Stage III
A stage in which the lung tumor can be any size, and more than one tumor may be within the same lung. The cancer may have spread to other parts
Addressing hepatic siphoning to enhance immunotherapy efficacy in veterans
How KRAS mutations affect gene expression in lung cancer
Targeting myeloid-derived suppressor cells in lung cancer
Immunotherapy has become a standard treatment regimen for advanced-stage non-small cell lung cancer. However, most patients do not respond. One significant barrier to immunotherapy efficacy is the tumor microenvironment (TME), which contains immunosuppressive cells, including myeloid-derived suppressor cells (MDSCs). MDSCs represent an important tumor immune escape mechanism and play a role in the development and progression of lung cancer. Dr. Owen will be studying how this group of cells can be targeted to improve the effect of immunotherapy.
Molecular Characterization of Lineage Plasticity
As a mechanism of resistance to EGFR inhibitors, cancers can change histology from adenocarcinoma to small cell or squamous cell lung cancer. Once this happens, EGFR inhibitors are no longer effective treatment; there are no strategies currently available to prevent or reverse transformation after it has occurred. Dr. Yu will use advanced molecular techniques to identify genetic changes that contribute to transformation. Understanding these genetic changes will identify biomarkers that can be utilized to develop treatments to prevent and reverse transformation.
Targeting Drug Tolerant States + DNA Damage to Block Osimertinib Resistance
Despite high tumor response rates, patients treated with EGFR targeted therapies, such as osimertinib, inevitably develop disease progression. Mechanisms of drug resistance remain incompletely understood on both a genomic and proteomic level. The objective of Dr. Lovly’s project is to find new targeted treatments and drug combinations that can tackle cancer evolution and osimertinib resistance.
Overcoming ALK resistance with covalent cysteine-reactive inhibitors
Overcoming bypass signaling to enhance clinical responses in ALK-positive lung cancer
Phase 1 first in-human clinical trial with a therapeutic ALK vaccine in patients with ALK+ NSCLC
Mechanisms of resistance to direct KRAS G12C inhibition
Dr. Arbour will test a combination treatment regimen (MRTX849 for KRAS G12C and TNO155 for SHP2) in specialized mouse models of KRAS-mutant lung cancer, as well as analyze blood samples from patients who are currently receiving the MRTX849 drug to proactively monitor how these patients are developing resistance to MRTX849. Her ultimate goal is for new drugs, such as TNO155, to be added to the treatment regimen for KRAS-positive patients to combat acquired resistance. Dr. Arbour is the recipient of the Kristie Rolke Smith/LUNGevity Career Development Award, generously funded by the Rolke family in memory of their daughter, Kristie.