Costa Roberta, Civello Davide Antonio, Bernardinelli Emanuele, Vanoni Simone, Zopf Michaela, Scantamburlo Giada, Nofziger Charity, Patsch Wolfgang, Paulmichl Markus, Dossena Silvia
Institute of Pharmacology and Toxicology, Paracelsus Medical University, Salzburg, Austria.
PharmGenetix Gmbh, Sonystrasse 20, Niederalm-Anif, Austria.
Cell Physiol Biochem. 2018;45(3):867-882. doi: 10.1159/000487282. Epub 2018 Feb 2.
BACKGROUND/AIMS: In the human genome, more than 400 genes encode ion channels, which are ubiquitously expressed and often coexist and participate in almost all physiological processes. Therefore, ion channel blockers represent fundamental tools in discriminating the contribution of individual channel types to a physiological phenomenon. However, unspecific effects of these compounds may represent a confounding factor. Three commonly used chloride channel inhibitors, i.e. 4,4'-diisothiocyano-2,2'-stilbene-disulfonic acid (DIDS), 5-nitro-2-[(3-phenylpropyl) amino]benzoic acid (NPPB) and the anti-inflammatory drug niflumic acid were tested to identify the lowest concentration effective on Cl- channels and ineffective on K+ channels.
The activity of the above mentioned compounds was tested by whole cell patch-clamp on the swelling-activated Cl- current ICl,swell and on the endogenous voltage-dependent, outwardly rectifying K+ selective current in human kidney cell lines (HEK 293/HEK 293 Phoenix).
Micromolar (1-10 µM) concentrations of DIDS and NPPB could not discriminate between the Cl- and K+ selective currents. Specifically, 1 µM DIDS only affected the K+ current and 10 µM NPPB equally affected the Cl- and K+ currents. Only relatively high (0.1-1 mM) concentrations of DIDS and prolonged (5 minutes) exposure to 0.1-1 mM NPPB preferentially suppressed the Cl- current. Niflumic acid preferentially inhibited the Cl- current, but also significantly affected the K+ current. The endogenous voltage-dependent, outwardly rectifying K+ selective current in HEK 293/HEK 293 Phoenix cells was shown to arise from the Kv 3.1 channel, which is extensively expressed in brain and is involved in neurological diseases.
The results of the present study underscore that sensitivity of a given physiological phenomenon to the Cl- channel inhibitors NPPB, DIDS and niflumic acid may actually arise from an inhibition of Cl- channels but can also result from an inhibition of voltage-dependent K+ channels, including the Kv 3.1 channel. The use of niflumic acid as anti-inflammatory drug in patients with concomitant Kv 3.1 dysfunction may result contraindicated.
背景/目的:在人类基因组中,400 多个基因编码离子通道,这些通道广泛表达,常常共存并参与几乎所有生理过程。因此,离子通道阻滞剂是区分个体通道类型对生理现象贡献的基本工具。然而,这些化合物的非特异性作用可能是一个混杂因素。测试了三种常用的氯离子通道抑制剂,即 4,4'-二异硫氰基-2,2'-二苯乙烯二磺酸(DIDS)、5-硝基-2-[(3-苯丙基)氨基]苯甲酸(NPPB)和抗炎药氟尼辛,以确定对氯离子通道有效而对钾离子通道无效的最低浓度。
通过全细胞膜片钳技术,在人肾细胞系(HEK 293/HEK 293 Phoenix)中,检测上述化合物对肿胀激活的氯离子电流 ICl,swell 和内源性电压依赖性外向整流钾离子选择性电流的活性。
微摩尔浓度(1-10 μM)的 DIDS 和 NPPB 无法区分氯离子和钾离子选择性电流。具体而言,1 μM DIDS 仅影响钾离子电流,10 μM NPPB 对氯离子和钾离子电流的影响相同。只有相对较高浓度(0.1-1 mM)的 DIDS 和长时间(5 分钟)暴露于 0.1-1 mM NPPB 才优先抑制氯离子电流。氟尼辛优先抑制氯离子电流,但也显著影响钾离子电流。HEK 293/HEK 293 Phoenix 细胞中的内源性电压依赖性外向整流钾离子选择性电流显示源自 Kv 3.1 通道,该通道在大脑中广泛表达并参与神经疾病。
本研究结果强调,特定生理现象对氯离子通道抑制剂 NPPB、DIDS 和氟尼辛的敏感性实际上可能源于对氯离子通道的抑制,但也可能源于对电压依赖性钾离子通道(包括 Kv 3.1 通道)的抑制。在伴有 Kv 3.
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