FLNA公司
菲拉明
荚体
破骨细胞
细胞生物学
骨吸收
化学
癌症研究
下调和上调
信号转导
骨髓
间质细胞
生物
细胞迁移
整合素
细胞分化
HEK 293细胞
蛋白酶体
双膦酸盐
骨细胞
电池类型
表型
MAPK/ERK通路
细胞内
跨细胞
免疫学
细胞培养中氨基酸的稳定同位素标记
骨质疏松症
骨重建
作者
Jing Guo,Jingjing Wang,Ying Xie,Yixuan Wang,Ziyi Peng,Mengdi Wang,Hao Cheng,Tiantian Li,Linchuang Jia,Hongwei Xu,D Su,Mu Qiao,Huan Liu,Keqing Li,Wenjing Li,Di Wu,Jianyong Huang,P. Leif Bergsagel,F. Li,Zhigang Zhao
出处
期刊:Blood
[Elsevier BV]
日期:2026-04-08
标识
DOI:10.1182/blood.2025031627
摘要
Intercellular communications between multiple myeloma (MM) cells and osteoclast precursor cells (pre-OCs) contribute extensively to the occurrence and development of myeloma-related bone destruction. However, key interacting modes and the substances exchanged involved in this communication remain unclear. In this study, we discover that tunnelling nanotubes (TNT) directly connect MM and pre-OCs. Using stable isotope labeling with amino acids in cell culture (SILAC) assay and a positive-negative double selection strategy, we identify Filamin-A (FLNA) as a major protein transported from MM to pre-OCs. FLNA acts as a molecular clutch linking ECM-bound MAC1 to the cytoskeleton, activating Rho and MAPK signaling pathways and promoting F-actin polymerization, which subsequently enhances osteoclast differentiation by modulating cellular stiffness, traction force, and deformability. Additionally, FLNA directly binds vinculin and promotes its recruitment to podosome, thereby enhancing functions of podosome and bone resorption capacity of osteoclasts. Conditional depletion of Flna in mice suppresses podosome activity and reduces stiffness, traction force, and deformability in pre-OCs, leading to significantly impaired osteoclast differentiation and increased bone mass. In the Vk*MYC mouse model of myeloma, administration of the TNT inhibitor Latrunculin B disrupts FLNA transport to osteoclasts and alleviates osteolytic bone disease. These findings highlight the critical role of MM-transferred FLNA in osteoclastogenesis and suggest that targeting TNTs may represent a therapeutic strategy to limit pathological bone resorption associated with multiple myeloma.
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