collier/Olf/Ebf (COE)型转录因子在轴向运动神经元发育中的古老作用

IF 4 3区 生物学 Q1 DEVELOPMENTAL BIOLOGY
Catarina Catela, Edgar Correa, Kailong Wen, Jihad Aburas, Laura Croci, G Giacomo Consalez, Paschalis Kratsios
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引用次数: 17

摘要

背景:哺乳动物运动回路显示出显著的细胞多样性,数百种运动神经元(MN)亚型支配着数百种不同的肌肉。对肢体肌肉神经支配的MNs的广泛研究已经开始阐明控制动物运动的遗传程序。与之形成鲜明对比的是,对控制呼吸和脊柱排列的轴向肌肉神经支配的分子机制研究甚少。方法:我们之前的研究表明,Collier/Olf/Ebf (COE)家族转录因子(TFs)在轴向MN发育中的功能可能从线虫到简单脊索动物都是保守的。在这里,我们研究了所有四个小鼠COE家族成员(mEbf1-mEbf4)在脊柱MN中的表达模式,并采用线虫和小鼠的遗传方法来研究它们在轴向MN发育中的功能。结果:我们报道了mEbf1和mEbf2在支配不同轴向肌肉的不同MN簇(称为“柱”)中表达。小鼠Ebf1表达在呼吸所必需的下轴运动柱(HMC)的MNs中,而mEbf2表达在控制脊柱对齐的内侧运动柱(MMC)的MNs中。我们对Ebf2敲除小鼠的表征揭示了MMC MNs子集分化程序中对Ebf2的需求,并首次揭示了MMC神经元内的分子多样性。有趣的是,mEbf1或mEbf2的转基因表达可以挽救缺乏unc-3的秀丽隐杆线虫(Caenorhabditis elegans)的轴向MN分化和运动缺陷,unc-3是秀丽隐杆线虫中唯一的COE家族同源物,这表明mEbf1、mEbf2和线虫unc-3之间的功能保守性。结论:这些发现支持了控制轴向MN发育的遗传程序在物种间高度保守的假设,并通过揭示Ebf2在小鼠轴向MN中的重要作用进一步推进了我们对这些程序的理解。由于人类COE同源基因的突变导致以运动发育迟缓为特征的神经发育障碍,我们的研究结果可能会促进我们对这些人类疾病的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

An ancient role for collier/Olf/Ebf (COE)-type transcription factors in axial motor neuron development.

An ancient role for collier/Olf/Ebf (COE)-type transcription factors in axial motor neuron development.

An ancient role for collier/Olf/Ebf (COE)-type transcription factors in axial motor neuron development.

An ancient role for collier/Olf/Ebf (COE)-type transcription factors in axial motor neuron development.

Background: Mammalian motor circuits display remarkable cellular diversity with hundreds of motor neuron (MN) subtypes innervating hundreds of different muscles. Extensive research on limb muscle-innervating MNs has begun to elucidate the genetic programs that control animal locomotion. In striking contrast, the molecular mechanisms underlying the development of axial muscle-innervating MNs, which control breathing and spinal alignment, are poorly studied.

Methods: Our previous studies indicated that the function of the Collier/Olf/Ebf (COE) family of transcription factors (TFs) in axial MN development may be conserved from nematodes to simple chordates. Here, we examine the expression pattern of all four mouse COE family members (mEbf1-mEbf4) in spinal MNs and employ genetic approaches in both nematodes and mice to investigate their function in axial MN development.

Results: We report that mEbf1 and mEbf2 are expressed in distinct MN clusters (termed "columns") that innervate different axial muscles. Mouse Ebf1 is expressed in MNs of the hypaxial motor column (HMC), which is necessary for breathing, while mEbf2 is expressed in MNs of the medial motor column (MMC) that control spinal alignment. Our characterization of Ebf2 knock-out mice uncovered a requirement for Ebf2 in the differentiation program of a subset of MMC MNs and revealed for the first time molecular diversity within MMC neurons. Intriguingly, transgenic expression of mEbf1 or mEbf2 can rescue axial MN differentiation and locomotory defects in nematodes (Caenorhabditis elegans) lacking unc-3, the sole C. elegans ortholog of the COE family, suggesting functional conservation among mEbf1, mEbf2 and nematode UNC-3.

Conclusions: These findings support the hypothesis that genetic programs controlling axial MN development are deeply conserved across species, and further advance our understanding of such programs by revealing an essential role for Ebf2 in mouse axial MNs. Because human mutations in COE orthologs lead to neurodevelopmental disorders characterized by motor developmental delay, our findings may advance our understanding of these human conditions.

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来源期刊
Neural Development
Neural Development 生物-发育生物学
CiteScore
6.60
自引率
0.00%
发文量
11
审稿时长
>12 weeks
期刊介绍: Neural Development is a peer-reviewed open access, online journal, which features studies that use molecular, cellular, physiological or behavioral methods to provide novel insights into the mechanisms that underlie the formation of the nervous system. Neural Development aims to discover how the nervous system arises and acquires the abilities to sense the world and control adaptive motor output. The field includes analysis of how progenitor cells form a nervous system during embryogenesis, and how the initially formed neural circuits are shaped by experience during early postnatal life. Some studies use well-established, genetically accessible model systems, but valuable insights are also obtained from less traditional models that provide behavioral or evolutionary insights.
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