盐酸盐受体与NG2胶质细胞的信号整合。

Neuron glia biology Pub Date : 2009-05-01 Epub Date: 2009-12-22 DOI:10.1017/S1740925X09990081
Maria Kukley, Dirk Dietrich
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引用次数: 20

摘要

已经确定的是,年轻和成年大脑中的NG2细胞一致地检测到来自附近轴突的充满谷氨酸的单个囊泡的释放。释放的神经递质谷氨酸通过非nmda (n-甲基- d -天冬氨酸)谷氨酸受体电刺激NG2细胞,但AMPA和kainate受体对神经元-NG2细胞信号传导的单独贡献尚不清楚。在这里,我们通过药物阻断ampa型谷氨酸受体,并研究海马NG2细胞是否也表达谷氨酸受体的盐酸盐亚型,以及它们对突触连接的贡献。先前的研究表明,囊泡谷氨酸释放不会导致NG2细胞上的盐酸盐受体的可检测激活。在这里,我们报告了虽然250 nM-1 muM盐酸盐对NG2细胞没有主要影响,但它始终诱导一个小而持久的去极化电流。这个电流没有被ATPA模拟,这表明这个电流是由不含glur5的盐酸盐受体携带的。除了这种向内电流外,纳摩尔浓度的海盐酸盐还会显著增加NG2细胞中自发GABA-A受体介导的突触电流(IPSCs)的频率。在使用glur5特异性激动剂ATPA时,自发性IPSC频率的增加更为明显(频率增加约15倍)。相比之下,NG2细胞中记录的单突触刺激IPSCs不受盐酸盐受体激活的影响。这些及进一步的实验表明,IPSCs的高频发生是由于海马间神经元体突膜上GluR5受体的激活引起的海马间神经元动作电位放电。我们的数据表明,海马盐酸盐受体不仅对神经元之间的通信很重要,而且可能在神经元-神经胶质信号传导中发挥双重和亚型特异性的作用:首先,NG2细胞膜上的突触外非glur5盐酸盐受体非常适合通过环境谷氨酸指导NG2细胞局部兴奋性神经元的群体活动。其次,基于已知的海马中间神经元上GluR5受体对网络节律产生的重要性,以及基于我们发现这些中间神经元大量映射到NG2细胞上,神经元间GluR5受体的突触激活似乎触发了向NG2细胞的信号,从而传递了发育中的海马正在进行的网络振荡的阶段和频率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Kainate receptors and signal integration by NG2 glial cells.

It is well established that NG2 cells throughout the young and adult brain consistently detect the release of single vesicles filled with glutamate from nearby axons. The released neurotransmitter glutamate electrically excites NG2 cells via non-NMDA (N-methyl-D-aspartic acid) glutamate receptors but the individual contribution of AMPA and kainate receptors to neuron-NG2 cell signalling, is not well understood. Here we pharmacologically block AMPA-type glutamate receptors and investigate whether hippocampal NG2 cells also express the kainate subtype of glutamate receptors and what may be their contribution to synaptic connectivity. It has been shown previously that vesicular glutamate release does not lead to a detectable activation of kainate receptors on NG2 cells. Here we report that while bath application of 250 nM-1 muM kainate does not have a major effect on NG2 cells it consistently induces a small and persistent depolarising current. This current was not mimicked by ATPA, suggesting that this current is carried by non-GluR5 containing kainate receptors. In addition to this inward current, nanomolar concentrations of kainate also produced a dramatic increase in the frequency of spontaneous GABA-A receptor-mediated synaptic currents (IPSCs) in NG2 cells. This increase in spontaneous IPSC frequency was even more pronounced on application of the GluR5-specific agonist ATPA (approximately 15-fold increase in frequency). In contrast, mono-synaptic stimulated IPSCs recorded in NG2 cells were unaffected by kainate receptor activation. Those and further experiments show that the occurrence of the high frequency of IPSCs is due to action potential firing of hippocampal interneurons caused by activation of GluR5 receptors on the somatodendritic membrane of the interneurons. Our data suggest that hippocampal kainate receptors are not only important for communication between neurons but may also play a dual and subtype-specific role for neuron-glia signalling: Firstly, extra-synaptic non-GluR5 kainate receptors in the membrane of NG2 cells are ideally suited to instruct NG2 cells on the population activity of local excitatory neurons via ambient glutamate. Secondly, based on the known importance of GluR5 receptors on hippocampal interneurons for the generation of network rhythms and based on our finding that these interneurons heavily project onto NG2 cells, it appears that synaptic activation of interneuronal GluR5 receptors triggers signalling to NG2 cells which transmits the phase and frequency of ongoing network oscillations in the developing hippocampus.

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Neuron glia biology
Neuron glia biology 医学-神经科学
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