Active Protein Interaction Network and Its Application on Protein Complex Detection

Jianxin Wang, Xiaoqing Peng, Min Li, Yong Luo, Yi Pan
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引用次数: 17

Abstract

In recent years, more and more attentions are focused on modelling and analyzing dynamic network. Some researchers attempted to extract dynamic network by combining the dynamic information from gene expression data or sub cellular localization data with protein network. However, the dynamics of proteins' presence does not guarantee the dynamics of interactions, since the presence of a protein does not indicate the protein's activity. The activity of a protein is closely connected with its function. Thus only the dynamics of proteins activity ensure the dynamics of interaction. The gene expression of a cellular process or cycle carries more information than only the dynamics of proteins' presence. We assume that a protein is active when its expression values are near its maximum expression value, since the expression quantity will decrease after it has performed its function that leads a feedback for controlling the expression quantity. In this paper, we proposed a method to identify active time points for each protein in a cellular process or cycle by using a 3-sigma principle to compute an active threshold for each gene according to the characteristics of its expression curve. Combined the activity information and protein interaction network, we can construct an active protein interaction network (APPI). To demonstrate the efficiency of APPI network model, we applied it on complex detection. Compared with single threshold time series networks, APPI network achieves a better performance on protein complex prediction.
活性蛋白相互作用网络及其在蛋白复合物检测中的应用
近年来,动态网络的建模和分析越来越受到人们的关注。一些研究者试图将基因表达数据或亚细胞定位数据中的动态信息与蛋白质网络相结合来提取动态网络。然而,蛋白质存在的动态并不能保证相互作用的动态,因为蛋白质的存在并不表明蛋白质的活性。蛋白质的活性与其功能密切相关。因此,只有蛋白质活性的动态才能保证相互作用的动态。细胞过程或周期的基因表达携带的信息比仅仅是蛋白质存在的动态更多。我们假设一个蛋白在其表达值接近其最大表达值时是有活性的,因为它在完成其功能后,表达量会减少,导致控制表达量的反馈。在本文中,我们提出了一种识别细胞过程或周期中每个蛋白质的活性时间点的方法,该方法使用3-sigma原理根据每个基因的表达曲线特征计算每个基因的活性阈值。将活性信息与蛋白质相互作用网络相结合,构建活性蛋白质相互作用网络(APPI)。为了验证APPI网络模型的有效性,我们将其应用于复杂检测。与单阈值时间序列网络相比,APPI网络在蛋白质复合体预测上取得了更好的性能。
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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