行为可塑性与人类疾病的无脊椎动物模型

Invertebrate models of behavioural plasticity and human disease.

作者信息

Holden-Dye Lindy, Walker Robert J

机构信息

Biological Sciences, University of Southampton, Southampton, UK.

出版信息

Brain Neurosci Adv. 2018 Dec 7;2:2398212818818068. doi: 10.1177/2398212818818068. eCollection 2018 Jan-Dec.

DOI:10.1177/2398212818818068

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7058240/

Abstract

The fundamental processes of neural communication have been largely conserved through evolution. Throughout the last century, researchers have taken advantage of this, and the experimental tractability of invertebrate animals, to advance understanding of the nervous system that translates to mammalian brain. This started with the inspired analysis of the ionic basis of neuronal excitability and neurotransmission using squid during the 1940s and 1950s and has progressed to detailed insight into the molecular architecture of the synapse facilitated by the genetic tractability of the nematode and the fruit fly . Throughout this time, invertebrate preparations have provided a means to link neural mechanisms to behavioural plasticity and thus key insight into fundamental aspects of control systems, learning, and memory. This article captures key highlights that exemplify the historical and continuing invertebrate contribution to neuroscience.

摘要

神经通信的基本过程在进化过程中基本得到了保留。在过去的一个世纪里，研究人员利用这一点以及无脊椎动物在实验上的易处理性，来推进对神经系统的理解，而这种理解可以类推到哺乳动物的大脑。这始于20世纪40年代和50年代利用鱿鱼对神经元兴奋性和神经传递的离子基础进行的开创性分析，并发展到借助线虫和果蝇的遗传易处理性对突触的分子结构有了详细的了解。在这一过程中，无脊椎动物的标本提供了一种将神经机制与行为可塑性联系起来的方法，从而对控制系统、学习和记忆的基本方面有了关键的认识。本文总结了一些关键要点，这些要点例证了无脊椎动物在历史上以及对神经科学持续不断的贡献。

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