四足动物基底神经节的演化：基于近期对两栖动物研究的新视角

Evolution of the basal ganglia in tetrapods: a new perspective based on recent studies in amphibians.

作者信息

Marín O, Smeets W J, González A

机构信息

Departamento de Biología Celular, Facultad de Biología, Universidad Complutense, Madrid, Spain.

出版信息

Trends Neurosci. 1998 Nov;21(11):487-94. doi: 10.1016/s0166-2236(98)01297-1.

DOI:10.1016/s0166-2236(98)01297-1

PMID:9829691

Abstract

It has been postulated frequently that the fundamental organization of the basal ganglia (BG) in vertebrates arose with the appearance of amniotes during evolution. An alternative hypothesis, however, is that such a condition was already present in early anamniotic tetrapods and, therefore, characterizes the acquisition of the tetrapod phenotype rather than the anamniotic-amniotic transition. Re-examination of the BG organization in tetrapods in the light of recent findings in amphibians strongly supports the notion that elementary BG structures were present in the brain of ancestral tetrapods and that they were organized according to a general plan shared today by all extant tetrapods.

摘要

人们常常推测，脊椎动物基底神经节（BG）的基本组织结构是在进化过程中随着羊膜动物的出现而产生的。然而，另一种假说认为，这种情况在早期无羊膜四足动物中就已经存在，因此，它是四足动物表型获得的特征，而不是无羊膜动物向羊膜动物转变的特征。根据两栖动物的最新研究结果重新审视四足动物的BG组织，有力地支持了这样一种观点，即基本的BG结构存在于原始四足动物的大脑中，并且它们是按照所有现存四足动物共有的一般模式组织起来的。

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四足动物基底神经节的演化：基于近期对两栖动物研究的新视角

Evolution of the basal ganglia in tetrapods: a new perspective based on recent studies in amphibians.

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