科尔-摩尔效应：仍无法解释？

The Cole-Moore Effect: Still Unexplained?

作者信息

Hoshi Toshinori, Armstrong Clay M

机构信息

Department of Physiology, University of Pennsylvania, Philadelphia, Pennsylvania.

出版信息

Biophys J. 2015 Oct 6;109(7):1312-6. doi: 10.1016/j.bpj.2015.07.052.

DOI:10.1016/j.bpj.2015.07.052

PMID:26445430

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4601067/

Abstract

In the first issue, on the first page of the Biophysical Journal in 1960, Cole and Moore provided the first confirmation of the Hodgkin and Huxley formulation of the sodium and potassium conductances that underlie the action potential. In addition, working with the squid giant axon, Cole and Moore noted that strong hyperpolarization preceding a depolarizing voltage-clamp pulse delayed the rise of the potassium conductance: once started, the time course of the rise was always the same but after significant hyperpolarization there was a long lag before the rise began. This phenomenon has come to be known as the Cole-Moore effect. Their article examines and disproves the hypothesis that the lag reflects the time required to refill the membrane with potassium ions after the ions are swept out of the membrane into the axoplasm by hyperpolarization. The work by Cole and Moore indirectly supports the idea of a membrane channel for potassium conductance. However, the mechanism of the Cole-Moore effect remains a mystery even now, buried in the structure of the potassium channel, which was completely unknown at the time.

摘要

1960年，在《生物物理杂志》的第一期第一页上，科尔和摩尔首次证实了霍奇金和赫胥黎提出的构成动作电位基础的钠电导和钾电导理论。此外，通过对鱿鱼巨轴突的研究，科尔和摩尔指出，在去极化电压钳制脉冲之前的强超极化会延迟钾电导的上升：一旦开始，上升的时间进程总是相同的，但在显著超极化之后，上升开始前会有很长的延迟。这种现象后来被称为科尔 - 摩尔效应。他们的文章研究并否定了这样一种假设，即这种延迟反映了钾离子在被超极化作用从膜中扫入轴浆后，重新填充膜所需的时间。科尔和摩尔的工作间接支持了钾电导膜通道的观点。然而，即使在现在，科尔 - 摩尔效应的机制仍然是个谜，它隐藏在当时完全未知的钾通道结构中。

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