通过引入冯·诺依曼熵和一种新颖的缺口处理方法来估计残基进化保守性。
Estimating residue evolutionary conservation by introducing von Neumann entropy and a novel gap-treating approach.
作者信息
Zhang S-W, Zhang Y-L, Pan Q, Cheng Y-M, Chou K-C
机构信息
College of Automation, Northwestern Polytechnical University, Xi'an, China.
出版信息
Amino Acids. 2008 Aug;35(2):495-501. doi: 10.1007/s00726-007-0586-0. Epub 2007 Aug 21.
Abstract
Evolutionary conservation derived from a multiple sequence alignment is a powerful indicator of the functional significance of a residue, and it can help to predict active sites, ligand-binding sites, and protein interaction interfaces. The results of the existing algorithms in identifying the residue's conservation strongly depend on the sequence alignment, making the results highly variable. Here, by introducing the amino acid similarity matrix, we propose a novel gap-treating approach by combining the evolutionary information and von Neumann entropies to compute the residue conservation scores. It is indicated through a series of tested results that the new approach is quite encouraging and promising and may become a useful tool in complementing the existing methods.
摘要
多序列比对得出的进化保守性是一个残基功能重要性的有力指标,它有助于预测活性位点、配体结合位点和蛋白质相互作用界面。现有算法在识别残基保守性方面的结果强烈依赖于序列比对,导致结果高度可变。在此,通过引入氨基酸相似性矩阵,我们提出了一种新颖的空位处理方法,将进化信息与冯·诺依曼熵相结合来计算残基保守性得分。一系列测试结果表明,新方法相当令人鼓舞且前景广阔,可能成为补充现有方法的有用工具。
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