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Brief Title: Local Modulation of Immune Receptors to Enhance the Response to Dendritic Cell Vaccination in Metastatic Melanoma
Official Title: Phase 1 Study of Local Modulation of Immune Receptor Function to Enhance Immune Responses to Dendritic Cell Vaccination in Subjects With Metastatic Melanoma
Study ID: NCT01216436
Brief Summary: Our proposed study is designed to test the safety of a new vaccine against melanoma. The induction of immune activity against cancers such as melanoma is a promising approach to cancer treatment, but to date, only a few clinically significant immune responses have been seen following vaccine therapy. This is an important problem, since there are very limited treatment options for patients with metastatic melanoma (melanoma that has spread to lymph nodes and organs). Studies suggest that monoclonal antibodies (mAbs) that block inhibitory receptors on immune cells can enhance the immune responses against cancer, but the intravenous injection of such mAbs has caused severe side effects in animals and humans. In our laboratory, we have developed a method to deliver mAbs and other proteins that block such inhibitory receptors locally at the site where immune responses against melanoma proteins are stimulated by vaccination, enhancing anti-melanoma immunity while avoiding the side-effects associated with intravenous injection of these immune modulators. This is achieved by loading dendritic cells, a type of immune cell, with RNA that encodes the immune modulator. The RNA-loaded dendritic cells then make the immune modulatory proteins and release them locally. By mixing these dendritic cells with additional dendritic cells loaded with melanoma proteins, the immune modulators are released at the site where anti-melanoma immune cells are stimulated. In this phase I trial, subjects with metastatic melanoma will undergo the process of leukapheresis, in which white blood cells are removed from the body. Monocytes, a type of immune cell, will then be purified from the white blood cells and cultured under conditions that will change them into dendritic cells. Half of these dendritic cells are then loaded with melanoma antigen RNA, which will lead to the production of melanoma antigen proteins within the dendritic cells. The remaining half of the dendritic cells will be either untreated or loaded with RNA encoding immune modulators so that these dendritic cells will release immune modulators at the site of vaccination. These dendritic cells will be mixed with the melanoma antigen-loaded dendritic cells and injected as a vaccine into lymph nodes. Each subject will receive six weekly injections of their own dendritic cells. Safety and toxicity will be closely monitored. In addition, immune responses against melanoma, as well as clinical responses, will be assessed.
Detailed Description: A variety of trials of immunotherapy in metastatic melanoma have clearly demonstrated that immune responses against melanoma can be induced, but only a few patient have responded clinically, suggesting that new strategies to enhance anti-cancer immune responses are needed. Most of these immunotherapy trials have focused on antigen delivery and providing stimulatory antigen-specific signals to T cells. However, the induction of antigen-specific T cell-mediated immune responses is regulated not only by stimulatory signals, but also by inhibitory receptor-mediated signals. Studies have demonstrated that administering mAbs targeting such immune-modulating receptors on T cells enhances vaccine-induced anti-tumor immunity, suggesting that such an approach might improve the efficacy of clinical cancer vaccines. However, systemic administration such mAbs has been associated with severe, sometimes fatal, autoimmunity. We have developed an approach for targeted delivery of such immune modulatory proteins and mAbs, using immune modulator RNA-transfected dendritic cells (DC), to sites where anti-tumor T cells are induced. Our preliminary studies indicate that this approach may eliminate the adverse effects associated with systemic administration immune modulators, while also enhancing vaccine-induced immune responses. Therefore, the objective of this proposed Phase I immunotherapy trial is to determine the safety and obtain preliminary data on the efficacy of vaccination of human subjects with melanoma tumor associated antigen (TAA) RNA-transfected mature monocyte-derived DC coadministered with additional untransfected DC (Study Arm A), DC transfected with RNA encoding a soluble GITR-L fusion protein (Study Arm B), DC transfected with RNA encoding the humanized heavy and light chains of an antagonistic anti-CTLA-4 mAb (Study Arm C), or DC transfected with combined GITR-L and anti-CTLA-4 mAb RNA (Study Arm D). All study subjects will undergo leukapheresis for collection of peripheral blood mononuclear cells (PBMC) and purified monocytes will be cultured with the cytokines GM-CSF and IL-4 to produce immature DC. After the induction maturation with a standard cytokine cocktail, half of the DC will then be transfected with RNA encoding melanoma TAAs MART, tyrosinase, and gp100, and MAGE-3, while the remaining half of the DC will be either untransfected (Study Arm A) or will be transfected with immune modulator RNA (Study Arm B, C, and D). DC will be cryopreserved. Subjects will then be immunized with these DC, weekly for six intranodal injections. For each subject, safety and toxicity will be assessed, and anti-tumor immune responses will be measured.
Minimum Age: 18 Years
Eligible Ages: ADULT, OLDER_ADULT
Sex: ALL
Healthy Volunteers: No
Duke University Medical Center, Durham, North Carolina, United States
Name: Scott K Pruitt, MD, PhD
Affiliation: Duke University
Role: PRINCIPAL_INVESTIGATOR