氧化应激诱导线粒体DNA缺失是脑血管疾病药物开发的一个标志。

Gjumrakch Aliev, Yi Li, Hector H Palacios, Mark E Obrenovich
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引用次数: 52

摘要

心血管系统,包括脑微血管和/或实质细胞中的氧化应激导致活性氧(ROS)和活性氮(RNS)化合物的积累,从而促进白细胞粘附和增加内皮细胞的通透性。由此产生的慢性损伤刺激导致进行性细胞低代谢。我们认为,低代谢,加上氧化应激源,是大多数阿尔茨海默病(AD)和脑血管意外(cva)的原因,似乎是血管异常、线粒体损伤和血管活性物质活性失衡的中心启动因素,如血管壁和脑实质细胞中一氧化氮合酶(NOS)、内皮素-1 (ET-1)、氧化应激标志物、mtDNA和线粒体酶的不同同工型。在较高浓度下,ROS诱导细胞损伤和死亡,这发生在衰老过程中,其中ROS的生成加速,细胞抗氧化防御机制逐渐下降,特别是在线粒体中。由于血管内皮细胞和神经元线粒体在能量供应和使用中的作用,它们特别容易受到氧化应激的影响,氧化应激会导致一系列的衰弱因素,比如产生巨大的和/或脆弱的年轻线粒体,这些线粒体的DNA已经受损。因此,线粒体DNA异常,如过度增殖和/或缺失,可以作为疾病分化和治疗效果的关键标志。我们推测,特定的抗氧化剂,如乙酰左旋肉碱和r - α硫辛酸似乎是治疗AD的潜在方法。它们针对破坏线粒体的因素并逆转其作用,从而消除能量产生中的不平衡并恢复正常的细胞功能,使这些抗氧化剂成为治疗心脑血管以及包括AD在内的神经退行性疾病的强有力的替代策略。未来利用mtDNA标记的潜在探索可以被认为是诊断和监测人类疾病治疗的更准确的标志。本文讨论了氧化应激方面的一些专利。
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Oxidative stress induced mitochondrial DNA deletion as a hallmark for the drug development in the context of the cerebrovascular diseases.

Oxidative stress in the cardiovascular system, including brain microvessels and/or parenchymal cells results in an accumulation of reactive oxygen species (ROS) and reactive nitrogen species (RNS) compounds thus promoting leukocyte adhesion and increasing endothelial permeability. The resulting chronic injury stimulus results in progressive cellular hypometabolism. We propose that hypometabolism, coupled with oxidative stressors, is responsible for most Alzheimer disease (AD) and cerebrovascular accidents (CVAs) and appears to be a central initiating factor for vascular abnormalities, mitochondrial damage and an imbalance in the activity of vasoactive substances, such as different isoforms of nitric oxide synthase (NOS), endothelin-1 (ET-1), oxidative stress markers, mtDNA and mitochondrial enzymes in the vascular wall and in brain parenchymal cells. At higher concentrations, ROS induces cell injury and death, which occurs during the aging process, where accelerated generation of ROS and a gradual decline in cellular antioxidant defense mechanisms, especially in the mitochondria. Vascular endothelial and neuronal mitochondria are especially vulnerable to oxidative stress due to their role in energy supply and use, which can cause a cascade of debilitating factors such as the production of giant and/or vulnerable young mitochondrion who's DNA has been compromised. Therefore, mitochondrial DNA abnormalities such as overproliferation and or deletion can be used as a key marker for diseases differentiation and effectiveness of the treatment. We speculate that specific antioxidants such as acetyl-L-carnitine and R-alpha lipoic acid seem to be potential treatments for AD. They target the factors that damage mitochondria and reverse its effect, thus eliminating the imbalance seen in energy production and restore the normal cellular function, making these antioxidants very powerful alternate strategies for the treatment of cardiovascular cerebrovascular as well as neurodegenerative diseases including AD. Future potential exploration using mtDNA markers can be considered more accurate hallmarks for diagnosis and monitoring treatment of human diseases. The present article discusses some of the patents regarding the oxidative stress.

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