Immunity to carcinogen-induced transplantable fibrosarcoma in B2B2 chickens: V. Relationship to tumor cell-specific delayed hypersensitivity and serum antibody

Lasting immunity to the chemically induced (DMBA) fibrosarcomas (CHCT-NYU1, 2, and 4) of SC chickens ($\text{B2}\text{B2}$) can be obtained by injection of Corynebacterium parvum (CP)-primed chickens with tumor cells and CP in one wing and tumor cells alone in the other wing. The local delayed hypersensitivity (DH) reaction to CP in the wing inhibits local growth completely, whereas the tumor on the contralateral side shows transient growth. In the present studies, the development of tumor immunity was studied in detail by monitoring DH and antibody formation to the tumor cells and adoptive immunity with spleen cells in Winn tests. Injection of NYU1 cells alone in normal or CP-treated animals induced transient immunity in Winn tests in 50% of the animals, weak DH reactivity, and antibody detectable by immunofluorescence within the first 2 weeks. Chickens receiving both NYU1 cells and CP in one wing and NYU1 cells alone on the other side developed stronger DH reactions to the tumor cells and a higher incidence of immunity in Winn tests which was sustained throughout the period of observation. Antibody levels were similar to those of animals receiving tumor cells alone. In contrast, injection of CP and tumor cells on one side without a tumor challenge on the contralateral side did not induce detectable immunity in CP-primed chickens. Chickens immunized to NYU2 and 4 cells were also tested for DH reactivity and antibody formation. Studies on the cross-reactivity between the tumor lines showed that there was cross-reactivity at the humoral level while at the cellular level this was not apparent. However, animals immune to one tumor line rejected transplants of another tumor line. Observations on the antibody specificity(s) suggested that it was not directed against minor histocompatibility or avian sarcoma viral antigens. SC embryo fibroblasts could induce DH, and serum antibody induced by tumor cells usually reacted also with such embryo cells.     

Immunity to transplantable carcinogen-induced fibrosarcomas in B2/B2 chickens. I. Use of bacterial adjuvants in induction of immunity demonstrable in Winn tests.

Tumor line specific immunity could be induced in chickens with the use of BCG or CP. Direct contact between bacteria and tumor cells was required for immunity induction, but succeeded only in animals which also had been previously injected with the same bacterial vaccine. While other methods such as iv injected live mitomycin treated tumor was capable of inducing immunity, only BCG or CP mediated immunity was capable of being adoptively transferred in the Winn assay. Bursectomized agamma-globulinemic chickens also produced strong transferable immunity. Crossreactivity between transplant lines was detectable upon rechallenge of immune donors but was not evident upon adoptive immunity transfer. Immunity was detectable in the spleen and in peripheral blood lymphocytes but could not be transferred by thymus cells.     

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.     

DNA vaccination against the idiotype of a murine B cell lymphoma: mechanism of tumor protection

Several studies have shown that immunization with DNA, which encodes the idiotypic determinants of a B cell lymphoma, generates tumor-specific immunity. Although induction of antiidiotypic Abs has correlated with tumor protection, the effector mechanisms that contribute to tumor protection have not been clearly identified. This study evaluated the tumor protective effects of humoral and cellular immune mechanisms recruited by idiotype-directed DNA vaccines in the 38C13 murine B cell lymphoma model. Antiidiotypic Abs induced by DNA vaccination supported in vitro complement-mediated cytotoxicity of tumor cells, and simultaneous transfer of tumor cells and hyperimmune sera protected naive animals against tumor growth. However, in vitro stimulation of immune splenocytes with tumor cells failed to induce idiotype-specific cytotoxicity, and following vaccination, depletion of CD4 or CD8 T cell subsets did not compromise protection. Furthermore, protection of naive recipients against tumor challenge could not be demonstrated either by a Winn assay approach or by adoptive transfer of spleen and lymph node cells. Thus, in this experimental model, current evidence suggests that the tumor-protective effects of DNA vaccination can be largely attributed to idiotype-specific humoral immunity.     

Regulation of cell-mediated cytotoxicity. II. Synergism of two types of thymus dependent cells in vivo.

