分子异质性和受体共扩增驱动MET扩增的食管胃癌对靶向治疗的耐药性。

Molecular Heterogeneity and Receptor Coamplification Drive Resistance to Targeted Therapy in MET-Amplified Esophagogastric Cancer.

作者信息

Kwak Eunice L, Ahronian Leanne G, Siravegna Giulia, Mussolin Benedetta, Borger Darrell R, Godfrey Jason T, Jessop Nicholas A, Clark Jeffrey W, Blaszkowsky Lawrence S, Ryan David P, Lennerz Jochen K, Iafrate A John, Bardelli Alberto, Hong Theodore S, Corcoran Ryan B

机构信息

Massachusetts General Hospital Cancer Center, Boston, Massachusetts. Department of Medicine, Harvard Medical School, Boston, Massachusetts.

Department of Oncology, University of Torino, Torino, Italy. Candiolo Cancer Institute-FPO, IRCCS, Candiolo, Torino, Italy.

出版信息

Cancer Discov. 2015 Dec;5(12):1271-81. doi: 10.1158/2159-8290.CD-15-0748. Epub 2015 Oct 2.

DOI:10.1158/2159-8290.CD-15-0748

PMID:26432108

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4670804/

Abstract

UNLABELLED

MET inhibition is effective in some patients with MET-amplified esophagogastric cancer (EGC), but understanding acquired and de novo resistance mechanisms will be critical to improving therapy. We identified KRAS mutation as a novel cause of acquired resistance in a patient after a 2-year response to a MET inhibitor. We also observed that 40% to 50% of patients with MET-amplified EGC harbor coamplification of HER2 and/or EGFR concurrently in the same tumor cells, which can drive de novo resistance. One patient with concurrent MET and HER2 amplification was refractory to HER2 blockade, but responded to combined MET/HER2 inhibition. We also found striking heterogeneity in MET amplification between distinct metastatic lesions and primary tumors in individual patients with EGC. In these patients, MET inhibition led to mixed responses and disease progression through outgrowth of non-MET-amplified clones, which could be monitored in circulating tumor DNA. Thus, receptor coamplification and molecular heterogeneity may be key drivers of clinical resistance in MET-amplified EGC.

SIGNIFICANCE

Coamplification of driver oncogenes occurs frequently in EGC and can drive therapeutic resistance, supporting a role for comprehensive molecular analysis prior to targeted therapy. EGCs can also exhibit extensive heterogeneity in gene amplification between distinct tumor lesions within the same patient, suggesting that molecular profiling of a single-lesion biopsy may be insufficient to guide targeted therapy selection.

摘要

未标记

MET抑制对一些MET扩增的食管胃癌（EGC）患者有效，但了解获得性和原发性耐药机制对于改善治疗至关重要。我们在一名对MET抑制剂有2年反应的患者中确定KRAS突变是获得性耐药的新原因。我们还观察到，40%至50%的MET扩增EGC患者在同一肿瘤细胞中同时存在HER2和/或EGFR的共扩增，这可导致原发性耐药。一名同时存在MET和HER2扩增的患者对HER2阻断治疗无效，但对MET/HER2联合抑制有反应。我们还发现，在EGC个体患者中，不同转移病灶与原发肿瘤之间的MET扩增存在显著异质性。在这些患者中，MET抑制导致混合反应和疾病进展，通过非MET扩增克隆的生长实现，这可在循环肿瘤DNA中监测到。因此，受体共扩增和分子异质性可能是MET扩增EGC临床耐药的关键驱动因素。

意义

驱动癌基因的共扩增在EGC中频繁发生，并可导致治疗耐药，支持在靶向治疗前进行全面分子分析的作用。EGC在同一患者不同肿瘤病灶之间的基因扩增也可表现出广泛的异质性，这表明单病灶活检的分子谱分析可能不足以指导靶向治疗选择。

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