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非小细胞肺癌中 BRAF 突变的分子特征揭示了克隆性与驱动基因突变之间的关系,并确定了可靶向的非 V600 驱动基因突变。

Molecular Landscape of BRAF-Mutant NSCLC Reveals an Association Between Clonality and Driver Mutations and Identifies Targetable Non-V600 Driver Mutations.

机构信息

Department of Thoracic/Head and Neck Medical Oncology, The University of Texas MD Anderson Cancer Center, Houston, Texas.

Guardant Health, Redwood City, California.

出版信息

J Thorac Oncol. 2020 Oct;15(10):1611-1623. doi: 10.1016/j.jtho.2020.05.021. Epub 2020 Jun 13.

DOI:10.1016/j.jtho.2020.05.021
PMID:32540409
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7529990/
Abstract

INTRODUCTION

Approximately 4% of NSCLC harbor BRAF mutations, and approximately 50% of these are non-V600 mutations. Treatment of tumors harboring non-V600 mutations is challenging because of functional heterogeneity and lack of knowledge regarding their clinical significance and response to targeted agents.

METHODS

We conducted an integrative analysis of BRAF non-V600 mutations using genomic profiles of BRAF-mutant NSCLC from the Guardant360 database. BRAF mutations were categorized by clonality and class (1 and 2: RAS-independent; 3: RAS-dependent). Cell viability assays were performed in Ba/F3 models. Drug screens were performed in NSCLC cell lines.

RESULTS

A total of 305 unique BRAF mutations were identified. Missense mutations were most common (276, 90%), and 45% were variants of unknown significance. F468S and N581Y were identified as novel activating mutations. Class 1 to 3 mutations had higher clonality than mutations of unknown class (p < 0.01). Three patients were treated with MEK with or without BRAF inhibitors. Patients harboring G469V and D594G mutations did not respond, whereas a patient with the L597R mutation had a durable response. Trametinib with or without dabrafenib, LXH254, and lifirafenib had more potent inhibition of BRAF non-V600-mutant NSCLC cell lines than other MEK, BRAF, and ERK inhibitors, comparable with the inhibition of BRAF V600E cell line.

CONCLUSIONS

In BRAF-mutant NSCLC, clonality is higher in known functional mutations and may allow identification of variants of unknown significance that are more likely to be oncogenic drivers. Our data indicate that certain non-V600 mutations are responsive to MEK and BRAF inhibitors. This integration of genomic profiling and drug sensitivity may guide the treatment for BRAF-mutant NSCLC.

摘要

简介

大约 4%的 NSCLC 存在 BRAF 突变,其中约 50%是非 V600 突变。由于功能异质性以及对其临床意义和对靶向药物反应的认识不足,治疗非 V600 突变的肿瘤具有挑战性。

方法

我们使用 Guardant360 数据库中 BRAF 突变 NSCLC 的基因组谱进行了 BRAF 非 V600 突变的综合分析。根据克隆性和类别(1 和 2:RAS 独立;3:RAS 依赖)对 BRAF 突变进行分类。在 Ba/F3 模型中进行细胞活力测定。在 NSCLC 细胞系中进行药物筛选。

结果

共鉴定出 305 个独特的 BRAF 突变。错义突变最为常见(276,90%),45%为意义不明的变异。F468S 和 N581Y 被鉴定为新的激活突变。1 类至 3 类突变的克隆性高于未知类别的突变(p<0.01)。3 名患者接受了 MEK 加或不加 BRAF 抑制剂的治疗。携带 G469V 和 D594G 突变的患者没有反应,而携带 L597R 突变的患者则有持久的反应。与其他 MEK、BRAF 和 ERK 抑制剂相比,trametinib 加或不加 dabrafenib、LXH254 和 lifirafenib 对 BRAF 非 V600 突变 NSCLC 细胞系的抑制作用更强,与 BRAF V600E 细胞系的抑制作用相当。

结论

在 BRAF 突变的 NSCLC 中,已知功能突变的克隆性更高,这可能有助于鉴定更可能是致癌驱动因素的意义不明变异。我们的数据表明,某些非 V600 突变对 MEK 和 BRAF 抑制剂有反应。这种基因组谱分析和药物敏感性的整合可能指导 BRAF 突变 NSCLC 的治疗。

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