认知功能衰退
细胞生物学
生物
线粒体
神经科学
神经退行性变
品脱1
活性氧
海马结构
组蛋白
线粒体呼吸链
线粒体生物发生
氧化应激
兴奋毒性
神经炎症
神经可塑性
调解人
呼吸链
机制(生物学)
线粒体分裂
信号转导
海马体
功能(生物学)
衰老的大脑
染色质
粒体自噬
程序性细胞死亡
标识
DOI:10.17632/dscmsyv6gn.1
摘要
Brain aging is accompanied by cognitive decline and an increased risk of neurodegenerative disease, with neuronal aging being a key causative factor. Studies have shown that the earliest damage to blood-brain barrier (BBB) integrity occurs in the hippocampus, leading to the abnormal accumulation of Fe²⁺;however, the mechanisms underlying subsequent neuronal aging remain unclear. Using single-cell and spatial transcriptomic analyses, this study focuses on the phospholipid flippase ATP11B. We found that ATP11B deficiency facilitates the transport of Fe²⁺ from ependymal cells to hippocampal neurons, activating the Hippo signaling pathway and inducing mitochondrial respiratory dysfunction and dynamic imbalance, which results in neuronal ferroptosis and exacerbation of aging phenotypes. Mechanistically, ATP11B blocks mitochondrial respiratory function by regulating the chromatin accessibility of KLF4 to mitochondrial respiratory chain complex genes. Simultaneously, it impairs the mitochondrial quality control system, resulting in elevated levels of reactive oxygen species(ROS) and enhanced neuronal aging. The mitochondria-associated metabolite, lactate, facilitates histone lactylation of ferroptosis and the key aging-related genes Acsl4, Trp53 and Cdkn1a via the TEAD-YAP complex, thereby promoting transcription. This research uncovers the molecular mechanism through which ATP11B mediates neuronal aging: regulating the iron transport-mitochondrial plasticity axis. This provides a novel avenue for targeting iron homeostasis to intervene in cognitive decline and neurodegenerative disease.
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