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神经调节蛋白-4 对于维持运动皮层锥体神经元胞体大小是必需的。

Neuregulin-4 Is Required for Maintaining Soma Size of Pyramidal Neurons in the Motor Cortex.

机构信息

School of Biosciences, Cardiff University, Cardiff CF10 3AX, Wales

School of Biosciences, Cardiff University, Cardiff CF10 3AX, Wales.

出版信息

eNeuro. 2021 Feb 25;8(1). doi: 10.1523/ENEURO.0288-20.2021. Print 2021 Jan-Feb.

DOI:10.1523/ENEURO.0288-20.2021
PMID:33495243
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8114872/
Abstract

The regulation of neuronal soma size is essential for appropriate brain circuit function and its dysregulation is associated with several neurodevelopmental disorders. A defect in the dendritic growth and elaboration of motor neocortical pyramidal neurons in neonates lacking neuregulin-4 (NRG4) has previously been reported. In this study, we investigated whether the loss of NRG4 causes further morphologic defects that are specific to these neurons. We analyzed the soma size of pyramidal neurons of layer (L)2/3 and L5 of the motor cortex and a subpopulation of multipolar interneurons in this neocortical region in and mice. There were significant decreases in pyramidal neuron soma size in mice compared with littermates at all stages studied [postnatal day (P)10, P30, and P60]. The reduction was especially marked at P10 and in L5 pyramidal neurons. Soma size was not significantly different for multipolar interneurons at any age. This phenotype was replicated in pyramidal neurons cultured from mice and was rescued by NRG treatment. Analysis of a public single-cell RNA sequencing repository revealed discrete and expression in subpopulations of L5 pyramidal neurons, suggesting that the observed defects were due in part to loss of autocrine Nrg4/ErbB4 signaling. The pyramidal phenotype in the motor cortex of mice was associated with a lack of Rotarod test improvement in P60 mice, suggesting that absence of NRG4 causes alterations in motor performance.

摘要

神经元胞体大小的调节对于适当的大脑回路功能至关重要,其失调与几种神经发育障碍有关。先前已经报道过,缺乏神经调节蛋白 4(NRG4)的新生鼠的运动新皮层锥体神经元的树突生长和细化存在缺陷。在这项研究中,我们研究了 NRG4 的缺失是否会导致这些神经元特有的进一步形态缺陷。我们分析了运动皮层的 L2/3 和 L5 层以及该新皮层区域中多极中间神经元的锥体神经元的胞体大小。与 同窝仔相比, 鼠的锥体神经元胞体大小在所有研究阶段[出生后第 10 天(P10)、P30 和 P60]均显著减小。在 P10 和 L5 锥体神经元中,减少尤为明显。在任何年龄,多极中间神经元的胞体大小均无显著差异。这种表型在 鼠培养的锥体神经元中得到了复制,并通过 NRG 处理得到了挽救。对公共单细胞 RNA 测序库的分析显示,L5 锥体神经元的亚群中存在离散的 和 表达,表明观察到的缺陷部分归因于自分泌 Nrg4/ErbB4 信号的缺失。 鼠运动皮层中的锥体表型与 P60 鼠在旋转棒测试中改善不足有关,这表明 NRG4 的缺失会导致运动表现的改变。

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