使用隐马尔可夫模型和进化信息可实现最佳的α-螺旋跨膜蛋白拓扑结构预测。
Best alpha-helical transmembrane protein topology predictions are achieved using hidden Markov models and evolutionary information.
作者信息
Viklund Håkan, Elofsson Arne
机构信息
Stockholm Bioinformatics Center, Stockholm University, SE-10691 Stockholm, Sweden.
出版信息
Protein Sci. 2004 Jul;13(7):1908-17. doi: 10.1110/ps.04625404.
Abstract
Methods that predict the topology of helical membrane proteins are standard tools when analyzing any proteome. Therefore, it is important to improve the performance of such methods. Here we introduce a novel method, PRODIV-TMHMM, which is a profile-based hidden Markov model (HMM) that also incorporates the best features of earlier HMM methods. In our tests, PRODIV-TMHMM outperforms earlier methods both when evaluated on "low-resolution" topology data and on high-resolution 3D structures. The results presented here indicate that the topology could be correctly predicted for approximately two-thirds of all membrane proteins using PRODIV-TMHMM. The importance of evolutionary information for topology prediction is emphasized by the fact that compared with using single sequences, the performance of PRODIV-TMHMM (as well as two other methods) is increased by approximately 10 percentage units by the use of homologous sequences. On a more general level, we also show that HMM-based (or similar) methods perform superiorly to methods that focus mainly on identification of the membrane regions.
摘要
预测螺旋膜蛋白拓扑结构的方法是分析任何蛋白质组时的标准工具。因此,提高此类方法的性能很重要。在此,我们介绍一种新方法PRODIV-TMHMM,它是一种基于轮廓的隐马尔可夫模型(HMM),还融合了早期HMM方法的最佳特性。在我们的测试中,无论是在“低分辨率”拓扑数据还是高分辨率三维结构上进行评估,PRODIV-TMHMM都优于早期方法。此处给出的结果表明,使用PRODIV-TMHMM可以正确预测大约三分之二的所有膜蛋白的拓扑结构。与使用单序列相比,通过使用同源序列,PRODIV-TMHMM(以及其他两种方法)的性能提高了约10个百分点,这一事实强调了进化信息对拓扑预测的重要性。在更一般的层面上,我们还表明,基于HMM(或类似)的方法比主要专注于识别膜区域的方法表现更优。
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