Targeting a Novel Inducible GPX4 Alternative Isoform to Alleviate Ferroptosis and Treat Metabolic-associated Fatty Liver Disease

Overview

Journal Acta Pharm Sin B

Publisher Elsevier

Specialty Pharmacology

Date 2022 Sep 30

PMID 36176906

Authors

Jie Tong

Dongjie Li

Hongbo Meng

Diyang Sun

Xiuting Lan

Min Ni

Jiawei Ma

Feiyan Zeng

Sijia Sun

Jiangtao Fu

Guoqiang Li

Qingxin Ji

Guoyan Zhang

Qirui Shen

Yuanyuan Wang

Jiahui Zhu

Yi Zhao

Xujie Wang

Yi Liu

Shenxi Ouyang

Chunquan Sheng

Fuming Shen

Pei Wang

Affiliations

Soon will be listed here.

Abstract

Metabolic-associated fatty liver disease (MAFLD), which is previously known as non-alcoholic fatty liver disease (NAFLD), represents a major health concern worldwide with limited therapy. Here, we provide evidence that ferroptosis, a novel form of regulated cell death characterized by iron-driven lipid peroxidation, was comprehensively activated in liver tissues from MAFLD patients. The canonical-GPX4 (cGPX4), which is the most important negative controller of ferroptosis, is downregulated at protein but not mRNA level. Interestingly, a non-canonical GPX4 transcript-variant is induced (inducible-GPX4, iGPX4) in MAFLD condition. The high fat-fructose/sucrose diet (HFFD) and methionine/choline-deficient diet (MCD)-induced MAFLD pathologies, including hepatocellular ballooning, steatohepatitis and ﬁbrosis, were attenuated and aggravated, respectively, in cGPX4-and iGPX4-knockin mice. cGPX4 and iGPX4 isoforms also displayed opposing effects on oxidative stress and ferroptosis in hepatocytes. Knockdown of iGPX4 by siRNA alleviated lipid stress, ferroptosis and cell injury. Mechanistically, the triggered iGPX4 interacts with cGPX4 to facilitate the transformation of cGPX4 from enzymatic-active monomer to enzymatic-inactive oligomers upon lipid stress, and thus promotes ferroptosis. Co-immunoprecipitation and nano LC-MS/MS analyses confirmed the interaction between iGPX4 and cGPX4. Our results reveal a detrimental role of non-canonical GPX4 isoform in ferroptosis, and indicate selectively targeting iGPX4 may be a promising therapeutic strategy for MAFLD.

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