PGK1 acts as a non-catalytic gatekeeper of ferroptosis by stabilizing SLC7A11
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ABSTRACT: Ferroptosis is restrained by layered antioxidant defenses, yet whether glycolytic enzymes directly constitute ferroptosis-defense machinery remains unclear. Here we identify phosphoglycerate kinase 1 (PGK1) as a non-canonical suppressor of ferroptosis that functions independently of its glycolytic kinase activity. Across pan-cancer bulk and single-cell transcriptomes, glycolysis inversely associates with ferroptosis programs, with PGK1 emerging as a prognostic hub. PGK1 loss in multiple tumor models elicits hallmark ferroptotic features, elevates lipid peroxidation and labile iron, and suppresses xenograft growth, all of which are reversed by liproxstatin-1. Mechanistically, PGK1 physically binds the C-terminal tail of SLC7A11 (aa 471-501) and shields it from ubiquitin-proteasome degradation, thereby sustaining cystine-driven glutathione synthesis and redox homeostasis. This scaffolding role is preserved in a kinase-dead PGK1 mutant, establishing a strict separation between metabolic and ferroptosis-regulatory functions. Restoring SLC7A11 rescues PGK1-deficient tumor growth, whereas a rationally designed competing peptide SLC7A11471-501 (FP-01) disrupts the PGK1-SLC7A11 interface, depletes SLC7A11/GSH, triggers ferroptosis, and suppresses tumor progression in vivo. Collectively, the PGK1-SLC7A11 interaction represents a druggable ferroptosis vulnerability that enables selective ferroptosis induction while sparing essential glycolysis.
ORGANISM(S): Homo sapiens
PROVIDER: GSE317428 | GEO | 2026/07/12
REPOSITORIES: GEO
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