Jason Attanucci

Bone marrow-derived dendritic cells pulsed with a tumor-specific peptide elicit effective anti-tumor immunity against intracranial neoplasms.

Although the central nervous system (CNS) is often regarded as an immunologically privileged site, it is well established that specific CNS immunoreactivity can be generated through peripheral vaccination with CNS antigens. Dendritic cells (DC) are potent antigen presenting cells of hematopoietic origin that have emerged as a promising tool for cancer immunotherapy capable of evoking significant anti‐tumor immunity when pulsed with tumor‐associated peptides. To explore a role for DC‐based immunization strategies for the treatment of CNS tumors, we developed a brain tumor model using the C3 sarcoma cell line which expresses the tumor‐specific, major histocompatibility complex (MHC) class I‐restricted peptide epitope E749–57. Syngeneic C57Bl/6 mice receiving intravenous (i.v.) injections of bone marrow‐derived DCs pulsed with E7 peptide were effectively protected against a subsequent intracerebral challenge with C3 tumor cells. More importantly, this systemic immunization strategy was effective in a therapy model as 67% of animals (10 of 15) with established (day 7) intracerebral C3 tumors treated with 3 weekly injections of E7 peptide‐pulsed DCs achieved a long‐term survival (>90 days) while no control animals survived beyond day 41. In vivo depletion of CD8+ cells, but not CD4+ or asialo‐GM1+ cells, abrogated the efficacy of E7 peptide‐pulsed DC therapy of established tumors, indicating a pivotal role of specific CD8+ T‐cell responses in mediating the anti‐tumor effect. Our findings support the hypothesis that effective CNS anti‐tumor immunoreactivity can be generated with DC‐based tumor vaccines. Int. J. Cancer 78:196–201, 1998.© 1998 Wiley‐Liss, Inc.

Effective cytokine gene therapy against an intracranial glioma using a retrovirally transduced IL-4 plus HSVtk tumor vaccine

To explore the potential for molecular immunotherapies in the treatment of malignant gliomas, we evaluated the efficacy of subcutaneous tumor cell vaccines in the treatment of intracranial 9L tumors, using 9L gliosarcoma cell lines stably transduced with the murine interleukin-4 cDNA (9L-IL4), the herpes simplex virus-thymidine kinase cDNA (9L-Tk) or both (9L-IL4-Tk). The expression of multiple genes from a single transcript was achieved by incorporating internal ribosomal entry site (IRES) cassettes in the retroviral constructs. Subcutaneous immunization of rats with nonirradiated 9L-IL4 cells or 9L-IL4-Tk cells followed by treatment with ganciclovir (GCV) completely protected the animals from a subsequent intracranial challenge with wild-type 9L cells. In contrast, only 50% of animals immunized with 9L-Tk cells and 0% of 9L-neo immunized animals rejected the same challenge with wild-type 9L. More importantly, treatment of established (day 3) intracranial 9L tumors with genetically engineered tumor cells resulted in long-term survival (>100 days) for 25–43% of 9L-IL4-Tk immunized animals and for 27% of nonirradiated 9L-IL4 immunized animals. In striking contrast, no 9L-Tk, 9L-neo or irradiated 9L-IL4 immunized animals survived for more than 33 days. As a marker of a cellular immune response, splenocytes from nonirradiated 9L-IL4, 9L-Tk or 9L-IL4-Tk immunized animals produced interferon-gamma (IFN-γ) in greater amounts than those from 9L-neo immunized or Hank’s balanced salts solution (HBSS) treated animals when stimulated with wild-type 9L in vitro. Our findings support the use of tumor cell vaccines expressing the IL-4 and HSVtk genes for the treatment of malignant gliomas.

Cytokine gene therapy of gliomas: effective induction of therapeutic immunity to intracranial tumors by peripheral immunization with interleukin-4 transduced glioma cells

To provide a means for comparing strategies for cytokine gene therapy against intracranial (i.c.) tumors, we generated rat gliosarcoma 9L cells transfected with interleukin-4 (9L-IL4), interleukin-12 (9L-IL12), granulocyte–macrophage colony-stimulating factor (9L-GMCSF) or interferon-α (9L-IFNα). To simulate direct and highly efficient cytokine gene delivery, cytokine transfected 9L tumors were implanted i.c. into syngeneic rats. i.c. injection led to tumor-outgrowth in the brain and killed most animals, whereas these cell lines were rejected following intradermal (i.d.) injection. Cytokine-expressing i.c. 9L tumors, however, had a greater degree of infiltration by immune cells compared with control, mock-transfected 9L-neo, but to a lesser degree than i.d. cytokine-expressing tumors. Tumor angiogenesis was suppressed in cytokine-transfected tumors. In a prophylaxis model, i.d. vaccination with 9L-IL4 resulted in long-term survival of 90% of rats challenged i.c. with parental 9L; whereas 40% of 9L-GM-CSF, 40% of 9L-IFNα and 0% of 9L-IL12-immunized rats were protected. In a therapy model (day 3 i.c. 9L tumors), only i.d. immunization with 9L-IL4 had long-term therapeutic benefits as 43% of rats survived >100 days. These data indicate that peripheral immunization with 9L-IL4 had the most potent therapeutic benefit among various cytokines and approaches tested against established, i.c. 9L tumors.

Gene therapy of malignant gliomas: a pilot study of vaccination with irradiated autologous glioma and dendritic cells admixed with IL-4 transduced fibroblasts to elicit an immune response.

IND 8918 Principal Investigator: Hideho Okada, M.D., Ph.D. Co-investigators: Ian F. Pollack, M.D. Frank Lieberman, M.D. Associate Investigators: Neurological Surgery L. Dade Lunsford, M.D. Douglas Kondziolka, M.D. David Schiff, M.D. Jason Attanucci, B.S. Biologic Therapy University of Pittsburgh Cancer Institute Howard Edington, M.D. William Chambers, Ph.D. Pawel Kalinski, M.D., Ph.D. Donna Kinzler, R.N. IMCPL/CT Theresa Whiteside, Ph.D. Elaine Elder, Sc.D. Statistics Douglas Potter, Ph.D.

Characterization and transduction of a retroviral vector encoding human interleukin-4 and herpes simplex virus-thymidine kinase for glioma tumor vaccine therapy.

Vaccination with cytokine-transduced tumor cells represents a potentially important approach to the treatment of central nervous system tumors. We have recently demonstrated the therapeutic efficacy of tumor cell vaccines expressing the murine interleukin 4 (IL-4) and the herpes simplex virus-thymidine kinase in a rat brain tumor model in which nonirradiated vaccine cells can be eliminated by the subsequent administration of ganciclovir. In this report, we demonstrate the construction and characterization of a retroviral vector that encodes human IL-4, neomycin phosphotransferase, and herpes simplex virus-thymidine kinase genes for use in human clinical trials. An MFG-based retroviral vector was used to generate the recombinant retrovirus, TFG-hIL4-Neo-Tk, in which a long terminal repeat-driven polycistronic transcript encodes three cDNAs that are linked and coexpressed using two intervening internal ribosome entry site fragments from the encephalomyocarditis virus. The amphotropic retroviral vector TFG-hIL4-Neo-Tk was then used to infect human primary glioma cultures and skin-derived fibroblasts. After infection and G418 selection, cells produced 89–131 ng/106 cells/48 hours of human IL-4, which was determined to be biologically active. Transduced glioma cells were highly sensitive to the cytotoxic effect of ganciclovir. These data demonstrate the suitability of the TFG-hIL4-Neo-Tk vector for therapeutic studies of cytokine-transduced autologous tumor vaccination in patients with malignant gliomas.