CD8 T cell help for innate antitumor immunity

Innate immunity is considered to initiate adaptive antitumor responses. We demonstrate that monoclonal CD8 T lymphocytes reactive to tumor Ag P1A on P815 mastocytoma cells provide essential "help" to NK cells for rejection of P1A-deficient tumors. RAG-deficient mice have normal NK cells but do not reject either tumor. Reconstitution of these mice with P1A-specific T cells conferred resistance to both P1A-expressing and -deficient tumor cells provided they were present at the same site. Elimination of Ag-negative tumor variants required both activated T and NK cells. Gene expression profiling of NK cells infiltrating P1A-positive tumors in mice with specific CD8 T cells demonstrated an activated effector phenotype. However, CD8 T cell help to NK cells appeared ineffective for P1A-negative variants separated from the P1A-positive tumor. Local tumor Ag-specific T cell-NK cell collaboration results in the elimination of tumor cells whether they express or not the T cell tumor Ag epitope, thus containing the emergence of tumor escape variants before metastasis.     

Failure of infiltrating precursor cytotoxic T cells to acquire direct cytotoxic function in immunologically privileged sites

Minor H incompatible P815 tumor cells inoculated into the anterior chamber (AC) of the eyes of BALB/c mice grow progressively, revealing this to be an immunologically privileged site. By contrast, a similar inoculation of tumor cells is rapidly rejected from nonprivileged ocular sites (subconjunctiva). Mice with progressively growing AC-tumors and those that reject their ocular subconjunctiva tumors both have expanded clones of tumor-specific cytotoxic precursor cells (pTc) in their spleens and cervical lymph nodes. In an effort to determine why the expanded pool of primed pTc is unable to effect rejection of AC intraocular tumors, we have examined the susceptibility of the tumor cells growing within the immunologically privileged AC to lysis by cytotoxic T cells and the cytotoxic function of tumor-infiltrating lymphocytes. P815 tumor cells extracted from intraocular tumors and P815 cells maintained in routine tissue culture are equally susceptible to lysis when exposed in vitro to fully differentiated, DBA/2-specific cytotoxic T cells. Thus, progressively growing tumor cells within the AC are not insensitive to immune-mediated lysis by cytotoxic T cells. We have been able to harvest significant numbers of DBA/2-specific pTc from these same intraocular tumors. When the tumor-infiltrating lymphocytes are driven in vitro with exogenous IL-2, they acquire the capacity to lyse specifically P815 tumor cells. However, no evidence of fully cytotoxic, tumor-specific T cells was found among lymphocytes harvested from intraocular tumors, i.e., when the harvested cells were tested immediately for cytolytic activity. Inasmuch as we have reported that directly cytotoxic T cells are present during tumor rejection at nonimmunologically privileged ocular sites, such as the subconjunctival space, we conclude that progressive growth of P815 tumor cells within the anterior chamber is due in part to a failure of infiltrating pTc to differentiate in situ into fully functional cytotoxic effector cells.     

Intracamerally induced concomitant immunity: mice harboring progressively growing intraocular tumors are immune to spontaneous metastases and secondary tumor challenge

Intracameral inoculation of allogeneic P815 mastocytoma cells (DBA/2) into BALB/c mice resulted in progressively growing intraocular tumors. Intraocular tumor cells disseminated rapidly to the spleen and cervical lymph nodes, yet extraocular nests of tumor cells never developed into fulminant tumors. Further experiments showed that tumor cells were continuously seeded from the primary intraocular tumor and were rapidly cleared from extraocular sites. Hosts harboring intraocular P815 mastocytomas rejected tumorigenic doses of P815 cells inoculated subcutaneously or even into the contralateral anterior chamber. This systemic tumor immunity was found to be radiosensitive and T cell dependent. Spleen cells from animals with progressively growing intraocular tumors protected recipient mice challenged with intracamerally inoculated tumor cells and thus suggests that a cell-mediated mechanism is the underlying basis for this form of tumor immunity. The data indicate that mice harboring progressively growing intraocular tumors develop a potent state of "concomitant immunity," that prevents the development of metastases, yet is ineffective in controlling the primary tumor.     

