Myelin sheaths are formed with proteins that originated in vertebrate lineages.

Robert M Gould, Todd Oakley, Jared V Goldstone, Jason C Dugas, Scott T Brady, Alexander Gow
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引用次数: 29

Abstract

All vertebrate nervous systems, except those of agnathans, make extensive use of the myelinated fiber, a structure formed by coordinated interplay between neuronal axons and glial cells. Myelinated fibers, by enhancing the speed and efficiency of nerve cell communication allowed gnathostomes to evolve extensively, forming a broad range of diverse lifestyles in most habitable environments. The axon-covering myelin sheaths are structurally and biochemically novel as they contain high portions of lipid and a few prominent low molecular weight proteins often considered unique to myelin. Here we searched genome and EST databases to identify orthologs and paralogs of the following myelin-related proteins: (1) myelin basic protein (MBP), (2) myelin protein zero (MPZ, formerly P0), (3) proteolipid protein (PLP1, formerly PLP), (4) peripheral myelin protein-2 (PMP2, formerly P2), (5) peripheral myelin protein-22 (PMP22) and (6) stathmin-1 (STMN1). Although widely distributed in gnathostome/vertebrate genomes, neither MBP nor MPZ are present in any of nine invertebrate genomes examined. PLP1, which replaced MPZ in tetrapod CNS myelin sheaths, includes a novel 'tetrapod-specific' exon (see also Möbius et al., 2009). Like PLP1, PMP2 first appears in tetrapods and like PLP1 its origins can be traced to invertebrate paralogs. PMP22, with origins in agnathans, and STMN1 with origins in protostomes, existed well before the evolution of gnathostomes. The coordinated appearance of MBP and MPZ with myelin sheaths and of PLP1 with tetrapod CNS myelin suggests interdependence - new proteins giving rise to novel vertebrate structures.

髓鞘由起源于脊椎动物谱系的蛋白质形成。
所有脊椎动物的神经系统,除了巨蜥,都广泛使用髓鞘纤维,这是一种由神经元轴突和胶质细胞协调相互作用形成的结构。髓鞘纤维通过提高神经细胞通讯的速度和效率,使颌口动物得以广泛进化,在大多数可居住的环境中形成了广泛多样的生活方式。覆盖轴突的髓鞘在结构上和生化上都是新颖的,因为它们含有大量的脂质和一些通常被认为是髓鞘特有的突出的低分子量蛋白质。在这里,我们检索了基因组和EST数据库,以确定以下髓鞘相关蛋白的同源物和相似物:(1)髓鞘碱性蛋白(MBP),(2)髓鞘蛋白零(MPZ,以前的P0),(3)蛋白脂质蛋白(PLP1,以前的PLP),(4)外周髓鞘蛋白-2 (PMP2,以前的P2),(5)外周髓鞘蛋白-22 (PMP22)和(6)stthmin -1 (STMN1)。尽管MBP和MPZ广泛分布于啮齿动物/脊椎动物基因组中,但在所研究的9种无脊椎动物基因组中均未发现。PLP1取代了四足动物中枢神经系统髓鞘中的MPZ,包括一个新的“四足动物特异性”外显子(另见Möbius et al., 2009)。像PLP1一样,PMP2首先出现在四足动物中,像PLP1一样,它的起源可以追溯到无脊椎动物的同类。起源于颌口动物的PMP22和起源于原口动物的STMN1早在颌口动物进化之前就存在了。MBP和MPZ与髓鞘的协调出现以及PLP1与四足动物中枢神经系统髓鞘的协调出现表明相互依赖-新的蛋白质产生新的脊椎动物结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Neuron glia biology
Neuron glia biology 医学-神经科学
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