利用共价对接、分子动力学模拟和 MM-PBSA 计算设计针对 Rhodesain 的人类非洲锥虫病新药的启示。

Igor José Dos Santos Nascimento, Mirelly Barbosa Santos, Washley Phyama De Jesus Marinho, Ricardo Olimpio de Moura
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引用次数: 0

摘要

背景:被忽视的热带疾病(NTDs)是寄生虫病和细菌性疾病,影响着约 149 个国家,主要是没有基本卫生条件的贫困人口。其中,非洲人类锥虫病(HAT)(又称昏睡病)的数据令人担忧,初期治疗以苏拉明和喷他脒为主,慢性期治疗以美拉索普罗和依氟鸟氨酸为主。因此,为了发现新的药物,一些研究指出荷包牡丹碱是一个很有前景的药物靶点,因为荷包牡丹碱具有降解蛋白质以及在昆虫和宿主细胞之间进行蛋白质胞内转运的功能,并且存在于寄生虫的所有周期阶段。方法:Nascimento等人(2021年)之前的研究显示了过去十年中荷包牡丹碱抑制剂的主要发展情况,在此基础上,我们对这些抑制剂数据集进行了分子对接和动力学研究,以揭示可用于药物设计的关键信息。因此,我们采用了传统和共价对接,并强调了拟肽支架中配体存在迈克尔受体,与 Gly19、Gly23、Gly65、Asp161 和 Trp184 的相互作用对抑制活性至关重要:同时,我们利用 MD 模拟和 MM-PBSA 计算的结果证实,Gly19、Gly23、Gly65、Asp161 和 Trp184 显示出很高的结合能(ΔGbind 在 -72.782 到 -124.477 kJ.mol-1 之间)。此外,范德华相互作用的贡献(-140,930 至 -96,988 kJ.mol-1)优于静电力(-43,270 至 -6,854 kJ.mol-1),这表明范德华相互作用是形成和维持配体-rhodesain 复合物的主导力量:此外,动态交叉相关图(DCCM)显示,与游离的罗得沙因相比,所有复合物都有更多的相关运动,并且在上述残基区域存在很强的相互作用。主成分分析(PCA)表明复合物的稳定性与 RMSF 和 RMSD 相吻合。这项研究可以提供有价值的见解,指导世界各地的研究人员发现抗 HAT 的新药。
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Insights to Design New Drugs against Human African Trypanosomiasis Targeting Rhodesain using Covalent Docking, Molecular Dynamics Simulations, and MM-PBSA Calculations.

Background: Neglected tropical diseases (NTDs) are parasitic and bacterial diseases that affect approximately 149 countries, mainly the poor population without basic sanitation. Among these, African Human Trypanosomiasis (HAT), known as sleeping sickness, shows alarming data, with treatment based on suramin and pentamidine in the initial phase and melarsoprol and eflornithine in the chronic phase. Thus, to discover new drugs, several studies point to rhodesain as a promising drug target due to the function of protein degradation and intracellular transport of proteins between the insect and host cells and is present in all cycle phases of the parasite.

Methodology: Here, based on the previous studies by Nascimento et al. (2021) that show the main rhodesain inhibitors development in the last decade, molecular docking and dynamics were applied in these inhibitors datasets to reveal crucial information that can be into drug design. Thus, conventional and covalent docking was employed and highlighted the presence of Michael acceptors in the ligands in a peptidomimetics scaffold, and interaction with Gly19, Gly23, Gly65, Asp161, and Trp184 is essential to the inhibiting activity.

Results: Also, our findings using MD simulations and MM-PBSA calculations confirmed Gly19, Gly23, Gly65, Asp161, and Trp184, showing high binding energy (ΔGbind between -72.782 to -124.477 kJ.mol-1). In addition, Van der Waals interactions have a better contribution (-140,930 to -96,988 kJ.mol-1) than electrostatic forces (-43,270 to -6,854 kJ.mol-1), indicating Van der Waals interactions are the leading forces in forming and maintaining ligand-rhodesain complexes.

Conclusion: Furthermore, the Dynamic Cross-Correlation Maps (DCCM) show more correlated movements for all complexes than the free rhodesain and strong interactions in the regions of the aforementioned residues. Principal Component Analysis (PCA) demonstrates complex stability corroborating with RMSF and RMSD. This study can provide valuable insights that can guide researchers worldwide to discover a new promising drug against HAT.

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