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2020年对基于张力的皮质形态发生的见解。

A 2020 view of tension-based cortical morphogenesis.

作者信息

Van Essen David C

机构信息

Department of Neuroscience, Washington University School of Medicine, Saint Louis, MO 63110.

出版信息

Proc Natl Acad Sci U S A. 2020 Dec 29;117(52):32868-32879. doi: 10.1073/pnas.2016830117. Epub 2020 Dec 15.

DOI:10.1073/pnas.2016830117
PMID:33323481
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7780001/
Abstract

Mechanical tension along the length of axons, dendrites, and glial processes has been proposed as a major contributor to morphogenesis throughout the nervous system [D. C. Van Essen, 385, 313-318 (1997)]. Tension-based morphogenesis (TBM) is a conceptually simple and general hypothesis based on physical forces that help shape all living things. Moreover, if each axon and dendrite strive to shorten while preserving connectivity, aggregate wiring length would remain low. TBM can explain key aspects of how the cerebral and cerebellar cortices remain thin, expand in surface area, and acquire their distinctive folds. This article reviews progress since 1997 relevant to TBM and other candidate morphogenetic mechanisms. At a cellular level, studies of diverse cell types in vitro and in vivo demonstrate that tension plays a major role in many developmental events. At a tissue level, I propose a differential expansion sandwich plus (DES+) revision to the original TBM model for cerebral cortical expansion and folding. It invokes tangential tension and "sulcal zipping" forces along the outer cortical margin as well as tension in the white matter core, together competing against radially biased tension in the cortical gray matter. Evidence for and against the DES+ model is discussed, and experiments are proposed to address key tenets of the DES+ model. For cerebellar cortex, a cerebellar multilayer sandwich (CMS) model is proposed that can account for many distinctive features, including its unique, accordion-like folding in the adult, and experiments are proposed to address its specific tenets.

摘要

沿轴突、树突和神经胶质突起长度方向的机械张力被认为是整个神经系统形态发生的主要促成因素[D. C. 范埃森,《科学》385,313 - 318(1997年)]。基于张力的形态发生(TBM)是一个概念上简单且通用的假说,它基于有助于塑造所有生物的物理力。此外,如果每个轴突和树突在保持连接性的同时努力缩短,那么总的布线长度将保持较低水平。TBM可以解释大脑和小脑皮质如何保持薄度、扩大表面积并形成其独特褶皱的关键方面。本文回顾了自1997年以来与TBM及其他候选形态发生机制相关的进展。在细胞水平上,对多种细胞类型在体外和体内的研究表明,张力在许多发育事件中起主要作用。在组织水平上,我针对大脑皮质扩张和折叠的原始TBM模型提出了一种差异扩张三明治加(DES +)修正模型。它涉及沿皮质外边缘的切向张力和“沟回拉链”力以及白质核心中的张力,这些力共同与皮质灰质中径向偏向的张力相互竞争。文中讨论了支持和反对DES +模型的证据,并提出了实验来验证DES +模型的关键原则。对于小脑皮质,提出了一种小脑多层三明治(CMS)模型,该模型可以解释许多独特特征,包括其在成体中独特的手风琴样折叠,并提出了实验来验证其具体原则。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/49a8/7780001/d215cf5a91c8/pnas.2016830117fig08.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/49a8/7780001/d215cf5a91c8/pnas.2016830117fig08.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/49a8/7780001/5187f97706d2/pnas.2016830117fig02.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/49a8/7780001/d215cf5a91c8/pnas.2016830117fig08.jpg

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