Alice Valentini, Bethany Dibnah, Marija Ciba, Trond Ulven, Brian D Hudson, Elisabeth Rexen Ulven
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引用次数: 0
摘要
G 蛋白偶联受体(GPCR)是最大的信号蛋白家族,也是非常成功的药物靶点。迄今为止,大多数 GPCR 药物都与天然配体的结合袋相互作用,通常靠近跨膜区的细胞外部分。结构生物学的最新进展已经在这些受体的其他部位发现了更多的异生结合位点。异构位点具有多种理论优势,包括能够调节天然配体的功能,因此需要更好的方法来研究配体如何与不同的 GPCR 结合位点结合和相互作用。我们开发了一种研究多种配体与同一受体结合的方法,这种方法基于同时与 GPCR 结合的两种荧光配体之间的顺序共振能量转移。我们利用这种方法来深入了解一种临床相关受体的异构配体相互作用。这种方法将为帮助开发新的 GPCR 药物提供重要信息。
Multi-Coloured Sequential Resonance Energy Transfer for Simultaneous Ligand Binding at G Protein-Coupled Receptors
G protein coupled receptors (GPCRs) are the largest family of signalling proteins and highly successful drug targets. To date, most GPCR drugs interact with the binding pocket for the natural ligand, typically near the extracellular part of the transmembrane region. Recent advancements in structural biology have identified additional allosteric binding sites in other parts of these receptors. Allosteric sites provide several theoretical advantages, including the ability to modulate natural ligand function, and there is a need for better ways to study how ligands bind and interact with diVerent GPCR binding sites. We have developed an approach to study multiple ligands binding to the same receptor based on sequential resonance energy transfer between two fluorescent ligands bound simultaneously to a GPCR. We use this approach to gain insight into allosteric ligand interactions for a clinically relevant receptor. This method will provide important information to aid development of new GPCR drugs.
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