a syngeneic murine sarcoma

We have previously demonstrated that following the adoptive transfer of immune cells, the regression of established pulmonary metastases from a weakly immunogenic sarcoma, MCA 105, required the collaboration of two T cell subsets. In this study, we found that the critical role played by L3T4+ immune cells was to provide a helper function since tumor regression proceeded in the absence of L3T4+ immune cells if exogenous interleukin 2 (IL-2) was administered. To extend these observations, we analyzed the events leading to the induction and generation of L3T4+ and Lyt-2+ immune T cells after immunization of mice with viable tumor cells admixed with Corynebacterium parvum. The basic protocol involved immunization, surgical excision of the immunization site on day 7, and challenge with viable tumor cells on day 21. The ability of mice to reject tumor challenge provided a means to evaluate the occurrence of a systemic antitumor immunity. With the use of this experimental protocol, we have found that depletion of T cell subsets in vivo with either L3T4 or Lyt-2 monoclonal antibodies after active immunization abrogated the development of antitumor immunity. Mice immunized and depleted of L3T4+ but not Lyt-2+ T cells were able to reject tumor challenge if exogenous IL-2 was given for 7 days. However, the rejection of tumor challenge required 3 days of additional exogenous IL-2 administration. These results indicate that the induction of Lyt-2+ immune T cells depended on the helper function of L3T4+ T cells via the secretion of IL-2. In the absence of L3T4+ immune lymphocytes, the expression of antitumor immunity by Lyt-2+ immune cells could be facilitated by in vivo administration of exogenous IL-2. The induction of L3T4+ immune T cells, on the other hand, occurred independently of the Lyt-2+ T cell response because the transfer of spleen cells from Lyt-2+ cell-depleted, immunized animals was able to restore antitumor reactivity in L3T4+ cell-depleted, immunized mice. These results demonstrate the intricate cellular interactions leading to the induction as well as the expression of antitumor immunity.     

Effect of recombinant interleukin 2 (R-IL2) on in vivo growth of murine myeloma X5563

Summary The present study deals with the effect of recombinant interleukin 2 (R-IL2) on in vivo growth of murine myeloma X5563. Administration of R-IL2 (5×10⁴ J.U./mouse per day) s.c. starting 1 day after X5563 inoculation i.d. had a marginal effect on the growth of X5563, and all the mice repeatedly given R-IL2 from day 1 to day 17 died. However, daily administration of R-IL2 starting 7 days after the tumor inoculation was highly effective and significantly lengthened survival time compared with the control mice injected with vehicle alone. About 50% of the treated mice were completely cured, and survived for more than a month after the therapy ceased. In a representative experiment, where the growth of X5563 was slow because of the small number of inoculated tumor cells, all the mice (n=6) given R-IL2 from day 11 to day 23 showed complete cure of the established X5563 solid tumor. These mice showed in vivo protective immunity and in vitro cytotoxic T cell responses to X5563 tumor antigens. Histologically, a large number of macrophages and lymphocytes had infiltrated the area around the necrotic X5563 tumor mass in the mice which had received R-IL2 therapy. These results suggest that repeated injections of R-IL2 at the local site after tumor development can augment antitumor immunological responses and subsequently induce tumor regression.     

Tumor regression after adoptive transfer of effector T cells is independent of perforin or Fas ligand (APO-1L/CD95L).

The adoptive transfer of tumor-specific effector T cells can result in complete regression and cure mice with systemic melanoma, but the mechanisms responsible for regression are not well characterized. Perforin- and Fas ligand (APO-1/CD95 ligand)-mediated cytotoxicity have been proposed as mechanisms for T cell-mediated tumor destruction. To determine the role of perforin and Fas ligand (FasL) in T cell-mediated tumor regression in a murine melanoma model, B16BL6-D5 (D5), we generated D5-specific effector T cells from tumor vaccine-draining lymph nodes of wild type (wt), perforin knock out (PKO), or FasL mutant (gld) mice and treated established D5 metastases in mice with the same genotype. Effector T cells from wt, PKO and gld mice induced complete regression of pulmonary metastases and significantly prolonged survival of the treated animals regardless of their genotype. Complete tumor regression induced by PKO effector T cells was also observed in a sarcoma model (MCA-310). Furthermore, adoptive transfer of PKO and wt effector T cells provided long-term immunity to D5. Therapeutic T cells from wt, PKO, or gld mice exhibit a tumor-specific type 1 cytokine profile; they secrete IFN-gamma, but not IL-4. In these models, T cell-mediated tumor regression and long-term antitumor immunity are perforin and FasL independent.