Sublethal (500 rads) doses of radiation given to mice before the intravenous injection of allogeneic spleen cells induced the development of an increased cell-mediated cytotoxicity (CMC) of the recipients' spleen cells. The effector cells from the irradiated animals were shown to carry the θ alloantigenic marker and to be capable of transferring adoptive immunity in vivo. On the other hand, irradiation of mice with the same dose before the administration of skin or tumor allografts induced a suppression of CMC. The response of irradiated mice treated with tumor allografts was restored with small numbers of spleen or lymph node cells from syngeneic or semi-allogeneic F₁ hybrid donors. With the use of the appropriate cytotoxic alloantisera, it was demonstrated that the majority of the effector cells generated in the spleens of mice restored with semiallogeneic cells were of host origin. These results demonstrate that the precursors of the cytotoxic lymphocytes are radioresistant and indicate that for their stimulation some radiosensitive T cells are necessary to amplify their reaction to nonlymphoid allografts. Allogeneic lymphoid cells, on the other hand, supply a stimulus which does not require the intervention of such amplifier cells. In this case, irradiation induces a stronger CMC response probably by inactivating radiosensitive cells with suppressor activity.     

The antimetastatic function of concomitant antitumor immunity. II. Evidence that the generation of Ly-1+2+ effector T cells temporarily causes the destruction of already disseminated tumor cells

Progressive growth of the P815 mastocytoma in an immunocompetent host evokes the generation of an antitumor immune response that can be measured in terms of the production of cytolytic Ly-1+2+ T cells in the draining lymph node and spleen. This immunity, designated concomitant immunity, is present on day 6 of tumor growth, peaks on day 9, and decays progressively thereafter. It fails to develop in mice made T cell deficient by thymectomy and lethal whole-body gamma-radiation, and reconstituted with syngeneic bone marrow cells (TXB mice). Employment of a mouse survival assay, capable of enumerating metastatic P815 cells in cell suspensions, showed that the P815 tumor metastasizes to the draining lymph node and spleen at the same rate in normal and TXB mice for the first 6 days of growth of an intradermal P815 tumor. By day 6 of tumor growth there were approximately 10(3) P815 cells in the draining lymph node in both types of mice. However, during the generation of concomitant immunity between days 6 and 9, the number of metastatic P815 cells in the draining lymph nodes and spleens of normal tumor-bearing mice declined by nearly 90%. After day 12, however, the number of tumor cells in the nodes and spleens increased concordantly with the decay of concomitant immunity. These findings, together with the demonstration that T cell-deficient mice failed to restrain the number of metastatic P815 cells in the draining lymph node and spleen, suggest that concomitant immunity is an important defense mechanism against the development of systemic disease. Additional evidence consistent with this interpretation was provided by studies which showed that adoptive immunization with spleen cells from concomitant immune donors significantly prolonged the median survival time of TXB tumor-bearing mice by destroying a substantial proportion of P815 tumor cells already seeded in the draining lymph node. Adoptive immunization also delayed the appearance of metastatic tumor cells in the spleen.     

Host B7-1 and B7-2 costimulatory molecules contribute to the eradication of B7-1-transfected P815 tumor cells via a CD8+ T cell-dependent mechanism

B7-1 (CD80)-transfected P815 tumor cells were previously shown to elicit tumor-eradicating immunity that leads to the regression of B7-1+ P815 tumors after transient growth in normal syngeneic (DBA/2) mice. Here, we show that not only the B7-1 molecule but also the B7-2 (CD86) molecule contributed to the eradication of B7-1+ P815 tumors. The B7-1 molecule that contributed to the eradication of B7-1+ P815 tumors was expressed not only on the tumor cells but also on host APCs, including MAC-1+ cells. The B7-2 molecule that contributed to the eradication of B7-1+ P815 tumors was expressed only on host APCs, such as B220+ cells, and not on the tumor cells. In spite of the fact that B7-expressing host APCs contributed to the eradication of B7-1+ P815 tumors, only CD8+ T cells without help from CD4+ T cells were important for tumor eradication. Taken together, these findings indicate that in addition to the ability of B7-1-transfected tumor cells to stimulate CD8+ T cell-mediated tumor-eradicating immunity directly, such tumor cells can also stimulate CD8+ T cell-mediated tumor-eradicating immunity indirectly as a result of cross-priming through B7-expressing host APCs.     

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.     

