线粒体反向电子传递失调会改变活性氧和 NAD+/NADH 的代谢,是阿尔茨海默病的治疗靶标

Suman Rimal, Wen Li, Tejender Pal Khaket, Yu Li, Ishaq Tantray, Yanping Li, Sunil Bhurtel, L. Grinberg, Salvatore Spina, Maria Inmaculada Cobos Sillero, William W Seeley, Su Guo, Bingwei Lu
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摘要

目的:活性氧(ROS)和 NAD(H)代谢改变导致的氧化应激和 NAD+/NADH 失衡是与正常衰老和包括阿尔茨海默病(AD)在内的老年相关疾病相关的病理特征。目前还不太清楚在这些病理条件下如何发生活性氧和 NAD(H) 代谢异常,也不知道它们之间是否存在机理联系并可同时作为治疗靶点。本研究旨在确定 ROS 和 NAD(H) 代谢异常的原因,并检验其在 AD 发病机制中的作用。研究方法在某些热力学条件下,线粒体复合物 I 会发生逆电子传递(RET),导致产生过多的 ROS 和 NAD+ 转化为 NADH,从而降低 NAD+/NADH 比率。通过测量在 RET 条件下呼吸的脑裂解物和纯化线粒体中的 ROS 和 NAD+/NADH 比率,我们利用 AD 患者和小鼠 AD 模型的脑样本来评估 RET 的状态。一种小分子 RET 抑制剂被用于治疗 APP(swe)/PS1(deltaE9) 和 5xFAD 小鼠模型以及人类诱导多能干细胞(iPSC)衍生的 AD 神经元模型。研究还考察了RET对行为和AD相关神经病理学的影响。蛋白质相互作用研究探讨了 RET 改变的生化机制。研究结果在转基因 AD 小鼠大脑和 AD 患者中,RET 被异常激活。药理抑制 RET 可减轻淀粉样蛋白负荷和神经炎症,并能挽救 APP(swe)/PS1(deltaE9) 和 5xFAD 小鼠模型的认知和行为缺陷。在人类 AD iPSC 衍生神经元中,抑制 RET 可减少淀粉样蛋白聚集、tau 过度磷酸化和早期内体缺陷。从机理上讲,AD相关淀粉样前体蛋白C端片段(APP.C99)与复合体I蛋白相互作用,促进了RET。结论RET在AD中异常激活,导致ROS和NAD+/NADH代谢改变。药理抑制 RET 对小鼠和人类 iPSC 多发性硬化症模型有益。RET 激活是一种关键的病理驱动因素,也是 AD 以及其他可能与年龄相关的神经退行性疾病的合理治疗靶点。
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Deregulation of mitochondrial reverse electron transport alters the metabolism of reactive oxygen species and NAD+/NADH and presents a therapeutic target in Alzheimer’s disease
Aim: Oxidative stress and NAD+/NADH imbalance caused by alterations in reactive oxygen species (ROS) and NAD(H) metabolism are pathological features associated with normal aging and age-related diseases including Alzheimer’s disease (AD). How abnormalities in ROS and NAD(H) metabolism occur under these pathological conditions is not well understood, nor is it known whether they are mechanistically linked and can be therapeutically targeted together. The aim of this study is to identify the cause of aberrant ROS and NAD(H) metabolism and test its role in the pathogenesis of AD. Methods: Reverse electron transport (RET) along mitochondrial complex I can occur under certain thermodynamic conditions, leading to excessive ROS generation and NAD+ conversion to NADH, and thus lowered NAD+/NADH ratio. Brain samples from AD patients and mouse AD models were used to assess the status of RET by measuring ROS and NAD+/NADH ratio in brain lysates and purified mitochondria respiring under RET conditions. A small molecule RET inhibitor was used to treat APP(swe)/PS1(deltaE9) and 5xFAD mouse models and human induced pluripotent stem cell (iPSC)-derived neuronal model of AD. Effects on behavior and AD-related neuropathology were examined. The biochemical mechanism underlying RET alteration was examined by protein-protein interaction studies. Results: RET is aberrantly activated in transgenic AD mouse brains and in individuals with AD. Pharmacological inhibition of RET reduced amyloid burden and neuroinflammation and rescued cognitive and behavioral deficits in the APP(swe)/PS1(deltaE9) and 5xFAD mouse models. In human AD iPSC-derived neurons, RET inhibition reduced amyloid aggregation, tau hyperphosphorylation, and early endosomal defects. Mechanistically, the AD-associated amyloid precursor protein C-terminal fragment (APP.C99) was found to interact with complex I proteins to promote RET. Conclusion: RET is aberrantly activated in AD, causing altered ROS and NAD+/NADH metabolism. Pharmacological inhibition of RET is beneficial in mouse and human iPSC models of AD. RET activation represents a key pathological driver and a rational therapeutic target for AD and possibly other age-related neurodegenerative diseases.
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