周期蛋白依赖性激酶抑制的保龙分子支架的结构设计修饰。

Anti-cancer drug design Pub Date : 2000-02-01
R Gussio, D W Zaharevitz, C F McGrath, N Pattabiraman, G E Kellogg, C Schultz, A Link, C Kunick, M Leost, L Meijer, E A Sausville
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引用次数: 0

摘要

使用具有细胞周期蛋白依赖性激酶1 (CDK1)抑制数据的3-D QSAR对同源系列泡龙进行了表征。从CDK2-cyclin A的晶体结构中建立了CDK1-cyclin B的同源性模型,这随后成为基于结构的设计的基础。Paullones被停靠在CDK1-cylin B模型的ATP结合位点上,并通过分子力学进行优化。根据量子力学计算的每个配体的电子性质分配原子类型后,对保龙- cdk1配合物进行了水亲性分析。亲水描述符形成了一个显著的多元回归方程,可以预测泡龙IC50数据。结果表明,亲水描述符与分子力学几何图形的结合足以设计配体的明显空间和化学互补性。然而,来自量子力学的电子性质有助于指导合成化学的努力,以产生共振稳定促进更好的电荷转移和加强氢键的配体。对CDK1亲和力低的化合物是较差的电荷受体,与受体的氢键排列不理想。这些考虑导致预测结构,如9-氰帕罗酮将比母体化合物有效得多,这一发现得到酶抑制数据的支持。此外,9-硝基保龙作为一种保龙,在活细胞中也具有类似的酶抑制效力和良好的抗增殖活性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Structure-based design modifications of the paullone molecular scaffold for cyclin-dependent kinase inhibition.

A congeneric series of paullones were characterized using a 3-D QSAR with cyclin-dependent kinase 1 (CDK1) inhibition data. A homology model of CDK1-cyclin B was developed from the crystal structure of CDK2-cyclin A, which subsequently served as the basis for the structure-based design. Paullones were docked into the ATP binding site of the CDK1-cylin B models and were optimized with molecular mechanics. Hydropathic analyses of the paullone-CDK1 complexes were performed after the atom types were assigned based on each ligand's electronic properties calculated from quantum mechanics. Hydropathic descriptors formed a significant multiple regression equation that predicts paullone IC50 data. The results indicate that the combination of hydropathic descriptors with molecular mechanics geometries are sufficient to design overt steric and chemical complementarity of the ligands. However, the electronic properties derived from quantum mechanics helped direct synthetic chemistry efforts to produce ligands that promote better charge transfer and strengthen hydrogen bonding as facilitated by resonance stabilization. Compounds with low affinity for CDK1 were poor charge acceptors and made less than ideal hydrogen bonding arrangements with the receptor. These considerations led to the prediction that structures such as 9-cyanopaullone would be considerably more potent than the parent compound, a finding supported by enzyme inhibition data. Also, 9-nitropaullone emerged as a paullone which also had similar potency in enzyme inhibition as well as a favorable anti-proliferative activity profile in living cells.

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