Immunity to Plasmodium yoelii: kinetics of the generation of T and B lymphocytes that passively transfer protective immunity against virulent challenge

Adoptive immunization of A/Tru mice with splenic B cells or T cells from syngeneic donors with a primary, nonvirulent, Plasmodium yoelii (17X) infection confers on these recipients the capacity to resist a challenge infection with a virulent strain (YM) of P. yoelii. Unfractionated spleen cells as well as spleen cells enriched for T or B cells capable of transferring protective immunity were detected as early as Day 7 of the primary nonvirulent infection, and reached peak levels on Day 14. Spleen cells that were harvested from donor animals after resolution of the immunizing infection [on Days 21 or 28] were incapable of transferring protective immunity. The capacity of 7-day immune spleen cells to transfer immunity could be abolished by pretreatment with mitomycin C. In addition, it was found that immunocompetent recipient mice were required for successful adoptive immunization, since thymectomized, irradiated, bone marrow reconstituted mice infused with immune spleen cells failed to survive lethal challenge infections.     

Suppressor T cells with histamine type II receptors in chickens bearing chemically induced fibrosarcomas

Immunity to a local (wing web) challenge with transplantable, chemically induced tumors, such as CHCT-NYU-4, can be transferred to histocompatible SC chickens with intravenously injected splenic T cells from tumor-immune chickens. Simultaneous iv injection of splenic T cells from chickens bearing progressively growing CHCT-NYU-4 prevents the expression of this adoptive systemic tumor immunity. The splenic suppressor T cells are B-L(Ia) positive and adhere to dishes coated with cimetidine-protein conjugate, suggesting that they bear type II histamine receptors (H2R). Intravenous injection of gamma-irradiated CHCT-NYU-4 cells 7 days prior to a local challenge with the same tumor promotes growth of a normally suboptimal tumor cell dose such that the incidence of progressive tumor growth is significantly increased. Concomitant treatment with the H2R antagonist, ranitidine, inhibits tumor growth of an optimal tumor dose challenge and promotes induction of tumor immunity. However, this drug cannot reverse the effect of iv injected tumor cells. Another drug with reported antisuppressor cell activity, cyclophosphamide (50 mg/kg), injected 1 day prior to challenge causes a transient inhibition of tumor growth. Injection of this drug on Day 7 does not have a significant effect by itself but, in combination with the Day-1 pretreatment, a significant inhibition of tumor growth by size and tumor incidence measurements is obtained. These results indicate that manipulation of immunity to transplantable fibrosarcomas in the chicken is possible with drugs acting on suppressor cells.     

Bradykinin B2 Receptors of dendritic cells, acting as sensors of kinins proteolytically released by Trypanosoma cruzi, are critical for the development of protective type-1 responses

Although the concept that dendritic cells (DCs) recognize pathogens through the engagement of Toll-like receptors is widely accepted, we recently suggested that immature DCs might sense kinin-releasing strains of Trypanosoma cruzi through the triggering of G-protein-coupled bradykinin B2 receptors (B2R). Here we report that C57BL/6.B2R-/- mice infected intraperitoneally with T. cruzi display higher parasitemia and mortality rates as compared to B2R+/+ mice. qRT-PCR revealed a 5-fold increase in T. cruzi DNA (14 d post-infection [p.i.]) in B2R-/- heart, while spleen parasitism was negligible in both mice strains. Analysis of recall responses (14 d p.i.) showed high and comparable frequencies of IFN-gamma-producing CD4+ and CD8+ T cells in the spleen of B2R-/- and wild-type mice. However, production of IFN-gamma by effector T cells isolated from B2R-/- heart was significantly reduced as compared with wild-type mice. As the infection continued, wild-type mice presented IFN-gamma-producing (CD4+CD44+ and CD8+CD44+) T cells both in the spleen and heart while B2R-/- mice showed negligible frequencies of such activated T cells. Furthermore, the collapse of type-1 immune responses in B2R-/- mice was linked to upregulated secretion of IL-17 and TNF-alpha by antigen-responsive CD4+ T cells. In vitro analysis of tissue culture trypomastigote interaction with splenic CD11c+ DCs indicated that DC maturation (IL-12, CD40, and CD86) is controlled by the kinin/B2R pathway. Further, systemic injection of trypomastigotes induced IL-12 production by CD11c+ DCs isolated from B2R+/+ spleen, but not by DCs from B2R-/- mice. Notably, adoptive transfer of B2R+/+ CD11c+ DCs (intravenously) into B2R-/- mice rendered them resistant to acute challenge, rescued development of type-1 immunity, and repressed TH17 responses. Collectively, our results demonstrate that activation of B2R, a DC sensor of endogenous maturation signals, is critically required for development of acquired resistance to T. cruzi infection.     

