Enyeart J J, Biagi B A, Mlinar B
Department of Pharmacology, Ohio State University College of Medicine, Columbus 43210-1239.
Mol Pharmacol. 1992 Aug;42(2):364-72.
We have used the whole-cell version of the patch-clamp technique to analyze the inhibition of Ca2+ currents by antipsychotic agents in neural crest-derived rat and human thyroid C cell lines. Diphenylbutylpiperidine (DPBP) antipsychotics, including penfluridol and fluspirilene, potently and preferentially block T-type Ca2+ current in the rat medullary thyroid carcinoma 6-23 (clone 6) cell line. When step depolarizations were applied at 0.1 Hz from a holding potential of -80 mV, with 10 mM Ca2+ as the charge carrier, the DPBP penfluridol inhibited T-type current with an IC50 of 224 nM. High voltage-activated L and N currents were less potently blocked. At a concentration of 500 nM, penfluridol inhibited 78.0 +/- 2.3% (n = 29) of inactivating T-type Ca2+ current, whereas the sustained high voltage-activated current was reduced by 25.6 +/- 3.5% (n = 28). Block of T-type current by penfluridol was enhanced by depolarizing test pulses applied at frequencies above 0.03 Hz. The use-dependent component of block was largely reversed by pulse-free periods at -80 mV. T-type Ca2+ channels in the human TT C cell line were blocked by penfluridol, and the potency was enhanced by reduction of extracellular Ca2+. Non-DPBP antipsychotics, including haloperidol, clozapine, and thioridazine, also blocked T-type channels, but these were 20-100 times less potent than the DPBPs. These results identify the DPBPs as a new class of organic Ca2+ channel antagonists, which are distinctive in their ability to preferentially block T-type channels. These agents will be useful in defining the function of T channels in various excitable cells. Their potent block of T-type Ca2+ channels, which would be enhanced in rapidly firing cells, suggests that this action may be relevant to the therapeutic or toxic effects of these drugs when used in clinical pharmacology.
我们运用膜片钳技术的全细胞版本,来分析抗精神病药物对源自神经嵴的大鼠和人类甲状腺C细胞系中Ca2+电流的抑制作用。二苯基丁基哌啶(DPBP)类抗精神病药物,包括五氟利多和氟司必林,能有效且优先阻断大鼠甲状腺髓样癌6 - 23(克隆6)细胞系中的T型Ca2+电流。当从 - 80 mV的 holding 电位以0.1 Hz的频率施加阶跃去极化,以10 mM Ca2+作为电荷载体时,DPBP类药物五氟利多抑制T型电流的IC50为224 nM。高压激活的L型和N型电流受到的阻断作用较弱。在500 nM的浓度下,五氟利多抑制了78.0±2.3%(n = 29)的失活T型Ca2+电流,而持续的高压激活电流减少了25.6±3.5%(n = 28)。当以高于0.03 Hz的频率施加去极化测试脉冲时,五氟利多对T型电流的阻断作用增强。通过在 - 80 mV下的无脉冲期,阻断的使用依赖性成分在很大程度上得以逆转。人类TT C细胞系中的T型Ca2+通道被五氟利多阻断,且通过降低细胞外Ca2+可增强其阻断效力。非DPBP类抗精神病药物,包括氟哌啶醇、氯氮平和硫利达嗪,也能阻断T型通道,但效力比DPBP类药物低20 - 100倍。这些结果表明DPBP类药物是一类新型的有机Ca2+通道拮抗剂,其独特之处在于能够优先阻断T型通道。这些药物将有助于确定T通道在各种可兴奋细胞中的功能。它们对T型Ca2+通道的强效阻断作用,在快速放电的细胞中会增强,这表明该作用可能与这些药物在临床药理学中使用时的治疗或毒性作用相关。
