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线粒体蛋白酶AFG3L2对轴突发育至关重要。

The mitochondrial protease AFG3L2 is essential for axonal development.

作者信息

Maltecca Francesca, Aghaie Asadollah, Schroeder David G, Cassina Laura, Taylor Benjamin A, Phillips Sandra J, Malaguti Mariachiara, Previtali Stefano, Guénet Jean-Louis, Quattrini Angelo, Cox Gregory A, Casari Giorgio

机构信息

Human Molecular Genetics Unit, and Neuropathology Unit and Istituto di Neurologia Sperimentale, San Raffaele Scientific Institute, 20132 Milan, Italy.

出版信息

J Neurosci. 2008 Mar 12;28(11):2827-36. doi: 10.1523/JNEUROSCI.4677-07.2008.

DOI:10.1523/JNEUROSCI.4677-07.2008
PMID:18337413
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6670688/
Abstract

The mitochondrial metalloprotease AFG3L2 assembles with the homologous protein paraplegin to form a supracomplex in charge of the essential protein quality control within mitochondria. Mutations of paraplegin cause a specific axonal degeneration of the upper motoneuron and, therefore, hereditary spastic paraplegia. Here we present two Afg3l2 murine models: a newly developed null and a spontaneous mutant that we found carrier of a missense mutation. Contrasting with the mild and late onset axonal degeneration of paraplegin-deficient mouse, Afg3l2 models display a marked impairment of axonal development with delayed myelination and poor axonal radial growth leading to lethality at P16. The increased severity of the Afg3l2 mutants is explained by two main molecular features that differentiate AFG3L2 from paraplegin: its higher neuronal expression and its versatile ability to support both hetero-oligomerization and homo-oligomerization. Our data assign to AFG3L2 a crucial role by linking mitochondrial metabolism and axonal development. Moreover, we propose AFG3L2 as an excellent candidate for motoneuron and cerebellar diseases with early onset unknown etiology.

摘要

线粒体金属蛋白酶AFG3L2与同源蛋白痉挛性截瘫蛋白组装形成一个超复合物,负责线粒体中至关重要的蛋白质质量控制。痉挛性截瘫蛋白的突变会导致上运动神经元发生特定的轴突变性,进而引发遗传性痉挛性截瘫。在此,我们展示两种Afg3l2小鼠模型:一种新构建的基因敲除模型和一个我们发现携带错义突变的自发突变体。与痉挛性截瘫蛋白缺陷小鼠轻微且迟发性的轴突变性不同,Afg3l2模型表现出轴突发育的显著受损,伴有髓鞘形成延迟和轴突径向生长不良,导致在出生后第16天死亡。Afg3l2突变体严重程度增加可由区分AFG3L2与痉挛性截瘫蛋白的两个主要分子特征来解释:其在神经元中的更高表达以及支持异源寡聚化和同源寡聚化的多种能力。我们的数据通过将线粒体代谢与轴突发育联系起来,赋予AFG3L2一个关键作用。此外,我们提出AFG3L2是病因不明的早发性运动神经元和小脑疾病的一个极佳候选因素。

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