一氧化氮在缺血性脑神经变性和兴奋性毒性中的作用。

P J Strijbos
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引用次数: 55

摘要

自由基一氧化氮(NO)作为细胞信号分子参与调节血压和免疫宿主防御反应等关键生理过程,这一发现可能是近十年来生物学领域最重要和最令人兴奋的发现之一。同样,在大脑中,NO也参与了许多基本过程,包括记忆形成、性行为和脑血流量的控制。这从根本上改变了脑生理学的公认教条,并将NO置于神经科学研究的中心舞台。有证据表明,NO在大脑中的某些作用可能与经典的兴奋性神经递质谷氨酸密切相关。历史观点认为谷氨酸信号转导的异常可能是脑缺血后中枢神经退行性变的基础,这暗示一氧化氮在默认情况下是神经元死亡的潜在介质。事实上,随着与NO合成酶和NO信号级联相互作用的强效和特异性化合物的出现,现在有充分的证据表明NO可以介导神经退行性变,尽管其参与是矛盾的。其对脑血管的作用可能通过保持组织灌注和防止血小板聚集来限制缺血损伤,而在缺血损伤后直接或后期作为神经炎症反应的一部分在实质中产生的NO可能对缺血的结果有害。尽管如此,在脑缺血和其他中枢神经退行性疾病的治疗中,化学NO供体和特异性NOS抑制剂的潜在治疗用途已经取得了重大进展。本文讨论了一氧化氮在缺血性脑神经退行性变中的作用的最新概念和进展。
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Nitric oxide in cerebral ischemic neurodegeneration and excitotoxicity.

The observation that the free radical nitric oxide (NO) acts as a cell signaling molecule in key physiological processes such as regulation of blood pressure and immunological host-defense responses is probably one of the most important and exciting findings made in biology in the last decade. Likewise, in the brain NO has been implicated in a number of fundamental processes, including memory formation, sexual behavior and the control of cerebral blood flow. This has radically altered the accepted dogma of brain physiology and has placed NO at the center stage of neuroscience research. Evidence suggests that some of the actions of NO in the brain may be intimately linked to those of the classic excitatory neurotransmitter glutamate. The historical view that aberrations in glutamate signal transduction may underlie central neurodegeneration following, for example, cerebral ischemia, has implicated NO, by default, as a potential mediator of neuronal death. Indeed, with the advent of potent and specific compounds that interact with NO synthesizing (NOS) enzymes and with the NO signaling cascade, there is now ample evidence to suggest that NO can mediate neurodegeneration, although its involvement is paradoxical. Its cerebrovascular effects may act to limit ischemic damage by preserving tissue perfusion and preventing platelet aggregation, while NO produced in the parenchyma, either directly following the ischemic insult or at a later stage as part of a neuroinflammatory response, may be deleterious to the outcome of ischemia. Nonetheless, significant efforts are made into the potential therapeutic use of chemical NO donors and specific NOS inhibitors in the treatment of cerebral ischemia and other central neurodegenerative disorders. Here, the latest concepts and developments in our understanding of the role of NO in cerebral ischemic neurodegeneration are discussed.

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