Department of Medicine for Orthopaedics and Motor Organ, Juntendo University Graduate School of Medicine, Tokyo, Japan.
Division of Cellular Signaling, National Cancer Center Research Institute, Tokyo, Japan.
Clin Orthop Relat Res. 2024 Mar 1;482(3):549-563. doi: 10.1097/CORR.0000000000002901. Epub 2023 Nov 28.
Approximately 1% of clinically treatable tyrosine kinase fusions, including anaplastic lymphoma kinase, neurotrophic tyrosine receptor kinase, RET proto-oncogene, and ROS proto-oncogene 1, have been identified in soft tissue sarcomas via comprehensive genome profiling based on DNA sequencing. Histologic tumor-specific fusion genes have been reported in approximately 20% of soft tissue sarcomas; however, unlike tyrosine kinase fusion genes, these fusions cannot be directly targeted in therapy. Approximately 80% of tumor-specific fusion-negative sarcomas, including myxofibrosarcoma and leiomyosarcoma, that are defined in complex karyotype sarcomas remain genetically uncharacterized; this mutually exclusive pattern of mutations suggests that other mutually exclusive driver oncogenes are yet to be discovered. Tumor-specific, fusion-negative sarcomas may be associated with unique translocations, and oncogenic fusion genes, including tyrosine kinase fusions, may have been overlooked in these sarcomas.
QUESTIONS/PURPOSES: (1) Can DNA- or RNA-based analysis reveal any characteristic gene alterations in bone and soft tissue sarcomas? (2) Can useful and potential tyrosine kinase fusions in tumors from tumor-specific, fusion-negative sarcomas be detected using an RNA-based screening system? (3) Do the identified potential fusion tumors, especially in neurotrophic tyrosine receptor kinase gene fusions in bone sarcoma, transform cells and respond to targeted drug treatment in in vitro assays? (4) Can the identified tyrosine kinase fusion genes in sarcomas be useful therapeutic targets?
Between 2017 and 2020, we treated 100 patients for bone and soft tissue sarcomas at five institutions. Any biopsy or surgery from which a specimen could be obtained was included as potentially eligible. Ninety percent (90 patients) of patients were eligible; a further 8% (8 patients) were excluded because they were either lost to follow-up or their diagnosis was changed, leaving 82% (82 patients) for analysis here. To answer our first and second questions regarding gene alterations and potential tyrosine kinase fusions in eight bone and 74 soft tissue sarcomas, we used the TruSight Tumor 170 assay to detect mutations, copy number variations, and gene fusions in the samples. To answer our third question, we performed functional analyses involving in vitro assays to determine whether the identified tyrosine kinase fusions were associated with oncogenic abilities and drug responses. Finally, to determine usefulness as therapeutic targets, two pediatric patients harboring an NTRK fusion and an ALK fusion were treated with tyrosine kinase inhibitors in clinical trials.
DNA/RNA-based analysis demonstrated characteristic alterations in bone and soft tissue sarcomas; DNA-based analyses detected TP53 and copy number alterations of MDM2 and CDK4 . These single-nucleotide variants and copy number variations were enriched in specific fusion-negative sarcomas. RNA-based screening detected fusion genes in 24% (20 of 82) of patients. Useful potential fusions were detected in 19% (11 of 58) of tumor-specific fusion-negative sarcomas, with nine of these patients harboring tyrosine kinase fusion genes; five of these patients had in-frame tyrosine kinase fusion genes ( STRN3-NTRK3, VWC2-EGFR, ICK-KDR, FOXP2-MET , and CEP290-MET ) with unknown pathologic significance. The functional analysis revealed that STRN3-NTRK3 rearrangement that was identified in bone had a strong transforming potential in 3T3 cells, and that STRN3-NTRK3 -positive cells were sensitive to larotrectinib in vitro. To confirm the usefulness of identified tyrosine kinase fusion genes as therapeutic targets, patients with well-characterized LMNA-NTRK1 and CLTC-ALK fusions were treated with tyrosine kinase inhibitors in clinical trials, and a complete response was achieved.
We identified useful potential therapeutic targets for tyrosine kinase fusions in bone and soft tissue sarcomas using RNA-based analysis. We successfully identified STRN3-NTRK3 fusion in a patient with leiomyosarcoma of bone and determined the malignant potential of this fusion gene via functional analyses and drug effects. In light of these discoveries, comprehensive genome profiling should be considered even if the sarcoma is a bone sarcoma. There seem to be some limitations regarding current DNA-based comprehensive genome profiling tests, and it is important to use RNA testing for proper diagnosis and accurate identification of fusion genes. Studies on more patients, validation of results, and further functional analysis of unknown tyrosine kinase fusion genes are required to establish future treatments.
DNA- and RNA-based screening systems may be useful for detecting tyrosine kinase fusion genes in specific fusion-negative sarcomas and identifying key therapeutic targets, leading to possible breakthroughs in the treatment of bone and soft tissue sarcomas. Given that current DNA sequencing misses fusion genes, RNA-based screening systems should be widely considered as a worldwide test for sarcoma. If standard treatments such as chemotherapy are not effective, or even if the sarcoma is of bone, RNA sequencing should be considered to identify as many therapeutic targets as possible.
