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DS-3032B的分子对接,一种具有肿瘤治疗开发潜力的小鼠双微体2酶拮抗剂。

Molecular docking of DS-3032B, a mouse double minute 2 enzyme antagonist with potential for oncology treatment development.

作者信息

da Mota Vítor Hugo Sales, Freire de Melo Fabrício, de Brito Breno Bittencourt, da Silva Filipe Antônio França, Teixeira Kádima Nayara

机构信息

Campus Toledo, Universidade Federal do Paraná, Toledo 85.919-899, Paraná, Brazil.

Instituto Multidisciplinar em Saúde, Universidade Federal da Bahia, Vitória da Conquista 45029-094, Bahia, Brazil.

出版信息

World J Clin Oncol. 2022 Jun 24;13(6):496-504. doi: 10.5306/wjco.v13.i6.496.

DOI:10.5306/wjco.v13.i6.496
PMID:35949428
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9244969/
Abstract

BACKGROUND

It is known that p53 suppression is an important marker of poor prognosis of cancers, especially in solid tumors of the breast, lung, stomach, and esophagus; liposarcomas, glioblastomas, and leukemias. Because p53 has mouse double minute 2 (MDM2) as its primary negative regulator, this molecular docking study seeks to answer the following hypotheses: Is the interaction between DS-3032B and MDM2 stable enough for this drug to be considered as a promising neoplastic inhibitor?

AIM

To analyze, , the chemical bonds between the antagonist DS-3032B and its binding site in MDM2

METHODS

For molecular docking simulations, the file containing structures of MDM2 (receptor) and the drug DS-3032B (ligand) were selected. The three-dimensional structure of MDM2 was obtained from Protein Data Bank, and the one for DS-3032B was obtained from PubChem database. The location and dimensions of the Grid box was determined using AutoDock Tools software. In this case, the dimensions of the Grid encompassed the entire receptor. The ligand DS-3032B interacts with the MDM2 receptor in a physiological environment with pH 7.4; thus, to simulate more reliably, its interaction was made with the calculation for the prediction of its protonation state using the MarvinSketch software. Both ligands, with and without the protonation, were prepared for molecular docking using the AutoDock Tools software. This software detects the torsion points of the drug and calculates the angle of the torsions. Molecular docking simulations were performed using the tools of the AutoDock platform connected to the Vina software. The analyses of the amino acid residues involved in the interactions between the receptor and the ligand as well as the twists of the ligand, atoms involved in the interactions, and type, strength, and length of the interactions were performed using the PyMol software (pymol.org/2) and Discovery Studio from BIOVIA.

RESULTS

The global alignment indicated crystal structure 5SWK was more suitable for docking simulations by presenting the p53 binding site. The three-dimensional structure 5SWK for MDM2 was selected from Protein Data Bank and the three-dimensional structure of DS-3032B was selected from PubChem (Compound CID: 73297272; Milademetan). After molecular docking simulations, the most stable conformer was selected for both protonated and non-protonated DS-3032B. The interaction between MDM2 and DS-3032B occurs with high affinity; no significant difference was observed in the affinity energies between the MDM2/pronated DS-3032B (-9.9 kcal/mol) and MDM2/non-protonated DS-3032B conformers (-10.0 kcal/mol). Sixteen amino acid residues of MDM2 are involved in chemical bonds with the protonated DS-3032B; these 16 residues of MDM2 belong to the p53 biding site region and provide high affinity to interaction and stability to drug-protein complex.

CONCLUSION

Molecular docking indicated that DS-3032B antagonist binds to the same region of the p53 binding site in the MDM2 with high affinity and stability, and this suggests therapeutic efficiency.

摘要

背景

已知p53抑制是癌症预后不良的一个重要标志,尤其是在乳腺癌、肺癌、胃癌和食管癌等实体瘤;脂肪肉瘤、胶质母细胞瘤和白血病中。由于p53以小鼠双微体2(MDM2)作为其主要负调节因子,本分子对接研究旨在回答以下假设:DS-3032B与MDM2之间的相互作用是否足够稳定,使该药物被视为一种有前景的肿瘤抑制剂?

目的

分析拮抗剂DS-3032B与其在MDM2中的结合位点之间的化学键

方法

对于分子对接模拟,选择包含MDM2(受体)和药物DS-3032B(配体)结构的文件。MDM2的三维结构从蛋白质数据库获得,DS-3032B的三维结构从PubChem数据库获得。使用AutoDock Tools软件确定网格框的位置和尺寸。在这种情况下,网格的尺寸涵盖了整个受体。配体DS-3032B在pH 7.4的生理环境中与MDM2受体相互作用;因此,为了更可靠地模拟,使用MarvinSketch软件对其质子化状态进行预测计算,使其相互作用。使用AutoDock Tools软件对有质子化和无质子化的两种配体进行分子对接准备。该软件检测药物的扭转点并计算扭转角度。使用连接到Vina软件的AutoDock平台工具进行分子对接模拟。使用PyMol软件(pymol.org/2)和BIOVIA的Discovery Studio对受体与配体之间相互作用中涉及的氨基酸残基、配体的扭转、相互作用中涉及的原子以及相互作用的类型、强度和长度进行分析。

结果

全局比对表明晶体结构5SWK通过呈现p53结合位点更适合对接模拟。从蛋白质数据库中选择MDM2的三维结构5SWK,从PubChem中选择DS-3032B的三维结构(化合物登记号:73297272;米拉美坦)。经过分子对接模拟后,为质子化和非质子化的DS-3032B选择了最稳定的构象。MDM2与DS-3032B之间的相互作用以高亲和力发生;在MDM2/质子化DS-3032B(-9.9千卡/摩尔)和MDM2/非质子化DS-3032B构象体(-10.0千卡/摩尔)之间的亲和力能量上未观察到显著差异。MDM2的1六个氨基酸残基与质子化的DS-3032B形成化学键;MDM2的这16个残基属于p53结合位点区域,为药物 - 蛋白质复合物的相互作用和稳定性提供高亲和力。

结论

分子对接表明DS-3032B拮抗剂以高亲和力和稳定性结合到MDM2中p53结合位点的相同区域,这表明其具有治疗效果。

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