基因传递
间充质干细胞
细胞生物学
遗传增强
微泡
转染
干细胞
生物
细胞外小泡
胞外囊泡
基因靶向
小泡
细胞
基因
电穿孔
小RNA
基因表达
化学
内吞作用
再生医学
细胞培养
病毒载体
计算生物学
细胞疗法
核糖核酸
单元格排序
基因表达调控
再生(生物学)
组织工程
外体
细胞分化
体外
电池类型
重组DNA
DNA
作者
Yue Su,Zaiyong An,Daopin Wu,Di Mu,Yaxuan Liang
摘要
Mesenchymal stem cell (MSC)-derived extracellular vesicles (EVs) hold great promise for therapeutic applications and regenerative medicine. EVs are nanoscale vesicles secreted by all known cell types, carrying diverse cargos including membrane-anchored proteins, soluble factors, multiple RNA species, and metabolites that regulate the physiology and behavior of recipient cells. While MSC-derived or engineered EVs can deliver therapeutic proteins and RNAs, EV-mediated DNA delivery remains challenging due to the lack of efficient mechanisms for sorting DNA sequences into vesicles. Previous work from our group and others demonstrated that adeno-associated virus (AAV)-containing EVs enable targeted nuclear delivery and sustained gene expression in vitro and in vivo. However, their production and isolation have been limited by low yield and time-intensive procedures. Here, we report the development of MSC membrane-enveloped nanovesicles generated by a size-defined extrusion method for efficient gene delivery. These vesicles, approximately 200 nm in diameter, mimic the properties of natural EVs while encapsulating recombinant AAV vectors carrying therapeutic gene sequences. Compared with conventional AAVs, the engineered MSC vesicles improved gene delivery efficiency and achieved significantly higher yields with reduced time and cost relative to naturally secreted EV-AAVs. In summary, we present a novel MSC-based membrane nanovesicle platform that combines the advantages of EV-mimicking structures with AAV-mediated gene transfer. This approach enhances delivery efficiency and production scalability, offering a promising strategy to advance gene therapy toward clinical translation.
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