KRAS

A gene that is commonly mutated in NSCLC. This is not an actionable mutation

Phase 2 trial of neoadjuvant KRAS G12C directed therapy in resectable NSCLC

Career Development Award
Kristen Marrone, MD
Johns Hopkins School of Medicine
Baltimore
MD

Around one in three patients with non-small cell lung cancer are diagnosed with early-stage disease, where surgery is offered as curative therapy. Unfortunately, the cancer can recur in 50%-60% of patients. The rate of recurrence is higher in patients whose tumors have certain mutations, such as mutations in the KRAS gene. Dr. Marrone and her team will be conducting a phase 2 trial to test whether treatment with a KRAS G12C blocking drug, adagrasib, given as a single drug or in combination with an immunotherapy drug, nivolumab, before a patient undergoes surgery can delay or prevent recurrence in patients whose tumors have a KRAS G12C mutation.

How KRAS mutations affect gene expression in lung cancer

Veterans Affairs Research Scholar Award
Harold Bien, MD, PhD
Stony Brook University/Northport VA Medical Center
Stony Brook
NY

Mechanisms of resistance to direct KRAS G12C inhibition

Career Development Award
Kathryn Arbour, MD
Memorial Sloan Kettering Cancer Center
New York
NY

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.

Dissecting novel mechanisms of lung cancer pathogenesis

Career Development Award
Kathryn O’Donnell, PhD
UT Southwestern Medical Center
Dallas
TX

Dr. O’Donnell has discovered that lung cancer cells make a protein called PCDH7 that is present on the surface of cancer cells where it may be accessible to therapies. In cooperation with the KRAS protein, the PCDH7 protein relays signals from outside the cell to make cancer cells grow faster. She is studying the function of the PCDH7 protein and developing strategies to reduce its effect on the KRAS pathway.

Exploring the therapeutic potential of novel KRAS inhibitors in lung cancer

Career Development Award
Piro Lito, MD, PhD
Memorial Sloan Kettering Cancer Center
New York
NY

Dr. Lito is working with a new drug that works efficiently to stop the growth of lung cancer cells with a mutation in the KRAS gene. Funding from LUNGevity will provide resources to test the drug in mice that have KRAS-positive lung cancer. Dr. Lito’s ultimate aim is to develop a clinical trial for the drug for use in patients who test positive for a KRAS mutation.

Targeting NF-KappaB as a new treatment for lung cancer

Targeted Therapeutics Research Award
Funded equally by LUNGevity Foundation and the National Lung Cancer Partnership
Albert S. Baldwin, PhD
Lineberger Cancer Center, The University of North Carolina at Chapel Hill
Chapel Hill
NC

Dr. Baldwin is identifying and testing new therapeutic targets for KRAS-positive lung cancer. KRAS activates the factor NF-κβ, which, when abnormally active, can contribute to the growth of lung tumors. This activation involves two kinases, and well-validated inhibitors of these pathways exist. This project is determining whether these inhibitors will block the initiation and/or progression of lung tumors.

Notch signaling regulates lung cancer

Targeted Therapeutics Research Award
Funded by LUNGevity Foundation and Arkansas Respiratory Health Association, Breathe California of Los Angeles County, Breathe California of the Bay Area, Breathe New Hampshire, and Respiratory Health Association of Metropolitan Chicago
Navdeep Chandel, PhD
Feinberg School of Medicine, Northwestern University
Chicago
IL

Dr. Chandel is working to identify novel pathways underlying KRAS-driven lung cancer. He is testing two pathways, to determine how mitochondria (powerhouses of the cell) and Notch signaling (a pathway often activated in lung cancer that relays information from outside the cell to inside) behave differently in cancer and non-cancer cells.

Inflammation-Related Lung Cancer Prevention by Targeting the NF-kB Pathway

Targeted Therapeutics Research Award
American Lung Association/LUNGevity Foundation Discovery Award
Seyed Javad Moghaddam, MD
University of Texas MD Anderson Cancer Center
Houston
TX

Dr. Moghaddam is investigating how airway inflammation can lead to lung cancer.  The factor NF-κβ is involved in both inflammation and carcinogenesis. Dr. Moghaddam’s hypothesis is that NF-κβ is a likely candidate for the promotion of lung cancer by inflammation in chronic obstructive pulmonary disease patients.

A Broad Spectrum Lung Cancer Stem Cell Vaccine

Targeted Therapeutics Research Award
Funded equally by LUNGevity Foundation and the American Lung Association
John Eaton, PhD
University of Louisville
Louisville
KY

Previous work of Dr. Eaton and colleagues has demonstrated that mice vaccinated with certain stem cells are 80%-90% protected against the growth of lung tumors injected into the mice as well as protected against the development of lung cancer caused by administration of a carcinogen. The current research is determining whether lung cancer stem cells are selectively destroyed by lymphocytes (immune cells) from vaccinated mice. Dr. Eaton is also determining whether stem cell vaccination  affects the growth of lung tumors in mice that have been genetically engineered to spontaneously develop lung cancer.

Analysis of Lung Adenocarcinoma Heterogeneity Based Upon Cell-of-Origin

Targeted Therapeutics Research Award
National Lung Cancer Partnership/LUNGevity Foundation Research Grant
Mark W. Onaitis, MD
Duke University
Durham
NC

The KRAS gene is the most common mutation in non-small cell lung cancer. Dr. Onaitis is studying how mutations of the KRAS gene affect different types of cells in the lungs and how these differences can be used to develop a targeted therapy that can lessen the effects of KRAS in lung cancer cells.