A Mitochondria-Targeted Nitroxide Radical Mitigates Radiation-Induced Liver Injury by Attenuating Oxidative Stress and Preserving Mitochondrial Function
Miaomiao Li, Xiaojun Deng, Haibo WangRadiation-induced liver injury (RILI) is a major complication of abdominal radiotherapy, originating from mitochondrial oxidative stress, and effective radioprotectants are lacking. We designed an antioxidant intended to target mitochondria, TPP-C6-NIT, by conjugating a triphenylphosphonium cation to an imidazole nitroxide radical. Its protective effects were evaluated through in vitro assays, studies on irradiated L-02 and Huh-7 cells, a mouse model of whole-body irradiation, combined with metabolomics, molecular docking, and assessments of mitochondrial function, apoptosis, and inflammation. TPP-C6-NIT exhibited potent radical scavenging activity in vitro. In L-02 cells, it reduced oxidative stress, preserved mitochondrial function (membrane potential, ATP, respiratory capacity), and improved viability. In mice, pretreatment with TPP-C6-NIT significantly improved survival, alleviated liver injury (reduced serum ALT/AST and histopathological damage), and suppressed systemic inflammation. Mechanistic exploration suggested TPP-C6-NIT treatment was associated with increased Nrf2/GPX4 expression and reversal of lipid metabolic changes. Notably, TPP-C6-NIT did not confer significant protection in Huh-7 cells, indicating selective cytoprotection. By reducing oxidative stress and preserving mitochondrial function, TPP-C6-NIT demonstrates potent protection against radiation-induced liver injury in a whole-body irradiation mouse model, presenting a promising candidate for further development.