脂滴
脂肪变性
化学
线粒体
细胞器
磷酸化
细胞生物学
肝细胞
调解人
脂质代谢
脂毒性
联轴节(管道)
β氧化
焊剂(冶金)
生物化学
内科学
内分泌学
非酒精性脂肪肝
脂肪肝
生物发生
鞘脂
脂肪酸
蛋白质组学
生物物理学
氧化磷酸化
生物
脂质氧化
自噬
营养感应
作者
Sun Woo Sophie Kang,Lauryn A. Brown,Colin B. Miller,Katherine M Barrows,Jihye L. Golino,Hanyang Liu,Constance M. Cultraro,Daniel Feliciano,Mercedes B. Cornelius-Muwanuzi,Kirsten Remmert,Jonathan M. Hernandez,Andy D. Tran,Michael J. Kruhlak,Alexei Lobanov,Maggie Cam,Natalie Porat-Shliom
标识
DOI:10.1038/s42255-026-01476-1
摘要
Steatotic liver disease is common, yet the mechanisms by which hepatocytes cope with surges in dietary fatty acids remain unclear. Here we use single-cell tissue imaging (scPhenomics) and spatial proteomics to map lipid handling across dietary states. Fasting remodeled mitochondria and lipid droplets (LDs), increasing mitochondria-LD contacts, whereas contacts were infrequent in Western diet (WD)-fed male mice. Fasting also elevated perilipin-5 (PLIN5), a mediator of mitochondria-LD tethering. PLIN5 overexpression modulated contact formation in a phosphorylation-dependent manner: the S155A variant enhanced organelle contacts and LD expansion, whereas the S155E variant reduced contacts and yielded fewer, smaller LDs. Overexpression of the S155A variant in WD reduced lipotoxicity. These data reveal an adaptive organelle-interaction program that channels lipids during nutrient stress and is attenuated by an obesogenic diet. Our work establishes scPhenomics for spatially resolved cell-state analysis and identifies PLIN5 phosphorylation as a lever to tune hepatocyte lipid flux, suggesting therapeutic potential for targeting mitochondria-LD coupling.
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