Ferroptosis is an iron-dependent form of necrotic cell death marked by oxidative damage to phospholipids 1,2. To date, ferroptosis has been believed to be restrained only by the phospholipid hydroperoxide (PLOOH)-reducing enzyme glutathione peroxidase 4 (GPX4) 3,4 and radicaltrapping antioxidants (RTAs) 5,6. The factors which underlie a given cell type's sensitivity to ferroptosis 7 is, however, critical to understand the pathophysiological role of ferroptosis and how it may be exploited for cancer treatment. Although metabolic constraints 8 and phospholipid composition 9,10 contribute to ferroptosis sensitivity, no cell-autonomous mechanisms have been yet been identified that account for ferroptosis resistance. We undertook an expression cloning approach to identify genes able to complement GPX4 loss. These efforts uncovered the flavoprotein "apoptosis inducing factor mitochondria-associated 2 (AIFM2)" as a previously unrecognized anti-ferroptotic gene. AIFM2, hereafter renamed "ferroptosis-suppressor-protein 1" (FSP1), initially described as a pro-apoptotic gene 11 , confers an unprecedented protection against ferroptosis elicited by GPX4 deletion. We further demonstrate that ferroptosis suppression by FSP1 is mediated via ubiquinone (CoQ10): its reduced form ubiquinol traps lipid peroxyl radicals that mediate lipid peroxidation, while FSP1 catalyses its regeneration by using NAD(P)H. Pharmacological targeting of FSP1 strongly synergizes with GPX4 inhibitors to trigger ferroptosis in a number of cancer entities. Conclusively, FSP1/CoQ10/NAD(P)H exists as a standalone parallel system, which cooperates with GPX4 and glutathione (GSH) to suppress phospholipid peroxidation (pLPO) and ferroptosis. program NEUROPROTEKT (03VP04260), as well as the m4 Award provided by the Bavarian Ministry of Economic Affairs, Regional Development and Energy (StMWi) to M.C., the Cancer Research UK
Ferroptosis is a form of regulated necrosis associated with the iron-dependent accumulation of lipid hydroperoxides that may play a key role in the pathogenesis of degenerative diseases in which lipid peroxidation has been implicated. High-throughput screening efforts have identified ferrostatin-1 (Fer-1) and liproxstatin-1 (Lip-1) as potent inhibitors of ferroptosis − an activity that has been ascribed to their ability to slow the accumulation of lipid hydroperoxides. Herein we demonstrate that this activity likely derives from their reactivity as radical-trapping antioxidants (RTAs) rather than their potency as inhibitors of lipoxygenases. Although inhibited autoxidations of styrene revealed that Fer-1 and Lip-1 react roughly 10-fold more slowly with peroxyl radicals than reactions of α-tocopherol (α-TOH), they were significantly more reactive than α-TOH in phosphatidylcholine lipid bilayers − consistent with the greater potency of Fer-1 and Lip-1 relative to α-TOH as inhibitors of ferroptosis. None of Fer-1, Lip-1, and α-TOH inhibited human 15-lipoxygenase-1 (15-LOX-1) overexpressed in HEK-293 cells when assayed at concentrations where they inhibited ferroptosis. These results stand in stark contrast to those obtained with a known 15-LOX-1 inhibitor (PD146176), which was able to inhibit the enzyme at concentrations where it was effective in inhibiting ferroptosis. Given the likelihood that Fer-1 and Lip-1 subvert ferroptosis by inhibiting lipid peroxidation as RTAs, we evaluated the antiferroptotic potential of 1,8-tetrahydronaphthyridinols (hereafter THNs): rationally designed radical-trapping antioxidants of unparalleled reactivity. We show for the first time that the inherent reactivity of the THNs translates to cell culture, where lipophilic THNs were similarly effective to Fer-1 and Lip-1 at subverting ferroptosis induced by either pharmacological or genetic inhibition of the hydroperoxide-detoxifying enzyme Gpx4 in mouse fibroblasts, and glutamate-induced death of mouse hippocampal cells. These results demonstrate that potent RTAs subvert ferroptosis and suggest that lipid peroxidation (autoxidation) may play a central role in the process.
Bonded Complex 9026 2.3. Pushing to the Limit: Pyridinols and Pyrimidinols 9026 2.4. Effects of Intramolecular Hydrogen Bonds on the RTA Activities of Phenols 9028 2.5. Enhancing Reactivity: Effects of Acids and Bases 9029 2.6. Synergy and Regeneration of Phenolic RTAs 9029 2.6.1. Synergy in Phenolic RTAs 9030 2.6.2. Regeneration of Alkyl-Chalcogen-Substituted Phenols by Sacrificial Reductants 9030 3. Peroxyl Radical Trapping by Diarylamines and Closely Related Compounds 9033 4. Di-tert-alkyl Amine, Nitroxide, and Alkoxyamine RTAs 9035 4.1. Hindered Amine Light Stabilizers, HALS 9035 4.1.1. HALS Activation 9035 4.1.2. Mechanism of Catalytic Inhibition by HALS at Ambient Temperatures 9036 4.2. Effect of Organic Acids on the RTA Activity of TEMPO 9036 5. Sulfenic Acid RTAs 9037 5.1. Organosulfur Compounds from Garlic and Other Alliums 9037 5.2. Insights from Reactions of Selenenic Acids 9040 6. Carbon-Centered Radicals as RTAs 9040 7. Conclusions and Outlook 9042 Author Information 9043 Corresponding Authors 9043 Notes 9043 Biographies 9043 Acknowledgments 9043 References 9043
Lipoxygenases (LOXs) have been implicated as central players in ferroptosis, a recently characterized cell death modality associated with the accumulation of lipid hydroperoxides: the products of LOX catalysis. To provide insight on their role, human embryonic kidney cells were transfected to overexpress each of the human isoforms associated with disease, 5-LOX, p12-LOX, and 15-LOX-1, which yielded stable cell lines that were demonstrably sensitized to ferroptosis. Interestingly, the cells could be rescued by less than half of a diverse collection of known LOX inhibitors. Furthermore, the cytoprotective compounds were similarly potent in each of the cell lines even though some were clearly isoform-selective LOX inhibitors. The cytoprotective compounds were subsequently demonstrated to be effective radical-trapping antioxidants, which protect lipids from autoxidation, the autocatalytic radical chain reaction that produces lipid hydroperoxides. From these data (and others reported herein), a picture emerges wherein LOX activity may contribute to the cellular pool of lipid hydroperoxides that initiate ferroptosis, but lipid autoxidation drives the cell death process.
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