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龙虾多振荡器系统的肽能调节。I. 神经肽促肠肌肽和红色素浓缩激素对心囊运动模式的激活

Peptidergic modulation of a multioscillator system in the lobster. I. Activation of the cardiac sac motor pattern by the neuropeptides proctolin and red pigment-concentrating hormone.

作者信息

Dickinson P S, Marder E

机构信息

Biology Department, Bowdoin College, Brunswick, Maine 04011.

出版信息

J Neurophysiol. 1989 Apr;61(4):833-44. doi: 10.1152/jn.1989.61.4.833.

DOI:10.1152/jn.1989.61.4.833
PMID:2723723
Abstract
  1. The cardiac sac motor pattern consists of slow and irregular impulse bursts in the motor neurons [cardiac sac dilator 1 and 2 (CD1 and CD2)] that innervate the dilator muscles of the cardiac sac region of the crustacean foregut. 2. The effects of the peptides, proctolin and red pigment-concentrating hormone (RPCH), on the cardiac sac motor patterns produced by in vitro preparations of the combined stomatogastric nervous system [the stomatogastric ganglion (STG), the paired commissural ganglia (CGs), and the oesophageal ganglion (OG)] were studied. 3. Bath applications of either RPCH or proctolin activated the cardiac sac motor pattern when this motor pattern was not already active and increased the frequency of the cardiac sac motor pattern in slowly active preparations. 4. The somata of CD1 and CD2 are located in the esophageal and stomatogastric ganglia, respectively. Both neurons project to all four of the ganglia of the stomatogastric nervous system. RPCH elicited cardiac sac motor patterns when applied to any region of the stomatogastric nervous system, suggesting a distributed pattern generating network with multiple sites of modulation. 5. The anterior median (AM) neuron innervates the constrictor muscles of the cardiac sac. The AM usually functions as a part of the gastric mill pattern generator. However, when the cardiac sac is activated by RPCH applied to the stomatogastric ganglion, the AM neuron becomes active in antiphase with the cardiac sac dilator bursts. This converts the cardiac sac motor pattern from a one-phase rhythm to a two-phase rhythm. 6. These data show that a neuropeptide can cause a neuronal element to switch from being solely a component of one neuronal circuit to functioning in a second one as well. This example shows that peptidergic "reconfiguration" of neuronal networks can produce substantial changes in the behavior of associated neurons.
摘要
  1. 心囊运动模式由支配甲壳类前肠心囊区域扩张肌的运动神经元[心囊扩张肌1和2(CD1和CD2)]中缓慢且不规则的冲动爆发组成。2. 研究了肽类物质促胃液素和红色素浓缩激素(RPCH)对体外制备的联合口胃神经系统[口胃神经节(STG)、成对的连合神经节(CGs)和食管神经节(OG)]所产生的心囊运动模式的影响。3. 当这种运动模式尚未活跃时,浴用RPCH或促胃液素均可激活心囊运动模式,并增加缓慢活跃制剂中心囊运动模式的频率。4. CD1和CD2的胞体分别位于食管神经节和口胃神经节。这两个神经元都投射到口胃神经系统的所有四个神经节。当将RPCH应用于口胃神经系统的任何区域时,均可引发心囊运动模式,这表明存在一个具有多个调节位点的分布式模式生成网络。5. 前正中(AM)神经元支配心囊的收缩肌。AM通常作为胃磨模式发生器的一部分发挥作用。然而,当通过将RPCH应用于口胃神经节来激活心囊时,AM神经元会与心囊扩张肌的爆发呈反相激活。这将心囊运动模式从单相节律转变为双相节律。6. 这些数据表明,一种神经肽可使一个神经元元件从仅仅作为一个神经回路的组成部分转变为也能在第二个神经回路中发挥作用。这个例子表明,神经网络的肽能“重新配置”可在相关神经元的行为中产生实质性变化。

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