Abstract Spinal cord injury (SCI) leads to severe mitochondrial dysfunction and ROS cascade, with microglia playing a dual role in both exacerbating damage and providing neuroprotection. Recent evidence has highlighted the importance of P2Y12R in microglial-neuron interactions, particularly in modulating mitochondrial quality control and mitigating oxidative stress. Here, we develop a dual-targeting nanoparticle system (P2Y-TK-Nano) to enhance P2Y12R expression in microglia and promote neuronal mitophagy, aiming to reduce mitochondrial reactive oxygen species (mtROS) and improve neuronal survival following SCI. The P2Y-TK-Nano system combines a ROS-responsive thioketal bond for injury-site targeting with an MG1 peptide to selectively target microglia. This design enables precise nanoparticle delivery to the ROS-enriched injury microenvironment, effectively restoring P2Y12R expression in microglia. Microglia treated with P2Y-TK-Nano exhibit elevated P2Y12R expression, leading to increased interaction with injured neurons, improved mitophagy, and reduced mtROS production. These combined effects significantly attenuate secondary damage and contribute to neuroprotection post-SCI. Our findings reveal a novel regulatory mechanism by which P2Y12R overexpression in microglia enhances neuronal mitophagy and mitigates oxidative stress after SCI. The dual-targeting P2Y-TK-Nano system offers a promising therapeutic approach to address microglial activation and mitochondrial dysfunction in the context of SCI.
Tian et al. (Sun,) studied this question.