生物
多发性骨髓瘤
癌症研究
造血
干细胞
等离子体电池
谱系(遗传)
B细胞
恶性转化
细胞分化
细胞
免疫学
骨髓
造血干细胞
淋巴细胞生成
克隆(Java方法)
细胞生物学
体细胞
髓样
细胞培养
细胞生长
T细胞
川地34
体外
作者
Jiaojiao Guo,Yaru Li,Zhiling Yan,Qing Li,Zhenhao Liu,Zhengjiang Li,Ruiqi Zhou,Nihan He,YingHong Zhu,Xiaoshuang Wang,Xun Chen,Yi Qiu,Liang Zhao,Fangming Shi,Yanjuan He,Sha Hao,Jia Yu,Lu Xie,Jiaxi Zhou,Jian Li
标识
DOI:10.1126/scitranslmed.adu0114
摘要
The initiation and progression of multiple myeloma (MM) are intricate processes, and a critical challenge lies in understanding the mechanisms of malignant transformation in MM-initiating cells (MICs) and their driver genes. In this study, we used single-cell sequencing and genetic tracer analysis at each developmental stage, from hematopoietic stem cells to lymphoid lineage differentiation, to identify abnormal differentiation stages in patients with MM. We found that chromosome 1q amplification (1q Amp ) originated from a specific subgroup of B cells, whereas chromosome 17p deletion occurred at the plasma cell stage. 1q Amp was present in CD24 − FCRL5 + B cell subgroups and initiated B cell transformation into malignant plasma cells by enhancing B cell proliferation and promoting plasma cell differentiation in vitro and in vivo. FCRL5 facilitated B cell differentiation into malignant plasma cells through its interaction with the IRF4/SPI1 complex. The use of targeted FCRL5 CAR T cells in patients with relapsed or refractory MM (RRMM) showed promising safety and efficacy. Together, our work identified genetic events linked to the initiation and malignant transformation of MM along the B cell lineage. These findings form the foundation for identifying potential therapeutic strategies for patients with RRMM by targeting MICs and their driving oncogenes.
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