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丝状伪足诱导调节剂Paralemmin-1是棘突成熟所必需的。

Paralemmin-1, a modulator of filopodia induction is required for spine maturation.

作者信息

Arstikaitis Pamela, Gauthier-Campbell Catherine, Carolina Gutierrez Herrera Rosario, Huang Kun, Levinson Joshua N, Murphy Timothy H, Kilimann Manfred W, Sala Carlo, Colicos Michael A, El-Husseini Alaa

机构信息

Department of Psychiatry and the Brain Research Centre, University of British Columbia, Vancouver, V6T 1Z3, Canada.

出版信息

Mol Biol Cell. 2008 May;19(5):2026-38. doi: 10.1091/mbc.e07-08-0802. Epub 2008 Feb 20.

DOI:10.1091/mbc.e07-08-0802
PMID:18287537
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2366842/
Abstract

Dendritic filopodia are thought to participate in neuronal contact formation and development of dendritic spines; however, molecules that regulate filopodia extension and their maturation to spines remain largely unknown. Here we identify paralemmin-1 as a regulator of filopodia induction and spine maturation. Paralemmin-1 localizes to dendritic membranes, and its ability to induce filopodia and recruit synaptic elements to contact sites requires protein acylation. Effects of paralemmin-1 on synapse maturation are modulated by alternative splicing that regulates spine formation and recruitment of AMPA-type glutamate receptors. Paralemmin-1 enrichment at the plasma membrane is subject to rapid changes in neuronal excitability, and this process controls neuronal activity-driven effects on protrusion expansion. Knockdown of paralemmin-1 in developing neurons reduces the number of filopodia and spines formed and diminishes the effects of Shank1b on the transformation of existing filopodia into spines. Our study identifies a key role for paralemmin-1 in spine maturation through modulation of filopodia induction.

摘要

树突丝状伪足被认为参与神经元接触的形成以及树突棘的发育;然而,调节丝状伪足延伸及其向棘成熟的分子仍 largely unknown。在这里,我们确定膜联蛋白-1 是丝状伪足诱导和棘成熟的调节因子。膜联蛋白-1 定位于树突膜,其诱导丝状伪足并将突触元件募集到接触位点的能力需要蛋白质酰化。膜联蛋白-1 对突触成熟的影响通过调节棘形成和 AMPA 型谷氨酸受体募集的可变剪接来调节。膜联蛋白-1 在质膜上的富集受神经元兴奋性的快速变化影响,并且这个过程控制神经元活动驱动的对突起扩张的影响。在发育中的神经元中敲低膜联蛋白-1 会减少形成的丝状伪足和棘的数量,并减弱 Shank1b 对将现有丝状伪足转化为棘的作用。我们的研究通过调节丝状伪足诱导确定了膜联蛋白-1 在棘成熟中的关键作用。

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