Passive transfer of tumor immunity with spleen cells from guinea pigs cured of hepatocarcinoma by nonspecific immunotherapy

Summary The purpose of this study was to evaluate cell-mediated tumor immunity in strain-2 guinea pigs cured of line-10 hepatocarcinoma by oil-in-water emulsions containing phenol-water extracts from either BCG or the Re mutant of Salmonella typhimurium (Re ET) admixed with mycobacteria glycolipid (P3). Treatment with these emulsions produced complete regression of established tumor nodules and prevented the growth of lymph node metastases in 25 of the 28 animals inoculated intradermally (ID) with 10⁶ line-10 cells and given intralesional immunotherapy 6 days later. No tumor regression was observed in animals given phenol-water extracts alone. Spleen cells, taken from guinea pigs cured of line-10 by BCG extract + P3 or Re ET + P3, were tested for their influence on tumor growth by means of an in vivo adoptive neutralization test (Winn test). Cell transfer was accomplished by the subcutanous injection of various concentrations of spleen cells admixed with 10⁵ viable line-10 cells. The results showed that as few as 10⁷ immune spleen cells completely inhibited the growth of 10⁵ tumor cells in 46–54% of the animals. The best tumor growth inhibition (77–85%) was observed in animals given 5 × 10⁷ immune cells admixed with 10⁵ tumor cells. The onset of transferrable tumor immunity was earlier in animals treated with the BCG extract + P3 than in those given the Re ET + P3. However, the duration of detectable tumor immunity was longer in the latter group. In contrast, no inhibition of tumor growth was observed in animals given spleen cells from normal or tumor-bearing guinea pigs. Moreover, spleen cells obtained from guinea pigs immunized with BCG extract + P3 or Re ET + P3 emulsions only and admixed with line-10 cells failed to transfer tumor immunity to normal animals. Thus, results from this study clearly demonstrated that cell-mediated tumor immunity was elicited in animals cured of line-10 tumor with combinations of P3 and phenol-water extracts of either BCG or Re mutant of S. typhimurium and that sensitized spleen cells effectively transferred systemic tumor immunity to normal recipients.     

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.     

Induction of antigen-specific tumor immunity by genetic and cellular vaccines against MAGE: enhanced tumor protection by coexpression of granulocyte-macrophage colony-stimulating factor and B7-1.

BACKGROUND: A number of tumors express antigens that are recognized by specific cytotoxic T cells. The normal host immune responses, however, are not usually sufficient to cause tumor rejection. Using appropriate immunization strategies, tumor-specific antigens may serve as targets against which tumor-destructive immune responses can be generated. MAGE-1 and MAGE-3 are two clinically relevant antigens expressed in many human melanomas and other tumors, but not in normal tissues, except testis. Here, we have investigated whether DNA and cellular vaccines against MAGE-1 and MAGE-3 can induce antigen-specific anti-tumor immunity and cause rejection of MAGE-expressing tumors. MATERIALS AND METHODS: Mice were immunized against MAGE-1 and MAGE-3 by subcutaneous injection of genetically modified embryonic fibroblasts or intramuscular injection of purified DNA. Mice were injected with lethal doses of B16 melanoma cells expressing the corresponding MAGE antigens or the unrelated protein SIV tat, and tumor development and survival were monitored. RESULTS: Intramuscular expression of MAGE-1 and MAGE-3 by plasmid DNA injection and subcutaneous immunization with syngeneic mouse embryonic fibroblasts transduced with recombinant retroviruses to express these antigens induced specific immunity against tumors expressing MAGE-1 and MAGE-3. Both CD4+ and CD8+ T cells were required for anti-tumor immunity. Coexpression of granulocyte-macrophage colony-stimulating factor (GM-CSF) or B7-1 significantly increased anti-tumor immunity in an antigen-specific manner and resulted in a considerable proportion of mice surviving lethal tumor challenge. CONCLUSIONS: Our results suggest that genetic and cellular vaccines against MAGE and other tumor antigens may be useful for the therapy of tumors expressing specific markers, and that GM-CSF and B7-1 are potent stimulators for the induction of antigen-specific tumor immunity.     

