Overcoming mechanisms of therapeutic resistance in pancreatic ductal adenocarcinoma

PROJECT SUMMARY – Overall While mortality rates for many cancers are declining, pancreatic ductal adenocarcinoma (PDA) remains a highly lethal malignancy with the worst 5-year survival rate of the common malignancies. Unfortunately, current therapies are largely ineffective in PDA, an outcome attributed in large part to therapeutic resistance. The highly

fibrotic and poorly vascularized tumor microenvironment (TME) restricts both nutrient availability and drug delivery, and provides pro-survival and immunosuppressive cues. These limitations create energy stresses that drive metabolic adaptations to support tumor growth and therapeutic resistance. Moreover, the hyperactivation

of pro-survival and resistance pathways in tumor and stromal cell types results in an integrated resistance network. The induction of these pathways is orchestrated by cell-to-cell communications within the TME, including aberrant glycosylation (CA-19-9) and the secretion of immunosuppressive and pro-survival paracrine

factors, such as Leukemia Inhibitory Factor (LIF) from cancer-associated fibroblasts (CAFs). In addition, cells adapt to the hypoxic, nutrient-depleted TME by upregulating cell type-specific survival programs, including autophagy. Ultimately, to support and respond to these signaling and metabolic programs, both the tumor and

stromal cell epigenomes are reprogrammed, leading to cellular heterogeneity and plasticity that restricts durable therapy responses. Each of these programs promote resistance to a broad range of therapeutics, including chemotherapies, targeted therapies, and immune checkpoint inhibitors. The central hypothesis of this program is that pancreatic cancer has co-opted an integrated network

of epigenetic programs, paracrine signaling pathways, and metabolic adaptations to promote tumor survival and therapeutic resistance. Building upon the investigators’ complementary expertise in epigenetics, cell signaling, and metabolic adaptations, as well as common interests in pancreatic cancer, this program seeks

to understand the interactions that hinder PDA therapeutic responses, with the ultimate goal of identifying vulnerabilities that can be exploited and targeted to overcome drug resistance. Importantly, the program will utilize advanced mono- and co-culture organoid systems, cutting-edge mouse models, novel therapeutics,

single-cell approaches, and human clinical specimens to delineate the contributions of both tumor cells and their stromal support network to therapeutic resistance. Moreover, proposed cooperative and innovative approach will reveal how these resistance nodes are integrated and can be targeted to improve therapeutic outcomes in PDA.