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鸡胚中菱脑节3诱导面旁节律发生器的形成。

Induction of a parafacial rhythm generator by rhombomere 3 in the chick embryo.

作者信息

Coutinho Ana P, Borday Caroline, Gilthorpe Jonathan, Jungbluth Stefan, Champagnat Jean, Lumsden Andrew, Fortin Gilles

机构信息

Medical Research Council Centre for Developmental Neurobiology, King's College London, Guy's Campus, London SE1 1UL, United Kingdom.

出版信息

J Neurosci. 2004 Oct 20;24(42):9383-90. doi: 10.1523/JNEUROSCI.2408-04.2004.

DOI:10.1523/JNEUROSCI.2408-04.2004

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6730091/

Abstract

Observations of knock-out mice suggest that breathing at birth requires correct development of a specific hindbrain territory corresponding to rhombomeres (r) 3 and 4. Focusing on this territory, we examined the development of a neuronal rhythm generator in the chick embryo. We show that rhythmic activity in r4 is inducible after developmental stage 10 through interaction with r3. Although the nature of this interaction remains obscure, we find that the expression of Krox20, a segmentation gene responsible for specifying r3 and r5, is sufficient to endow other rhombomeres with the capacity to induce rhythmic activity in r4. Induction is robust, because it can be reproduced with r2 and r6 instead of r4 and with any hindbrain territory that normally expresses Krox20 (r3, r5) or can be forced to do so (r1, r4). Interestingly, the interaction between r4 and r3/r5 that results in rhythm production can only take place through the anterior border of r4, revealing a heretofore unsuspected polarity in individual rhombomeres. The r4 rhythm generator appears to be homologous to a murine respiratory parafacial neuronal system developing in r4 under the control of Krox20 and Hoxa1. These results identify a late role for Krox20 at the onset of neurogenesis.

摘要

对基因敲除小鼠的观察表明，出生时的呼吸需要后脑特定区域（对应于菱脑节（r）3和4）的正确发育。聚焦于该区域，我们研究了鸡胚中神经元节律发生器的发育。我们发现，在发育阶段10之后，通过与r3相互作用，r4中的节律性活动是可诱导的。尽管这种相互作用的本质仍不清楚，但我们发现，负责指定r3和r5的分割基因Krox20的表达足以赋予其他菱脑节诱导r4中节律性活动的能力。诱导作用很强，因为用r2和r6代替r4，以及用任何正常表达Krox20（r3、r5）或可被强制表达Krox20（r1、r4）的后脑区域都能重现这种诱导作用。有趣的是，导致节律产生的r4与r3/r5之间的相互作用只能通过r4的前缘发生，这揭示了单个菱脑节中一种前所未有的极性。r4节律发生器似乎与在Krox20和Hoxa1控制下于r4中发育的小鼠呼吸旁面神经神经元系统同源。这些结果确定了Krox20在神经发生开始时的后期作用。