Abstract P076: Novel mechanisms of acquired TKI resistance in ROS1+ NSCLC

Abstract

Abstract ROS1 tyrosine kinase inhibitors (TKIs) entrectinib and crizotinib have significantly improved outcomes for patients with ROS1 gene fusion positive (ROS1+) lung adenocarcinoma. However, drug resistance inevitably develops, leading to disease progression. Approximately one-third of patients resistant to ROS1 TKIs demonstrate on-target ROS1 kinase domain (KD) mutations (Dziadziuszko et al. ESMO 2019), but the mechanism of resistance in the majority of patients remain unknown or poorly characterized. The purpose of this study was to model and characterize mechanisms of acquired ROS1 TKI resistance. To investigate resistance to ROS1 TKIs, we used patient-derived cell lines CUTO28 (TPM3-ROS1) and CUTO37 (CD74-ROS1) to generate drug-resistant derivatives to entrectinib (CUTO28-ER, CUTO37-ER) or crizotinib (CUTO28-CR,CUTO37-CR) in vitro. We utilized several techniques to probe the mechanisms driving resistance, including DNA and RNA sequencing, fluorescence in-situ hybridization (FISH), cell proliferation assays, and western blotting. DNA sequencing of the ROS1 KD in all resistant cell lines did not reveal any mutations. CUTO28-ER cells displayed sensitivity to MET-selective TKIs in cell proliferation assays. Consistent with MET dependency, MAPK and Akt pathways were inhibited by treatment with a MET-selective, but not a ROS1-selective, TKI. Western blot demonstrated MET overexpression and interphase FISH confirmed MET gene amplification (MET:CEP7 ratio 4.2) compared to parental cells (MET:CEP7 ratio 1.0). Notably, metaphase FISH revealed extrachromosomal DNA (ecDNA) amplification of MET. CUTO28-CR cells displayed sensitivity to Src family kinase (SFK) TKIs, and addition of pan-HER TKI afatinib resulted in synergistic inhibition of proliferation and downstream MAPK signaling. CUTO37-ER cells displayed sensitivity via proliferation and signaling to pan-HER inhibitor afatinib, and phosphorylation of EGFR Y845 consistent with Src-mediated activation of EGFR. Parental CUTO28 and CUTO37 cells were not sensitive to SFK or HER inhibition. Interphase FISH revealed modest EGFR gene amplification in CUTO28-CR cells—(EGFR:CEP7 ratio 2.1) compared to parental (EGFR:CEP7 ratio 1.0)—but not in CUTO37-ER or CUTO37-CR cells. HER2 gene amplification was not identified in any of the cell lines. Stimulation with epidermal growth factor (EGF) markedly enhanced MAPK signaling in CUTO28-CR, CUTO37-ER, and CUTO37-CR cells to a greater extent than in corresponding parental cells, consistent with EGFR or HER2 dependence. In conclusion, we demonstrated novel mechanisms of resistance to ROS1 TKIs entrectinib and crizotinib. These include ecDNA amplification of MET as an alternate oncogene driver and Src/EGFR axis as a driver of bypass signaling. Combination strategies with existing TKIs could be explored in patients with ROS1 TKI resistance. The discovery of ecDNA MET amplification is particularly intriguing; ecDNA is associated with more aggressive cancers and next generation sequencing analyses do not typically involve amplicon reconstruction to detect ecDNA. Citation Format: Logan C. Tyler, Anh T. Le, Hala Nijmeh, Liming Bao, Kristen Turner, Jason Christianson, Robert C. Doebele. Novel mechanisms of acquired TKI resistance in ROS1+ NSCLC [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2021 Oct 7-10. Philadelphia (PA): AACR; Mol Cancer Ther 2021;20(12 Suppl):Abstract nr P076.