基于结合自由能和氢键分析的抗egfr耐药性预测

2013 IEEE Symposium on Computational Intelligence in Bioinformatics and Computational Biology (CIBCB) Pub Date : 2013-04-16 DOI:10.1109/CIBCB.2013.6595408

Weiqiang Zhou, D. D. Wang, Hong Yan, M. Wong, V. Lee

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引用次数: 7

摘要

EGFR激酶结构域的突变可引起非小细胞肺癌，这是世界上最致命的疾病之一。然而，目前的治疗受到不同EGFR突变体的耐药效应的限制。迫切需要开发计算方法来预测耐药突变。在本研究中，我们使用量子力学和分子力学模型来生成EGFR突变体，并应用分子动力学来模拟EGFR与药物的相互作用。氢键和结合自由能被用来揭示EGFR耐药的基本原理。结果表明，耐药突变体具有较大的结合自由能，但药物与蛋白质分子之间不建立氢键。这些特性可用于预测由于蛋白质突变对抗egfr药物的耐药性。

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Prediction of anti-EGFR drug resistance base on binding free energy and hydrogen bond analysis

Mutations in EGFR kinase domain can cause non-small-cell lung cancer, which is one of the most lethal diseases in the world. However, current therapy is limited by the drug resistance effect in different EGFR mutants. There is an urgent demand for developing computational methods to predict drug resisted mutations. In this study, we use quantum mechanics and molecular mechanics models to generate EGFR mutants, and apply molecular dynamic to simulate EGFR-drug interactions. Hydrogen bonds and binding free energy are used to reveal the underlying principle of drug resistance in EGFR. The results show that drug resisted mutants do not establish hydrogen bond between the drug and the protein molecule while having large binding free energy. These properties can be used to predict resistance to anti-EGFR drugs due to protein mutations.

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2013 IEEE Symposium on Computational Intelligence in Bioinformatics and Computational Biology (CIBCB)

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