KRASG12C抑制剂治疗患者临床获得性耐药改变的基因组图谱

IF 56.7 1区医学 Q1 ONCOLOGY

Annals of Oncology Pub Date : 2025-02-04 DOI:10.1016/j.annonc.2025.01.020

J.M. Riedl , F. Fece de la Cruz , J.J. Lin , C. Parseghian , J.E. Kim , H. Matsubara , H. Barnes , B. Caughey , B.L. Norden , A.A. Morales-Giron , E.W. Kushner , S. Ehnstrom , H. Nakamura , P.S. Patel , H. Ellis , L. Pappas , A. Vakaris , J.F. Gainor , S. Kopetz , S.J. Klempner , R.B. Corcoran

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引用次数: 0

摘要

背景：KRASG12C突变选择性抑制剂（KRASG12Ci）已被证明对KRASG12C癌症有效。然而，耐药性总是会产生，导致短暂的反应。我们的目的是确定KRASG12Ci获得性耐药的基因组图谱，并阐明新型KRAS抑制剂是否可以克服这些耐药机制。方法：为了评估获得性耐药改变的临床频率，我们评估了两个美国癌症中心接受KRASG12Ci治疗的患者进展后无细胞DNA样本的基因组测序数据，以及先前发表的六项研究的数据。利用工程细胞模型进行细胞活力测定，从功能上验证候选耐药驱动因素，并评估新型KRAS抑制剂。结果：共分析143例患者。大多数患者为非小细胞肺癌（NSCLC, n=68）或结直肠癌（CRC, n=58），采用KRASG12Ci单药治疗（n=109）或联合抗egfr抗体治疗（n=30）。46%的患者（n=66）出现RAS/MAPK改变，39%出现≥1个新的KRAS改变（n=56）， 23% （n=33）出现多个并发改变。获得性改变的基因组图谱包括KRAS激活突变（25%的患者）、KRAS扩增（22%）、RAF/MAPK突变/融合（21%）、KRAS开关- ii口袋突变（14%）和NRAS/HRAS突变（8%）。值得注意的是，与非小细胞肺癌相比，获得性RAS/MAPK改变≥1的患者比例在结直肠癌中显著高于非小细胞肺癌（69% vs. 26%）。结论：获得性RAS/MAPK改变是结直肠癌中检测到的KRASG12Ci耐药的复发驱动因素，而在非小细胞肺癌中则较少。临床前数据表明，新型(K)RAS抑制剂可能克服许多这些耐药性改变。

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Genomic landscape of clinically acquired resistance alterations in patients treated with KRASG12C inhibitors

Background

Mutant-selective inhibitors of KRAS^G12C (KRAS^G12Ci) have demonstrated efficacy in KRAS^G12C cancers. However, resistance invariably develops, resulting in short-lived responses. We aimed to define the genomic landscape of acquired resistance to KRAS^G12Ci and to elucidate whether novel classes of KRAS inhibitors can overcome these resistance mechanisms.

Methods

To assess clinical frequencies of acquired resistance alterations, we evaluated genomic sequencing data from postprogression cell-free DNA samples in patients treated with KRAS^G12Ci at two United States cancer centers, alongside data from six previously published studies. Cell viability assays using engineered cell models were employed to functionally validate candidate resistance drivers and to evaluate novel classes of KRAS inhibitors.

Results

A total of 143 patients were analyzed. Most patients had non-small-cell lung cancer (NSCLC, n = 68) or colorectal cancer (CRC, n = 58) and were treated with single-agent KRAS^G12Ci (n = 109) or combined with anti-EGFR antibodies (n = 30). RAS/MAPK alterations emerged in 46% of patients (n = 66), with 39% developing one or more new KRAS alterations (n = 56) and 23% (n = 33) showing multiple concurrent alterations. The genomic landscape of acquired alterations included KRAS-activating mutations (25% of patients), KRAS amplifications (22%), RAF/MAPK mutations/fusions (21%), KRAS switch-II pocket mutations (14%), and NRAS/HRAS mutations (8%). Notably, the proportion of patients with one or more acquired RAS/MAPK alteration was significantly higher in CRC compared with NSCLC (69% versus 26%, P < 0.001). Functional studies confirmed most alterations as resistance drivers. Sotorasib, adagrasib, and divarasib demonstrated distinct activity against KRAS switch-II pocket mutations, yet all were responsive to the RAS(ON) G12C-selective tri-complex inhibitor RM-018. The KRAS-selective inhibitor Pan KRAS-IN-1 effectively targeted KRAS-activating mutations, and the RAS(ON) multiselective tri-complex inhibitor RMC-7797 demonstrated high potency across all RAS alterations.

Conclusions

Acquired RAS/MAPK alterations are recurrent drivers of resistance to KRAS^G12Ci detected in CRC and, less frequently, in NSCLC. Preclinical data suggest that novel (K)RAS inhibitors may overcome many of these resistance alterations.

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来源期刊

Annals of Oncology 医学-肿瘤学

CiteScore

63.90

自引率

1.00%

发文量

3712

审稿时长

2-3 weeks

期刊介绍： Annals of Oncology, the official journal of the European Society for Medical Oncology and the Japanese Society of Medical Oncology, offers rapid and efficient peer-reviewed publications on innovative cancer treatments and translational research in oncology and precision medicine. The journal primarily focuses on areas such as systemic anticancer therapy, with a specific emphasis on molecular targeted agents and new immune therapies. We also welcome randomized trials, including negative results, as well as top-level guidelines. Additionally, we encourage submissions in emerging fields that are crucial to personalized medicine, such as molecular pathology, bioinformatics, modern statistics, and biotechnologies. Manuscripts related to radiotherapy, surgery, and pediatrics will be considered if they demonstrate a clear interaction with any of the aforementioned fields or if they present groundbreaking findings. Our international editorial board comprises renowned experts who are leaders in their respective fields. Through Annals of Oncology, we strive to provide the most effective communication on the dynamic and ever-evolving global oncology landscape.