Halogenation as a Strategy to Improve Antiplasmodial Activity: A Report of New 3-Alkylpyridine Marine Alkaloid Analogs

International Journal of Travel Medicine and Global Health Pub Date : 2019-12-15 DOI:10.15171/ijtmgh.2019.27

Camila S Barbosa, Daniel Silqueira Martins Guimarães, Juliana Da Costa Alves, C. F. Brito, R. Ribeiro-Viana, F. Varotti, G. H. R. Viana

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引用次数: 1

Abstract

Introduction: Due to the emergence of resistance to antimalarial drugs as well as the lack of vaccination for malaria, there is an urgent demand for the development of new antimalarial alternatives. Recently, our research group developed a new set of 3-alkylpyridine marine alkaloid analogs, of which a compound known as compound 5 was found to be inactive against Plasmodium falciparum. Methods: Herein, we report a successful halogenation strategy to improve the antiplasmodial activity of compound 5 through the replacement of a hydroxyl group by chlorine (compound 6) and fluorine (compound 7) atoms. Results: Compounds 6 and 7 showed improved antiplasmodial activities (IC50 = 7.2 and 8.3 μM, respectively) 20 times higher than that of their precursor, compound 5 (IC50 = 210.7 μM). Ultraviolet-visible titration experiments demonstrated that halogenation of compound 5 did not alter its ability to bind its target, hematin. Conclusion: Halogenation can enhance the antiplasmodial activity of a compound without altering its mechanism of action.

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卤化作为提高抗疟原虫活性的策略:新的3-烷基吡啶海洋生物碱类似物的报道

引言：由于抗疟药物耐药性的出现以及缺乏疟疾疫苗接种，迫切需要开发新的抗疟替代品。最近，我们的研究小组开发了一套新的3-烷基吡啶海洋生物碱类似物，其中一种称为化合物5的化合物被发现对恶性疟原虫没有活性。方法：在此，我们报道了一种成功的卤化策略，通过氯（化合物6）和氟（化合物7）原子取代羟基来提高化合物5的抗等离子体活性。结果：化合物6和7的抗疟原虫活性（IC50分别为7.2和8.3μM）是其前体化合物5（IC50为210.7μM）的20倍。紫外-可见滴定实验表明，化合物5的卤化并没有改变其结合其靶标血红素的能力。结论：卤化能在不改变其作用机制的前提下提高化合物的抗疟原虫活性。

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International Journal of Travel Medicine and Global Health

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15 weeks