通过基于 DNA 测序的全面基因组分析,在软组织肉瘤中发现了约 1%的可临床治疗的酪氨酸激酶融合,包括间变性淋巴瘤激酶、神经营养性酪氨酸受体激酶、RET 原癌基因和 ROS 原癌基因 1。在大约 20%的软组织肉瘤中已经报道了组织特异性融合基因;然而,与酪氨酸激酶融合基因不同,这些融合不能直接作为治疗靶点。大约 80%的组织特异性融合阴性肉瘤,包括黏液纤维肉瘤和平滑肌肉瘤,在复杂核型肉瘤中定义为遗传上未被表征的;这种相互排斥的突变模式表明,其他相互排斥的驱动致癌基因尚未被发现。组织特异性、融合阴性肉瘤可能与独特的易位有关,而包括酪氨酸激酶融合在内的致癌融合基因可能在这些肉瘤中被忽视。
问题/目的:(1)基于 DNA 或 RNA 的分析能否揭示骨和软组织肉瘤中任何特征性的基因改变?(2)能否使用基于 RNA 的筛选系统检测到肿瘤特异性、融合阴性肉瘤中的有用和潜在的酪氨酸激酶融合?(3)所鉴定的潜在融合肿瘤,特别是骨肉瘤中的神经营养性酪氨酸受体激酶基因融合,是否能在体外实验中转化细胞并对靶向药物治疗有反应?(4)肉瘤中鉴定的酪氨酸激酶融合基因能否作为有用的治疗靶点?
在 2017 年至 2020 年间,我们在五家机构治疗了 100 名患有骨和软组织肉瘤的患者。纳入了任何可以获得标本的活检或手术。90%(90 名)的患者符合条件;另外 8%(8 名)因失访或诊断改变而被排除在外,剩下 82%(82 名)用于这里的分析。为了回答我们关于八种骨肉瘤和 74 种软组织肉瘤中的基因改变和潜在酪氨酸激酶融合的第一个和第二个问题,我们使用 TruSight Tumor 170 检测来检测样本中的突变、拷贝数变异和基因融合。为了回答我们的第三个问题,我们进行了体外实验的功能分析,以确定所鉴定的酪氨酸激酶融合是否与致癌能力和药物反应有关。最后,为了确定作为治疗靶点的有用性,两名患有 NTRK 融合和 ALK 融合的儿科患者在临床试验中接受了酪氨酸激酶抑制剂治疗。
DNA/RNA 分析显示骨和软组织肉瘤具有特征性改变;DNA 分析检测到 TP53 和 MDM2 和 CDK4 的拷贝数改变。这些单核苷酸变异和拷贝数变化在特定的融合阴性肉瘤中富集。RNA 筛选在 24%(82 名患者中的 20 名)的患者中检测到融合基因。在 19%(58 名肿瘤特异性融合阴性肉瘤中的 11 名)的患者中检测到有用的潜在融合,其中 9 名患者携带酪氨酸激酶融合基因;其中 5 名患者携带框内酪氨酸激酶融合基因(STRN3-NTRK3、VWC2-EGFR、ICK-KDR、FOXP2-MET 和 CEP290-MET),其病理意义未知。功能分析显示,在骨中鉴定的 STRN3-NTRK3 重排具有很强的转化潜能,STRN3-NTRK3 阳性细胞对 larotrectinib 有反应。为了证实鉴定的酪氨酸激酶融合基因作为治疗靶点的有用性,两名具有明确 LMNA-NTRK1 和 CLTC-ALK 融合的患者在临床试验中接受了酪氨酸激酶抑制剂治疗,取得了完全缓解。
我们使用 RNA 分析在骨和软组织肉瘤中鉴定了有用的潜在治疗性酪氨酸激酶融合靶点。我们成功地在一名骨平滑肌肉瘤患者中鉴定了 STRN3-NTRK3 融合,并通过功能分析和药物作用确定了该融合基因的恶性潜能。鉴于这些发现,即使肉瘤是骨肉瘤,也应考虑进行全面的基因组分析。目前的基于 DNA 的全面基因组分析测试似乎存在一些局限性,使用 RNA 测试对于正确诊断和准确鉴定融合基因非常重要。需要对更多的患者进行研究,验证结果,并进一步对未知的酪氨酸激酶融合基因进行功能分析,以建立未来的治疗方法。
DNA 和 RNA 筛查系统可能有助于检测特定融合阴性肉瘤中的酪氨酸激酶融合基因,并确定关键的治疗靶点,从而为骨和软组织肉瘤的治疗带来突破。鉴于目前的 DNA 测序可能会错过融合基因,RNA 筛查系统应作为一种全球测试被广泛考虑用于肉瘤。如果标准治疗如化疗无效,或者即使肉瘤是骨肉瘤,也应考虑进行 RNA 测序,以尽可能多地鉴定治疗靶点。
