Department of Oncology, The Sidney Kimmel Comprehensive Cancer Center, The Johns Hopkins Hospital, Baltimore, MD, USA.
Center for Personalized Cancer Therapy and Division of Hematology and Oncology, Department of Medicine, UC San Diego Moores Cancer Center, La Jolla, CA, USA.
Cancer Treat Rev. 2024 Apr;125:102721. doi: 10.1016/j.ctrv.2024.102721. Epub 2024 Mar 21.
Cancer is traditionally diagnosed and treated on the basis of its organ of origin (e.g., lung or colon cancer). However, organ-of-origin diagnostics does not reveal the underlying oncogenic drivers. Fortunately, molecular diagnostics have advanced at a breathtaking pace, and it is increasingly apparent that cancer is a disease of the genome. Hence, we now have multiple genomic biomarker-based, tissue-agnostic Food and Drug Administration approvals for both gene- and immune-targeted therapies (larotrectinib/entrectinib, for NTRK fusions; selpercatinib, RET fusions; dabrafenib plus trametinib, BRAF mutations; pembrolizumab/dostarlimab, microsatellite instability; and pembrolizumab for high tumor mutational burden; pemigatinib is also approved for FGFR1-rearranged myeloid/lymphoid neoplasms). There are emerging targets as well, including but not limited to ALK, BRCA and/or homologous repair deficiency, ERBB2 (HER2), IDH1/2, KIT, KRAS, NRG1, and VHL. Many tissue-agnostic approvals center on rare/ultra-rare biomarkers (often < 1 % of cancers), necessitating screening hundreds of tumors to find a single one harboring the cognate molecular alteration. Approval has generally been based on small single-arm studies (<30-100 patients) with high response rates (>30 % to > 75 %) of remarkable durability. Because of biomarker rarity, single-gene testing is not practical; next generation sequencing of hundreds of genes must be performed to obtain timely answers. Resistance to biomarker-driven therapeutics is often due to secondary mutations or co-driver gene defects; studies are now addressing the need for customized drug combinations matched to the complex molecular alteration portfolio in each tumor. Future investigation should expand tissue-agnostic therapeutics to encompass both hematologic and solid malignancies and include biomarkers beyond those that are DNA-based.
癌症传统上是根据其起源器官(例如肺癌或结肠癌)进行诊断和治疗的。然而,起源器官的诊断并不能揭示潜在的致癌驱动因素。幸运的是,分子诊断技术已经取得了惊人的进展,越来越明显的是,癌症是一种基因组疾病。因此,我们现在有多个基于基因组生物标志物的、与组织无关的美国食品和药物管理局批准的基因和免疫靶向治疗药物(larotrectinib/entrectinib,用于 NTRK 融合;selpercatinib,用于 RET 融合;dabrafenib 加 trametinib,用于 BRAF 突变;pembrolizumab/dostarlimab,用于微卫星不稳定;pembrolizumab 用于高肿瘤突变负担;pemigatinib 也批准用于 FGFR1 重排的髓系/淋巴肿瘤)。也有新出现的靶点,包括但不限于 ALK、BRCA 和/或同源修复缺陷、ERBB2(HER2)、IDH1/2、KIT、KRAS、NRG1 和 VHL。许多与组织无关的批准都集中在罕见/超罕见的生物标志物(通常<1%的癌症)上,需要筛选数百个肿瘤才能找到一个携带同源分子改变的肿瘤。批准通常基于小型单臂研究(<30-100 例患者),具有高缓解率(>30%至>75%)和显著的持久性。由于生物标志物的稀有性,单基因检测是不切实际的;必须对数百个基因进行下一代测序,以获得及时的答案。对生物标志物驱动的治疗的耐药性通常是由于继发突变或共驱动基因缺陷所致;目前的研究正在解决根据每个肿瘤复杂的分子改变组合定制匹配的药物联合治疗的需求。未来的研究应该将与组织无关的治疗方法扩展到涵盖血液系统和实体恶性肿瘤,并包括超越基于 DNA 的生物标志物。
