同源性、新皮质和发育机制的演化。
Homology, neocortex, and the evolution of developmental mechanisms.
机构信息
Max Planck Institute of Molecular Cell Biology and Genetics, Dresden, Germany.
Department of Neurobiology, University of Chicago, Chicago, IL, USA.
出版信息
Science. 2018 Oct 12;362(6411):190-193. doi: 10.1126/science.aau3711.
Abstract
The six-layered neocortex of the mammalian pallium has no clear homolog in birds or non-avian reptiles. Recent research indicates that although these extant amniotes possess a variety of divergent and nonhomologous pallial structures, they share a conserved set of neuronal cell types and circuitries. These findings suggest a principle of brain evolution: that natural selection preferentially preserves the integrity of information-processing pathways, whereas other levels of biological organization, such as the three-dimensional architectures of neuronal assemblies, are less constrained. We review the similarities of pallial neuronal cell types in amniotes, delineate candidate gene regulatory networks for their cellular identities, and propose a model of developmental evolution for the divergence of amniote pallial structures.
摘要
哺乳动物皮层的六层新皮质在鸟类或非鸟类爬行动物中没有明显的同源物。最近的研究表明,尽管这些现存的羊膜动物具有各种不同和非同源的皮层结构,但它们共享一组保守的神经元细胞类型和回路。这些发现表明了大脑进化的一个原则:自然选择优先保护信息处理途径的完整性,而其他层次的生物组织,如神经元集合的三维结构,受到的限制较小。我们回顾了羊膜动物皮层神经元细胞类型的相似性,描绘了它们细胞身份的候选基因调控网络,并提出了一个羊膜动物皮层结构分化的发育进化模型。
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