Chimeric-antigen receptor (CAR) T cells have opened a new era for targeted immunotherapy of cancer. The applicant's mentor, Dr. Carl June, is recognized as a world leader in the field of genetically-engineered T cell therapy for hematologic malignancy. Although anti-CD19 CAR T cells (CART19) generate unprecedented responses in patients with B-cell leukemia and lymphoma, relapse represents the major cause of treatment failure. The long term goal of this proposal is to develop an independent research career focused on improving targeted immunotherapy by studying and neutralizing tumor evasion mechanisms. The unifying objective of this application is to design novel strategies for the treatment and prevention of tumor immunoescape based on the mechanisms leading to relapse, using CART19 as a model. The central hypothesis is that multiple mechanisms can lead to escape from immune attack; therefore, combined approaches targeting the problem from multiple sides will prevent escape. The rationale for this research is that identification of key tumor escape mechanisms would allow us to develop specific remedies for these. The central hypothesis of this proposal will be tested by pursuing two specific aims: 1) to characterize the pathogenesis of leukemia relapses occurring after CD19-targeted immunotherapies by studying minor CD19-negative resistant clones present before CART19 treatment and by identifying key resistance pathways in CD19-positive relapses using functional genomics; 2) To design dual-specific chimeric antigen receptor T cells that will prevent tumor escape. This research will be significant because it will contribute depth (of understanding the mechanisms of relapse) and breadth (of novel potentially curative therapy) to the immunotherapeutic arsenal against cancer. Ultimately, such knowledge has the potential to vertically advance the field of CAR-redirected T cell immunotherapy as well as other targeted immunotherapies. This is project is innovative because it combines high throughput screening techniques together with in vitro and in vivo functional studies to study the possible mechanisms of resistance after immunotherapy and therefore to generate novel treatments. The proposed research activities are crucial to the development of the applicant as an independently-funded scientist with a focus on cellular immunotherapy. Dr. Ruella will receive further training in molecular biology, translational medicine, and immunology from his mentors and training in next-generation sequencing, cancer biology and bioinformatics from experienced collaborators at the University of Pennsylvania. Therefore at the conclusion of the training period, the applicant will have acquired a unique set of intellectual and technical skills that will allow him to attack the problem of resistance to targeted immunotherapies from several angles at once. In addition, this award will support a unique training experience in translational research and will establish an academic pathway for the discovery and development of new CAR T cell approaches.
This proposal seeks to improve targeted immunotherapy for cancer by understanding the key factors that lead to tumor resistance using several complimentary approaches. The proposed research is relevant to public health because targeted immunotherapy represents the latest arrow in the quiver of cancer therapy, and because increasing numbers of patients are being treated with this modality. The project is relevant to those parts of the NCI?s mission that pertain to the treatment of cancer, and to the support of education and training in fundamental and clinical sciences relating to cancer.
Rotolo, Antonia; Karadimitris, Anastasios; Ruella, Marco (2018) Building upon the success of CART19: chimeric antigen receptor T cells for hematologic malignancies. Leuk Lymphoma 59:2040-2055 |
Ghione, Paola; Moskowitz, Alison J; De Paola, Nadia E K et al. (2018) Novel Immunotherapies for T Cell Lymphoma and Leukemia. Curr Hematol Malig Rep : |
Ruella, Marco; Xu, Jun; Barrett, David M et al. (2018) Induction of resistance to chimeric antigen receptor T cell therapy by transduction of a single leukemic B cell. Nat Med 24:1499-1503 |
Ruella, Marco; Kenderian, Saad S (2017) Next-Generation Chimeric Antigen Receptor T-Cell Therapy: Going off the Shelf. BioDrugs 31:473-481 |
Singh, Nathan; Shi, Junwei; June, Carl H et al. (2017) Genome-Editing Technologies in Adoptive T Cell Immunotherapy for Cancer. Curr Hematol Malig Rep 12:522-529 |