米贝拉地尔和硝苯地平对小动脉肌源性反应性及细胞内钙离子的影响
Effects of mibefradil and nifedipine on arteriolar myogenic responsiveness and intracellular Ca(2+).
作者信息
Potocnik S J, Murphy T V, Kotecha N, Hill M A
机构信息
Microvascular Biology Group, Department of Human Biology and Movement Science, RMIT University, Bundoora, Victoria 3083, Australia.
出版信息
Br J Pharmacol. 2000 Nov;131(6):1065-72. doi: 10.1038/sj.bjp.0703650.
Abstract
- Ca(2+) entry mechanisms underlying spontaneous arteriolar tone and acute myogenic reactivity remain uncertain. These studies aimed to compare the effects of nifedipine and the putative T-channel blocker, mibefradil, on arteriolar myogenic responsiveness and intracellular Ca(2+) (Ca(2+)(i)). 2. First order cremaster muscle arterioles (1A) were isolated from rats, cannulated, pressurized to 70 mmHg in the absence of intraluminal flow, and mechanical responses studied by video microscopy. The Ca(2+)(i) was measured using fluorescence imaging of Fura 2 loaded arterioles. 3. Both nifedipine and mibefradil showed dose-dependent inhibition of spontaneous myogenic tone (at 70 mmHg; pEC(50) 7.04+/-0.17 vs 6.65+/-0.20 respectively, n=6 for both, n.s.) and KCl-induced vasoconstriction (at 70 mmHg; pEC(50) 6.93+/-0. 38 vs 6.45+/-0.27 respectively, n=6 for both, n.s.). 4. In arterioles maintained at 50 mmHg, nifedipine (10(-7) and 10(-5) M) caused a concentration dependent reduction in Ca(2+)(i), however, mibefradil (10(-7) and 10(-5) M) had no effect. Furthermore nifedipine significantly attenuated the increase in Ca(2+)(i) associated with an acute pressure step (50 - 120 mmHg) whereas mibefradil was considerably less effective. 5. Mibefradil (10(-7) M) significantly attenuated contractile responses to 60 mM KCl without altering the KCl-induced increase in Ca(2+)(i), in contrast to nifedipine (10(-7) M) which reduced both Ca(2+)(i) and contraction. 6. Membrane potential of arterioles with spontaneous myogenic tone (70 mmHg) was -41.5+/-1. 0 mV. Nifedipine (10(-7) or 10(-5) M) had no effect on membrane potential, however mibefradil (10(-5) M) caused significant depolarization. 7. In summary, both mibefradil and nifedipine inhibit arteriolar spontaneous tone and acute myogenic reactivity. While there may be overlap in the mechanisms by which these agents inhibit tone, differences in effects on membrane potential and intracellular Ca(2+) levels suggest mibefradil exhibits actions other than blockade of Ca(2+) entry in skeletal muscle arterioles.
摘要
- 小动脉自发张力和急性肌源性反应性背后的Ca(2+)内流机制仍不明确。这些研究旨在比较硝苯地平与假定的T通道阻滞剂米贝拉地尔对小动脉肌源性反应性和细胞内Ca(2+)(Ca(2+)(i))的影响。2. 从大鼠分离出一级提睾肌小动脉(1A),插管,在无管腔内血流的情况下加压至70 mmHg,并通过视频显微镜研究机械反应。使用装载Fura 2的小动脉的荧光成像测量Ca(2+)(i)。3. 硝苯地平和米贝拉地尔均显示出自发肌源性张力的剂量依赖性抑制(在70 mmHg时;pEC(50)分别为7.04±0.17和6.65±0.20,两者n = 6,无显著性差异)以及KCl诱导的血管收缩(在70 mmHg时;pEC(50)分别为6.93±0.38和6.45±0.27,两者n = 6,无显著性差异)。4. 在维持于50 mmHg的小动脉中,硝苯地平(10(-7)和10(-5) M)导致Ca(2+)(i)浓度依赖性降低,然而,米贝拉地尔(10(-7)和10(-5) M)无作用。此外,硝苯地平显著减弱了与急性压力阶跃(50 - 120 mmHg)相关的Ca(2+)(i)增加,而米贝拉地尔的效果则明显较差。5. 米贝拉地尔(10(-7) M)显著减弱对60 mM KCl的收缩反应,而不改变KCl诱导的Ca(2+)(i)增加,与之形成对比的是,硝苯地平(10(-7) M)同时降低Ca(2+)(i)和收缩。6. 具有自发肌源性张力(70 mmHg)的小动脉的膜电位为-41.5±1.0 mV。硝苯地平(10(-7)或10(-5) M)对膜电位无影响,然而米贝拉地尔(10(-5) M)导致显著去极化。7. 总之,米贝拉地尔和硝苯地平均抑制小动脉自发张力和急性肌源性反应性。虽然这些药物抑制张力的机制可能存在重叠,但对膜电位和细胞内Ca(2+)水平影响的差异表明,米贝拉地尔在骨骼肌小动脉中除了阻断Ca(2+)内流外还表现出其他作用。
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