Sakmann B, Trube G
J Physiol. 1984 Feb;347:641-57. doi: 10.1113/jphysiol.1984.sp015088.
Single ventricular cells were enzymatically isolated from adult guinea-pig hearts (Isenberg & Klöckner, 1982). The patch-clamp technique (Hamill, Marty, Neher, Sakmann & Sigworth, 1981) was used to examine the conductance properties of an inward-rectifying K+ channel present in their sarcolemmal membrane. When the K+ concentration on the extracellular side of the patch was between 10.8 and 300 mM, inward current steps were observed at potentials more negative than the K+ equilibrium potential (EK). At more positive potentials no current steps were detectable, demonstrating the strong rectification of the channel. The zero-current potential extrapolated from the voltage dependence of the inward currents depends on the external K4 concentration [K+]o in a fashion expected for a predominantly K+-selective ion channel. It is shifted by 49 mV for a tenfold change in [K+]o. The conductance of the channel depends on the square root of [K+]o. In approximately symmetrical transmembrane K+ concentrations (145 mM-external K+), the single-channel conductance is 27 pS (at 19-23 degrees C). In normal Tyrode solution (5.4 mM-external K+) we calculate a single-channel conductance of 3.6 pS. The size of inward current steps at a fixed negative membrane potential V increases with [K+]o. The relation between step size and [K+]o shows saturation. Assuming a Michaelis-Menten scheme for binding of permeating K+ to the channel, an apparent binding constant of 210 mM is calculated for a membrane potential of -100 mV. For this potential the current at saturating [K+]o is estimated as 6.5 pA. The rectification of the single-channel conductance at membrane potentials positive to EK occurs within 1.5 ms of stepping the membrane potential from a potential of high conductance to one of low conductance. In addition to the main conductance state, the channel can adopt several substates of conductance. The main state could be the result of the simultaneous opening of four conducting subunits, each of which has a conductance of about 7 pS in 145 mM-external K+. The density of the inward-rectifying K+ channels in the ventricular sarcolemma is 0-10 channel/10 micron2 of surface membrane; the average of twenty-eight patches was 1 channel/1.8 micron2. It is concluded that the inward-rectifying K+ channels mediate the resting K+ conductance of ventricular heart muscle and the current termed IK1 in conventional voltage-clamp experiments.
从成年豚鼠心脏中酶解分离出单个心室肌细胞(伊森伯格和克洛克纳,1982年)。采用膜片钳技术(哈米尔、马蒂、内尔、萨克曼和西格沃思,1981年)来检测其肌膜中存在的内向整流钾通道的电导特性。当膜片外侧的钾离子浓度在10.8至300毫摩尔之间时,在比钾离子平衡电位(EK)更负的电位下可观察到内向电流阶跃。在更正的电位下未检测到电流阶跃,这表明该通道具有很强的整流特性。从内向电流的电压依赖性外推得到的零电流电位取决于外部钾离子浓度[K+]o,这符合主要为钾离子选择性离子通道的预期模式。[K+]o每变化10倍,其电位偏移49毫伏。通道的电导取决于[K+]o的平方根。在近似对称的跨膜钾离子浓度(外部钾离子浓度为145毫摩尔)下,单通道电导为27皮西门子(在19 - 23摄氏度)。在正常台氏液(外部钾离子浓度为5.4毫摩尔)中,我们计算出单通道电导为3.6皮西门子。在固定的负膜电位V下,内向电流阶跃的大小随[K+]o增加。阶跃大小与[K+]o之间的关系呈现饱和。假设通透钾离子与通道结合符合米氏方程,对于膜电位为 - 100毫伏,计算出表观结合常数为210毫摩尔。对于该电位,在饱和[K+]o时的电流估计为6.5皮安。当膜电位从高电导电位跃变为低电导电位时,在膜电位正向于EK时单通道电导的整流在1.5毫秒内发生。除了主要的电导状态外,该通道还可呈现几种亚电导状态。主要状态可能是四个导电亚基同时开放的结果,在外部钾离子浓度为145毫摩尔时,每个亚基的电导约为7皮西门子。心室肌膜中内向整流钾通道的密度为0 - 10个通道/10平方微米的表面膜;28个膜片的平均值为1个通道/1.8平方微米。结论是,内向整流钾通道介导心室肌的静息钾电导以及传统电压钳实验中称为IK1的电流。
