Adenosine and brain ischemia.

K A Rudolphi, P Schubert, F E Parkinson, B B Fredholm
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Abstract

Recent experimental data indicate a probable role of adenosine as an endogenous neuroprotective substance in brain ischemia. This nucleoside is rapidly formed during ischemia as a result of intracellular breakdown of ATP and it is subsequently transported into the extracellular space. With use of microdialysis and other techniques, a massive increase of interstitial adenosine has been measured during ischemia in different brain areas. Adenosine acts through two subtypes of receptors, A1 and A2, which are located on neurons, glial cells, blood vessels, platelets, and leukocytes and are linked via G-proteins to different effector systems such as adenylate cyclase and membrane ion channels. There is a very high density of A1-receptors in the hippocampus, an area with specific vulnerability to ischemia. In different in vivo and in vitro models of brain ischemia, the pharmacological manipulation of the adenosine system by adenosine receptor antagonists tended to aggravate ischemic brain damage, whereas the reinforcement of adenosine action by receptor agonists or inhibitors of cellular reuptake and inactivation showed neuroprotection. The up-regulation of adenosine A1-receptor number and affinity by chronic preadministration of the competitive antagonist caffeine also attenuated ischemic brain damage. The mechanisms underlying the neuroprotective effects of adenosine seem to involve both types of adenosine receptors, A1 and A2, but the A1-mediated pre- and postsynaptic neuromodulation may be of special importance. By inhibiting neuronal Ca2+ influx, adenosine counteracts the presynaptic release of the potentially excitotoxic neurotransmitters glutamate and aspartate, which may impair intracellular Ca2+ homeostasis via metabotrophic glutamate receptors or induce uncontrolled membrane depolarization via ion channel-linked glutamate receptors, especially of the N-methyl-D-aspartate (NMDA) type. In addition, adenosine directly stabilizes the neuronal membrane potential by increasing the conductance for K+ and Cl- ions, thereby counteracting excessive membrane depolarization. The latter triggers a number of pathological events including blockade of voltage-sensitive K+ currents, increase of NMDA receptor-mediated Ca2+ influx, and presumably also impairment of glutamate uptake by astrocytes. In the way of a vicious cycle, all these factors again tend to enhance extracellular glutamate levels and membrane depolarization, finally leading to cytotoxic calcium loading and neuronal cell death. In addition to its important neuromodulatory effects, which tend to reduce energy demand of the brain, adenosine acting via A2-receptors in brain vessels, platelets, and neutrophilic granulocytes may improve the cerebral microcirculation and thus oxygen and substrate supply to the tissue. There is evidence that the functional state of adenosine receptors is impaired during ischemia, limiting the time window of the adenosine action.(ABSTRACT TRUNCATED AT 400 WORDS)

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腺苷与脑缺血。
最近的实验数据表明腺苷可能在脑缺血中发挥内源性神经保护物质的作用。这种核苷在缺血过程中由于细胞内ATP的分解而迅速形成,随后被转运到细胞外空间。利用微透析和其他技术,测量了缺血时不同脑区间质腺苷的大量增加。腺苷通过位于神经元、神经胶质细胞、血管、血小板和白细胞上的两种亚型受体A1和A2起作用,并通过g蛋白连接到不同的效应系统,如腺苷酸环化酶和膜离子通道。海马体中有非常高密度的a1受体,这是一个特别容易缺血的区域。在不同的体内和体外脑缺血模型中,腺苷受体拮抗剂对腺苷系统的药理学操作倾向于加重缺血性脑损伤,而受体激动剂或细胞再摄取和失活抑制剂对腺苷作用的增强具有神经保护作用。竞争性拮抗剂咖啡因对腺苷a1受体数量和亲和力的上调也可减轻缺血性脑损伤。腺苷神经保护作用的机制似乎涉及两种类型的腺苷受体A1和A2,但A1介导的突触前和突触后神经调节可能特别重要。通过抑制神经元Ca2+内流,腺苷抵消潜在的兴奋毒性神经递质谷氨酸和天冬氨酸的突触前释放,这可能通过代谢性谷氨酸受体损害细胞内Ca2+稳态,或通过离子通道连接的谷氨酸受体,特别是n -甲基- d -天冬氨酸(NMDA)型诱导不受控制的膜去极化。此外,腺苷通过增加K+和Cl-离子的电导直接稳定神经元膜电位,从而抵消过度的膜去极化。后者引发许多病理事件,包括电压敏感的K+电流的阻断,NMDA受体介导的Ca2+内流的增加,可能也会损害星形胶质细胞对谷氨酸的摄取。所有这些因素以恶性循环的方式,再次倾向于提高细胞外谷氨酸水平和膜去极化,最终导致细胞毒性钙负荷和神经元细胞死亡。腺苷除了具有降低大脑能量需求的重要神经调节作用外,还可通过脑血管、血小板和嗜中性粒细胞中的a2受体起作用,改善大脑微循环,从而改善组织的氧气和底物供应。有证据表明,缺血时腺苷受体的功能状态受损,限制了腺苷作用的时间窗口。(摘要删节为400字)
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