细胞生物学
细胞外基质
肿瘤微环境
免疫系统
归巢(生物学)
细胞外
免疫
体内
树突状细胞
趋化性
生物
化学
淋巴
机制(生物学)
胞外囊泡
微泡
肌球蛋白
免疫疗法
获得性免疫系统
细胞迁移
癌症研究
神经科学
趋化因子
内吞作用
淋巴结
肿瘤细胞
效应器
外体
细胞外小泡
作者
Qiangyuan Zhu,Shenglan Liu,Lei Chen,Xin Wang,Jiayi Liu,Cen Gao,Rongbing Tang
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-02-04
卷期号:12 (6): eaeb7714-eaeb7714
被引量:1
标识
DOI:10.1126/sciadv.aeb7714
摘要
Mechanical stimuli originating from extracellular matrix have been proved to affect antitumor immunity by regulating dendritic cell (DC) locomotion. However, the immunological consequences of ultrasmall bioparticle–induced nanocollision remain largely an unexplored realm despite its ubiquitous and incessant occurrence within the in vivo milieu. Herein, we disclose that nanocollisions caused by endogenous bioparticles, such as extracellular vesicles, can induce localized membrane deformations. This spatially confined mechanical input activates Piezo1 at collision sites and promotes myosin IIA phosphorylation–mediated F-actin stabilization, enhancing DC intrinsic motility. Subsequent diffusion of Ca 2+ up-regulates chemotaxis machinery, improving their capacity of tumor microenvironment patrolling and lymph node homing for antitumor immunity. This finding reveals a previously unidentified mechanoimmunological mechanism of immune surveillance. To accelerate the translation of this mechanism into clinical therapeutics, we developed an ultrasound-responsive nanocollision generator using gas-liquid-solid triphase conversion. This system achieves precise nanocollision to augment DC locomotion, promoting antitumor immunity in vivo.
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