Treatment of disseminated leukemia with cyclophosphamide and immune cells: tumor immunity reflects long-term persistence of tumor-specific donor T cells

B6 mice bearing disseminated syngeneic FBL leukemia can be cured by treatment on day 5 with 180 mg/kg cyclophosphamide and 2 x 10(7) adoptively transferred syngeneic immune spleen cells. Complete tumor eradication in this model requires more than 30 days and is dependent upon the transfer of specifically immune T cells. To evaluate the relative contributions of host and donor T cells to tumor elimination and the maintenance of tumor immunity, donor cells obtained from Thy congenic mice were used for adoptive transfer. Thus, host and donor T cells could be readily distinguished by the expression of either Thy-1.2 or Thy-1.1 antigen. The results demonstrated that the majority of immunologically competent T cells present in hosts cured by adoptive therapy were of host origin. A small population of donor T cells, however, persisted long after transfer. At day 60, a time point shortly after tumor eradication had been completed, 5% of splenic T cells were of donor origin, and by day 120 this percentage had decreased to less than 2%. Functional studies performed at both time points revealed that this small number of residual donor T cells contained the subpopulation of tumor-reactive T cells present in the host. Thus, host T cells did not make a substantial contribution to the expression of the anti-tumor response and presumably have little role in either tumor eradication or the long-term maintenance of tumor immunity.     

Tumor-specific immunity induced by somatic hybrids: III. Persistence of adoptively transferred immunity specific for TEPC-15 plasmacytoma in normal BALB/c mice

Immunity against TEPC-15 tumor cells was induced in BALB/c mice by injecting semi-allogeneic hybrid cells derived from fusion of TEPC-15 tumor cells with LM(TK^?) cells of the C3H origin. Adoptive transfer of spleen cells from the immune mice into normal BALB/ c recipients rendered them free from tumors following tumor challenge; the recipients were most significantly protected from the tumor when tumor cells were injected 7–14 days after the adoptive transfer of immune cells. Such immunity following adoptive transfer appeared to persist in the recipients for at least 60 days. Moreover, the tumor-specific immunity was consecutively transferable (more than nine passages) into normal BALB/c recipients by serially passing spleen cells from the recipients every 14 days, without further stimulation with the hybrid cells or inactivated TEPC-15 tumor cells. Such consecutive transfer of the immune spleen cells induced splenomegaly in the recipients: a two- to five-fold increase over normal spleen cell recipients. The ability of spleen cells to transfer immunity, but not splenomegaly, was abrogated by treatment with mitomycin C. These results suggest that proliferation of donor cells is necessary to transfer immunity, and that splenomegaly alone does not manifest such immunity in the recipients.     

Cross-reactive cellular and humoral immunity to carcinogen-induced chicken fibrosarcomas. I. Protective cross-immunity between transplantable tumor lines

Dimethylbenz[a]anthracene (DMBA)-induced transplantable fibrosarcomas in B2 homozygous chickens (SC line) grow progressively in normal chickens, but are rejected by chickens immunized previously with irradiated tumor cells and Corynebacterium parvum. Tumor-immune chickens resist challenge by the immunizing tumor lines as well as by some, but not all, fibrosarcoma lines. The pattern of cross-reactivity between four DMBA-induced transplantable tumor lines was examined in detail. Ability to reject a tumor challenge correlated very well (p less than 0.001) with the presence of delayed-type hypersensitivity (DTH) to that tumor. Immunization with one of two of the DMBA-induced lines tested also caused rejection of transplantable tumors developed from methylcholanthrene-induced and benzo(a)pyrene-induced primary fibrosarcomas. Although immunization with tumor caused DTH to chicken embryo fibroblasts (CEF), immunization with CEF failed to cause protective immunity or DTH to tumors. Presence of protective immunity, where tested, also correlated with the ability of spleen cells from immune donors to inhibit tumor growth in Winn tests. Humoral immunity exhibited even greater cross-reactivity than did cellular immunity. Distinct patterns of cross-reactivity were nevertheless observed with respect to the serum antibodies as detected in ELISA. Two of these patterns were also observed in several sera from primary tumor-bearing chickens, both including reactivity with CEF. Such reactivity was absent from normal chicken sera.     