Failure of specific adoptive immunotherapy owing to survival and outgrowth of variant cells

Summary Adoptive immunotherapy, the transfer of spleen cells from immunized mice to mice with a small tumor, was usually curative for mice with the P815 mastocytoma provided that steps were taken to prevent the generation of tumor-induced suppressor cells in the recipient animal. However, failure of adoptive immunotherapy of the P815 tumor, resulting in regrowth of either the primary intradermal or a metastatic tumor, was observed in 10 out of 112 animals receiving graded doses of 7.5×10⁷ to 3.0×10⁸ immune spleen cells. Examination of the ten tumors in mice that failed to respond to therapy revealed that seven of them were significantly less susceptible than the original P815 tumor to rejection in vivo by transferred anti-P815-specific effector cells. In addition, nine of the ten therapy-failure tumors were also less susceptible than the original P815 tumor to lysis in vitro by P815-specific, but not DBA/2-specific, cytotoxic T lymphocytes. Sensitivity to lysis by tumor-specific cytotoxic T cells was not, however, strongly correlated with sensitivity to rejection in vivo by P815-specific effector spleen cells. Neither in vivo sensitivity to rejection, nor sensitivity to cytotoxic T cells, was correlated with alterations in class I major histocompatibility complex antigen expression. These results suggest that the survival and outgrowth of variant tumor cells was frequently the cause of failure of specific adoptive immunotherapy of the P815 tumor, and that selection for cells with a reduced sensitivity to killing by cytotoxic T cells was only one mechanism that might lead to an immunotherapeutic failure.This work was supported by a grant from RJR Nabisco Inc., a grant from the J. M. Foundation, and by USPHS grant CA-40597 awarded by the National Cancer Institute     

Adoptive T cell immunotherapy of human uveal melanoma targeting gp100

HLA-A*0201-restricted CTL against human gp100 were isolated from HLA-A*0201/K(b) (A2/K(b))-transgenic mice immunized with recombinant canarypox virus (ALVAC-gp100). These CTL strongly responded to the gp100(154-162) epitope, in the context of both the chimeric A2/K(b) and the wild-type HLA-A*0201- molecule, and efficiently lysed human HLA-A*0201(+), gp100(+) melanoma cells in vitro. The capacity of the CTL to eradicate these tumors in vivo was analyzed in A2/K(b)-transgenic transgenic mice that had received a tumorigenic dose of human uveal melanoma cells in the anterior chamber of the eye. This immune-privileged site offered the unique opportunity to graft xenogeneic tumors into immunocompetent A2/K(b)-transgenic mice, a host in which they otherwise would not grow. Importantly, systemic (i.v.) administration of the A2/K(b)-transgenic gp100(154-162)-specific CTL resulted in rapid elimination of the intraocular uveal melanomas, indicating that anti-tumor CTL are capable of homing to the eye and exerting their tumoricidal effector function. Flow cytometry analysis of ocular cell suspensions with HLA-A*0201-gp100(154-162) tetrameric complexes confirmed the homing of adoptively transferred CTL. Therefore, the immune-privileged state of the eye permitted the outgrowth of xenogeneic uveal melanoma cells, but did not protect these tumors against adoptive immunotherapy with highly potent anti-tumor CTL. These data constitute the first direct indication that immunotherapy of human uveal melanoma may be feasible.     

Rejection of intraocular tumors by CD4(+) T cells without induction of phthisis.

Immune privilege of the eye protects against sight-threatening inflammatory events, but can also permit outgrowth of otherwise nonlethal immunogenic tumors. Nonetheless, ocular tumor growth can be controlled by cellular immune responses. However, this will normally result in phthisis of the eye, in case tumor rejection is mediated by a delayed-type hypersensitivity response orchestrated by CD4(+) T cells. We now show that intraocular tumors can be eradicated by CD4(+) Th cells without inducing collateral damage of neighboring ocular tissue. Injection of tumor cells transformed by the early region 1 of human adenovirus type 5 in the anterior chamber of the eye leads to intraocular tumor formation. Tumor growth is transient in immunocompetent mice, but lethal in immunodeficient nude mice, indicating that T cell-dependent immunity is responsible for tumor clearance. Tumor rejection has all the characteristics of a CD8(+) T cell-mediated immune response, as the tumor did not express MHC class II and only tumor tissue was the subject of destruction. However, analysis of the molecular and cellular mechanisms involved in tumor clearance revealed that perforin, TNF-alpha, Fas ligand, MHC class I, and CD8(+) T cells did not play a crucial role in tumor eradication. Instead, effective tumor rejection was entirely dependent on CD4(+) Th cells, as CD4-depleted as well as MHC class II-deficient mice were unable to reject their intraocular tumor. Taken together, these observations demonstrate that CD4(+) T cells are able to eradicate MHC class II-negative tumors in an immune-privileged site without affecting surrounding tissues or the induction of phthisis.     

