Computer-Assisted Design of Benzoisoxazol derivatives Inhibitors of Bromodomain-containing Protein 4 (BRD4) with Favorable Pharmacokinetic Profile

Rika J Kouadja, Logbo M Mouss, K. C. Kouman, M. Nsangou, E. Megnassan
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Abstract

We performed a relation computed-aided design based on the structure of benzo[d]isoxazol derivatives inhibitors (BDIO) derivatives, new potent inhibitors of the BRD4 protein. By using in-situ modifications of the three dimensional (3D) models of BRD4-BDIOx complex (Protein Data Bank (PDB) entry code: 5Y8Z) were prepared for the training and validation sets compounds of 29 BDIOx with observed inhibitory potencies (). We first built a quantitative structure activity relationship (QSAR) model in the gas phase, linearly correlating the calculated enthalpies of the BRD4-BDIOx complex formation with (; = 0,80) first and then a superior QSAR model was brought forth, correlating computed relative Gibbs’ free energies of complexation and ( = -0.1205 + 6.9374 ; = 0.96) which was then validated by a 3D-QSAR pharmacophore generation model (PH4) ( = 0.996 + 0.0554 ; = 0.95). The structural information of the active conformation of the training set BDIOs from the models guided us in the design of a virtual combinatorial library (VCL) of 99 225 analogs. We then filtered the VCL by applying Lipinski’s rule-of-five, in order to identify new BDIOs drug likely analogs. The pharmacophore (PH4)-based screening retained 106 new and potent BDIOs with predicted inhibitory potencies up to 158 times more active than the most active traing set BDIO1 (). Finally, the predicted pharmacokinetic profiles of the best potent of these new analogs () were compared to current orally administered anticancer drugs. This computational approach, which combines molecular mechanics and the Poisson–Boltzmann (PB) implicit solvation theory, the pharmacophore model, the analysis of BRD4-BDIOs interaction energies, the in-silico screening of VCL compounds, and the inference of ADME properties resulted in a set of new suggested BRD4 inhibitors for the fight against CRPC.
计算机辅助设计具有良好药代动力学特征的含溴结构域蛋白 4 (BRD4) 苯并异噁唑衍生物抑制剂
我们根据苯并[d]异恶唑衍生物抑制剂(BDIO)衍生物--BRD4 蛋白的新型强效抑制剂--的结构进行了关联计算辅助设计。通过原位修改 BRD4-BDIOx 复合物的三维(3D)模型(蛋白质数据库(PDB)条目代码:5Y8Z)为训练集和验证集制备了 29 种 BDIOx 复合物,并观察到其抑制效力()。我们首先建立了一个气相定量结构活性关系(QSAR)模型,将计算得出的 BRD4-BDIOx 复合物形成的热焓与 (; = 0,80) 线性相关,然后提出了一个高级 QSAR 模型,将计算得出的复合物相对吉布斯自由能与 ( = -0.1205 + 6.9374 ; = 0.96),然后通过三维-QSAR 药效生成模型(PH4)( = 0.996 + 0.0554 ; = 0.95)进行验证。模型中训练集 BDIO 的活性构象结构信息指导我们设计了一个由 99 225 种类似物组成的虚拟组合库(VCL)。然后,我们运用利平斯基五法则对虚拟组合库进行筛选,以确定新的 BDIOs 药物可能的类似物。基于药代动力学(PH4)的筛选保留了 106 种新的强效 BDIO,其预测抑制效力是最活跃的 BDIO1()的 158 倍。最后,将这些新类似物中药效最好的()的预测药代动力学特征与目前口服的抗癌药物进行了比较。这种计算方法结合了分子力学和泊松-波尔兹曼(PB)隐式溶解理论、药效模型、BRD4-BDIOs 相互作用能量分析、VCL 化合物的体内筛选以及 ADME 特性推断,最终为抗击 CRPC 提出了一套新的 BRD4 抑制剂建议。
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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