KRAS突变型肺腺癌的分子特征:EGFR、ALK、STK11和PD-L1共存状态的分析

IF 1.9 Q3 PATHOLOGY
Jim Hsu, Joseph F Annunziata, E. Burns, E. Bernicker, R. Olsen, Jessica S. Thomas
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引用次数: 1

摘要

背景:KRAS突变是西方非小细胞肺癌(NSCLC)最常见的致癌驱动突变。KRAS基因突变在当前和以前吸烟的患者群体中最为普遍。最近,针对KRAS p.G12C突变和预处理的NSCLC患者的靶向抑制剂疗法获得了关键批准,有必要对这些肿瘤患者在所有临床阶段的KRAS突变的异质性和伴随的分子变化进行分析。方法:在这项回顾性分析中,回顾了我们医院系统内所有接受NSCLC病理诊断的病例的病理记录。所有数据均经IRB批准收集。有利于非肺原发性和非腺癌NSCLC(如鳞状细胞癌)的不确定肿瘤类型的病例被排除在队列之外。在该医院系统中,KRAS突变的分子检测是分子生物标志物小组的一部分,该小组是病理学家在最初诊断时反射命令的,可以作为单基因检测或作为下一代测序的实体器官癌症热点小组进行。对每个患者的KRAS突变状态和特定KRAS突变(如果存在)进行核对。本研究评估的其他信息包括患者人口统计学(年龄、性别和吸烟史)、肿瘤分期(如有)、免疫组织化学(IHC)检测的PD-L1表达水平以及其他基因改变(EGFR、ALK和STK11)的存在。结果:在2017年1月1日至2019年1月一日期间,在我们的医院系统中,共有276名被诊断为所有阶段的NSCLC患者进行了KRAS突变分析,并符合纳入研究队列的标准。在这些患者中有29%检测到KRAS驱动基因突变。最常见的KRAS突变是p.G12C(38%),其次是p.G12D(21%)和p.G12V(13%)。在该队列中,KRAS突变的肺腺癌与当前或以前的患者吸烟状况显著相关(29/202(14%)吸烟者和1/74(1%)非吸烟者;P = .0006)。IHC至少1%的PD-L1表达存在于43%的KRAS突变的肺腺癌和45%的非KRAS突变腺癌中。在这项研究中,没有发现KRAS突变与EGFR、ALK或STK11的基因改变同时发生。在48%的病例中,至少发现了一种基因改变(KRAS、ALK、EGFR或STK11)。结论:在该研究队列中,KRAS突变的肺腺癌表现出显著的突变异质性,这与先前发表的研究一致。KRAS突变状态也与当前或以前的吸烟史显著相关。值得注意的是,p.G12C是该队列中最常见的KRAS突变,频率为38%。鉴于KRAS p.G12特异性靶向抑制剂疗法最近获得批准,以及可能被证明对治疗NSCLC有效的其他KRAS靶向疗法的持续开发,这一发现尤其重要。这些发现还强调了在有吸烟史的NSCLC患者中考虑KRAS突变的分子检测的必要性,因为这一人群最常携带KRAS突变,并可能受益于这些新兴的靶向治疗。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular Signatures of KRAS-Mutated Lung Adenocarcinoma: Analysis of Concomitant EGFR, ALK, STK11, and PD-L1 Status
Background: KRAS mutations are the most common oncogenic driver mutations of non-small cell lung cancer (NSCLC) in the Western world. Mutations of the KRAS gene are most prevalent in the patient population of current and former cigarette smokers. With the recent pivotal approval of a targeted inhibitor therapy for patients with KRAS p.G12C mutated and pretreated NSCLC, analysis of the heterogeneity of KRAS mutations and concomitant molecular alterations in patients with these tumors at all clinical stages is indicated. Methods: In this retrospective analysis, patient pathology records were reviewed for all cases receiving a pathologic diagnosis of NSCLC within our hospital system. All data were collected with IRB approval. Cases of indeterminate tumor type favoring a non-lung primary, as well as non-adenocarcinoma NSCLC (eg, squamous) were excluded from the cohort. In this hospital system, molecular testing for KRAS mutations is part of a molecular biomarker panel that is reflex ordered at initial diagnosis by the pathologist and may be performed as a single gene test or as a solid organ cancer hotspot panel by next generation sequencing. For each patient, KRAS mutational status and specific KRAS mutations, if present, were collated. Additional information assessed for this study included patient demographics (age, gender, and smoking history), tumor staging if available, PD-L1 expression levels by immunohistochemistry (IHC), and the presence of other genetic alterations (EGFR, ALK, and STK11). Results: Between January 1, 2017 and January 1, 2019, there were 276 patients diagnosed with NSCLC of all stages who had KRAS mutational analysis performed in our hospital system and who met the criteria for inclusion into the study cohort. A KRAS driver mutation was detected in 29% of these patients. The most frequently identified KRAS mutation was p.G12C (38%), followed by p.G12D (21%) and p.G12V (13%). KRAS-mutated lung adenocarcinoma was significantly associated with current or former patient smoking status in this cohort (29/202 (14%) smokers and 1/74 (1%) non-smokers; P = .0006). PD-L1 expression of at least 1% by IHC was present in 43% of KRAS-mutated lung adenocarcinomas and 45% of non-KRAS-mutated adenocarcinomas. In this study, KRAS mutations were not found to co-occur with gene alterations in EGFR, ALK, or STK11. In 48% of cases, at least one genetic alteration (KRAS, ALK, EGFR, or STK11) was identified. Conclusions: In this study cohort, KRAS-mutated lung adenocarcinoma demonstrated significant mutational heterogeneity, which is consistent with previously published studies. KRAS mutational status was also significantly associated with a current or former smoking history. Notably, p.G12C was the most frequently identified KRAS mutation in this cohort, with a frequency of 38%. This finding is particularly relevant given the recent approval of a KRAS p.G12C-specific targeted inhibitor therapy and the continued development of additional KRAS targeted therapies that may prove effective in treating NSCLC. These findings also highlight the necessity of considering molecular testing for KRAS mutations in patients with NSCLC and a smoking history, as this population most frequently harbors KRAS mutations and may benefit from these emerging targeted therapies.
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来源期刊
Clinical Pathology
Clinical Pathology PATHOLOGY-
CiteScore
2.20
自引率
7.70%
发文量
66
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