Targeting an anti-viral CD8+ T cell response to a growing tumor facilitates its rejection

 We demonstrate in a murine model that targeting an anti-viral T cell response to a growing tumor facilitates priming of a tumor-associated antigen (TAA)-specific, rejecting T cell response. Murine P815 mastocytoma cells grow aggressively in a syngeneic host. Transfected P815/S cells (expressing the hepatitis B surface antigen, HBsAg) also grow as subcutaneous tumors, but occasional ‘spontaneous’ rejections after transient growth are observed. Growth of P815/S tumors (but not of P815 tumors) is efficiently suppressed by a CD8⁺ cytotoxic T lymphocyte (CTL)-dependent immune mechanism in mice primed to HBsAg by DNA–immunization. In hosts immunized against HBsAg by DNA vaccination, HBsAg-specific CTL are generated. This specific CTL reactivity was targeted to s.c.-growing P815 tumors by intra tumor injections of either HBsAg-encoding plasmid DNA or viable P815/S cells; this treatment led to tumor rejection in 70–80% of the tumor-bearing animals. All rejecting animals showed a CD8⁺ CTL-dependent resistance to subsequent challenges by native, non-transfected P815 tumors. Targeting an established anti-viral (‘strong’) CTL response to a growing tumor hence is an efficient strategy to facilitate priming of a rejecting CTL response against (‘weak’) TAA in this system. Received: 18 December 1996 / Accepted: 6 February 1997     

TNF-mediated toxicity after massive induction of specific CD8+ T cells following immunization of mice with a tumor-specific peptide

We immunized mice with antigenic peptide P815E, which is presented by H-2K(d) and recognized by tumor-specific CTL raised against P815 tumor cells. This peptide is encoded by the ubiquitously expressed gene MsrA and carries a mutated residue conferring tumor specificity. Unexpectedly, we observed a severe toxicity occurring in the early hours after the third injection, resulting in the death of most mice within 24 h. The toxic syndrome was reminiscent of TNF-induced shock, and the sera of ill mice contained high levels of TNF. Toxicity was prevented by injection of neutralizing anti-TNF Abs, confirming the involvement of TNF. Depletion of CD8+ T cells could also prevent toxicity, and ex vivo experiments confirmed that CD8+ lymphocytes were the major cellular source of TNF in immunized mice. Tetramer analysis of the lymphocytes of immunized mice indicated a massive expansion of P815E-specific T cells, up to >60% of circulating CD8+ lymphocytes. A similar toxicity was observed after massive expansion of specific CD8+ T cells following immunization with another P815 peptide, which is encoded by gene P1A and was injected in a form covalently linked to an immunostimulatory peptide derived from IL-1. We conclude that the toxicity is caused by specific CD8+ lymphocytes, which are extensively amplified by peptide immunization in a QS21-based adjuvant and produce toxic levels of TNF upon further stimulation with the peptide. Our results suggest that immunotherapy trials involving new peptides should be pursued with caution and should include a careful monitoring of the T cell response.     

Induction by DNA immunization of a protective antitumor cytotoxic T lymphocyte response against a minimal-epitope-expressing tumor

