操纵一种蜘蛛肽毒素可以改变其对脂质双层的亲和力以及对电压门控钠离子通道亚型 1.7 的效力和选择性。

Manipulation of a spider peptide toxin alters its affinity for lipid bilayers and potency and selectivity for voltage-gated sodium channel subtype 1.7.

机构信息

Institute for Molecular Bioscience, Centre for Pain Research, The University of Queensland, Brisbane, Queensland 4072, Australia.

School of Pharmacy, The University of Queensland, Woolloongabba, Queensland 4103, Australia.

出版信息

J Biol Chem. 2020 Apr 10;295(15):5067-5080. doi: 10.1074/jbc.RA119.012281. Epub 2020 Mar 5.

DOI:10.1074/jbc.RA119.012281

PMID:32139508

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7152767/

Abstract

Huwentoxin-IV (HwTx-IV) is a gating modifier peptide toxin from spiders that has weak affinity for the lipid bilayer. As some gating modifier toxins have affinity for model lipid bilayers, a tripartite relationship among gating modifier toxins, voltage-gated ion channels, and the lipid membrane surrounding the channels has been proposed. We previously designed an HwTx-IV analogue (gHwTx-IV) with reduced negative charge and increased hydrophobic surface profile, which displays increased lipid bilayer affinity and activity at the voltage-gated sodium channel subtype 1.7 (Na1.7), a channel targeted in pain management. Here, we show that replacements of the positively-charged residues that contribute to the activity of the peptide can improve gHwTx-IV's potency and selectivity for Na1.7. Using HwTx-IV, gHwTx-IV, [R26A]gHwTx-IV, [K27A]gHwTx-IV, and [R29A]gHwTx-IV variants, we examined their potency and selectivity at human Na1.7 and their affinity for the lipid bilayer. [R26A]gHwTx-IV consistently displayed the most improved potency and selectivity for Na1.7, examined alongside off-target Nas, compared with HwTx-IV and gHwTx-IV. The lipid affinity of each of the three novel analogues was weaker than that of gHwTx-IV, but stronger than that of HwTx-IV, suggesting a possible relationship between potency at Na1.7 and affinity for lipid bilayers. In a murine Na1.7 engagement model, [R26A]gHwTx-IV exhibited an efficacy comparable with that of native HwTx-IV. In summary, this study reports the development of an HwTx-IV analogue with improved selectivity for the pain target Na1.7 and with an efficacy similar to that of native HwTx-IV.

摘要

虎纹捕鸟蛛毒素-IV（HwTx-IV）是一种来自蜘蛛的门控修饰肽毒素，对脂质双层的亲和力较弱。由于一些门控修饰毒素对模型脂质双层具有亲和力，因此提出了门控修饰毒素、电压门控离子通道和围绕通道的脂质膜之间的三分体关系。我们之前设计了一种 HwTx-IV 类似物（gHwTx-IV），其负电荷减少，疏水性表面轮廓增加，该类似物显示出与电压门控钠离子通道亚型 1.7（Na1.7）的亲和力增加，Na1.7 是疼痛管理的靶点。在这里，我们表明，对有助于肽活性的带正电荷残基的取代可以提高 gHwTx-IV 对 Na1.7 的效力和选择性。使用 HwTx-IV、gHwTx-IV、[R26A]gHwTx-IV、[K27A]gHwTx-IV 和 [R29A]gHwTx-IV 变体，我们研究了它们在人源 Na1.7 上的效力和选择性及其与脂质双层的亲和力。与 HwTx-IV 和 gHwTx-IV 相比，[R26A]gHwTx-IV 对 Na1.7 的效力和选择性始终表现出最显著的改善。三种新型类似物的脂质亲和力均弱于 gHwTx-IV，但强于 HwTx-IV，这表明 Na1.7 的效力与脂质双层的亲和力之间可能存在关系。在小鼠 Na1.7 结合模型中，[R26A]gHwTx-IV 表现出与天然 HwTx-IV 相当的疗效。总之，本研究报告了一种 HwTx-IV 类似物的开发，该类似物对疼痛靶标 Na1.7 的选择性提高，且疗效与天然 HwTx-IV 相似。

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