<p>Ischemic stroke (IS) remains a leading cause of global mortality and neurological disability, with neuronal mitochondrial dysfunction as a central pathological mechanism. Astrocytes, the metabolic custodians of the central nervous system, exert neuroprotection by transferring functional mitochondria to compromised neurons via tunneling nanotubes (TNTs), extracellular vesicles (EVs), connexin 43 (Cx43) mediated gap junctions, and membrane fusion. These transfers replenish neuronal energy reserves, mitigate oxidative stress, and enhance synaptic plasticity. This review systematically delineates the molecular mechanisms of astrocyte-mediated mitochondrial transfer, its regulatory roles in oxidative stress, calcium dyshomeostasis, and ferroptosis, and its therapeutic potential in IS. Experimental models demonstrate that pharmacological enhancement of mitochondrial transfer or exogenous transplantation significantly reduces infarct volume and improves neuronal survival. However, clinical translation faces challenges including low mitochondrial viability, immune rejection, and inefficient delivery. Future research should integrate gene-editing tools, nanocarrier systems, and organoid models to optimize mitochondrial dynamics and develop precision therapies. By bridging mechanistic insights with translational innovations, astrocytic mitochondrial transfer emerges as a groundbreaking strategy for ischemic stroke treatment.</p>

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Astrocytic mitochondrial transfer: a new horizon for metabolic rescue and precision therapy in ischemic stroke

  • Xin Lan,
  • Chuxin Zhang,
  • Zilin Ren,
  • Jialin Cheng,
  • Congai Chen,
  • Yuxiao Zheng,
  • Jinhua Han,
  • Yang Zhao,
  • Jiaming Li,
  • Fafeng Cheng,
  • Xueqian Wang,
  • Qingguo Wang,
  • Changxiang Li

摘要

Ischemic stroke (IS) remains a leading cause of global mortality and neurological disability, with neuronal mitochondrial dysfunction as a central pathological mechanism. Astrocytes, the metabolic custodians of the central nervous system, exert neuroprotection by transferring functional mitochondria to compromised neurons via tunneling nanotubes (TNTs), extracellular vesicles (EVs), connexin 43 (Cx43) mediated gap junctions, and membrane fusion. These transfers replenish neuronal energy reserves, mitigate oxidative stress, and enhance synaptic plasticity. This review systematically delineates the molecular mechanisms of astrocyte-mediated mitochondrial transfer, its regulatory roles in oxidative stress, calcium dyshomeostasis, and ferroptosis, and its therapeutic potential in IS. Experimental models demonstrate that pharmacological enhancement of mitochondrial transfer or exogenous transplantation significantly reduces infarct volume and improves neuronal survival. However, clinical translation faces challenges including low mitochondrial viability, immune rejection, and inefficient delivery. Future research should integrate gene-editing tools, nanocarrier systems, and organoid models to optimize mitochondrial dynamics and develop precision therapies. By bridging mechanistic insights with translational innovations, astrocytic mitochondrial transfer emerges as a groundbreaking strategy for ischemic stroke treatment.