Department of Pathology, Memorial Sloan Kettering Cancer Center, New York, NY, 10065, USA.
Department of Medicine, Memorial Sloan Kettering Cancer Center, New York, NY, 10065, USA.
Mod Pathol. 2020 Jan;33(1):38-46. doi: 10.1038/s41379-019-0324-7. Epub 2019 Aug 2.
With the FDA approval of larotrectinib, NTRK fusion assessment has recently become a standard part of management for patients with locally advanced or metastatic cancers. Unlike somatic mutation assessment, the detection of NTRK fusions is not straightforward, and various assays exist at the DNA, RNA, and protein level. Here, we investigate the performance of immunohistochemistry and DNA-based next-generation sequencing to indirectly or directly detect NTRK fusions relative to an RNA-based next-generation sequencing approach in the largest cohort of NTRK fusion positive solid tumors to date. A retrospective analysis of 38,095 samples from 33,997 patients sequenced by a targeted DNA-based next-generation sequencing panel (MSK-IMPACT), 2189 of which were also examined by an RNA-based sequencing assay (MSK-Fusion), identified 87 patients with oncogenic NTRK1-3 fusions. All available institutional NTRK fusion positive cases were assessed by pan-Trk immunohistochemistry along with a cohort of control cases negative for NTRK fusions by next-generation sequencing. DNA-based sequencing showed an overall sensitivity and specificity of 81.1% and 99.9%, respectively, for the detection of NTRK fusions when compared to RNA-based sequencing. False negatives occurred when fusions involved breakpoints not covered by the assay. Immunohistochemistry showed overall sensitivity of 87.9% and specificity of 81.1%, with high sensitivity for NTRK1 (96%) and NTRK2 (100%) fusions and lower sensitivity for NTRK3 fusions (79%). Specificity was 100% for carcinomas of the colon, lung, thyroid, pancreas, and biliary tract. Decreased specificity was seen in breast and salivary gland carcinomas (82% and 52%, respectively), and positive staining was often seen in tumors with neural differentiation. Both sensitivity and specificity were poor in sarcomas. Selection of the appropriate assay for NTRK fusion detection therefore depends on tumor type and genes involved, as well as consideration of other factors such as available material, accessibility of various clinical assays, and whether comprehensive genomic testing is needed concurrently.
随着拉罗替尼(larotrectinib)获得美国食品药品监督管理局(FDA)批准,NTRK 融合评估最近已成为局部晚期或转移性癌症患者管理的标准部分。与体细胞突变评估不同,NTRK 融合的检测并不简单,并且在 DNA、RNA 和蛋白质水平上存在各种检测方法。在这里,我们研究了免疫组织化学和基于 DNA 的下一代测序相对于迄今为止最大的 NTRK 融合阳性实体瘤的 RNA 为基础的下一代测序方法,以间接或直接检测 NTRK 融合的性能。对通过靶向 DNA 为基础的下一代测序面板(MSK-IMPACT)对 33997 名患者中的 38095 个样本进行的回顾性分析中,其中 2189 个样本还通过 RNA 为基础的测序检测(MSK-Fusion)进行了检查,确定了 87 例具有致癌性 NTRK1-3 融合的患者。所有可用的机构 NTRK 融合阳性病例均通过泛 Trk 免疫组织化学进行评估,并对一组通过下一代测序为阴性的 NTRK 融合对照病例进行评估。与基于 RNA 的测序相比,DNA 为基础的测序显示出检测 NTRK 融合的总体敏感性和特异性分别为 81.1%和 99.9%。当融合涉及未被检测到的检测点时,会出现假阴性。免疫组织化学显示出 87.9%的总体敏感性和 81.1%的特异性,NTRK1(96%)和 NTRK2(100%)融合的敏感性较高,而 NTRK3 融合的敏感性较低(79%)。对于结直肠癌、肺癌、甲状腺癌、胰腺癌和胆管癌,特异性为 100%。在乳腺癌和唾液腺癌中特异性降低(分别为 82%和 52%),并且在具有神经分化的肿瘤中经常看到阳性染色。肉瘤的敏感性和特异性都很差。因此,选择用于 NTRK 融合检测的适当检测方法取决于肿瘤类型和涉及的基因,以及其他因素的考虑,例如可用材料、各种临床检测方法的可及性以及是否需要同时进行全面的基因组测试。
