BackgroundReactive oxygen species (ROS) from mitochondrial dysfunction are critical in triggering apoptosis and inflammation in acute liver failure (ALF). Quercetin (QUE), an antioxidant, is renowned for its therapeutic effects onliverdiseases. There are no studies on whether QUE regulates mitophagy level in hepatocytes to inhibit ALF. ObjectiveThis study investigates QUE’s protective effects on ALF and elucidates the mechanisms involved. MethodsThe ALF and hepatocyte inflammatory injury model was established using LPS and D-Galn. To predict potential targets and mechanisms of QUE in ALF treatment, transcriptomics, network pharmacology, molecular docking techniques, and ChIP were employed. The expression level related to mitophagy, apoptosis, and signaling pathways were detected by CCK8, IHC, IF staining, TUNEL, RT-qPCR, TEM, Western blotting, ELISA, and flow cytometry. ResultsNetwork pharmacology and transcriptomics revealed common targets between QUE and ALF. Enrichment analysis showed that the anti-ALF targets of QUE were significantly associated with mitochondria and NF-κB-related pathways. Subsequent experiments showed that QUE pretreatment significantly alleviated the loss of hepatocyte viability, enhanced mitochondrial membrane potential, activated mitophagy, and promoted the clearance of damaged mitochondria, thereby reducing ROS accumulation, significantly reducing cell apoptosis and inflammatory responses, reducing ALT and AST levels, and improving liver tissue pathology. Mechanistically, molecular docking, DARTS, and CETSA analyses confirmed that QUE directly binds to the PPARγ molecule, which reduced binding to IκB and significantly inhibit the NF-κB pathway to exert its protective effects. ConclusionIn short, our results provide the first evidence that QUE improves acute liver failure by promoting mitophagy through regulating the PPARγ/PGC-1α/NF-κB axis and inhibiting apoptosis and inflammatory responses mediated by mitochondrial dysfunction, which provides evidence for the potential of QUE in the treatment of ALF.
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