 In order to examine the use of DNA immunization to block tumor growth, we have developed a model system in which a defined 9-amino-acid epitope from the nucleoprotein of influenza virus is used as a surrogate tumor-associated antigen. A mastocytoma cell line of DBA/2 origin (P815) was transfected with a plasmid encoding the minimal H-2K^d-restricted NP(147–155) cytotoxic T lymphocyte (CTL) epitope, pCMV/NPep, to generate the cell line designated P815-NPep. Mice primed and boosted once with a plasmid encoding the full-length NP gene, pCMV/NP, but not with the minigene pCMV/NPep, developed a strong NP(147–155)-specific CTL response within 2 weeks after the boost. When challenged with 10⁴ P815-NPep cells, pCMV/NP-immunized DBA/2 mice were protected from tumor challenge, whereas control mice immunized with the vector backbone rapidly developed lethal tumor. Importantly, the P815-NPep-immune mice were also protected from a subsequent challenge with the untransfected parental tumor P815. By depleting the NP-immune mice of either CD4⁺ or CD8⁺ T cells and then challenging with 10⁴ P815-NPep tumor cells, it was determined that the CD8-depleted mice rapidly developed tumors, whereas the CD4-depleted or non-treated mice were protected. These data clearly indicate that intramuscular (i.m.) plasmid DNA immunization can be used to mobilize an effective CD8⁺ CTL-mediated antitumor response. Received: 8 May 1997 / Accepted: 28 August 1997     

Characterization of the suppressor cell(s) responsible for anterior chamber-associated immune deviation (ACAID) induced in BALB/c mice by P815 cells

Anterior chamber-associated immune deviation (ACAID) is a complex set of immune responses induced by the inoculation of antigens into the anterior chamber of the eye. Histocompatibility antigens, tumor-specific antigens, reactive haptens, and viral antigens have been shown to induce this phenomenon, which comprises the following specific host responses: high titer humoral antibodies, primed cytotoxic T cells, but specifically, impaired skin graft rejection and delayed-type hypersensitivity (DTH). Using the model system of ACAID induced by inoculation of P815 mastocytoma cells into the anterior chambers of H-2-compatible, but minor H-incompatible, BALB/c mice, we demonstrate that the impaired capacity of these animals to develop and express DTH is due to the activation of suppressor T cells. Generation of these cells requires an intact spleen, is not inhibited by cyclophosphamide pretreatment, and is abrogated by systemic treatment of the host with anti-I-J monoclonal antibodies. This splenic suppressor cell(s) can transfer suppression of DTH adoptively to naive syngeneic mice. One suppressor cell is Thy-1.2, Lyt-2.2, and I-Jd positive. A minority of these cells (or a second population of suppressor cells) also expresses the L3T4 surface marker. Suppression is exerted on the efferent limb of DTH expression, although afferent suppression is not excluded. P815-induced ACAID suppressor cells resemble similar cells induced by haptenated spleen cells inoculated into the anterior chamber of the eye. We propose that induction of these suppressor cells, whose target of action is selective for T DTH cells, but not for other types of T cells, is responsible for the phenomenon of immune privilege in the anterior chamber of the eye.     

IL-17-dependent, IFN-gamma-independent tumor rejection is mediated by cytotoxic T lymphocytes and occurs at extraocular sites, but is excluded from the eye

Although intraocular tumors reside in an immune-privileged site where immune responses are suppressed, some tumors are rejected. An example of this is the rejection of intraocular adenovirus-induced (adenovirus type 5 early region 1 [Ad5E1]) tumors in C57BL/6 mice. We previously identified an Ad5E1 tumor clone in which the rejection is IFN-γ dependent and culminates in the destruction of both the tumor and the eye. Although Ad5E1 tumors are not rejected when transplanted into the eyes of IFN-γ KO mice, they are rejected after s.c. transplantation. Thus, outside of the eye Ad5E1 tumors elicit a form of tumor immunity that is IFN-γ independent. In this article, we demonstrate that IFN-γ-independent s.c. rejection requires both CD4(+) and CD8(+) T cells. Furthermore, s.c. tumor rejection requires IL-17, which is produced by IFN-γ-deficient CD4(+) T cells in response to tumor Ags (TAs). Splenocytes from CD4-depleted IFN-γ KO mice produce significantly less IL-17 compared with splenocytes from isotype-treated IFN-γ KO animals in response to TAs. Furthermore, depletion of IL-17 decreases CTL activity against Ad5E1 tumor cells. In this model we propose that, in the absence of IFN-γ, CD4(+) T cells produce IL-17 in response to TAs, which increases CTL activity that mediates tumor rejection; however, this does not occur in the eye. IL-6 production within the eye is severely reduced, which is consistent with the failure to induce Th17 cells within the intraocular tumors. In contrast, the s.c. environment is replete with IL-6 and supports the induction of Th17 cells. Therefore, IFN-γ-independent tumor rejection is excluded from the eye and may represent a newly recognized form of ocular immune privilege.     

