Abstract
Mitochondrial reverse electron transport (RET) represents a fundamental but potentially hazardous metabolic process in eukaryotic cells. This review systematically examines current understanding of RET mechanisms and their pathophysiological consequences. RET occurs when electrons flow inversely from reduced coenzyme Q (CoQH(2)) to complex I, driven by excessive reduction of the CoQ pool and elevated mitochondrial membrane potential, resulting in substantial superoxide production. While moderate RET contributes to physiological redox signaling, sustained RET activation leads to oxidative damage and activates regulated cell death pathways. Notably, RET demonstrates metabolic duality: it facilitates ATP generation through NAD(+) reduction while simultaneously inducing mitochondrial dysfunction via reactive oxygen species overproduction. Pathologically, RET has been implicated in myocardial ischemia-reperfusion injury, neurodegenerative disorders including Alzheimer's diseases, and exhibits context-dependent roles in tumor progression. Emerging evidence also suggests RET involvement in microbial pathogenesis through modulation of host immune responses. These findings position RET as a critical regulatory node in cellular metabolism with broad implications for human diseases. Future investigations should focus on developing tissue-specific RET modulators and elucidating the molecular switches governing its activation threshold, which may yield novel therapeutic strategies for diverse pathological conditions.