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哺乳动物内耳前庭感觉器官的发育与进化。

Development and evolution of the vestibular sensory apparatus of the mammalian ear.

作者信息

Beisel Kirk W, Wang-Lundberg Yesha, Maklad Adel, Fritzsch Bernd

机构信息

Creighton University, Omaha, NE and BTNRH, Omaha, NE 68178, USA.

出版信息

J Vestib Res. 2005;15(5-6):225-41.

Abstract

Herein, we will review molecular aspects of vestibular ear development and present them in the context of evolutionary changes and hair cell regeneration. Several genes guide the development of anterior and posterior canals. Although some of these genes are also important for horizontal canal development, this canal strongly depends on a single gene, Otx1. Otx1 also governs the segregation of saccule and utricle. Several genes are essential for otoconia and cupula formation, but protein interactions necessary to form and maintain otoconia or a cupula are not yet understood. Nerve fiber guidance to specific vestibular end-organs is predominantly mediated by diffusible neurotrophic factors that work even in the absence of differentiated hair cells. Neurotrophins, in particular Bdnf, are the most crucial attractive factor released by hair cells. If Bdnf is misexpressed, fibers can be redirected away from hair cells. Hair cell differentiation is mediated by Atoh1. However, Atoh1 may not initiate hair cell precursor formation. Resolving the role of Atoh1 in postmitotic hair cell precursors is crucial for future attempts in hair cell regeneration. Additional analyses are needed before gene therapy can help regenerate hair cells, restore otoconia, and reconnect sensory epithelia to the brain.

摘要

在此,我们将回顾内耳前庭发育的分子层面,并结合进化变化和毛细胞再生的背景进行阐述。有几个基因指导前后半规管的发育。尽管其中一些基因对水平半规管的发育也很重要,但该半规管强烈依赖于单个基因Otx1。Otx1还控制球囊和椭圆囊的分离。有几个基因对耳石和壶腹嵴的形成至关重要,但形成和维持耳石或壶腹嵴所需的蛋白质相互作用尚不清楚。神经纤维向特定前庭终器的导向主要由可扩散的神经营养因子介导,这些因子即使在没有分化的毛细胞的情况下也能发挥作用。神经营养蛋白,特别是脑源性神经营养因子(Bdnf),是毛细胞释放的最关键的吸引因子。如果Bdnf表达错误,纤维可以被重新导向远离毛细胞的方向。毛细胞的分化由Atoh1介导。然而,Atoh1可能不会启动毛细胞前体的形成。解决Atoh1在有丝分裂后毛细胞前体中的作用对于未来毛细胞再生的尝试至关重要。在基因治疗能够帮助再生毛细胞、恢复耳石并使感觉上皮与大脑重新连接之前,还需要进行更多分析。

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