髓磷脂是什么?

Daniel K Hartline
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引用次数: 78

摘要

如果有相同角色的趋同出现的例子可供比较,就能更好地理解角色的进化。在无脊椎动物中已知的轴突鞘进化的三个实例具有脊椎动物髓鞘的功能特性和许多结构特性。这些无脊椎髓鞘的比较提出了一个问题,即鞘必须具有什么样的结构特征才能产生脉冲速度增强和能量节约这两个主要功能特征。本文综述了早期工作人员认识到的与脊椎动物和无脊椎动物髓磷脂有关的特征:亲锇性、负双折射和跳跃传导。然后,它检查了电子显微镜的出现所揭示的共同特征:脂质膜的多样性,这些膜的冷凝,特殊的边缘密封和淋巴结。接下来,它检查这些功能的稳健性作为一个速度增强护套的重要组成部分。对速度增强不完全必要的特征包括膜压实、层螺旋包裹、神经胶质细胞受累、轴突膜不活跃、甚至淋巴结和结周封闭。讨论了这种容许性与髓磷脂可能的进化起源的关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
What is myelin?

The evolution of a character is better appreciated if examples of convergent emergence of the same character are available for comparison. Three instances are known among invertebrates of the evolution of axonal sheaths possessing the functional properties and many of the structural properties of vertebrate myelin. Comparison of these invertebrate myelins raises the question of what structural features must a sheath possess in order to produce the two principal functional characteristics of impulse speed enhancement and energy savings. This essay reviews the features recognized by early workers as pertaining to myelin in vertebrate and invertebrate alike: osmiophilia, negative birefringence and saltatory conduction. It then examines common features revealed by the advent of electron microscopy: multiplicity of lipid membranes, condensation of those membranes, specialized marginal seals, and nodes. Next it examines the robustness of these features as essential components of a speed-enhancing sheath. Features that are not entirely essential for speed enhancement include membrane compaction, spiral wrapping of layers, glial cell involvement, non-active axonal membrane, and even nodes and perinodal sealing. This permissiveness is discussed in relation to the possible evolutionary origin of myelin.

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Neuron glia biology
Neuron glia biology 医学-神经科学
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