骨髓增生异常综合征及相关疾病治疗中的基因组测序。

IF 8.2 1区 医学 Q1 HEMATOLOGY
Mario Cazzola,Luca Malcovati
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引用次数: 0

摘要

髓系肿瘤起源于造血干细胞的克隆性增殖,其驱动力来自体细胞基因突变。在这些疾病中,骨髓增生异常综合征(MDS)的具体特征是形态异常(发育不良)和骨髓前体成熟受损(无效造血),导致外周血全血细胞减少。有几项研究推动了 MDS 领域的发展,其中几篇具有里程碑意义的论文导致了范式的转变,开辟了新的研究途径,促成了一场分子革命。这些开创性论文包括首次描述 5q- 综合征、确定骨髓肿瘤中 TET2 的体细胞突变、检测剪接机制中的常见通路突变以及发现克隆造血。目前,MDS 的体细胞基因组图谱已经明确。反复发生突变的基因包括表观遗传调控因子、RNA剪接机制基因、转录调控基因、DNA修复调控基因、粘合素复合物基因和信号转导基因。此外,还发现了几种具有MDS种系遗传易感性的疾病,它们合起来占所有MDS病例的15%。基因组图谱分析可大大改进 MDS 的诊断方法,从而确定不同的病理实体,如 SF3B1 突变或 TP53 突变 MDS。事实证明,MDS 分子国际预后评分系统(IPSS-M)是个体化风险评估和治疗决策的重要工具。此外,最近开发的 MDS 分子分类法可能会促进针对这些疾病的精准医疗方法的实施。这将需要在公共卫生系统内建立专门的基础设施,涉及医疗机构、学术界和生命科学行业之间的密切合作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Genome sequencing in the management of myelodysplastic syndromes and related disorders.
Myeloid neoplasms originate from the clonal proliferation of hematopoietic stem cells, which is driven by the acquisition of somatic genetic mutations. Within these disorders, myelodysplastic syndromes (MDS) are specifically characterized by morphologic abnormalities (dysplasia) and impaired maturation of myeloid precursors (ineffective hematopoiesis), resulting in peripheral blood cytopenia. Several studies have advanced the field of MDS, with a few landmark papers leading to a paradigm shift, opening new avenues of research and enabling a molecular revolution. These seminal papers include the first description of the 5q- syndrome, the identification of somatic mutations of TET2 in myeloid neoplasms, the detection of common pathway mutations in the splicing machinery, and the discovery of clonal hematopoiesis. The somatic genomic landscape of MDS is now well-defined. Genes that are recurrently mutated include epigenetic regulators, as well as genes of RNA splicing machinery, transcription regulation, DNA repair control, cohesin complex, and signal transduction. Furthermore, several disorders with a germline genetic predisposition to MDS have been identified, collectively accounting for up to 15% of all MDS cases. Genomic profiling can significantly improve the diagnostic approach to MDS, allowing the identification of distinct nosologic entities such as SF3B1-mutant or TP53-mutant MDS. The Molecular International Prognostic Scoring System for MDS (IPSS-M) has already proven to be a valuable tool for individualized risk assessment and treatment decisions. In addition, the recently developed molecular taxonomy of MDS will likely facilitate the implementation of precision medicine approaches for these disorders. This will necessitate the establishment of specialized infrastructures within public health systems, involving close collaboration between healthcare institutions, academia, and the life sciences industry.
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来源期刊
Haematologica
Haematologica 医学-血液学
CiteScore
14.10
自引率
2.00%
发文量
349
审稿时长
3-6 weeks
期刊介绍: Haematologica is a journal that publishes articles within the broad field of hematology. It reports on novel findings in basic, clinical, and translational research. Scope: The scope of the journal includes reporting novel research results that: Have a significant impact on understanding normal hematology or the development of hematological diseases. Are likely to bring important changes to the diagnosis or treatment of hematological diseases.
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