Lung cancers are the leading cause of cancer deaths globally. In particular, non-small cell lung cancer (NSCLC) is a devastating disease, and is rarely curable. While targeted therapies, such as those using epidermal growth factor receptor (EGFR) inhibitors, have shown clinical promise, these therapies are rarely curative for advanced cancers. As lung cancers are typically diagnosed at advanced phases and appear to possess inherent or acquired survival mechanisms that can protect the cells from EGFR inhibition, the discovery of pathways that mediate these compensatory survival mechanisms could reveal novel therapeutic targets that render EGFR inhibition a more effective therapy for lung cancer. Using a genome-wide shRNA screen, we have identified gene products whose inhibition synergizes with the EGFR inhibitor gefitinib to eliminate NSCLC cells. This screen identified a number of druggable gene products and potential pathways, including Wnt/tankyrase/?-catenin and NFAT/cytokine/STAT pathways. We refer to gene products whose inhibition sensitizes NSCLC cells to gefitinib treatment as 'SLuGs' for Synthetic Lethal upon Gefitinib. Follow up studies have shown that inhibition of these SLuG pathways potently synergizes with gefitinib to eliminate NSCLC cells. These studies will involve close collaborations between labs with expertise in genome-wide shRNA screens and cancer biology (DeGregori), computational biology (Tan), mouse models of NSCLC (Chan), and clinical application (Bunn). We will perform computational analysis and systematic validation of genome-wide shRNA screening results to reveal genes and pathways whose inhibition sensitizes NSCLC cells to EGFR inhibition. Further studies of the Wnt/tankyrase/?-catenin and NFAT/cytokine/STAT pathways show reveal roles for these pathways in NSCLC cell survival during EGFR inhibition. Additional studies will determine whether inhibition of these pathways cooperates with gefitinib treatment to eliminate NSCLC in vivo using mouse models. The overarching goals of this project are 1) to identify novel drug targets or unanticipated combination therapies for NSCLC, 2) to reveal pathways and processes that maintain NSCLC cell survival in the face of EGFR inhibition, and 3) to uncover therapeutic approaches to make NSCLC, either highly or moderately EGFR-inhibitor sensitive, even more sensitive to these inhibitors, leading to longer remissions and better control of the disease.
Lung cancer is a devastating disease, and is rarely curable. While targeted therapies, such as through inhibition of the epidermal growth factor receptor (EGFR), have shown clinical promise, these therapies are rarely if ever curative for advanced cancers. Our screen has identified pathways that contribute to lung cancer cell survival during EGFR inhibition. By targeting multiple pathways, we hope to minimize the development of drug resistance and improve therapeutic outcomes. The proposed studies could provide the necessary justification for clinical trials to treat EGFR dependent lung cancers.
Showing the most recent 10 out of 18 publications
