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鸭红细胞对高渗介质的反应。体积控制机制的进一步证据。

The response of duck erythrocytes to hypertonic media. Further evidence for a volume-controlling mechanism.

作者信息

Kregenow F M

出版信息

J Gen Physiol. 1971 Oct;58(4):396-412. doi: 10.1085/jgp.58.4.396.

DOI:10.1085/jgp.58.4.396
PMID:5112658
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2226033/
Abstract

The addition of a hypertonic bathing medium to duck erythrocytes results in an initial instantaneous phase of osmotic shrinkage and, when the K of the hypertonic solution is larger than "normal," in a second, more prolonged phase, the volume regulatory phase. During the latter, which also requires extracellular Na, the cells swell until they approach their initial isotonic volume. The increase in cell volume during the volume regulatory phase is accomplished by a gain in the cell content of K, Cl, and H(2)O. There is also a smaller increase in the Na content of the cell. Potassium is accumulated against an electrochemical gradient and is therefore actively transported into the cell. This accumulation is associated with an increase, although dissimilar, in both K influx and efflux. Changes in cell size during the volume regulatory phase are not altered by 10(-4)M ouabain, although this concentration of ouabain does change the cellular cation content. The response is independent of any effect of norepinephrine. The changes in cell size during the volume regulatory phase are discussed as the product of a volume controlling mechanism identical in principle to the one reported in the previous paper which controls cell volume in hypotonic media. Similarly, this mechanism can regulate cell size, when the Na-K exchange, ouabain-inhibitable pump mechanism is blocked.

摘要

向鸭红细胞中添加高渗性浴液会导致最初瞬间的渗透收缩阶段,并且当高渗溶液的K大于“正常”值时,会出现第二个更持久的阶段,即体积调节阶段。在后者阶段,这也需要细胞外的钠,细胞会膨胀直到接近其初始等渗体积。在体积调节阶段细胞体积的增加是通过细胞内K、Cl和H₂O含量的增加来实现的。细胞内的Na含量也有较小的增加。钾是逆着电化学梯度积累的,因此是被主动转运到细胞内的。这种积累与K的流入和流出的增加有关,尽管两者并不相同。在体积调节阶段细胞大小的变化不受10⁻⁴M哇巴因的影响,尽管这个浓度的哇巴因确实会改变细胞阳离子含量。这种反应与去甲肾上腺素的任何作用无关。体积调节阶段细胞大小的变化被认为是一种体积控制机制的产物,该机制原则上与前一篇论文中报道的在低渗介质中控制细胞体积的机制相同。同样,当钠钾交换、哇巴因抑制性泵机制被阻断时,这种机制可以调节细胞大小。

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