溶酶体
代谢组学
化学
细胞生物学
代谢组
电生理学
生物化学
运输机
质谱法
自噬
生物
酶
神经科学
色谱法
基因
细胞凋亡
作者
Hongying Zhu,Qianqian Li,Tiepeng Liao,Xiang Yin,Qi Chen,Sheng Wang,Meifang Dai,Lin Yi,Si-Yuan Ge,Chenjian Miao,Wenping Zeng,Lili Qu,Zhenyu Ju,Guangming Huang,Chunlei Cang,Wei Xiong
出处
期刊:Nature Methods
[Springer Nature]
日期:2021-06-14
卷期号:18 (7): 788-798
被引量:61
标识
DOI:10.1038/s41592-021-01182-8
摘要
Lysosomes are critical for cellular metabolism and are heterogeneously involved in various cellular processes. The ability to measure lysosomal metabolic heterogeneity is essential for understanding their physiological roles. We therefore built a single-lysosome mass spectrometry (SLMS) platform integrating lysosomal patch-clamp recording and induced nano-electrospray ionization (nanoESI)/mass spectrometry (MS) that enables concurrent metabolic and electrophysiological profiling of individual enlarged lysosomes. The accuracy and reliability of this technique were validated by supporting previous findings, such as the transportability of lysosomal cationic amino acids transporters such as PQLC2 and the lysosomal trapping of lysosomotropic, hydrophobic weak base drugs such as lidocaine. We derived metabolites from single lysosomes in various cell types and classified lysosomes into five major subpopulations based on their chemical and biological divergence. Senescence and carcinoma altered metabolic profiles of lysosomes in a type-specific manner. Thus, SLMS can open more avenues for investigating heterogeneous lysosomal metabolic changes during physiological and pathological processes.
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