缺氧生存:两个白质束的故事。

Selva Baltan
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引用次数: 14

摘要

成功的轴突功能对中枢神经系统(CNS)的整体性能至关重要。白质(WM)轴突依赖于持续的氧气和葡萄糖供应来传输高保真的信号。视神经是由完全有髓鞘的轴突组成的纯WM束,而胼胝体(CC)切片包含脑灰质和WM部分,混合有髓鞘和无髓鞘轴突。两个WM束中的轴突功能对缺氧具有抗性,其中一部分轴突能够完全依靠糖酵解产生的能量存活。在小鼠视神经(MONs)中,缺氧时葡萄糖的去除会导致轴突功能的完全丧失,这意味着葡萄糖是唯一的能量来源。相比之下,在大鼠视神经(RON)中,缺氧会导致快速和完全的功能丧失。由于RON直径约为MON的两倍,缺氧时葡萄糖扩散不足。增加葡萄糖浓度可以恢复RON轴突在缺氧时的持续能力。虽然在10毫米葡萄糖中,蒙斯和CC片表现出相同的耐缺氧性,但30毫米葡萄糖揭示了CC轴突更大的耐缺氧性,这表明无髓鞘轴突和/或具有最薄髓鞘的最小轴突具有耐缺氧性。这些结果表明,尽管中枢神经系统WM的功能和生存能力存在区域差异,但它们对缺氧具有显著的耐受性。为了在各种神经系统疾病中实现对中枢神经系统的最佳保护,了解区域能量代谢的特性和损伤机制对于成功的治疗方法至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Surviving anoxia: a tale of two white matter tracts.

Successful axon function is vital to the overall performance of the central nervous system (CNS). White matter (WM) axons are dependent on constant supply of oxygen and glucose to transmit signals with high fidelity. The optic nerve is a pure WM tract composed of completely myelinated axons while corpus callosum (CC) slices contain both gray and WM portions of the brain with a mixture of myelinated and unmyelinated axons. Axon function in both WM tracts is resistant to anoxia with a subset of axons able to survive exclusively on energy generated by glycolysis. In mouse optic nerves (MONs), removal of glucose during anoxia causes complete loss of axon function, implicating glucose as the sole source of energy. In contrast, in rat optic nerve (RON), anoxia causes rapid and complete loss of function. Because RON is about twice the diameter of MON, glucose diffusion during anoxia is inadequate. Increasing bath glucose concentration restores the ability of RON axons to persist during anoxia. Although in 10 mM glucose, MONs and CC slices exhibit identical resistance to anoxia, 30 mM glucose unmasks the greater resistance of CC axons suggesting unmyelinated axons and/or the smallest axons with the thinnest myelin sheath are resistant to anoxia. These results reveal that CNS WM is remarkably tolerant of anoxia although there is regional variability in their ability to function and survive anoxia. To achieve optimal protection of the CNS in various neurological diseases, it is critical to understand the properties of regional energy metabolisms and injury mechanisms for successful therapeutic approaches.

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