To study mechanisms of T cell-mediated rejection of B cell lymphomas, we developed a murine lymphoma model wherein three potential rejection antigens, human c-MYC, chicken ovalbumin (OVA), and GFP are expressed. After transfer into wild-type mice 60–70% of systemically growing lymphomas expressing all three antigens were rejected; lymphomas expressing only human c-MYC protein were not rejected. OVA expressing lymphomas were infiltrated by T cells, showed MHC class I and II upregulation, and lost antigen expression, indicating immune escape. In contrast to wild-type recipients, 80–100% of STAT1-, IFN-γ-, or IFN-γ receptor-deficient recipients died of lymphoma, indicating that host IFN-γ signaling is critical for rejection. Lymphomas arising in IFN-γ- and IFN-γ-receptor-deficient mice had invariably lost antigen expression, suggesting that poor overall survival of these recipients was due to inefficient elimination of antigen-negative lymphoma variants. Antigen-dependent eradication of lymphoma cells in wild-type animals was dependent on cross-presentation of antigen by cells of the tumor stroma. These findings provide first evidence for an important role of the tumor stroma in T cell-mediated control of hematologic neoplasias and highlight the importance of incorporating stroma-targeting strategies into future immunotherapeutic approaches.
Over-expression of the proto-oncogene c-MYC is frequently observed in a variety of tumors and is a hallmark of Burkitt´s lymphoma. The fact that many tumors are oncogene-addicted to c-MYC, renders c-MYC a powerful target for anti-tumor therapy. Using a xenogenic vaccination strategy by immunizing C57BL/6 mice with human c-MYC protein or non-homologous peptides, we show that the human c-MYC protein, despite its high homology between mouse and man, contains several immunogenic epitopes presented in the context of murine H2b haplotype. We identified an MHC class II-restricted CD4+ T-cell epitope and therein an MHC class I-restricted CD8+ T-cell epitope (SSPQGSPEPL) that, after prime/boost immunization, protected up to 25% of mice against a lethal lymphoma challenge. Lymphoma-rejecting animals contained MHC multimer-binding CD8+ cell within the peripheral blood and displayed in vivo cytolytic activity with specificity for SSPQGSPEPL. Taken together these data suggest that oncogenic c-MYC can be targeted with specific T-cells.
BackgroundA given tumor is usually dependent on the oncogene that is activated in the respective tumor entity. This phenomenon called oncogene addiction provides the rationale for attempts to target oncogene products in a therapeutic manner, be it by small molecules, by small interfering RNAs (siRNA) or by antigen-specific T cells. As the proto-oncogene product is required also for the function of normal cells, this raises the question whether there is a therapeutic window between the adverse effects of specific inhibitors or T cells to normal tissue that may limit their application, and their beneficial tumor-specific therapeutic action. To address this crucial question, suitable mouse strains need to be developed, that enable expression of the human proto-oncogene not only in tumor but also in normal cells. The aim of this work is to provide such a mouse strain for the human proto-oncogene product c-MYC.Principal FindingsWe generated C57BL/6-derived embryonic stem cells that are transgenic for a humanized c-Myc gene and established a mouse strain (hc-Myc) that expresses human c-MYC instead of the murine ortholog. These transgenic animals harbor the humanized c-Myc gene integrated into the endogenous murine c-Myc locus. Despite the lack of the endogenous murine c-Myc gene, homozygous mice show a normal phenotype indicating that human c-MYC can replace its murine ortholog.ConclusionsThe newly established hc-Myc mouse strain provides a model system to study in detail the adverse effects of therapies that target the human c-MYC protein. To mimic the clinical situation, hc-Myc mice may be cross-bred to mice that develop tumors due to overexpression of human c-MYC. With these double transgenic mice it will be possible to study simultaneously the therapeutic efficiency and adverse side effects of MYC-specific therapies in the same mouse.