Suppressor deletion therapy: selective elimination of T suppressor cells in vivo using a hematoporphyrin conjugated monoclonal antibody permits animals to reject syngeneic tumor cells

Summary A MAb (B16G) which recognizes a constant epitope on TsC and their soluble factors in DBA/2 mice has been described previously. In this study, we show that when this MAb is covalently linked to the photoactivable molecule Hp, and injected i.v. into P815 tumor-bearing mice which were subsequently exposed to light, tumors undergo permanent regression in 10%–40% of these mice (depending on the individual experiment). All control animals died within an average of 22–24 days after tumor cell injection. It is suggested that tumor regression is attributable to immune mechanisms facilitated by the elimination of a population of TsC. When splenocytes of B16G-Hptreated mice were assayed in vitro for the generation of CTL active against P815 tumor cells, it was found that 24 h after treatment, a significant increase in killer cell activity was noted but that this effect was gone by 48h. We also show that B16G-Hp conjugates are capable in vitro of specifically killing cells of a TsC hybridoma, A10 (which has been shown previously to secrete a T suppressor factor reactive with P815 cell surface antigens). This conjugate had no cytotoxic effect on P815 cells under conditions in which A10 cells were killed.Abbreviations CTL cytotoxic T lymphocytes - C-MAb control monoclonal antibody - EDCI 1-ethyl-3-(3-diemthylaminopropyl) carbodiimide - Hp hematoporphyrin - MAb monoclonal antibody - PBS phosphate-buffered saline - RMIg rabbit antimouse Ig - TsC T suppressor cell - TsF T suppressor factor - FCS fetal calf serum - DME Dulbecco's modified Eagle's medium     

B7-H3 enhances tumor immunity in vivo by costimulating rapid clonal expansion of antigen-specific CD8+ cytolytic T cells

B7-H3 is a B7 family molecule with T cell costimulatory function in vitro. The in vivo role of B7-H3 in the stimulation of tumor immunity is unclear. We report here that expression of B7-H3 by transfection of the mouse P815 tumor line enhances its immunogenicity, leading to the regression of tumors and amplification of a tumor-specific CD8+ CTL response in syngeneic mice. Tumor cells engineered to express B7-H3 elicit a rapid clonal expansion of P1A tumor Ag-specific CD8+ CTL in lymphoid organs in vivo and acquire the ability to directly stimulate T cell growth, division, and development of cytolytic activity in vitro. Our results thus establish a role for B7-H3 in the costimulation of T cell immune responses in vivo.     

Tumor cell surface expression of granulocyte-macrophage colony-stimulating factor elicits antitumor immunity and protects from tumor challenge in the P815 mouse mastocytoma tumor model.

A novel membrane-bound form of GM-CSF (mbGM-CSF) was expressed on the surface of the mouse mastocytoma cell line P815 to target tumor cell-associated Ags to epidermal Langerhans cells. Transfected clones stimulated the proliferation of syngeneic bone marrow cells, indicating that mbGM-CSF is biologically active. We evaluated the in vivo effects of mbGM-CSF by comparing the growth of mbGM-CSF cells (termed 1D6.1E5) to that of wild-type P815 cells in DBA/2 mice. The growth rates of tumors initiated by P815 and 1D6.1E5 were similar until day 12, after which P815 tumors grew to large sizes while 1D6. 1E5 tumors were rejected. In contrast, the growth of both tumors was unimpeded when injected into nude mice, suggesting that a T cell-dependent antitumor response was induced by 1D6.1E5 in normal mice. Lymphocytes from 1D6.1E5-vaccinated mice were able to kill 51Cr-labeled P815 cells in a dose-dependent fashion that was inhibited by anti-CD8 Abs, suggesting that the antitumor response involved CD8+ CTL. We then tested whether vaccination with these cells would elicit a protective antitumor response by injecting mice with either irradiated 1D6.1E5 or P815 cells and challenging them with nonirradiated P815 cells. 1D6.1E5-treated mice grew small tumors that soon disappeared in all animals. In contrast, the majority of animals receiving the irradiated wild-type tumor vaccine grew large tumors, and 50% died. These data demonstrate that mbGM-CSF expressed on the surface of tumor cells is biologically active and elicits protective antitumor immunity.     

