与脂膜的相互作用影响芬太尼药理学。

Katy J Sutcliffe, Robin A Corey, Norah Alhosan, Damiana Cavallo, Sam Groom, Marina Santiago, Chris Bailey, Steven J Charlton, Richard B Sessions, Graeme Henderson, Eamonn Kelly
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引用次数: 5

摘要

芬太尼的过量死亡在美国已经达到流行病的程度,并且在世界范围内正在增加。芬太尼是一种有效的阿片类激动剂,纳洛酮的逆转效果不如吗啡好。由于芬太尼的高亲脂性和细长的结构,我们假设其不同寻常的药理作用可能是通过与μ-阿片受体(MOPr)结合的途径与脂膜相互作用来解释的。通过粗粒度分子动力学模拟、电生理记录和细胞信号分析,我们确定了芬太尼和吗啡如何进入MOPr的正位口袋。吗啡通过水通道进入MOPr;首先结合到细胞外前庭,然后扩散到矫形袋。相比之下,芬太尼可能会走一条新的路线;首先进入膜,然后通过配体诱导的跨膜螺旋间隙扩散进入正位位点。在电生理记录中,芬太尼诱导的电流在冲洗后返回,表明芬太尼沉积在脂质膜上。然而,形成潜在的MOPr跨膜通路位点的残基突变并没有改变芬太尼在体外的药理学特征。脂膜中局部高浓度的芬太尼,可能与一种新的亲脂结合途径结合,可能解释了芬太尼被纳洛酮逆转的高效力和低易感性。
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Interaction With the Lipid Membrane Influences Fentanyl Pharmacology.

Overdose deaths from fentanyl have reached epidemic proportions in the USA and are increasing worldwide. Fentanyl is a potent opioid agonist that is less well reversed by naloxone than morphine. Due to fentanyl's high lipophilicity and elongated structure we hypothesised that its unusual pharmacology may be explained by its interactions with the lipid membrane on route to binding to the μ-opioid receptor (MOPr). Through coarse-grained molecular dynamics simulations, electrophysiological recordings and cell signalling assays, we determined how fentanyl and morphine access the orthosteric pocket of MOPr. Morphine accesses MOPr via the aqueous pathway; first binding to an extracellular vestibule, then diffusing into the orthosteric pocket. In contrast, fentanyl may take a novel route; first partitioning into the membrane, before accessing the orthosteric site by diffusing through a ligand-induced gap between the transmembrane helices. In electrophysiological recordings fentanyl-induced currents returned after washout, suggesting fentanyl deposits in the lipid membrane. However, mutation of residues forming the potential MOPr transmembrane access site did not alter fentanyl's pharmacological profile in vitro. A high local concentration of fentanyl in the lipid membrane, possibly in combination with a novel lipophilic binding route, may explain the high potency and lower susceptibility of fentanyl to reversal by naloxone.

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