Rac-Mid1信号通路在小脑内侧发育中的新作用。

Novel role of Rac-Mid1 signaling in medial cerebellar development.

作者信息

Nakamura Takashi, Ueyama Takehiko, Ninoyu Yuzuru, Sakaguchi Hirofumi, Choijookhuu Narantsog, Hishikawa Yoshitaka, Kiyonari Hiroshi, Kohta Masaaki, Sakahara Mizuho, de Curtis Ivan, Kohmura Eiji, Hisa Yasuo, Aiba Atsu, Saito Naoaki

机构信息

Laboratory of Molecular Pharmacology, Biosignal Research Center, Kobe University, Kobe 657-8501, Japan.

Department of Otolaryngology-Head and Neck Surgery, Kyoto Prefectural University of Medicine, Kyoto 602-8566, Japan.

出版信息

Development. 2017 May 15;144(10):1863-1875. doi: 10.1242/dev.147900.

DOI:10.1242/dev.147900

PMID:28512198

Abstract

Rac signaling impacts a relatively large number of downstream targets; however, few studies have established an association between Rac pathways and pathological conditions. In the present study, we generated mice with double knockout of and ( ) in cerebellar granule neurons (CGNs). We observed impaired tangential migration at E16.5, as well as numerous apoptotic CGNs at the deepest layer of the external granule layer (EGL) in the medial cerebellum of mice at P8. CGNs differentiated normally until expression of p27 and NeuN in the deep EGL at P5. Primary CGNs and cerebellar microexplants from mice exhibited impaired neuritogenesis, which was more apparent in Map2-positive dendrites. Such findings suggest that impaired tangential migration and final differentiation of CGNs have resulted in decreased cerebellum size and agenesis of the medial internal granule layer, respectively. Furthermore, Rac depleted/deleted cells exhibited decreased levels of Mid1 and impaired mTORC1 signaling. depletion in CGNs produced mild impairments in neuritogenesis and reductions in mTORC1 signaling. Thus, a novel Rac-signaling pathway (Rac1-Mid1-mTORC1) may be involved in medial cerebellar development.

摘要

Rac信号传导影响相对大量的下游靶点；然而，很少有研究证实Rac信号通路与病理状况之间存在关联。在本研究中，我们构建了小脑颗粒神经元（CGNs）中Rac1和Rac3双敲除的小鼠。我们观察到在胚胎第16.5天（E16.5）时切向迁移受损，并且在出生后第8天（P8）的Rac1/3双敲除小鼠小脑中内侧外颗粒层（EGL）最深层有大量凋亡的CGNs。在P5时，CGNs在深层EGL中p27和NeuN表达之前分化正常。来自Rac1/3双敲除小鼠的原代CGNs和小脑微型植块表现出神经突形成受损，这在Map2阳性树突中更为明显。这些发现表明，CGNs的切向迁移受损和最终分化分别导致了小脑尺寸减小和内侧内颗粒层发育不全。此外，Rac缺失/敲除的细胞表现出Mid1水平降低和mTORC1信号传导受损。CGNs中Rac3缺失在神经突形成方面产生轻度损伤，并导致mTORC1信号传导减少。因此，一条新的Rac信号通路（Rac1-Mid1-mTORC1）可能参与了小脑内侧的发育。

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Rac-Mid1信号通路在小脑内侧发育中的新作用。

Novel role of Rac-Mid1 signaling in medial cerebellar development.

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