Ongoing murine T1 or T2 immune responses to the hepatitis B surface antigen are excluded from the liver that expresses transgene-encoded hepatitis B surface antigen

Different protein- or DNA-based vaccination techniques are available that prime potent humoral and cellular, T1 or T2 immune responses to the hepatitis B surface Ag (HBsAg) in mice. T1 and T2 are immune responses with isotype profile indicating Th1 and Th2 immunoregulation. We tested whether HBsAg-specific immune responses can be established in transgenic mice that express HBsAg in the liver (HBs-tg mice) using either these different vaccination techniques or an adoptive transfer system. HBsAg-specific responses could not be primed in HBs-tg mice with the established, potent vaccine delivery techniques. In contrast, adoptive transfers of T1- and T2-type HBsAg-immune spleen cells into congenic HBs-tg hosts (that were not conditioned by pretreatment) suppressed HBsAg antigenemia and gave rise to HBsAg-specific serum Ab titers. The establishment of continuously rising anti-HBsAg serum Ab levels with alternative isotype profiles (reflecting T1 or T2 polarization) in transplanted HBs-tg hosts required donor CD4+ T cell-dependent restimulation of adoptively transferred immune cells by transgene-derived HBsAg. Injections of HBsAg-specific Abs into HBs-tg mice did not establish stable humoral immunity. The expanding T1 or T2 immune responses to HBsAg in HBs-tg hosts did not suppress transgene-directed HBsAg expression in the liver and did not induce liver injury. In addition to priming functional antiviral effector cells, the conditioning of the liver microenvironment to enable delivery of antiviral effector functions to this organ are therefore critical for effective antiviral defense. A major challenge in the development of a therapeutic vaccine against chronic hepatitis B or C virus infection is thus the efficient targeting of specifically induced immune effector specificities to the liver.     

Tumor-specific Tc1, but not Tc2, cells deliver protective antitumor immunity.

We investigated whether secretion of multiple cytokines by CD8+ T cells is associated with improved protection against tumor challenge. We show that antitumor immunity induced by immunization with dendritic cells and a MHC class I-binding tumor peptide are dependent on secretion of IFN-gamma but not IL-4 or IL-5 by host cells. To further address the role of IL-4 and IL-5 in antitumor immunity, tumor-specific TCR-transgenic CD8+ T cells were activated in vitro to generate cytotoxic T (Tc) 1 cells that secrete high IFN-gamma and no IL-4 or IL-5 or Tc2 cells that secrete IL-4, IL-5, and some IFN-gamma. Both cell types killed target cells in vitro. Tc1 and Tc2 cells were adoptively transferred into syngeneic hosts, and their ability to protect against tumor challenge was compared. Tc1 cells were able to significantly delay tumor growth, whereas Tc2 cells or Tc2 cells from IFN-gamma(-/-) donors had no effect. This was due to neither the inability of Tc2 cells to survive in vivo or to migrate to the tumor site nor their inability to secrete IL-4 and/or IL-5 in the presence of limiting amounts of anti-CD3. However, IFN-gamma secretion by Tc2 cells was triggered inefficiently by restimulation with Ag compared with anti-CD3. We conclude that the ability to secrete "type 2" cytokines, and cytotoxic ability, have a limited role in antitumor immune responses mediated by CD8+ T cells, whereas the capacity to secrete high amounts of IFN-gamma remains the most critical antitumor effector mechanism in vivo.     

Infectious nickel tolerance: a reciprocal interplay of tolerogenic APCs and T suppressor cells that is driven by immunization

Previously, we reported that tolerance to nickel, induced by oral administration of Ni(2+) ions, can be adoptively transferred to naive mice with only 10(2) splenic T cells. Here we show that 10(2) T cell-depleted spleen cells (i.e., APCs) from orally tolerized donors can also transfer nickel tolerance. This cannot be explained by simple passive transfer of the tolerogen. The APCs from orally tolerized donors displayed a reduced allostimulatory capacity, a tolerogenic phenotype, and an increased expression of CD38 on B cells. In fact, it was B cells among the APCs that carried the thrust of tolerogenicity. Through serial adoptive transfers with Ly5.1(+) donors and two successive sets of Ly5.2(+) recipients, we demonstrated that nickel tolerance was infectiously spread from donor to host cells. After the transfer of either T cells or APCs from orally tolerized donors, the spread of tolerance to the opposite cell type of the recipients (i.e., APCs and T cells, respectively) required recipient immunization with NiCl(2)/H(2)O(2). For the spread of tolerance from a given donor cell type, T cell or APC, to the homologous host cell type, the respective opposite cell type in the host was required as intermediate. We conclude that T suppressor cells and tolerogenic APCs induced by oral administration of nickel are part of a positive feedback loop that can enhance and maintain tolerance when activated by Ag associated with a danger signal. Under these conditions, APCs and T suppressor effector cells infectiously spread the tolerance to naive T cells and APCs, respectively.