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短杆菌肽通道中的水运输及离子-水相互作用

Water transport and ion-water interaction in the gramicidin channel.

作者信息

Dani J A, Levitt D G

出版信息

Biophys J. 1981 Aug;35(2):501-8. doi: 10.1016/S0006-3495(81)84805-9.

DOI:10.1016/S0006-3495(81)84805-9
PMID:6168311
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1327538/
Abstract

The diffuse permeability and the diffusion coefficient of water (Dw) in the gramicidin channel is determined from the osmotic water permeability of the channel and "single file" pore theory. Dw is about 7% of the self-diffusion coefficient of bulk water. The diffusion coefficient of a single water molecule alone in the channel is also determined and is about equal to the value in bulk water. This provides an estimate of the mobility of water on the channel walls in the absence of water-water interaction. Since the gramicidin channel walls should be representative of uncharged polar protein surfaces, this result provides direct evidence that the presence of a cation in the channel reduces the hydraulic water permeability by a factor ranging from 60 for Tl+ to 5 for Na+. The diffusion coefficient of a cation (Dc) in the channel is estimated and compared with Dw. For Na+ it is found that Dc approximately equal to Dw, which implies that the movement of the row of water molecules through the channel determines the local mobility of Na+. Thus, it seems that short range ion-wall interactions are not important in determining the channel conductance for Na+. In contrast, for Li+, local ion-wall interactions probably do limit the conductance.

摘要

通过通道的渗透水渗透率和“单列”孔隙理论来确定短杆菌肽通道中水分子的扩散渗透率和扩散系数(Dw)。Dw约为体相水自扩散系数的7%。还测定了单个水分子在通道中的扩散系数,其值与体相水中的大致相等。这给出了在不存在水分子间相互作用的情况下,水分子在通道壁上迁移率的一个估计值。由于短杆菌肽通道壁应代表不带电的极性蛋白质表面,这一结果提供了直接证据,表明通道中阳离子的存在会使水力水渗透率降低,降低系数在Tl⁺时为60至Na⁺时为5之间。估计了通道中阳离子的扩散系数(Dc)并与Dw进行比较。对于Na⁺,发现Dc大致等于Dw,这意味着一排水分子通过通道的移动决定了Na⁺的局部迁移率。因此,似乎短程离子-壁相互作用在决定Na⁺的通道电导率方面并不重要。相比之下,对于Li⁺,局部离子-壁相互作用可能确实限制了电导率。

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本文引用的文献

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The gramicidin A channel: a review of its permeability characteristics with special reference to the single-file aspect of transport.短杆菌肽A通道:对其通透性特征的综述,特别提及转运的单排方面。
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