Abstract

Abstract Background: Focal high copy number oncogene amplification frequently occurs on extrachromosomal DNA (ecDNA), acentric circular DNA derived from chromosomes during neoplastic transformation and tumor progression. The unique properties of ecDNA facilitate a high degree of genomic plasticity and tumor heterogeneity, which enables rapid acquired resistance to targeted therapies and results in poor patient outcomes. Reintegrated ecDNA, also referred to as homogeneously staining regions (HSR), can exist in dynamic equilibrium with their circular form, although their potential adaptive and resistance properties have not been well characterized. Elucidating the genomic plasticity and mechanisms afforded to cancer cells harboring HSR may provide insights into new therapeutic approaches necessary to address this ecDNA-derived focal amplification. Methods: A novel model was developed that recapitulates the genomic plasticity of focal oncogene amplifications involving FGFR2 and EGFR in response to the FGFR inhibitor, infigratinib. Results: KATOIII gastric cancer cells harbor focal amplification of the FGFR2 oncogene (absolute copy number (CN) = 136 based on next-generation sequencing (NGS) that resides on an HSR as determined by FISH. Short- and long-read NGS revealed prior DNA breakpoints consistent with circular structures containing FGFR2, suggestive of reintegrated ecDNA as HSR. Despite initial sensitivity to FGFR2 inhibition (EC50 = 20 nM), cells acquired resistance following infigratinib dose escalation within 12 weeks. Infigratinib-resistant KATOIII cells retained the FGFR2 HSR while further amplifying FGFR2 on ecDNA, which correlated with increased FGFR2 CN, mRNA, and protein expression. Structural breakpoint analysis of the FGFR2 amplicon revealed conservation between baseline and ecDNA-amplified infigratinib resistant cells, suggesting that the HSR gave rise to ecDNA. Removal of infigratinib resulted in near-complete disappearance of FGFR2 ecDNA and return to near-baseline FGFR2 CN, protein expression, and signaling within 3 weeks. Strikingly, at high infigratinib concentrations that effectively inhibit FGFR2 signaling, cells rapidly switched to EGFR amplified on ecDNA, with concomitant reduction of FGFR2 ecDNA (CN = 553 to 238) and signaling and increased EGFR (CN = 3 to 30), mRNA, and EGFR signaling. Following ecDNA switching from FGFR2 to EGFR, KATOIII cells remained insensitive to infigratinib while acquiring sensitivity to the EGFR inhibitor erlotinib. Mutational analysis revealed no new oncogenic mutations including FGFR2 and EGFR, indicating the EGFR overexpression afforded by ecDNA was sufficient to drive acquired resistance to high infigratinib concentrations. Conclusions: These findings indicate that tumor cells with ecDNA-derived chromosomally reintegrated HSR retain the capacity to amplify ecDNA, thus enabling rapid adaptation to therapeutic pressure. Consequently, new treatment strategies that disable adaptive genomic plasticity are needed to address oncogene amplified cancers that leverage ecDNA biology. Citation Format: Kristen Turner, Homa Hemmati, Cory DuPai, John Bibay, Claire Klebs, Joan Chen, Debbie Liao, Christian Hassig, Shailaja Kasibhatla. Intrinsic genomic plasticity of extrachromosomal DNA (ecDNA) enables oncogene amplified tumor cells to develop rapid acquired resistance to targeted therapy [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2023 Oct 11-15; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2023;22(12 Suppl):Abstract nr B092.

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