快速抑制性突触：脊椎动物运动行为的神经调节靶点与发育

Fast inhibitory synapses: targets for neuromodulation and development of vertebrate motor behaviour.

作者信息

Sillar Keith T, McLean David L, Fischer Hanno, Merrywest Simon D

机构信息

School of Biology, Division of Biomedical Sciences, University of St Andrews, Bute Medical Buildings, St Andrews, KY16 9TS, Fife, UK.

出版信息

Brain Res Brain Res Rev. 2002 Oct;40(1-3):130-40. doi: 10.1016/s0165-0173(02)00196-0.

DOI:10.1016/s0165-0173(02)00196-0

PMID:12589912

Abstract

Locomotor networks must possess the inherent flexibility to adapt their output. In this review we discuss evidence from a simple vertebrate locomotor network that suggests fast inhibitory synapses are important targets for the forms of neuromodulation that afford this flexibility. Two important inhibitory transmitters, glycine and GABA, are present in the CNS of Xenopus tadpoles, where they each play distinct roles in the control of swimming. Glycine, but not GABA, contributes to the inhibitory mid-cycle component of each swim-cycle, the strength of which determines the frequency of swimming. Meanwhile, GABA release onto the swim network prematurely terminates swimming episodes. Hence, glycine controls how fast, whilst GABA controls how far the tadpole swims. Our work has focused on how the amines serotonin (5-HT) and noradrenaline (NA), and more recently the gas nitric oxide (NO), selectively target glycine and GABA release in the spinal cord to modulate swimming. In particular, we have identified three brainstem populations of nitrergic neurons, which suggests that nitric oxide may co-localise with 5-HT, NA and GABA. Here we review this work and suggest a hierarchy of brainstem modulatory systems, with NO acting as a metamodulator.

摘要

运动网络必须具备内在的灵活性以调整其输出。在本综述中，我们讨论来自一个简单脊椎动物运动网络的证据，该证据表明快速抑制性突触是赋予这种灵活性的神经调节形式的重要靶点。两种重要的抑制性递质，甘氨酸和γ-氨基丁酸（GABA），存在于非洲爪蟾蝌蚪的中枢神经系统中，它们在控制游泳中各自发挥着不同的作用。甘氨酸而非GABA，对每个游泳周期的抑制性中间周期成分有贡献，其强度决定游泳频率。同时，GABA释放到游泳网络上会过早终止游泳过程。因此，甘氨酸控制蝌蚪游泳的速度，而GABA控制蝌蚪游泳的距离。我们的工作集中于胺类物质血清素（5-羟色胺，5-HT）和去甲肾上腺素（NA），以及最近的气体一氧化氮（NO）如何选择性地作用于脊髓中甘氨酸和GABA的释放以调节游泳。特别地，我们已经确定了三个脑干一氧化氮能神经元群，这表明一氧化氮可能与5-HT、NA和GABA共定位。在此我们综述这项工作，并提出一个脑干调节系统的层级结构，其中NO作为一种元调节因子发挥作用。

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快速抑制性突触：脊椎动物运动行为的神经调节靶点与发育

Fast inhibitory synapses: targets for neuromodulation and development of vertebrate motor behaviour.

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