Division of Hematology, Department of Translational Medicine, University of Eastern Piedmont, Novara, Italy.
Division of Hematology, Institute of Oncology Research, Oncology Institute of Southern Switzerland, Bellinzona, Switzerland.
Blood. 2017 Apr 6;129(14):1947-1957. doi: 10.1182/blood-2016-05-719641. Epub 2017 Jan 17.
Accessible and real-time genotyping for diagnostic, prognostic, or treatment purposes is increasingly impelling in diffuse large B-cell lymphoma (DLBCL). Cell-free DNA (cfDNA) is shed into the blood by tumor cells undergoing apoptosis and can be used as source of tumor DNA for the identification of DLBCL mutations, clonal evolution, and genetic mechanisms of resistance. In this study, we aimed at tracking the basal DLBCL genetic profile and its modification upon treatment using plasma cfDNA. Ultra-deep targeted next generation sequencing of pretreatment plasma cfDNA from DLBCL patients correctly discovered DLBCL-associated mutations that were represented in >20% of the alleles of the tumor biopsy with >90% sensitivity and ∼100% specificity. Plasma cfDNA genotyping also allowed for the recovery of mutations that were undetectable in the tissue biopsy, conceivably because, due to spatial tumor heterogeneity, they were restricted to clones that were anatomically distant from the biopsy site. Longitudinal analysis of plasma samples collected under rituximab-cyclophosphamide-doxorubicin-vincristine-prednisone (R-CHOP) chemotherapy showed a rapid clearance of DLBCL mutations from cfDNA among responding patients. Conversely, among patients who were resistant to R-CHOP, basal DLBCL mutations did not disappear from cfDNA. In addition, among treatment-resistant patients, new mutations were acquired in cfDNA that marked resistant clones selected during the clonal evolution. These results demonstrate that cfDNA genotyping of DLBCL is as accurate as genotyping of the diagnostic biopsy to detect clonally represented somatic tumor mutations and is a real-time and noninvasive approach to tracking clonal evolution and the emergence of treatment-resistant clones.
为了诊断、预后或治疗目的,能够方便且实时地进行基因分型在弥漫性大 B 细胞淋巴瘤(DLBCL)中变得越来越重要。处于凋亡状态的肿瘤细胞会将无细胞 DNA(cfDNA)释放到血液中,可用作鉴定 DLBCL 突变、克隆进化和耐药遗传机制的肿瘤 DNA 来源。在这项研究中,我们旨在使用血浆 cfDNA 追踪基础 DLBCL 遗传特征及其治疗后的变化。对 DLBCL 患者治疗前血浆 cfDNA 进行超深度靶向下一代测序,正确发现了与 DLBCL 相关的突变,这些突变在肿瘤活检的等位基因中代表 >20%,具有 >90%的灵敏度和 ∼100%的特异性。cfDNA 基因分型还可以恢复组织活检中无法检测到的突变,这可能是因为由于空间肿瘤异质性,它们仅限于与活检部位在解剖学上相距较远的克隆。在利妥昔单抗-环磷酰胺-多柔比星-长春新碱-泼尼松(R-CHOP)化疗下收集的血浆样本的纵向分析显示,在有反应的患者中,cfDNA 中 DLBCL 突变迅速清除。相反,在对 R-CHOP 耐药的患者中,cfDNA 中的基础 DLBCL 突变并未消失。此外,在耐药患者中,cfDNA 中获得了新的突变,这些突变标记了在克隆进化过程中选择的耐药克隆。这些结果表明,cfDNA 对 DLBCL 的基因分型与诊断性活检的基因分型一样准确,可以检测到克隆性肿瘤突变,并且是实时、非侵入性的方法,可以追踪克隆进化和耐药克隆的出现。