Adoptive T cell therapy is an important additional treatment option for malignant diseases resistant to chemotherapy. Using a murine high-grade B cell lymphoma model, we have addressed the question whether the B cell differentiation antigen CD19 can act as rejection antigen. CD19 2/2 mice inoculated with CD19 1 B cell lymphoma cells showed higher survival rates than WT mice and were protected against additional tumor challenge. T cell depletion prior to tumor transfer completely abolished the protective response. By heterotypic vaccination of CD19 2/2 mice against murine CD19, survival after tumor challenge was significantly increased. To define protective epitopes within the CD19 molecule, T cells collected from mice that had survived the tumor transfer were analyzed for IFNc secretion in response to CD19-derived peptides. The majority of mice exhibited a CD4 1 T cell response to CD19 peptide 27, which was the most dominant epitope after CD19 vaccination. A peptide 27-specific CD4 1 T cell line protected CD19 2/2 mice against challenge with CD19 1 lymphoma and also cured a significant proportion of WT mice from recurrent disease in a model of minimal residual disease after chemotherapy. In conclusion, our data highlight CD19-specific CD4 1 T cells for adoptive T cell therapy of B cell lymphomas.
4091 Poster Board III-1026 The rejection of Non Hodgkin Lymphomas expressing foreign, for example viral, antigens is compromised despite the presence of specific T-cells. The underlying immunosuppressive mechanisms are poorly understood. Using a transgenic mouse lymphoma model, where the proto-oncogene c-myc is driven by parts of the immunoglobulin lambda locus representing a t(8;22) translocation as found in Burkitt's lymphoma, we investigated the anti-lymphoma activity of specific T-cells. By retroviral transduction of a specific foreign antigen (chicken Ovalbumin-IRES-GFP, OVA) into cell lines from primary c-myc transgenic lymphomas we established a syngeneic model that would allow us to address the role of interferon gamma signalling in rejection of high grade lymphomas. All primary lymphoma cells displayed normal MHC class I and II levels on the surface when compared to wildtype splenic B-cells. This expression could be enhanced by treatment with interferon gamma (IFNg,100U/ml) up to 10 fold. When retrovirally OVA-transduced lymphoma cells were injected into either wildtype or GFP transgenic recipients, animals displayed a significant delay in lymphoma growth compared to non transduced or IRES-GFP transduced control cell lines. 80% of the recipient mice rejected OVA expressing lymphomas. By contrast, we observed 100% mortality when GFP expressing control lymphomas were injected in GFP transgenic recipients, which are tolerant for GFP. Developing OVA expressing lymphomas (20%) displayed a loss of GFP expression indicating a selection for antigen negative cells (p=0.001). In spleens from mice rejecting OVA-expressing lymphomas we found up to 1.8% SIINFEKL specific T-cells. To gain more mechanistic insights, we transferred OVA expressing lymphoma cells into IFNg, Stat1-/- or IFNg-/-receptor deficient recipients. Lack of STAT1-/- or IFNg-receptor on the recipient side or inability to secrete IFNg was associated with fast lymphoma progression and growth was not different when compared to non transduced, antigen negative cell lines. When IFNg-receptor or STAT1 deficient OVA expressing cell lines were transferred into wildytpe mice, rejection was not influenced. Outgrowing OVA expressing lymphomas in wildtype mice displayed a high MHC class I and II expression compared to the cell line prior to injection. MHC induction was absent in lymphomas transferred to Stat1 or IFNg deficient recipients. Depletion of NK cells by anti AsialoGM antibody in wildtype recipients resulted in a significant reduction of disease free survival (80% vs. 50%, p=0.002) and animals developed larger tumors which were eventually rejected resulting in a comparable overall survival. In peripheral blood of NK depleted mice significantly more OVA specific T-cells were detectable through pentamer staining. When lymphoma cell lines were injected into Rag1-/- mice, NK cell mediated rejection was also significantly impaired upon depletion. Our results suggest that T-cell mediated rejection of high grade B-cell lymphomas is strongly dependent on host IFNg secretion and that NK cells substantially contribute to T-cell mediated rejection. Disclosures: No relevant conflicts of interest to declare.
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