Accumulation of immunosuppressive CD11b+ myeloid cells correlates with the failure to prevent tumor growth in the anterior chamber of the eye

The purpose of these studies is to determine why an immunogenic tumor grows unchecked in the anterior chamber (a.c.) of the eye. The OVA-expressing EL4 tumor, E.G7-OVA, was injected into the a.c. or skin of immunocompetent and immunodeficient mice. Tumor growth and tumor-specific immune responses were monitored. Ocular tumor-infiltrating leukocytes were characterized phenotypically and functionally. Growth of E.G7-OVA was inhibited when limiting numbers of cells were injected in the skin but not in the a.c. of C57BL/6 mice, although both routes primed OVA-specific immune responses, which prevented the growth of a subsequent injection with E.G7-OVA in the skin or opposite eye. Tumor regression was OVA-specific because growth of the parental EL-4 tumor was not inhibited in primed mice. E.G7-OVA growth in the skin was not inhibited in immunodeficient Rag(-/-) or CD8 T cell-deficient mice, suggesting that CD8(+) CTLs mediate tumor elimination. CD8(+) T cell numbers were significantly increased in eyes of mice primed with E.G7-OVA, but few were detected in primary ocular tumors. Nevertheless, growth of E.G7-OVA was retarded in the a.c. of TCR-transgenic OT-I mice, and CD8(+) T cell numbers were increased within eyes, suggesting that tumor-specific CD8(+) CTLs migrated into and controlled primary ocular tumor growth. E.G7-OVA did not lose antigenicity or become immunosuppressive after 13 days of growth in the eye. However, CD11b(+) cells accumulated in primary ocular tumors and contained potent immunosuppressive activity when assayed in vitro. Thus, CD11b(+) cells that accumulate within the eye as tumors develop in the a.c. may contribute to immune evasion by primary ocular tumors by inhibiting CTLs within the eye.     

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.     

CD8+ T cells circumvent immune privilege in the eye and mediate intraocular tumor rejection by a TNF-alpha-dependent mechanism

Although intraocular tumors reside in an immune-privileged environment, T cells can circumvent immune privilege and mediate tumor rejection without inducing damage to normal ocular tissue. In this study, we used a well-characterized tumor, Ad5E1 (adenovirus type 5 early region 1), to analyze the role of CD8+ T cells in the pristine rejection of intraocular tumors. It has been previously documented that Ad5E1 tumor rejection can occur in the absence of CD8+ T cells. However, here we find that CD8+ T cells infiltrated intraocular Ad5E1 tumors in C57BL/6 mice. Surprisingly, CD8+ T cells from tumor-rejector mice could mediate intraocular tumor rejection following adoptive transfer to SCID mice. In determining the mechanisms behind CD8+ T cell-mediated tumor rejection, we discovered that antitumor CTL activity was neither observed nor necessary for rejection of the intraocular tumors. CD8+ T cells from rejector mice did not produce IFN-gamma in response to Ad5E1 tumor Ags or use FasL to mediate intraocular tumor rejection. Also, CD8+ T cells did not use perforin or TRAIL, as CD8+ T cells from perforin knockout (KO) and TRAIL KO mice conferred protection to SCID recipient mice following adoptive transfer. We discovered that CD8+ T cells used TNF-alpha to mediate tumor rejection, because Ad5E1 tumor cells were highly sensitive to TNF-alpha-induced apoptosis and CD8+ T cells from TNF-alpha KO mice did not protect SCID mice from progressive Ad5E1 tumor growth. The results indicate that CD8+ T cells circumvent immune privilege and mediate intraocular tumor rejection by a TNF-alpha-dependent manner while leaving the eye intact and vision preserved.     

