通过 Yoda1 的 4-苯甲酸修饰增强 PIEZO1 激动作用。

Improved PIEZO1 agonism through 4-benzoic acid modification of Yoda1.

机构信息

Leeds Institute of Cardiovascular and Metabolic Medicine, School of Medicine, University of Leeds, Leeds, UK.

School of Chemistry, University of Leeds, Leeds, UK.

出版信息

Br J Pharmacol. 2023 Aug;180(16):2039-2063. doi: 10.1111/bph.15996. Epub 2023 Jan 31.

DOI:10.1111/bph.15996

PMID:36457143

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10952572/

Abstract

BACKGROUND AND PURPOSE

The protein PIEZO1 forms mechanically activated, calcium-permeable, non-selective cation channels in numerous cell types from several species. Options for pharmacological modulation are limited and so we modified a small-molecule agonist at PIEZO1 channels (Yoda1) to increase the ability to modulate these channels.

EXPERIMENTAL APPROACH

Medicinal chemistry generated Yoda1 analogues that were tested in intracellular calcium and patch-clamp assays on cultured cells exogenously expressing human or mouse PIEZO1 or mouse PIEZO2. Physicochemical assays and wire myography assays on veins from mice with genetic disruption of PIEZO1.

KEY RESULTS

A Yoda1 analogue (KC159) containing 4-benzoic acid instead of the pyrazine of Yoda1 and its potassium salt (KC289) have equivalent or improved reliability, efficacy and potency, compared with Yoda1 in functional assays. Tested against overexpressed mouse PIEZO1 in calcium assays, the order of potency (as EC values, nM) was KC289, 150 > KC159 280 > Yoda1, 600). These compounds were selective for PIEZO1 over other membrane proteins, and the physicochemical properties were more suited to physiological conditions than those of Yoda1. The vasorelaxant effects were consistent with PIEZO1 agonism. In contrast, substitution with 2-benzoic acid failed to generate a modulator.

CONCLUSION AND IMPLICATIONS

4-Benzoic acid modification of Yoda1 improves PIEZO1 agonist activity at PIEZO1 channels. We suggest naming this new modulator Yoda2. It should be a useful tool compound in physiological assays and facilitate efforts to identify a binding site. Such compounds may have therapeutic potential, for example, in diseases linked genetically to PIEZO1 such as lymphatic dysplasia.

摘要

背景与目的

PIEZO1 蛋白在来自多个物种的多种细胞类型中形成机械激活、钙通透、非选择性阳离子通道。药理学调节的选择有限，因此我们对 PIEZO1 通道的小分子激动剂（Yoda1）进行了修饰，以提高调节这些通道的能力。

实验方法

通过对培养的细胞进行细胞内钙和膜片钳实验，测试了药物化学产生的 Yoda1 类似物，这些细胞外表达人或鼠 PIEZO1 或鼠 PIEZO2。对 PIEZO1 基因敲除小鼠的静脉进行理化测定和线描肌描记法测定。

主要结果

含有 4-苯甲酸而不是 Yoda1 的吡嗪的 Yoda1 类似物（KC159）及其钾盐（KC289）在功能测定中与 Yoda1 相比具有等效或改善的可靠性、效力和效力。在钙测定中对过表达的鼠 PIEZO1 进行测试，效力（以 EC 值表示，nM）的顺序为 KC289>150>KC159>600。这些化合物对 PIEZO1 具有选择性，而不是对其他膜蛋白，其理化性质更适合生理条件，而不是 Yoda1。血管舒张作用与 PIEZO1 激动作用一致。相比之下，用 2-苯甲酸替代未能产生调节剂。

结论与意义

Yoda1 的 4-苯甲酸修饰提高了 PIEZO1 激动剂在 PIEZO1 通道上的活性。我们建议将这种新的调节剂命名为 Yoda2。它应该是生理测定中的有用工具化合物，并有助于识别结合位点。例如，在与 PIEZO1 基因相关的疾病（如淋巴管发育不良）中，此类化合物可能具有治疗潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4933/10952572/a8ad5a03135b/BPH-180-2039-g001.jpg

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通过 Yoda1 的 4-苯甲酸修饰增强 PIEZO1 激动作用。

Improved PIEZO1 agonism through 4-benzoic acid modification of Yoda1.

机构信息

出版信息

BACKGROUND AND PURPOSE

EXPERIMENTAL APPROACH

KEY RESULTS

CONCLUSION AND IMPLICATIONS

背景与目的

实验方法

主要结果

结论与意义

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