生物发生
细胞生物学
酿酒酵母
ESCRT公司
小泡
胞外囊泡
微泡
生物
细胞外
细胞内
拉布
酵母
囊泡转运蛋白
转运蛋白
跨膜蛋白
定量蛋白质组学
化学
膜泡运输蛋白质类
膜蛋白
胞吐
细胞器生物发生
蛋白质组学
外体
生物化学
细胞室
细胞膜
细胞器
内体
膜转运
细胞
内吞作用
TSG101型
蛋白质聚集
细胞培养中氨基酸的稳定同位素标记
作者
Yueyan Li,XiaoRan Ma,Lichao Zhang,Lichao Zhang,Ning Cao,Z. J. Li,Ruixin Khoo,Mei Wang,Changyan Li,Deping Hua,Xintian Zheng,Jinhai Huang,Lilin Zhang,Lilin Zhang
标识
DOI:10.1111/1751-7915.70338
摘要
Extracellular vesicles (EVs) are emerging as versatile therapeutic platforms, yet the mechanisms governing their biogenesis in yeast remain incompletely understood. Saccharomyces cerevisiae, a well-characterised and safe microbial chassis, naturally secretes abundant EVs and provides an attractive system for mechanistic dissection and engineering. Here, we establish S. cerevisiae as a tractable model for elucidating EV cargo loading. By combining multicopy expression of chicken interferon-λ (ChiIFN-λ) with cell wall perturbation, we achieved a tenfold increase in EV yield and efficient incorporation of ChiIFN-λ into EVs. Quantitative proteomics identified 1555 EV-associated proteins, including 501 predicted transmembrane proteins derived from multiple organelles. ChiIFN-λ overexpression and cell wall stress selectively reduced the abundance of key vesicle trafficking regulators, including SNARE, ESCRT and Rab proteins, indicating reprogramming of intracellular membrane trafficking pathways. Functional analyses further demonstrated that the SNARE proteins Sso2 and Nyv1 are enriched in the EV membrane and modulate EV size distribution and subpopulation composition. Together, these results reveal conserved protein-sorting machinery underlying yeast-derived extracellular vesicles (YDEVs) biogenesis and establish S. cerevisiae as a powerful platform for engineered EV production.
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