High Proteolytic Resistance of Spider-Derived Inhibitor Cystine Knots

International Journal of Peptides Pub Date : 2015-12-30 DOI:10.1155/2015/537508

K. Kikuchi, Mika Sugiura, Tadashi Kimura

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引用次数: 24

Abstract

Proteolytic stability in gastrointestinal tract and blood plasma is the major obstacle for oral peptide drug development. Inhibitor cystine knots (ICKs) are linear cystine knot peptides which have multifunctional properties and could become promising drug scaffolds. ProTx-I, ProTx-II, GTx1-15, and GsMTx-4 were spider-derived ICKs and incubated with pepsin, trypsin, chymotrypsin, and elastase in physiological conditions to find that all tested peptides were resistant to pepsin, and ProTx-II, GsMTx-4, and GTx1-15 showed resistance to all tested proteases. Also, no ProTx-II degradation was observed in rat blood plasma for 24 hours in vitro and ProTx-II concentration in circulation decreased to half in 40 min, indicating absolute stability in plasma and fast clearance from the system. So far, linear peptides are generally thought to be unsuitable in vivo, but all tested ICKs were not degraded by pepsin and stomach could be selected for the alternative site of drug absorption for fast onset of the drug action. Since spider ICKs are selective inhibitors of various ion channels which are related to the pathology of many diseases, engineered ICKs will make a novel class of peptide medicines which can treat variety of bothering symptoms.

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蜘蛛衍生抑制剂胱氨酸结的高蛋白水解抗性

胃肠道和血浆中蛋白水解的稳定性是口服肽类药物开发的主要障碍。抑制剂胱氨酸结是一种具有多种功能的线性胱氨酸结肽，是一种很有前景的药物支架材料。ProTx-I、ProTx-II、GTx1-15和GsMTx-4是蜘蛛衍生的ICKs，在生理条件下与胃蛋白酶、胰蛋白酶、糜凝胰蛋白酶和弹性蛋白酶孵育，发现所有测试的肽都对胃蛋白酶具有抗性，ProTx-II、GsMTx-4和GTx1-15对所有测试的蛋白酶都具有抗性。此外，体外24小时大鼠血浆中未观察到ProTx-II降解，循环中ProTx-II浓度在40分钟内下降到一半，表明血浆中绝对稳定，从系统中快速清除。到目前为止，线性肽通常被认为不适合在体内使用，但所有测试的iks都不被胃蛋白酶降解，可以选择胃作为药物吸收的替代部位，以快速开始药物作用。由于蜘蛛iks是多种离子通道的选择性抑制剂，与许多疾病的病理有关，因此工程iks将成为一类新的肽类药物，可以治疗各种困扰症状。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Peptides

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