培养的人汗腺导管细胞中不同激动剂特异性振荡机制。
Separate agonist-specific oscillatory mechanisms in cultured human sweat duct cells.
作者信息
Pedersen P S
机构信息
University Department of Pediatrics 4061, Rigshospitalet, Copenhagen, Denmark.
出版信息
J Physiol. 1991 Feb;433:549-59. doi: 10.1113/jphysiol.1991.sp018443.
Abstract
- Cultured sweat duct cells (CSDCs) were grown to confluency on a permeable support, and the pharmacological ion transport regulation was assayed by transepithelial voltage clamp techniques. 2. Exposure of the serosal membrane of CSDCs to methacholine (MCh), lysylbradykinin (LBK) or histamine produced an oscillating short-circuit current (Iscc) response, which could be divided in an initial transient phase and a sustained oscillating phase, the latter of which was totally dependent on external Ca2+. 3. The Iscc responses evoked by LBK and histamine were, in contrast to the cholinergic response, characterized by a marked desensitization and short duration of the subsequent phase of Iscc oscillations. 4. Prolonged Iscc oscillations, reflecting continuous Ca2+ influx, were seen following MCh stimulation, and in response to LBK or histamine stimulation, when cells had been pre-treated with MCh. This pre-treatment effect of MCh was independent of continuous muscarinic receptor occupation, and it was unrelated to nicotinic receptor occupation. 5. It is suggested that MCh stimulation selectively initiates an influx of Ca2+ to an intracellular pool, from where Ca2+ can be discharged repetitively. In contrast, LBK and histamine only activate discharge of Ca2+ from such an intracellular pool, resulting in a limited response, given no prior stimulation by MCh of the Ca2+ influx mechanism.
摘要
- 将培养的汗腺导管细胞(CSDCs)在可渗透支持物上培养至汇合,并用跨上皮电压钳技术测定药理学离子转运调节。2. 将CSDCs的浆膜暴露于乙酰甲胆碱(MCh)、赖氨酰缓激肽(LBK)或组胺会产生振荡性短路电流(Iscc)反应,该反应可分为初始瞬态期和持续振荡期,后者完全依赖于细胞外Ca2+。3. 与胆碱能反应相反,LBK和组胺引起的Iscc反应的特征是Iscc振荡的后续阶段明显脱敏且持续时间短。4. 在MCh刺激后,以及当细胞用MCh预处理后对LBK或组胺刺激作出反应时,会出现反映持续Ca2+内流的长时间Iscc振荡。MCh的这种预处理作用与毒蕈碱受体的持续占据无关,且与烟碱受体的占据无关。5. 有人提出,MCh刺激选择性地启动Ca2+流入细胞内池,Ca2+可从该池中重复释放。相比之下,LBK和组胺仅激活Ca2+从这样一个细胞内池的释放,在没有MCh预先刺激Ca2+内流机制的情况下,导致有限的反应。
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