Research Project
10297039
PROJECT SUMMARY Pancreatic ductal adenocarcinoma (PDA) is a highly lethal malignancy with a 5-year overall survival of <10%. Lethality is due to late diagnosis, early metastasis and therapeutic resistance. A hallmark characteristic of PDA is the robust fibroinflammatory and suppressive tumor microenvironment that compresses blood vessels and restricts drug access. This tumor microenvironment is also believed to interfere with immunotherapies, which are transforming the standard of care for many other cancer indications. Tumor-antigen specific T cells are responsible for mediating the therapeutic effects of immunotherapy. While much has been learned about suppressive cells within the pancreatic tumor microenvironment, factors that impact the differentiation program of antigen-specific T cells and their antitumor activity is markedly understudied in this disease. We created a novel engineered T cell therapy that shows marked anti-tumor and anti-stromal activity in an aggressive and difficult to treat genetically engineered PDA animal model that recapitulates many aspects of the human disease, including response to immunotherapy. T cells engineered to express a tumor-reactive T cell receptor specific to mesothelin, which is highly expressed by tumor cells yet poorly expressed by normal cells, is safe, destroys the stroma, alters myeloid cell composition, induces objective responses, and significantly prolongs animal survival. Notably, engineered T cells preferentially accumulate in primary tumors and metastasis, challenging the dogma that PDA is immune privileged. Based on this efficacy, candidate T cell receptors specific to mesothelin for use in patients have been identified leading to a Phase 1 clinical trial. However, despite engineered T cell persistence and significant antitumor activity in vivo, a principle obstacle to cure is the progressive loss of engineered T cell function within the suppressive pancreatic tumor microenvironment. While T cell functionality and differentiation are well-studied in other cancer indications, little is understood regarding how the pancreatic tumor microenvironment impacts tumor antigen-specific T cells. Here, we incorporate innovative tools we have developed to identify mechanistically how engineered T cells mediate stromal remodeling, how the tumor adapts and evades anti-tumor T cells, and then use this knowledge to develop a cutting edge engineered T cell therapy for patient treatment with strategic advancements as compared to most cell engineering approaches. Our Specific Aims are to: (1) Identify how engineered T cells mediate stromal remodeling, (2) Identify the contribution of TCR affinity and the tumor microenvironment on T cell differentiation and functionality, and (3) Test the safety and efficacy of a novel cell engineering approach for targeting solid tumors. Our studies will identify characteristics of T cells and the tumor microenvironment that produce durable antitumor responses during immunotherapy to create safe and durable clinical opportunities for pancreatic cancer patient treatment.
