脑膜视黄酸在小鼠大脑发育过程中有助于新皮质分层和放射状迁移。

Meningeal retinoic acid contributes to neocortical lamination and radial migration during mouse brain development.

作者信息

Haushalter Carole, Schuhbaur Brigitte, Dollé Pascal, Rhinn Muriel

机构信息

Development and Stem Cells Department, Institut de Génétique et de Biologie Moléculaire et Cellulaire, Illkirch 67404, France.

Centre National de la Recherche Scientifique, UMR 7104, Illkirch 67404, France.

出版信息

Biol Open. 2017 Feb 15;6(2):148-160. doi: 10.1242/bio.021063.

DOI:10.1242/bio.021063

PMID:28011626

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5312094/

Abstract

Retinoic acid (RA) is a diffusible molecule involved in early forebrain patterning. Its later production in the meninges by the retinaldehyde dehydrogenase RALDH2 coincides with the time of cortical neuron generation. A function of RA in this process has not been adressed directly as mouse mutants are embryonic lethal. Here, we used a conditional genetic strategy to inactivate just prior to onset of its expression in the developing meninges. This inactivation does not affect the formation of the cortical progenitor populations, their rate of division, or timing of differentiation. However, migration of late-born cortical neurons is delayed, with neurons stalling in the intermediate zone and exhibiting an abnormal multipolar morphology. This suggests that RA controls the multipolar-to-bipolar transition that occurs in the intermediate zone and allows neurons to start locomotion in the cortical plate. Our work also shows a role for RA in cortical lamination, as deep layers are expanded and a subset of layer IV neurons are not formed in the -ablated mutants. These data demonstrate that meninges are a source of extrinsic signals important for cortical development.

摘要

视黄酸（RA）是一种参与早期前脑模式形成的可扩散分子。其随后由视网膜醛脱氢酶RALDH2在脑膜中产生的时间与皮质神经元生成的时间一致。由于小鼠突变体在胚胎期致死，RA在此过程中的功能尚未得到直接研究。在这里，我们使用条件性遗传策略，在其于发育中的脑膜中表达开始之前将其失活。这种失活并不影响皮质祖细胞群体的形成、它们的分裂速率或分化时间。然而，晚期生成的皮质神经元的迁移被延迟，神经元滞留在中间区并表现出异常的多极形态。这表明RA控制着在中间区发生的多极到双极的转变，并使神经元能够在皮质板中开始移动。我们的研究还表明RA在皮质分层中起作用，因为在RA缺失的突变体中，深层扩大且IV层的一部分神经元未形成。这些数据表明，脑膜是对皮质发育很重要的外在信号的来源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4884/5312094/5d5547bdb9ae/biolopen-6-021063-g1.jpg

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脑膜视黄酸在小鼠大脑发育过程中有助于新皮质分层和放射状迁移。

Meningeal retinoic acid contributes to neocortical lamination and radial migration during mouse brain development.

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