Abstract
ZIP14/SLC39A14, a membrane-bound metal transporter, is essential for systemic metal homeostasis and has been implicated in inflammatory and metabolic disorders, including cancer-associated cachexia. Despite its biological and therapeutic significance, no selective inhibitors have been identified. Here, we identify 1-phenyl-8-(2-phenylethyl)-1,3,8-triazaspiro[4.5]decan-4-one (PPTD) as the first selective small-molecule inhibitor of ZIP14. PPTD efficiently blocks ZIP14-mediated uptake of zinc, iron, manganese, and cadmium, while sparing the closely related transporter ZIP8/SLC39A8. Mechanistically, PPTD binds specifically to a pocket formed at the dimer interface of ZIP14, as revealed by AlphaFold3 structural prediction, ligand-interaction profiling, structure-activity analyses, and site-directed mutagenesis, providing direct evidence for a targeted inhibition mechanism. ZIP14-driven metal influx promotes reactive oxygen species and lipid peroxidation, leading to cytotoxicity, which PPTD effectively reverses. In vivo , PPTD ameliorates major features of cancer cachexia in mice, including weight loss, reduced survival, muscle wasting, impaired locomotor activity, and disease progression. PPTD thus provides both a chemical probe to dissect ZIP14 function and a potential therapeutic candidate for cancer cachexia, establishing a foundation for the development of therapies targeting ZIP14-mediated metal dysregulation.