合成肽对间隙连接通道活性的选择性抑制
Selective inhibition of gap junction channel activity by synthetic peptides.
作者信息
Kwak B R, Jongsma H J
机构信息
Department of Medical Physiology and Sports Medicine, Utrecht University, PO Box 80043, 3508 TA Utrecht, The Netherlands.
出版信息
J Physiol. 1999 May 1;516 ( Pt 3)(Pt 3):679-85. doi: 10.1111/j.1469-7793.1999.0679u.x.
Abstract
- The aim of this study was to inhibit specifically one type of gap junction channel in cells expressing multiple connexins (Cx) using synthetic oligopeptides. 2. A7r5 cells (an aortic smooth muscle cell line expressing Cx40 and Cx43) were incubated overnight with synthetic oligopeptides (P180-195) corresponding to a segment of the second extracellular loop of Cx43. This segment is different in sequence from the corresponding location in Cx40. 3. P180-195 (500 microM) decreased cell-to-cell coupling as assessed by dye coupling and dual whole-cell voltage clamp. The decrease in permeability and junctional conductance was caused by selective inhibition of Cx43 gap junction channels. In contrast, overnight incubation of A7r5 cells with oligopeptides corresponding to a segment of the intracellular cytoplasmic tail of Cx43 was without effect. 4. These results indicate that oligopeptides P180-195 may interact with the extracellular domain of the Cx43 protein, thereby possibly mimicking connexin-connexin binding. This apparently inhibits Cx43 channel activity without disturbing the activity of Cx40 channels. 5. Experiments with oligopeptides corresponding to the equivalent part of the second extracellular loop of Cx40 (P177-192) pointed towards a selective inhibition of Cx40 channel activity. 6. Competition assays using synthetic oligopeptides may help to resolve the regulatory properties of gap junction channels in primary cells expressing multiple Cx.
摘要
- 本研究的目的是使用合成寡肽特异性抑制表达多种连接蛋白(Cx)的细胞中的一种间隙连接通道。2. 将A7r5细胞(一种表达Cx40和Cx43的主动脉平滑肌细胞系)与对应于Cx43第二个细胞外环段的合成寡肽(P180 - 195)孵育过夜。该段序列与Cx40中的相应位置不同。3. 如通过染料偶联和双全细胞膜片钳评估,P180 - 195(500 microM)降低了细胞间偶联。通透性和连接电导的降低是由Cx43间隙连接通道的选择性抑制引起的。相比之下,将A7r5细胞与对应于Cx43细胞内胞质尾段的寡肽孵育过夜则没有效果。4. 这些结果表明,寡肽P180 - 195可能与Cx43蛋白的细胞外结构域相互作用,从而可能模拟连接蛋白 - 连接蛋白结合。这显然抑制了Cx43通道活性,而不干扰Cx40通道的活性。5. 用对应于Cx40第二个细胞外环等效部分的寡肽(P177 - 192)进行的实验表明对Cx40通道活性有选择性抑制作用。6. 使用合成寡肽的竞争分析可能有助于解析表达多种Cx的原代细胞中间隙连接通道的调节特性。
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