细胞外钾离子效应在大鼠 Erg 钾通道家族中是保守的。
Extracellular potassium effects are conserved within the rat erg K+ channel family.
作者信息
Sturm Patrick, Wimmers Sönke, Schwarz Jürgen R, Bauer Christiane K
机构信息
Institut für Angewandte Physiologie, Zentrum für Experimentelle Medizin, Universitätsklinikum Hamburg-Eppendorf, Martinistrasse 52, D-20246 Hamburg, Germany.
出版信息
J Physiol. 2005 Apr 15;564(Pt 2):329-45. doi: 10.1113/jphysiol.2004.078840. Epub 2005 Feb 10.
The biophysical properties of native cardiac erg1 and recombinant HERG1 channels have been shown to be influenced by the extracellular K(+) concentration (K(+)). The erg1 conductance, for example, increases dramatically with a rise in K(+). In the brain, where local K(+) can change considerably with the extent of physiological and pathophysiological neuronal activity, all three erg channel subunits are expressed. We have now investigated and compared the effects of an increase in K(+) from 2 to 10 mm on the three rat erg channels heterologously expressed in CHO cells. Upon increasing K(+), the voltage dependence of activation was shifted to more negative potentials for erg1 (DeltaV(0.5) = -4.0 +/- 1.1 mV, n = 28) and erg3 (DeltaV(0.5) = -8.4 +/- 1.2 mV, n = 25), and was almost unchanged for erg2 (DeltaV(0.5) = -2.0 +/- 1.3 mV, n = 6). For all three erg channels, activation kinetics were independent of K(+), but the slowing of inactivation by increased K(+) was even more pronounced for erg2 and erg3 than for erg1. In addition, with increased K(+), all three erg channels exhibited significantly slower time courses of recovery from inactivation and of deactivation. Whole-cell erg-mediated conductance was determined at the end of 4 s depolarizing pulses as well as with 1 s voltage ramps starting from the fully activated state. The rise in K(+) resulted in increased conductance values for all three erg channels which were more pronounced for erg2 (factor 3-4) than for erg1 (factor 2.5-3) and erg3 (factor 2-2.5). The data demonstrate that most K(+)-dependent changes in the biophysical properties are well conserved within the erg K(+) channel family, despite gradual differences in the magnitude of the effects.
天然心脏erg1通道和重组HERG1通道的生物物理特性已被证明会受到细胞外钾离子浓度([K⁺]o)的影响。例如,erg1的电导率会随着[K⁺]o的升高而显著增加。在大脑中,局部[K⁺]o会随着生理和病理生理神经元活动的程度而发生相当大的变化,erg通道的所有三个亚基均有表达。我们现在研究并比较了[K⁺]o从2 mM增加到10 mM对在CHO细胞中异源表达的三种大鼠erg通道的影响。随着[K⁺]o的增加,erg1(ΔV0.5 = -4.0 ± 1.1 mV,n = 28)和erg3(ΔV0.5 = -8.4 ± 1.2 mV,n = 25)的激活电压依赖性向更负的电位移动,而erg2(ΔV0.5 = -2.0 ± 1.3 mV,n = 6)几乎没有变化。对于所有三种erg通道,激活动力学与[K⁺]o无关,但[K⁺]o升高导致的失活减慢在erg2和erg3中比在erg1中更为明显。此外,随着[K⁺]o的增加,所有三种erg通道从失活和去激活中恢复的时间进程都显著减慢。在4秒去极化脉冲结束时以及从完全激活状态开始的1秒电压斜坡期间测定全细胞erg介导的电导率。[K⁺]o的升高导致所有三种erg通道的电导率值增加,其中erg2(系数3 - 4)比erg1(系数2.5 - 3)和erg3(系数2 - 2.5)更为明显。数据表明,尽管效应大小存在逐渐差异,但erg钾通道家族中大多数依赖于[K⁺]o的生物物理特性变化都得到了很好的保留。
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