在无钾培养基灌注的鱿鱼轴突中钾离子通透性和门控电流的存活情况。
Survival of K+ permeability and gating currents in squid axons perfused with K+-free media.
作者信息
Almers W, Armstrong C M
出版信息
J Gen Physiol. 1980 Jan;75(1):61-78. doi: 10.1085/jgp.75.1.61.
Abstract
K+ currents were recorded in squid axons internally perfused with impermeant electrolyte. Total absence of permeant ions inside and out leads to an irreversible loss of potassium conductance with a time constant of approximately 11 min at 8 degrees C. Potassium channels can be protected against this effect by external K+, Cs+, NH4+, and Rb+ at concentrations of 100-440 mM. These experiments suggest that a K+ channel is normally occupied by one or more small cations, and becomes nonfunctional when these cations are removed. A large charge movement said to be related to K+ channel gating in frog skeletal muscle is absent in squid giant axons. However, deliberate destruction of K+ conductance by removal of permeant cations is accompanied by measurable loss in asymmetric charge movement. This missing charge component is large enough to contain a contribution from K+ gating charge movements of more than five elementary charges per channel.
摘要
在内部灌注非渗透性电解质的乌贼轴突中记录钾离子电流。内外完全没有渗透性离子会导致钾离子电导不可逆丧失,在8摄氏度时时间常数约为11分钟。钾离子通道可以通过浓度为100 - 440 mM的外部钾离子、铯离子、铵离子和铷离子来防止这种效应。这些实验表明,钾离子通道通常被一个或多个小阳离子占据,当这些阳离子被去除时通道就会失去功能。乌贼巨大轴突中不存在据说与青蛙骨骼肌钾离子通道门控有关的大量电荷移动。然而,通过去除渗透性阳离子故意破坏钾离子电导会伴随着不对称电荷移动的可测量损失。这种缺失的电荷成分足够大,足以包含每个通道超过五个基本电荷的钾离子门控电荷移动的贡献。
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