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CB1中的一个隐秘口袋驱动外周和功能选择性。

A cryptic pocket in CB1 drives peripheral and functional selectivity.

作者信息

Rangari Vipin Ashok, O'Brien Evan S, Powers Alexander S, Slivicki Richard A, Bertels Zachariah, Appourchaux Kevin, Aydin Deniz, Ramos-Gonzalez Nokomis, Mwirigi Juliet, Lin Li, Mangutov Elizaveta, Sobecks Briana L, Awad-Agbaria Yaseen, Uphade Manoj B, Aguilar Jhoan, Peddada Teja Nikhil, Shiimura Yuki, Huang Xi-Ping, Folarin-Hines Jakayla, Payne Maria, Kalathil Anirudh, Varga Balazs R, Kobilka Brian K, Pradhan Amynah A, Cameron Michael D, Kumar Kaavya Krishna, Dror Ron O, Gereau Robert W, Majumdar Susruta

机构信息

Center for Clinical Pharmacology, University of Health Sciences and Pharmacy and Washington University School of Medicine, St. Louis, MO, USA.

Department of Anesthesiology and Washington University Pain Center, Washington University School of Medicine, St. Louis, MO, USA.

出版信息

Nature. 2025 Apr;640(8057):265-273. doi: 10.1038/s41586-025-08618-7. Epub 2025 Mar 5.

DOI:10.1038/s41586-025-08618-7
PMID:40044849
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11977287/
Abstract

The current opioid overdose epidemic highlights the urgent need to develop safer and more effective treatments for chronic pain. Cannabinoid receptor type 1 (CB1) is a promising non-opioid target for pain relief, but its clinical use has been limited by centrally mediated psychoactivity and tolerance. We overcame both issues by designing peripherally restricted CB1 agonists that minimize arrestin recruitment. We achieved these goals by computationally designing positively charged derivatives of the potent CB1 agonist MDMB-Fubinaca. We designed these ligands to occupy a cryptic pocket identified through molecular dynamics simulations-an extended binding pocket that opens rarely and leads to the conserved signalling residue D (ref. ). We used structure determination, pharmacological assays and molecular dynamics simulations to verify the binding modes of these ligands and to determine the molecular mechanism by which they achieve this dampening of arrestin recruitment. Our lead ligand, VIP36, is highly peripherally restricted and demonstrates notable efficacy in three mouse pain models, with 100-fold dose separation between analgesic efficacy and centrally mediated side effects. VIP36 exerts analgesic efficacy through peripheral CB1 receptors and shows limited analgesic tolerance. These results show how targeting a cryptic pocket in a G-protein-coupled receptor can lead to enhanced peripheral selectivity, biased signalling, desired in vivo pharmacology and reduced adverse effects. This has substantial implications for chronic pain treatment but could also revolutionize the design of drugs targeting other G-protein-coupled receptors.

摘要

当前的阿片类药物过量流行凸显了开发更安全、更有效的慢性疼痛治疗方法的迫切需求。1型大麻素受体(CB1)是一种有前景的非阿片类镇痛靶点,但其临床应用受到中枢介导的精神活性和耐受性的限制。我们通过设计外周限制型CB1激动剂来克服这两个问题,这种激动剂能最大限度地减少β-抑制蛋白的募集。我们通过对强效CB1激动剂MDMB-富马酸卡痛进行计算设计带正电荷的衍生物来实现这些目标。我们设计这些配体以占据通过分子动力学模拟确定的一个隐蔽口袋——一个很少打开且通向保守信号残基D的延伸结合口袋(参考文献)。我们使用结构测定、药理学分析和分子动力学模拟来验证这些配体的结合模式,并确定它们实现这种β-抑制蛋白募集抑制的分子机制。我们的先导配体VIP36具有高度外周限制性,并且在三种小鼠疼痛模型中显示出显著疗效,镇痛效果与中枢介导的副作用之间的剂量相差100倍。VIP36通过外周CB1受体发挥镇痛作用,并且显示出有限的镇痛耐受性。这些结果表明,靶向G蛋白偶联受体中的一个隐蔽口袋如何能够导致增强的外周选择性、偏向性信号传导、理想的体内药理学特性以及减少的不良反应。这对慢性疼痛治疗具有重大意义,但也可能彻底改变针对其他G蛋白偶联受体的药物设计。

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