Department of Dermatology, New York University Langone Medical Center, New York, New York, United States of America.
PLoS One. 2012;7(1):e29336. doi: 10.1371/journal.pone.0029336. Epub 2012 Jan 3.
The rationale for using small molecule inhibitors of oncogenic proteins as cancer therapies depends, at least in part, on the assumption that metastatic tumors are primarily clonal with respect to mutant oncogene. With the emergence of BRAF(V600E) as a therapeutic target, we investigated intra- and inter-tumor heterogeneity in melanoma using detection of the BRAF(V600E) mutation as a marker of clonality. BRAF mutant-specific PCR (MS-PCR) and conventional sequencing were performed on 112 tumors from 73 patients, including patients with matched primary and metastatic specimens (n = 18). Nineteen patients had tissues available from multiple metastatic sites. Mutations were detected in 36/112 (32%) melanomas using conventional sequencing, and 85/112 (76%) using MS-PCR. The better sensitivity of the MS-PCR to detect the mutant BRAF(V600E) allele was not due to the presence of contaminating normal tissue, suggesting that the tumor was comprised of subclones of differing BRAF genotypes. To determine if tumor subclones were present in individual primary melanomas, we performed laser microdissection and mutation detection via sequencing and BRAF(V600E)-specific SNaPshot analysis in 9 cases. Six of these cases demonstrated differing proportions of BRAF(V600E)and BRAF(wild-type) cells in distinct microdissected regions within individual tumors. Additional analyses of multiple metastatic samples from individual patients using the highly sensitive MS-PCR without microdissection revealed that 5/19 (26%) patients had metastases that were discordant for the BRAF(V600E) mutation. In conclusion, we used highly sensitive BRAF mutation detection methods and observed substantial evidence for heterogeneity of the BRAF(V600E) mutation within individual melanoma tumor specimens, and among multiple specimens from individual patients. Given the varied clinical responses of patients to BRAF inhibitor therapy, these data suggest that additional studies to determine possible associations between clinical outcomes and intra- and inter-tumor heterogeneity could prove fruitful.
使用致癌蛋白小分子抑制剂作为癌症治疗方法的基本原理,至少部分依赖于这样一个假设,即转移性肿瘤在突变致癌基因方面主要是克隆的。随着 BRAF(V600E) 作为治疗靶点的出现,我们使用 BRAF(V600E) 突变作为克隆性标志物,研究了黑色素瘤的肿瘤内和肿瘤间异质性。对来自 73 名患者的 112 个肿瘤进行了 BRAF 突变特异性 PCR(MS-PCR)和常规测序,包括具有匹配原发性和转移性标本的患者(n=18)。19 名患者有多个转移部位的组织。使用常规测序检测到 36/112(32%)黑色素瘤存在突变,而使用 MS-PCR 则检测到 85/112(76%)。MS-PCR 检测突变 BRAF(V600E)等位基因的更高敏感性不是由于存在污染的正常组织,这表明肿瘤由不同 BRAF 基因型的亚克隆组成。为了确定肿瘤亚克隆是否存在于单个原发性黑色素瘤中,我们在 9 例中通过测序和 BRAF(V600E)-特异性 SNaPshot 分析进行了激光微切割和突变检测。这 6 例中的 3 例在单个肿瘤的不同微切割区域显示了不同比例的 BRAF(V600E)和 BRAF(野生型)细胞。对来自单个患者的多个转移性样本使用无微切割的高度敏感 MS-PCR 进行的额外分析显示,5/19(26%)患者的转移灶存在 BRAF(V600E)突变不一致的情况。总之,我们使用了高度敏感的 BRAF 突变检测方法,并观察到单个黑色素瘤肿瘤标本内以及来自单个患者的多个标本中 BRAF(V600E)突变存在明显的异质性。鉴于患者对 BRAF 抑制剂治疗的不同临床反应,这些数据表明,进一步研究确定临床结果与肿瘤内和肿瘤间异质性之间可能存在的关联可能会有收获。
