内阻阴离子及其平均价和渗透性电荷不对称性

A. Dmitriev, R. Linsenmeier
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摘要

背景/目的:多年来,对控制活细胞跨膜电位及其体积的过程的实验和理论研究主要集中在离子上,首先是Na+, K+和Cl-,这些离子可以通过各种主动和被动机制进出细胞。但最近越来越多的注意力转向了内部不含阴离子(Xz-)——一个由许多非常不同的分子组成的复杂实体。内部不含阴离子最有趣的特征是它的数量,重要的是,它的平均价可以在细胞的代谢活动中改变。本文的目的是通过计算研究内部负离子的数量和均价的变化如何影响主要离子的浓度、膜电位和细胞体积。方法:采用前面所述的电荷差模型进行计算分析。结果和结论:计算模拟的结果证实了先前的结果,即如果z保持不变,Xz-的量的变化只影响细胞体积,尽管浓度和Em会发生短暂的干扰,其程度取决于Xz-变化的速度。z的变化有更严重的后果。|的降低导致阳离子([K+]i和[Na+]i)浓度的降低,阴离子([Cl-] i和[Xz-]i)浓度的增加,并导致细胞膜的去极化;|和|的增加会导致相反方向的变化。有趣的是,即使在Xz-保持不变的情况下,以Em变化表达的正常电生理活动也会影响[Cl-]i,从而影响[Xz-]i(由于体积变化),从而诱导阳离子浓度和Em的反馈效应。因此,Xz-被视为渗透压-电荷不对称这一更广泛概念的重要组成部分,但不是唯一组成部分。讨论了决定Xz-与离子浓度、Em和细胞体积之间相互关系的基本物理原因。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Internal Impermeant Anion, Its Mean Valence and Osmolarity-Charge Asymmetry
Background/Aims: For many years experimental and theoretical studies of the processes controlling the transmembrane potential of living cells and their volume were focused on ions, first of all Na+, K+, and Cl-, that can be moved in and out of the cell by various active and passive mechanisms. But recently more and more attention has been directed toward the internal impermeant anion (Xz-) – a complex entity that is comprised of many very different molecules. The most intriguing feature of the internal impermeant anion is that its amount and, importantly, its mean valence can be changed during the metabolic activity of the cell. The aim of this paper is to computationally investigate how changes in the amount and the mean valence of the internalimpermeant anion influence the concentration of the main ions, the membrane potential, and the cell volume. Methods: The computational analyses were performed using our charge-difference model describe earlier. Results and Conclusion: The results of computational simulations confirm previous results that changes in the amount of Xz- influence nothing but the cell volume if z remains constant, although transient disturbances of concentrations and Em happen and their extent depends on the speed of Xz- changes. Changes of z have more serious consequences. A decrease of |z| leads to a decrease of concentrations of cations ([K+]i and [Na+]i), to an increase of the concentrations of anions ([Cl-]I and [Xz-]i), and to depolarization of the cell membrane; an increase of |z| leads to changes in the opposite directions. Interestingly, even in conditions when Xz- remains unchanged, the normal electrophysiological activity expressed in changes of Em will affect [Cl-]i and consequently [Xz-]i (due to volume changes), inducing feedback effects on the cation concentrations and Em. Accordingly, Xz- is viewed as an important but not the only component of a broader concept of osmolarity-charge asymmetry. The basic physical reasons that determine the interrelations between Xz- on one hand and ionic concentrations, Em, and the cell volume on the other hand are discussed.
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