红霉素对HERG钾通道的阻断作用：F656和Y652的可及性

Erythromycin block of the HERG K+ channel: accessibility to F656 and Y652.

作者信息

Duncan Rona S, Ridley John M, Dempsey Christopher E, Leishman Derek J, Leaney Joanne L, Hancox Jules C, Witchel Harry J

机构信息

Department of Physiology and Cardiovascular Research Laboratories, School of Medical Sciences, University of Bristol, University Walk, Bristol BS8 1TD, UK.

出版信息

Biochem Biophys Res Commun. 2006 Mar 10;341(2):500-6. doi: 10.1016/j.bbrc.2006.01.008. Epub 2006 Jan 13.

DOI:10.1016/j.bbrc.2006.01.008

PMID:16446155

Abstract

The HERG potassium channel might have a non-canonical drug binding site, distinct from the channel's inner cavity, that could be responsible for elements of closed-state pharmacological inhibition of the channel. The macrolide antibiotic erythromycin is a drug that may block unconventionally because of its size. Here we used whole-cell patch-clamp recording at 37 degrees C from heterologously expressed HERG channels in a mammalian cell line to show that erythromycin either produces a rapid open-state-dependent HERG channel inhibition, or components of both open-state-dependent and closed-state-dependent inhibition. Alanine-substitution of HERG's canonical determinants of blockade revealed that Y652 was not important as a molecular determinant of blockade, and that mutation of F656 resulted in only weak attenuation of inhibition. In computer models of the channel, erythromycin could make several direct contacts with F656, but not with Y652, in the open-state model, and erythromycin was unable to fit into a closed-state channel model.

摘要

人醚 - 去极化激活的钾离子通道（HERG钾通道）可能有一个不同于通道内腔的非典型药物结合位点，该位点可能是通道封闭状态下药理学抑制作用的原因。大环内酯类抗生素红霉素是一种因其大小可能以非常规方式阻断通道的药物。在这里，我们在37摄氏度下使用全细胞膜片钳记录技术，从哺乳动物细胞系中异源表达的HERG通道进行记录，以表明红霉素要么产生快速的开放状态依赖性HERG通道抑制，要么产生开放状态依赖性和封闭状态依赖性抑制的成分。对HERG通道典型阻断决定因素进行丙氨酸替代显示，Y652作为阻断的分子决定因素并不重要，而F656的突变仅导致抑制作用的微弱减弱。在通道的计算机模型中，在开放状态模型中，红霉素可以与F656进行几次直接接触，但不能与Y652接触，并且红霉素无法适配到封闭状态通道模型中。

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红霉素对HERG钾通道的阻断作用：F656和Y652的可及性

Erythromycin block of the HERG K+ channel: accessibility to F656 and Y652.

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