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线虫蛔虫运动神经元的结构与生理活性

Structure and physiological activity of the motoneurons of the nematode Ascaris.

作者信息

Stretton A O, Fishpool R M, Southgate E, Donmoyer J E, Walrond J P, Moses J E, Kass I S

出版信息

Proc Natl Acad Sci U S A. 1978 Jul;75(7):3493-7. doi: 10.1073/pnas.75.7.3493.

DOI:10.1073/pnas.75.7.3493
PMID:277952
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC392804/
Abstract

The nervous system of the nematode worm Ascaris contains about 250 nerve cells; of these, the motoneurons consist of five segmental sets, each containing 11 cells. Morphologically, the motoneurons can be divided into seven different types. Their geometry is simple: some are unbranched, others have one branch point, and the most complex have two. There is no neuropil in the nerve cords; synapses are made by axo-axonal contact or onto short spines. These features enable us to study the anatomy and physiology of the system with a degree of completeness that would be difficult in other systems. The physiological activity of five of the motoneurons has been investigated, three being excitatory and two inhibitory. The excitatory motoneurons receive input from intersegmental interneurons. The inhibitory motoneurons do not receive input from the interneurons; instead they receive their input from the excitatory motoneurons in a circuit that can mediate reciprocal inhibition between the dorsal and the ventral musculature.

摘要

线虫蛔虫的神经系统包含约250个神经细胞;其中,运动神经元由五组节段性神经元组成,每组包含11个细胞。从形态学上看,运动神经元可分为七种不同类型。它们的结构简单:有些没有分支,有些有一个分支点,最复杂的有两个分支点。神经索中没有神经纤维网;突触通过轴突-轴突接触或在短棘上形成。这些特征使我们能够在一定程度上完整地研究该系统的解剖学和生理学,而这在其他系统中是很难做到的。已经研究了五个运动神经元的生理活动,其中三个是兴奋性的,两个是抑制性的。兴奋性运动神经元从节段间中间神经元接收输入。抑制性运动神经元不从中枢神经元接收输入;相反,它们在一个可以介导背侧和腹侧肌肉组织之间相互抑制的回路中从兴奋性运动神经元接收输入。

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