豚鼠膀胱离体平滑肌细胞中去极化介导的细胞内钙瞬变
Depolarization-mediated intracellular calcium transients in isolated smooth muscle cells of guinea-pig urinary bladder.
作者信息
Ganitkevich V Y a, Isenberg G
机构信息
Department of Applied Physiology, University of Cologne, Germany.
出版信息
J Physiol. 1991 Apr;435:187-205. doi: 10.1113/jphysiol.1991.sp018505.
Abstract
- Free intracellular calcium concentration ([Ca2+]i) was recorded in single smooth muscle cells of the guinea-pig urinary bladder held under voltage clamp at 36 degrees C and 3.6 mM-extracellular Ca2+. The Ca2+ indicator Indo-1 was loaded into the cells through patch electrodes. To separate Ca2+ currents (ICa), superimposed K+ currents were suppressed with a Cs(+)-containing electrode solution. 2. At a holding potential of -60 mV, resting [Ca2+]i was 114 +/- 22 nM (mean +/- S.D.). During 160 ms depolarization steps to 0 mV, [Ca2+]i rose to 885 +/- 140 nM. With steps of varied duration, peak [Ca2+]i increased with the time of depolarization up to about 1 s. Upon repolarization [Ca2+]i recovered to resting levels with a half-decay time of about 1 s; recovery was not significantly changed with repolarization potentials between -50 and -100 mV. 3. The potential dependence of the above peak [Ca2+]i transients was bell shaped, with a threshold around -40 mV and a maximum at 0 mV. During depolarization steps to potentials more positive than +80 mV [Ca2+]i did not significantly rise. 4. During step depolarizations to 0 mV lasting 10 s or longer, [Ca2+]i peaked within 814 +/- 18 ms and then decayed to a sustained level of 250 +/- 60 nM. The amplitude of the [Ca2+]i peak as well as the time course of the transient depended on the amplitude of ICa. The depolarizations increased [Ca2+]i to a sustained level with no clearly defined peak when ICa was reduced by partial inactivation or during steps close to the threshold of ICa (-40 mV). 5. The sustained level of [Ca2+]i with longer depolarizations of several seconds showed a bell-shaped voltage dependence with a maximum close to 0 mV. A bell-shaped voltage dependence for [Ca2+]i was also found during ramp-like depolarizations. However, when the rate of depolarization was low (7.5 mV s-1), the peak [Ca2+]i was found at more negative potentials (-15 mV). 6. The results are compatible with the idea that Ca2+ influx through voltage-operated Ca2+ channels is the key event in depolarization-mediated changes in [Ca2+]i in smooth muscle cells from urinary bladder.
摘要
- 在36℃和细胞外钙离子浓度为3.6 mM的条件下,对豚鼠膀胱单个平滑肌细胞进行电压钳制,记录细胞内游离钙离子浓度([Ca2+]i)。通过膜片电极将钙离子指示剂Indo-1载入细胞。为分离钙离子电流(ICa),使用含铯(Cs+)的电极溶液抑制叠加的钾离子电流。2. 在-60 mV的钳制电位下,静息[Ca2+]i为114±22 nM(平均值±标准差)。在向0 mV进行160 ms的去极化步骤期间,[Ca2+]i升至885±140 nM。对于不同持续时间的步骤,[Ca2+]i峰值随去极化时间增加,直至约1 s。复极化时,[Ca2+]i恢复到静息水平,半衰期约为1 s;在-50至-100 mV之间的复极化电位下,恢复情况无显著变化。3. 上述[Ca2+]i峰值瞬变的电位依赖性呈钟形,阈值约为-40 mV,在0 mV时达到最大值。在去极化至电位更正于+80 mV的步骤中,[Ca2+]i没有显著升高。4. 在持续10 s或更长时间的向0 mV的去极化步骤中,[Ca2+]i在814±18 ms内达到峰值,然后衰减至250±60 nM的持续水平。[Ca2+]i峰值的幅度以及瞬变的时间进程取决于ICa的幅度。当通过部分失活降低ICa或在接近ICa阈值(-40 mV)的步骤期间,去极化将[Ca2+]i升高至无明确峰值的持续水平。5. 数秒的较长时间去极化时[Ca2+]i的持续水平呈现钟形电压依赖性,最大值接近0 mV。在斜坡状去极化期间也发现了[Ca2+]i的钟形电压依赖性。然而,当去极化速率较低(7.5 mV s-1)时,[Ca2+]i峰值出现在更负的电位(-15 mV)。6. 这些结果与以下观点相符:通过电压门控钙离子通道的钙离子内流是膀胱平滑肌细胞中去极化介导的[Ca2+]i变化的关键事件。
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