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Peroxisome-driven ether-linked phospholipids biosynthesis is essential for ferroptosis

Weiwei Cui, Dong Liu, Wei Gu, Bo Chu

2021Cell Death and Differentiation229 citationsDOIOpen Access PDF

Abstract

It is well established that ferroptosis is primarily induced by peroxidation of long-chain poly-unsaturated fatty acid (PUFA) through nonenzymatic oxidation by free radicals or enzymatic stimulation of lipoxygenase. Although there is emerging evidence that long-chain saturated fatty acid (SFA) might be implicated in ferroptosis, it remains unclear whether and how SFA participates in the process of ferroptosis. Using endogenous metabolites and genome-wide CRISPR screening, we have identified FAR1 as a critical factor for SFA-mediated ferroptosis. FAR1 catalyzes the reduction of C16 or C18 saturated fatty acid to fatty alcohol, which is required for the synthesis of alkyl-ether lipids and plasmalogens. Inactivation of FAR1 diminishes SFA-dependent ferroptosis. Furthermore, FAR1-mediated ferroptosis is dependent on peroxisome-driven ether phospholipid biosynthesis. Strikingly, TMEM189, a newly identified gene which introduces vinyl-ether double bond into alkyl-ether lipids to generate plasmalogens abrogates FAR1-alkyl-ether lipids axis induced ferroptosis. Our study reveals a new FAR1-ether lipids-TMEM189 axis dependent ferroptosis pathway and suggests TMEM189 as a promising druggable target for anticancer therapy.

Topics & Concepts

ChemistryBiochemistryEtherBiosynthesisPhospholipidPlasmalogenFatty acidLipid peroxidationPolyunsaturated fatty acidEnzymeOrganic chemistryMembraneFerroptosis and cancer prognosisRNA modifications and cancerCancer, Lipids, and Metabolism
Peroxisome-driven ether-linked phospholipids biosynthesis is essential for ferroptosis | Litcius