The correlation between electronic structure and antitumor activity of a seletive focal adhesion kinase inhibitors

Eclética Química Journal Pub Date : 2018-10-10 DOI:10.26850/1678-4618eqj.v43.3.2018.p10-18

Daniel Augusto Barra de Oliveira

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Abstract

Focal Adhesion Kinase (FAK) is a non-tyrosine kinase responsible to phosphorylate other enzymes associated with signal transduction. This biochemical process plays an important role to control cancer. FAK is found overexpressed in the organism during metastasis. Since FAK may be involved in the invasion and metastasis of cancer, novel molecules based on drug design have been synthesized over the past few years. The inhibitors are designed to mimic the natural substrate which is the ATP molecule. This work studied the hydrogen bonds performed between inhibitors and FAK and other electronic properties involved in this interaction. The molecular structure of FAK docked with the inhibitors was simulated using classical molecular dynamics. FAK/ inhibitor complex obtained by dynamic was optimized using quantum mechanical ab-initio calculation. Our results show that all inhibitors interact with Cys502 located in the FAK-binding site. Ab-initio calculations show that HOMO orbital is situated under Met499 and Glu500 amino acids indicating chemical reactivity in this region. The results of molecular dynamics combined with quantum chemical calculations show that the sulfonamide has a strong hydrogen bond with close distances, while the thiazole has a weak hydrogen bond with long distances. Sulfonamide has known good activity against FAK while the thiazole molecule has an unknown activity. These results allow predicting that the molecule of thiazole is a not good inhibitor to FAK inhibition.

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一种选择性黏附激酶抑制剂的电子结构与抗肿瘤活性的关系

焦点黏附激酶(FAK)是一种非酪氨酸激酶，负责磷酸化与信号转导相关的其他酶。这一生化过程对控制癌症起着重要作用。在转移过程中发现FAK在机体中过度表达。由于FAK可能参与癌症的侵袭和转移，在过去的几年里，基于药物设计的新分子已经被合成。抑制剂被设计成模拟天然底物，即ATP分子。本工作研究了抑制剂和FAK之间的氢键以及这种相互作用所涉及的其他电子性质。用经典分子动力学方法模拟了与抑制剂对接的FAK的分子结构。采用量子力学从头算法对动力学得到的FAK/抑制剂配合物进行优化。我们的研究结果表明，所有抑制剂都与位于fak结合位点的Cys502相互作用。Ab-initio计算表明HOMO轨道位于Met499和Glu500氨基酸下，表明该区域具有化学反应性。分子动力学结合量子化学计算结果表明，磺胺类化合物具有强氢键且距离较近，而噻唑类化合物具有弱氢键且距离较远。已知磺胺对FAK有良好的活性，而噻唑分子对FAK的活性未知。这些结果可以预测噻唑分子对FAK的抑制作用不是很好。

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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Eclética Química Journal

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