基于靶标的 6-5 融合环杂环支架在体外显示出广泛的抗寄生虫效力

Darline Dize, M. Tali, Cyrille Armel Njanpa Ngansop, R. Keumoe, Eugenie Aimée Madiesse Kemgne, Lauve Rachel Tchokouaha Yamthe, Patrick Valere Tsouh Fokou, Boniface Pone Kamdem, Katsura Hata, Fabrice Fekam Boyom
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引用次数: 0

摘要

疟疾、利什曼病和非洲锥虫病等原生动物疾病是全球主要的健康问题,尤其是在发展中国家。不可否认,某些酶(二氢叶酸还原酶 [DHFR])或蛋白质(钾通道)参与了这些原生动物疾病的发病机制。本研究筛选了一系列三种 DHFR 抑制剂(6-5 嵌合杂环衍生物 X、Y 和 Z)和一种 K+ 通道阻断剂(E4031),以确定它们对利什曼原虫、恶性疟原虫和布氏锥虫的抑制作用。采用雷沙嘌呤检测法评估受试化合物的抗盘虫和抗利什曼活性,而抗疟原虫活性则通过 SYBR Green I 检测法进行评估。此外,还使用基于利马嗪的试验评估了测试化合物在 Vero、Raw 264.7 和 HepG-2 细胞中的细胞毒性,并使用在线工具 pkCSM 预测了它们的药代动力学特性。结果表明,化合物 Y 对唐诺瓦尼氏原虫(IC50:12.4 µM)、非原虫(IC50:4.28 µM)、恶性疟原虫(IC50:0.028 µM)和布鲁西氏疟原虫(IC50:0.81 µM)具有选择性(选择性指数范围:从 2.69 到 >61.4; Vero、Raw 264.7 和 HepG-2 细胞)和广谱抗原虫活性。此外,化合物 X 还能抑制恶性疟原虫(IC50:0.0052 µM)和布氏疟原虫(IC50:6.49 µM)的生长。对活性抗原虫化合物进行的硅学筛选显示,这些化合物的药物相似度得分均为正,因为这些化合物均未违反利宾斯基规则的标准。不过,还需要进行深入的药代动力学和机理研究,以支持通过重新利用 K+ 通道阻断剂和 DHFR 抑制剂来发现抗疟疾、利什曼病和非洲锥虫病的新型抗原虫药物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Target-Based 6-5 Fused Ring Heterocyclic Scaffolds Display Broad Antiparasitic Potency In Vitro
Malaria, leishmaniasis, and African trypanosomiasis are protozoan diseases that constitute major global health problems, especially in developing countries; however, the development of drug resistance coupled with the toxicity of current treatments has hindered their management. The involvement of certain enzymes (dihydrofolate reductase [DHFR]) or proteins (potassium channels) in the pathogenesis of these protozoan diseases is undeniable. In this study, a series of three DHFR inhibitors (6-5 fused heterocyclic derivatives X, Y, and Z) and one K+ channel blocker (E4031) were screened for their inhibitory effects on Leishmania donovani, Plasmodium falciparum, and Trypanosoma brucei. A resazurin assay was used to assess the antitrypanosomal and antileishmanial activities of the test compounds, whereas the antiplasmodial activity was evaluated through the SYBR Green I test. Moreover, the cytotoxicities of the test compounds were evaluated in Vero, Raw 264.7, and HepG-2 cells using a resazurin-based test, while their pharmacokinetic properties were predicted using the online tool, pkCSM. As a result, compound Y exhibited selective (selectivity index range: from 2.69 to >61.4; Vero, Raw 264.7, and HepG-2 cells) and broad-spectrum antiprotozoal activity against L. donovani promastigotes (IC50: 12.4 µM), amastigotes (IC50: 4.28 µM), P. falciparum (IC50: 0.028 µM), and T. brucei brucei (IC50: 0.81 µM). In addition, compound X inhibited the growth of P. falciparum (IC50: 0.0052 µM) and T. brucei brucei (IC50: 6.49 µM). In silico screening of the active antiprotozoal compounds revealed positive drug likeness scores, as none of the criteria for Lipinski’s rule were violated by these compounds. However, in-depth pharmacokinetic and mechanistic studies are warranted to support the discovery of novel antiprotozoal agents against malaria, leishmaniasis, and African trypanosomiasis by repurposing K+ channel blockers and DHFR inhibitors.
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