Drug Sensitivity and Allele‐specificity of First‐line Osimertinib Resistance EGFR Mutations

Abstract

Osimertinib, a mutant‐specific third generation EGFR TKI, is emerging as the preferred first‐line therapy for EGFR mutant lung cancer. Despite initial responses in patients, however, resistance inevitably develops over time. In order to investigate mechanisms of resistance to first‐line osimertinib, we modeled acquired resistance to this drug in transgenic mouse models of EGFRL858R‐induced lung adenocarcinoma and found that it is mediated largely through secondary mutations in EGFR – either C797S or L718V/Q (Figure 1A and 1B). Analysis of circulating free DNA data from patients with EGFR mutant lung cancer revealed that L718Q/V mutations almost always arise in the context of an L858R driver mutation. Therapeutic testing in mice revealed that both erlotinib and afatinib caused regression of osimertinib‐resistant C797S‐containing tumors, whereas only afatinib was effective in L718Q mutant tumors (Figure 1C and 1D). Combination first‐line osimertinib plus erlotinib treatment prevented the emergence of secondary mutations in EGFR. Our data identify specific secondary EGFR mutations as a major mechanism of acquired resistance to first‐line osimertinib treatment and highlight potential strategies to overcome or prevent osimertinib resistance in vivo. Furthermore, these findings emphasize how knowledge of the specific characteristics of resistance mutations are important for determining potential subsequent treatment approaches.Support or Funding InformationThis work was supported by ‐‐‐‐‐Yale’s Specialized Program of Research Excellence in Lung Cancer grant (to K. Politi, S.B. Goldberg and M.A. Lemmon) and funding from AstraZeneca (to K. Politi). Additional support came from the NIH/NCI‐funded Yale Cancer Biology Training Program T32 CA193200‐01A1 and F31 CA228268‐01A1 (to J.H. Starrett), R01 CA198164 (M.A. Lemmon), the Ginny and Kenneth Grunley Fund for Lung Cancer Research, and the Canadian Institutes of Health Research Project Grant PJT‐148725 (to W.W. Lockwood). W.W. Lockwood is supported by a Michael Smith Foundation for Health Research Scholar and NIHR New Investigator Awards, A. Guernet is a fellow funded by the IMED AstraZeneca postdoc program, A. Nagelberg is supported by a scholarship from the CIHR, and K.D. Ashtekar is an Arnold and Mabel Beckman Foundation Postdoctoral Fellow. Yale Cancer Center Shared Resources used for this work were in part supported by NIH/NCI Cancer Center Support Grant P30 CA016359.Acquired resistance to first‐line osimertinib arises partially due to the emergence of secondary mutations in EGFR, which are differentially sensitive to other EGFR TKIs.A. Schema of the experiment. CCSP‐rtTA;TetO‐EGFRL858R mice were administered doxycycline (dox) for the duration of the experiment and developed tumors after ~6 weeks on dox. When tumors were detected by MRI (see pre‐treatment image), osimertinib treatment was initiated (25 mg/kg QD M‐F) which elicited a response (see representative response MRI) and treated until the emergence of resistant tumors by MRI. Coronal MR images are shown, in which ‘H’ indicates heart and red arrows indicate tumor. The osimertinib‐resistant tumors were then collected and analyzed to determine the resistance mechanisms present. B. Pie‐chart illustrating the resistance mechanisms found in osimertinib‐resistant tumors. C and D. Average tumor volume changes for the osimertinib‐resistant tumors switched to 25 mg/kg erlotinib for 3 weeks (C) or 25 mg/kg afatinib for 10 days (D), as determined by MRI tumor volume measurements. Tumor volume is normalized to the point of TKI switch. Error bars represent SEM. For C, curves are the average of n=11 total tumors (C797S n=5; L718V n=3; L718Q n=3). For D, curves are the average of n=12 total tumors (C797S n=7; L718Q n=5).Figure 1