David C Kombo, Matthew J LaMarche, Chilaluck C Konkankit, S Rackovsky
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引用次数: 0
摘要
我们将人工智能和机器学习方法应用于蛋白质动态生物信息学。我们使用以前开发的一种表示方法重写了一个大型蛋白质数据集的序列,其中包含折叠分子和内在无序分子,该表示方法编码了天然氨基酸的内在动态特性。我们对得到的序列进行了傅立叶分析。结果表明,使用几种不同的监督学习方法建立的分类模型能够仅从序列上成功区分折叠蛋白质和内在无序蛋白质。研究进一步表明,这种区分最重要的序列特性是序列迁移率,即特定残基平均阿尔法碳 B 因子的序列平均值。这与我们以前的工作一致,我们在以前的工作中证明了序列流动性在蛋白质动态生物信息学和生物物理学中的核心作用。这一发现为将动态生物信息学与机器学习算法相结合应用于一系列重大生物医学问题开辟了道路。
Application of artificial intelligence and machine learning techniques to the analysis of dynamic protein sequences.
We apply methods of Artificial Intelligence and Machine Learning to protein dynamic bioinformatics. We rewrite the sequences of a large protein data set, containing both folded and intrinsically disordered molecules, using a representation developed previously, which encodes the intrinsic dynamic properties of the naturally occurring amino acids. We Fourier analyze the resulting sequences. It is demonstrated that classification models built using several different supervised learning methods are able to successfully distinguish folded from intrinsically disordered proteins from sequence alone. It is further shown that the most important sequence property for this discrimination is the sequence mobility, which is the sequence averaged value of the residue-specific average alpha carbon B factor. This is in agreement with previous work, in which we have demonstrated the central role played by the sequence mobility in protein dynamic bioinformatics and biophysics. This finding opens a path to the application of dynamic bioinformatics, in combination with machine learning algorithms, to a range of significant biomedical problems.
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