KRAS

KRAS mutations are the most common activating mutation in lung cancer and are identified in 25-30% of cases of lung adenocarcinoma. The clinical activity of molecularly targeted therapy in KRAS mutant lung cancer has been limited, as most prior approaches focused on downstream targets of the MAPK pathway, an approach which was largely ineffective. KRAS G12C is the most common subtype of activating KRAS mutation in NSCLC. Identification of a binding pocket of KRAS G12C enabled the development of covalent inhibitors (Ostrem et al. Nature, 2013), which selectively bind to the mutant cysteine and spare wild type or other mutant KRAS proteins (hereafter referred to as G12Ci). These drugs bind only to GDP-bound (i.e. inactive) KRAS G12C and trap the oncoprotein in its inactive state by preventing nucleotide exchange (Lito et al. Science, 2016). Of this new class of agents, two drugs (MRTX849 and AMG510) have demonstrated efficacy in early phase clinical trials, representing a remarkable breakthrough in the management of KRAS G12C mutant lung cancer. Acknowledging the limited number of patients treated thus far, response rates of 40-50% have been reported, demonstrating clinical activity far superior to prior molecularly targeted approaches for the management of KRAS mutant lung cancer. Despite this major advance it is clear that resistance to therapy, both primary and acquired, will remain a challenge and may in part be due to upstream receptor tyrosine kinase (RTK) signaling. Understanding the mechanisms of resistance to this new class of therapy is of paramount importance to improve the efficacy and durability of response, and for identifying rational combinatorial therapies for future clinical trials.

Non-small cell lung cancer (NSCLC) is the leading cause of cancer-associated deaths worldwide. Given the limited effectiveness of current treatments, there is a significant need to identify new driver genes that participate in lung cancer pathogenesis. Dr. O’Donnell and her group identified PROTOCADHERIN 7 (PCDH7) in a functional screen for genes that promote transformation of human bronchial epithelial cells (HBECs). This is of interest because PCDH7 encodes a poorly characterized cell surface receptor that is frequently overexpressed in NSCLC and high expression strongly associates with poor survival of NSCLC patients. Moreover, the presence of PCDH7 on the cell surface highlights the potential of this molecule as a novel target for future therapeutics.

They demonstrated that 1) enforced expression of PCDH7 is sufficient to promote transformation of HBECs, 2) PCDH7 cooperates with oncogenic KRAS to promote tumorigenesis, and 3) PCDH7 potently enhances KRAS-mediated activation of the ERK1/2 pathway. They will elucidate the role of this lung cancer driver by testing the following central hypothesis: Overexpression of PCDH7 initiates a signal transduction cascade that potentiates KRAS-induced MAPK-ERK signaling to promote lung tumorigenesis. In Aim 1, they will correlate PCDH7 immunoexpression with clinical features of resected NSCLCs. In Aim 2, they will elucidate the mechanisms through which PCDH7 potentiates MAPK signaling and tumorigenesis. In Aim 3, they will develop and test the therapeutic efficacy of PCDH7 blocking antibodies in patient-derived xenografts.

These experiments will yield insights into the mechanisms of PCDH7-mediated transformation and reveal new opportunities to pursue this cell-surface receptor as a therapeutic target in NSCLC.

KRAS mutations activate signaling from downstream effector proteins and are though to be required for tumor formation. Exactly how effector signaling is activated, however, is not fully understood. In addition, whether tumors harboring KRAS mutations depend on this oncogene for growth is unclear.

Dr. Lito and his group will dissect the phenotype of KRAS-mutant lung cancer by using a novel allosteric inhibitor that selectively targets KRAS G12C. They will first utilize biochemical assays in order to determine the mechanism of action of this inhibitor. An emphasis will be placed on evaluating how feedback pathways modulate this process, since this is likely to identify factors that may be used as biomarkers of response to treatment.

They will then determine which effector pathways drive the phenotype of KRAS G12C mutant lung cancer, and whether these exhibit adaptation (or reactivation) over time. If so, they will next explore combination-based interventions in order to establish the most effective antiproliferative strategy.

Finally, they will utilize novel patient-derived xenograft and cell line models, established from patients with lung cancer treated at MSKCC, in order to determine if KRAS G12C mutant lung cancers depend on this oncoprotein for growth. These models will also be used to test the most effective combination strategies determined above, as well as to test the potential benefit of intermittent administration schemes designed to best target tumor adaptation to this novel class of inhibitors.

The grand objective of this project is to establish a mutant KRAS-directed therapy for patients with lung cancer.