G蛋白偶联受体变构调节的分子机制：来自人A1腺苷受体结合动力学研究的见解

Molecular mechanism of allosteric modulation at GPCRs: insight from a binding kinetics study at the human A1 adenosine receptor.

作者信息

Guo Dong, Venhorst Suzanne N, Massink Arnault, van Veldhoven Jacobus P D, Vauquelin Georges, IJzerman Adriaan P, Heitman Laura H

机构信息

Division of Medicinal Chemistry, Leiden Academic Centre for Drug Research (LACDR), Leiden University, Leiden, The Netherlands.

出版信息

Br J Pharmacol. 2014 Dec;171(23):5295-312. doi: 10.1111/bph.12836. Epub 2014 Sep 5.

DOI:10.1111/bph.12836

PMID:25040887

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4294041/

Abstract

BACKGROUND AND PURPOSE

Many GPCRs can be allosterically modulated by small-molecule ligands. This modulation is best understood in terms of the kinetics of the ligand-receptor interaction. However, many current kinetic assays require at least the (radio)labelling of the orthosteric ligand, which is impractical for studying a range of ligands. Here, we describe the application of a so-called competition association assay at the adenosine A1 receptor for this purpose.

EXPERIMENTAL APPROACH

We used a competition association assay to examine the binding kinetics of several unlabelled orthosteric agonists of the A1 receptor in the absence or presence of two allosteric modulators. We also tested three bitopic ligands, in which an orthosteric and an allosteric pharmacophore were covalently linked with different spacer lengths. The relevance of the competition association assay for the binding kinetics of the bitopic ligands was also explored by analysing simulated data.

KEY RESULTS

The binding kinetics of an unlabelled orthosteric ligand were affected by the addition of an allosteric modulator and such effects were probe- and concentration-dependent. Covalently linking the orthosteric and allosteric pharmacophores into one bitopic molecule had a substantial effect on the overall on- or off-rate.

CONCLUSION AND IMPLICATIONS

The competition association assay is a useful tool for exploring the allosteric modulation of the human adenosine A1 receptor. This assay may have general applicability to study allosteric modulation at other GPCRs as well.

摘要

背景与目的

许多G蛋白偶联受体（GPCRs）可被小分子配体变构调节。这种调节从配体-受体相互作用的动力学角度理解最为恰当。然而，许多当前的动力学分析至少需要对正构配体进行（放射性）标记，这对于研究一系列配体而言并不实用。在此，我们描述了一种所谓的竞争结合分析在腺苷A1受体上的应用，用于此目的。

实验方法

我们使用竞争结合分析来检测在不存在或存在两种变构调节剂的情况下，A1受体的几种未标记正构激动剂的结合动力学。我们还测试了三种双位点配体，其中正构和变构药效基团通过不同长度的间隔基团共价连接。通过分析模拟数据，还探讨了竞争结合分析对于双位点配体结合动力学的相关性。

关键结果

未标记正构配体的结合动力学受到变构调节剂添加的影响，且这种影响具有探针和浓度依赖性。将正构和变构药效基团共价连接成一个双位点分子对整体结合或解离速率有显著影响。

结论与启示

竞争结合分析是探索人腺苷A1受体变构调节的有用工具。该分析可能也普遍适用于研究其他GPCRs的变构调节。

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