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RPM-1通过影响生长锥塌陷和微管稳定性来调节轴突终末。

RPM-1 regulates axon termination by affecting growth cone collapse and microtubule stability.

作者信息

Borgen Melissa A, Wang Dandan, Grill Brock

机构信息

Department of Neuroscience, The Scripps Research Institute, Scripps Florida, Jupiter, FL 33458, USA.

Department of Neuroscience, The Scripps Research Institute, Scripps Florida, Jupiter, FL 33458, USA

出版信息

Development. 2017 Dec 15;144(24):4658-4672. doi: 10.1242/dev.154187. Epub 2017 Oct 30.

DOI:10.1242/dev.154187
PMID:29084805
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5769622/
Abstract

Axon termination is essential for efficient and accurate nervous system construction. At present, relatively little is known about how growth cone collapse occurs prior to axon termination Using the mechanosensory neurons of , we found collapse prior to axon termination is protracted, with the growth cone transitioning from a dynamic to a static state. Growth cone collapse prior to termination is facilitated by the signaling hub RPM-1. Given the prominence of the cytoskeleton in growth cone collapse, we assessed the relationship between RPM-1 and regulators of actin dynamics and microtubule stability. Our results reveal several important findings about how axon termination is orchestrated: (1) RPM-1 functions in parallel to RHO-1 and CRMP/UNC-33, but is suppressed by the Rac isoform MIG-2; (2) RPM-1 opposes the function of microtubule stabilizers, including tubulin acetyltransferases; and (3) genetic epistasis suggests the microtubule-stabilizing protein Tau/PTL-1 potentially inhibits RPM-1. These findings provide insight into how growth cone collapse is regulated during axon termination , and suggest that RPM-1 signaling destabilizes microtubules to facilitate growth cone collapse and axon termination.

摘要

轴突终末对于高效且精确的神经系统构建至关重要。目前,对于轴突终末之前生长锥如何发生塌陷了解相对较少。利用[某种生物]的机械感觉神经元,我们发现轴突终末之前的塌陷过程是持久的,生长锥从动态状态转变为静态状态。终止前的生长锥塌陷由信号枢纽RPM-1促进。鉴于细胞骨架在生长锥塌陷中的重要性,我们评估了RPM-1与肌动蛋白动力学调节因子和微管稳定性之间的关系。我们的结果揭示了关于轴突终末如何被精心调控的几个重要发现:(1)RPM-1与RHO-1和CRMP/UNC-33并行发挥作用,但被Rac亚型MIG-2抑制;(2)RPM-1对抗微管稳定剂的功能,包括微管蛋白乙酰转移酶;(3)遗传上位性表明微管稳定蛋白Tau/PTL-1可能抑制RPM-1。这些发现为轴突终末期间生长锥塌陷如何被调节提供了见解,并表明RPM-1信号通路使微管不稳定以促进生长锥塌陷和轴突终末。

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