利用自然发生的氨基酸替换研究达诺啡肽 B 变体的结构-功能关系。

IF 4.4 2区 医学 Q1 PHARMACOLOGY & PHARMACY
Frontiers in Pharmacology Pub Date : 2024-10-30 eCollection Date: 2024-01-01 DOI:10.3389/fphar.2024.1484730
Luca Zangrandi, Barbara Fogli, Anna Mutti, René Staritzbichler, Victoria Most, Peter W Hildebrand, Regine Heilbronn, Christoph Schwarzer
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引用次数: 0

摘要

Dynorphins(Dyn)是与卡巴阿片受体(KOPrs)结合亲和力最高的内源性阿片肽子集。激活 KOPrs 的 G 蛋白偶联通路具有很强的抗惊厥作用。Dyn还能以较低的亲和力与μ(MOPrs)和δ阿片受体(DOPrs)结合,并能激活β-restin通路。为了充分发挥达吗啡的治疗潜力并减少潜在的不良反应,提高对 KOPrs 的选择性并减少对 mTOR 复合物的激活将是有利的。因此,我们在单阿片受体表达细胞上应用竞争性放射结合试验、GTPγS 试验、PRESTO-Tango 和 Western 印迹法研究了一系列用天然氨基酸取代一个或两个位置的达因吗啡 B(DynB)变体对阿片受体的不同激活作用。与 MOPrs 或 DOPrs 相比,七种 DynB 衍生物对 KOPrs 的选择性至少提高了 10 倍。DynB_G3M/Q8H 对 KOPrs 相对于 MOPrs 的选择性最高,DynB_L5S 对 KOPrs 相对于 DOPrs 的选择性最高。KOPr 对 MOPr 和 DOPr 的选择性增加是由于 MOPr 和 DOPr 的亲和力或效力降低,而不是 KOPr 的亲和力或效力提高。这表明,与 KOPr 相比,所研究的第 3、5 和 8 位氨基酸交换对 MOPr 或 DOPr 的结合和激活具有更重要的意义。在使用 GTPγS 试验进行的信号转导测试中,DynB 衍生物都没有显示出更强的效力。在测试中,将第 3 位的甘氨酸替换为蛋氨酸的三个变体显示出了较低的效力,因此被认为是部分激动剂。我们进一步研究了两种最有希望激活的候选化合物在 G 蛋白和 β-阿司匹林通路之间的功能选择性,以及对 mTOR 的激活作用。与野生型 DynB 相比,各自的读出结果均未发现差异。我们的数据表明,仅评估与 KOPr 的亲和力不足以预测肽能激动剂对 KOPr 的效力或功效。需要进一步评估下游途径,才能更可靠地预测体内效应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Structure-function relationship of dynorphin B variants using naturally occurring amino acid substitutions.

Dynorphins (Dyn) represent the subset of endogenous opioid peptides with the highest binding affinity to kappa opioid receptors (KOPrs). Activation of the G-protein-coupled pathway of KOPrs has strong anticonvulsant effects. Dyn also bind to mu (MOPrs) and delta opioid receptors (DOPrs) with lower affinity and can activate the β-arrestin pathway. To fully exploit the therapeutic potential of dynorphins and reduce potential unwanted effects, increased selectivity for KOPrs combined with reduced activation of the mTOR complex would be favorable. Therefore, we investigated a series of dynorphin B (DynB) variants, substituted in one or two positions with naturally occurring amino acids for differential opioid receptor activation, applying competitive radio binding assays, GTPγS assays, PRESTO-Tango, and Western blotting on single-opioid receptor-expressing cells. Seven DynB derivatives displayed at least 10-fold increased selectivity for KOPrs over either MOPrs or DOPrs. The highest selectivity for KOPrs over MOPrs was obtained with DynB_G3M/Q8H, and the highest selectivity for KOPrs over DOPrs was obtained with DynB_L5S. Increased selectivity for KOPr over MOPr and DOPr was based on a loss of affinity or potency at MOPr and DOPr rather than a higher affinity or potency at KOPr. This suggests that the investigated amino acid exchanges in positions 3, 5, and 8 are of higher importance for binding and activation of MOPr or DOPr than of KOPr. In tests for signal transduction using the GTPγS assay, none of the DynB derivatives displayed increased potency. The three tested variants with substitutions of glycine to methionine in position 3 displayed reduced efficacy and are, therefore, considered partial agonists. The two most promising activating candidates were further investigated for functional selectivity between the G-protein and the β-arrestin pathway, as well as for activation of mTOR. No difference was detected in the respective read-outs, compared to wild-type DynB. Our data indicate that the assessment of affinity to KOPr alone is not sufficient to predict either potency or efficacy of peptidergic agonists on KOPr. Further assessment of downstream pathways is required to allow more reliable predictions of in vivo effects.

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来源期刊
Frontiers in Pharmacology
Frontiers in Pharmacology PHARMACOLOGY & PHARMACY-
CiteScore
7.80
自引率
8.90%
发文量
5163
审稿时长
14 weeks
期刊介绍: Frontiers in Pharmacology is a leading journal in its field, publishing rigorously peer-reviewed research across disciplines, including basic and clinical pharmacology, medicinal chemistry, pharmacy and toxicology. Field Chief Editor Heike Wulff at UC Davis is supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide.
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