PPARδ激动剂的从头生成和对接研究:预测生物活性与生物制药描述符之间的相关性

IF 0.4 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Chem-Bio Informatics Journal Pub Date : 2010-01-01 DOI:10.1273/CBIJ.10.74

V. Avupati, P. N. Kurre, Santoshi Rupa Bagadi, Murali Krishna Kumar Muthyala, R. Yejella

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引用次数: 10

摘要

分子对接了一系列双芳基取代噻唑和恶唑作为PPARδ激动剂。采用对接技术，利用Molegro Virtual Docker v 4.0.0将一组具有代表性的化合物在3D5F的活性位点区域进行对接。对于这些化合物，结合自由能(kcal/mol)与log (1/EC50)之间的相关系数较好(r2 = 0.719)。对接模拟在0.91A RMSD范围内清晰地预测了与晶体学结合模式几乎相似的结合模式。基于Ar1和Ar2取代基的验证和相互作用，开始考虑简单组合的配体设计。使用ACD/ChemSketch v 12.0计算预测所设计化合物的生物制药性质，如亲脂性(logP)、溶解度(log)、电离常数(pKa)、分布系数(logD)。研究了氢键相互作用，并考虑了预测生物活性(log (1/EC50))与生物制药性能之间的二元统计相关性。配体11 (cC)对PPARδ具有较高的结合能(-206.73 kcal/mol)。这些结果有助于了解设计配体与PPARδ结合位点区域之间发生的相互作用类型，并解释Ar1和Ar2取代对双芳基取代噻唑和恶唑衍生物的重要性。

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De novo Based Ligand generation and Docking studies of PPARδ Agonists: Correlations between Predicted Biological activity vs. Biopharmaceutical Descriptors

Molecular docking was performed on a series of bisaryl substituted thiazoles and oxazoles as PPARδ agonists. The docking technique was applied to dock a set of representative compounds within the active site region of 3D5F using Molegro Virtual Docker v 4.0.0. For these compounds, the correlation between binding free energy (kcal/mol) and log (1/EC50) values produces a good correlation coefficient (r2 = 0.719). The docking simulation clearly predicted the binding mode that is nearly similar to the crystallographic binding mode within 0.91A RMSD. Based on the validations and interactions made by Ar1 and Ar2 substituents, ligand design was initiated considering simple combinations. For the designed compounds biopharmaceutical properties e.g. Lipophilicity (logP), Solubility (logS), Ionization constant (pKa), Distribution coefficient (logD) are predicted computationally using ACD/ChemSketch v 12.0. The hydrogen bond interactions are examined and bivariate statistical correlation between predicted biological activity (log (1/EC50) and biopharmaceutical properties are considered for evaluation. Ligand 11 (cC) thus, showed high binding energy (-206.73 kcal/mol) against PPARδ. The results avail to understand the type of interactions that occur between designed ligands with PPARδ binding site region and explain the importance of Ar1 and Ar2 substitutions on derivatives of bisaryl substituted thiazoles and oxazoles.

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来源期刊

Chem-Bio Informatics Journal BIOCHEMISTRY & MOLECULAR BIOLOGY-

CiteScore

0.60

自引率

0.00%

发文量