Modulation of neurons in the paraventricular thalamic nucleus by α 2 adrenoceptor agonists: evidence for physiological and morphological heterogeneity

Thalamus and Related Systems Pub Date : 2005-12-01 DOI:10.1017/S1472928807000313

U. Heilbronner, G. Flügge

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引用次数: 3

Abstract

The paraventricular thalamic nucleus (PVT) receives dense noradrenergic input, but little is known about α 2 adrenoceptors (ARs) in this nucleus. We have investigated effects of the agonist α-methyl-norepinephrine (m-NE) on PVT neurons in vitro. Based on their physiological and morphological characteristics, three distinct classes of PVT neurons have been identified. The first class exhibits membrane hyperpolarization on stimulation with m-NE (0.05–25 µM). This hyperpolarizing effect is observed in the presence of tetrodotoxin (TTX; 0.5–1 µM), blocked by yohimbine (1 µM) and mimicked by clonidine (10 µM), which indicates that it is mediated by postsynaptic α 2 ARs. Further experiments indicate that it is mediated through an increase in G protein-coupled K + conductance. In a second class of neurons, m-NE (0.05–25 µM) induces a slow membrane depolarization that is mimicked by phenylephrine (5 µM) and blocked by prazosin (75 nM), which indicates the involvement of α 1 ARs. The third class of neurons is insensitive to m-NE (5–25 µM), and has a lower input resistance and a larger dendritic tree compared to the two other classes. The three types of neurons differ in their resting properties, and their firing patterns are changed by m-NE. These findings indicate anatomical and functional specialization of PVT neurons.

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α 2肾上腺素能受体激动剂对室旁丘脑核神经元的调节:生理和形态异质性的证据

室旁丘脑核(PVT)接受密集的去肾上腺素能输入，但对该核中的α 2肾上腺素受体(ARs)知之甚少。我们在体外研究了激动剂α-甲基-去甲肾上腺素(m-NE)对PVT神经元的作用。根据PVT神经元的生理和形态特征，已确定了三种不同的PVT神经元。第一类细胞在M - ne(0.05 ~ 25µM)刺激下表现为膜超极化。这种超极化效应是在河豚毒素(TTX;0.5-1µM)，育亨宾阻断(1µM)，可乐定模拟(10µM)，表明它是由突触后α 2 ar介导的。进一步的实验表明，它是通过G蛋白偶联K +电导的增加介导的。在第二类神经元中，M - ne(0.05-25µM)诱导了一个缓慢的膜去极化过程，该过程被苯基肾上腺素(5µM)模拟，并被吡唑嗪(75 nM)阻断，这表明α 1ar的参与。第三类神经元对M - ne(5-25µM)不敏感，并且与其他两类相比具有更低的输入电阻和更大的树突树。这三种类型的神经元的静息特性不同，它们的放电模式被m-NE改变。这些发现表明PVT神经元的解剖和功能特化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Thalamus and Related Systems

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