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Genes associated with increased brain metastasis risk in non–small cell lung cancer: Comprehensive genomic profiling of 61 resected brain metastases versus primary non–small cell lung cancer (Guangdong Association Study of Thoracic Oncology 1036)
Author(s) -
Wang Hongsheng,
Ou Qiuxiang,
Li Delan,
Qin Tao,
Bao Hua,
Hou Xue,
Wang Kaicheng,
Wang Fang,
Deng Qianqian,
Liang Jianzhong,
Zheng Wei,
Wu Xue,
Wang Xiaonan,
Shao Yang W.,
Mou Yonggao,
Chen Likun
Publication year - 2019
Publication title -
cancer
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.052
H-Index - 304
eISSN - 1097-0142
pISSN - 0008-543X
DOI - 10.1002/cncr.32372
Subject(s) - cdkn2a , medicine , axin2 , kras , lung cancer , oncology , pdgfra , cancer research , wnt signaling pathway , hazard ratio , primary tumor , brain metastasis , cancer , pi3k/akt/mtor pathway , metastasis , gene , signal transduction , biology , genetics , colorectal cancer , confidence interval , gist , stromal cell
Background Patients with brain metastases (BMs) have a poor prognosis and limited therapeutic options. Lung cancer is the most common primary malignancy giving rise to BMs; thus, understanding the molecular mechanisms behind increased BM risk is essential for identifying therapeutic targets and developing effective interventions. Methods Sixty‐one patients who underwent surgical resection of primary non–small cell lung cancer (NSCLC) and BMs were retrospectively studied. Comprehensive genomic profiling of primary NSCLC and matched BMs was performed with next‐generation sequencing targeting 416 cancer‐relevant genes. Results Mutations of major drivers, including EGFR , KRAS , TP53 , and ALK , were highly concordant between primary NSCLC and matched BMs (>80%), whereas discordance suggested the unique genomic evolution and oncogenic mechanisms of NSCLC BMs. BMs also demonstrated higher levels of copy number variations in comparison with primary NSCLC. Furthermore, the alterations of genes encoding CDK4/CCND1, CDKN2A/2B, and PI3K signaling pathways were enriched in BMs, and this suggested their correlation with increased metastatic risk. Indeed, patients with activated PI3K signaling in their primary NSCLC had significantly shorter BM‐free survival (hazard ratio, 8.49; P = .0005). In addition, mutated TP53 or an activated WNT pathway via CTNNB1 , APC , and AXIN2 mutations trended toward shorter BM‐free intervals but not significantly so. Conclusions These findings yield detailed insights into the genomic complexity and heterogeneity of primary NSCLC and matched BMs. This study highlights the significant correlation of PI3K signaling with increased metastatic risk in patients with NSCLC and identifies genomic alterations enriched in NSCLC BMs that could serve as prognostic markers and potential therapeutic targets for treating patients with NSCLC BMs.