Tumor vaccine based on cell surface expression of DcR3/TR6

DcR3/TR6, a secreted protein belonging to the TNF receptor superfamily, interacts with lymphotoxin-like, exhibits inducible expression, and competes with herpes simplex virus glycoprotein D for herpes virus entrance mediator (LIGHT), Fas ligand (FasL), and TL1A, all members of the TNF superfamily. Solid-phase TR6 can trigger reverse signaling of LIGHT and FasL expressed on T cells, and lead to T cell costimulation. In this study, we engineered tumor cells to express cell surface TR6 and used these cells as a tumor vaccine. We demonstrated that mastocytoma P815 cells expressing surface TR6 (TR6-P815) effectively augmented the T cells response in vitro and ex vivo in terms of proliferation, as well as IL-2 and IFN-gamma secretion. TR6-P815 cells had reduced tumorigenicity compared with parental P815 cells. When inactivated TR6-P815 cells were employed as a vaccine, they protected the mice from challenge with live parental P815 cells, and eliminated established P815 tumors. The cell surface TR6-based tumor vaccine was also effective against low antigenicity tumors, such as B16 melanoma; co-administration of bacillus Calmette-Guérin further enhanced the vaccine's efficacy. Thus, cell surface TR6 expression is a useful addition to our tumor vaccine arsenal.     

Early development of CD8-negative and CD8-positive MHC-unrestricted cytotoxic cells induced by alloantigen inoculation in mice

Peritoneal cells (PC) in C57B1/6 (B6, H-2b) mice receiving an intraperitoneal (i.p.) injection of allogeneic BALB/c (H-2d) spleen cells demonstrated potent cytotoxic activity against syngeneic, xenogeneic, third-party allogeneic tumors as well as H-2d derived tumors. Maximum cytotoxic activity against various tumors other than H-2d derived tumor, B16 (H-2b) was elicited on day 3 post allosensitization and decreased drastically thereafter, whereas cytotoxic activity against P815 (H-2d) peaked 3 days after the inoculation and maintained the peak activity thereafter. Surface phenotype of PC responsible for the cytotoxic activity against B16 was Thy-1+/-, Lyt-2-, L3T4-, asialo GM1 (AGM1)+, and that of PC against P815 was Thy-1+, Lyt-2+ (or Lyt-2+/-), L3T4-, AGM1+. These phenotypes showed similar phenotypes to the counterparts against B16 and against P815 in spleen cells induced by intravenous inoculation of alloantigen. When mice were pretreated i.p. with anti-AGM1 antibody before the allosensitization, anti-P815 cytotoxic-activity in PC was completely diminished. Similar activity in spleen, however, was enhanced by i.v. treatment with the antibody before the i.v. inoculation of alloantigen. The data clearly demonstrate that in vivo inoculation of B6 mice with normal allogeneic cells induces "NK-like" CD8- cytotoxic cells and "anomalous" CD8+ cytotoxic cells in PC.     

Immunization of DBA/2 mice with a T cell hybridoma-derived TsF increases immune resistance to the syngeneic tumors P815 and L1210

The ability of a tumor-specific T suppressor factor (TsF) isolated from a T cell hybridoma, A10, to act as an immunogen in DBA/2 mice was investigated. The TsF was affinity purified from ascites over an immunoadsorbent column containing a monoclonal antibody (B16G) that has specificity for the TsF molecule, or over columns containing membrane extracts of the P815 mastocytoma (the tumor for which A10 is specific). The specificity control was BW5147 (the fusion partner for A10) membrane extracts treated in the same way as A10. DBA/2 mice were immunized with the affinity-purified material or PBS and were subsequently challenged with either the P815 tumor or the L1210 DBA/2 thymoma. When mice were immunized with material affinity purified over B16G, eluted material from both A10 ascites and BW5147 membrane extracts enhanced resistance to both P815 and L1210 challenge, indicating that B16G was binding immunogenic material derived from both preparations, which exerted a tumor-protective effect. However, when a P815 affinity column was used, protective material was eluted only from A10 ascites, and this bestowed resistance to both P815 and L1210. When irradiated whole cells were used as immunogens, only A10 cells stimulated anti-tumor immunity, and this appeared to be directed specifically to the P815 tumor. The implications of these findings in terms of the potential for immune modulation with anti-suppressor therapy, and the specificity of the B16G monoclonal, are discussed. The demonstration of B16G binding material (TsF) in the membranes (but not the ascites) of the BW5147 line is also of significance to investigators using BW5147 fused suppressor hybridomas.