De Wolf I, Van Driessche W
Am J Physiol. 1986 Nov;251(5 Pt 1):C696-706. doi: 10.1152/ajpcell.1986.251.5.C696.
The characteristics of the blockage of apical K+ channels in the frog skin (Rana temporaria) by Ba2+ were investigated with current-voltage measurements and current-fluctuation analysis. Inward K+ currents were recorded with a transepithelial K+ concentration gradient oriented from mucosa to serosa. When Ba2+ (5-10,000 microM) was added to the mucosal solution, the inward K+ current was progressively depressed. This blockage was strongly voltage dependent. The apparent macroscopic Michaelis-Menten constant decreased exponentially with increasing transepithelial voltage (Vt) (mucosa positive). According to Eyring rate theory, the binding site for the Ba2+ ion in the K+ channel was found to be located at a relative electrical distance of 0.72 of the apical membrane potential field, measured from the cytosolic side. From current-voltage (I-V) measurements and Michaelis-Menten kinetics, the Ba2+ dissociation constant was calculated: KBa = 57 microM (Vt = 0 mV). The voltage dependence of the on- and off-rate of the Ba2+-receptor interaction was obtained from the analysis of current fluctuations induced by Ba2+. An exponential relationship between the rates and Vt was obtained, as was found for KBa from the I-V measurements. KBa (at Vt = 0 mV) calculated from the noise experiments was 66 microM.
通过电流-电压测量和电流涨落分析,研究了Ba2+对蛙皮(林蛙)顶端K+通道的阻断特性。在黏膜到浆膜存在跨上皮K+浓度梯度的情况下记录内向K+电流。当向黏膜溶液中加入Ba2+(5 - 10000微摩尔)时,内向K+电流逐渐降低。这种阻断强烈依赖于电压。表观宏观米氏常数随着跨上皮电压(Vt,黏膜为正)的增加呈指数下降。根据艾林速率理论,发现K+通道中Ba2+离子的结合位点位于从胞质侧测量的顶端膜电位场相对电距离0.72处。通过电流-电压(I-V)测量和米氏动力学计算出Ba2+解离常数:KBa = 57微摩尔(Vt = 0毫伏)。通过分析由Ba2+诱导的电流涨落,得到了Ba2+ - 受体相互作用的开启和关闭速率的电压依赖性。速率与Vt之间呈指数关系,这与从I-V测量中得到的KBa情况相同。从噪声实验计算出的KBa(Vt = 0毫伏时)为66微摩尔。
