Abstract
BackgroundProtein interaction networks (PINs) are known to be useful to detect protein complexes. However, most available PINs are static, which cannot reflect the dynamic changes in real networks. At present, some researchers have tried to construct dynamic networks by incorporating time-course (dynamic) gene expression data with PINs. However, the inevitable background noise exists in the gene expression array, which could degrade the quality of dynamic networkds. Therefore, it is needed to filter out contaminated gene expression data before further data integration and analysis.ResultsFirstly, we adopt a dynamic model-based method to filter noisy data from dynamic expression profiles. Then a new method is proposed for identifying active proteins from dynamic gene expression profiles. An active protein at a time point is defined as the protein the expression level of whose corresponding gene at that time point is higher than a threshold determined by a standard variance involved threshold function. Furthermore, a noise-filtered active protein interaction network (NF-APIN) is constructed. To demonstrate the efficiency of our method, we detect protein complexes from the NF-APIN, compared with those from other dynamic PINs.ConclusionA dynamic model based method can effectively filter out noises in dynamic gene expression data. Our method to compute a threshold for determining the active time points of noise-filtered genes can make the dynamic construction more accuracy and provide a high quality framework for network analysis, such as protein complex prediction.
Highlights
Proteomics is the most exciting frontier in life science
The static Protein interaction networks (PINs), in which the interactions are accumulated in different conditions and time points, cannot reflect the real dynamic PIN networks in cell, and has certain influence on the accuracy of protein complex prediction
We construct a noise filter active protein interaction network (NF-APIN) based on the active information extracted from gene expression profile and the static PIN
Summary
Proteomics is the most exciting frontier in life science It becomes one of the hottest research topics in systematically analyzing and comprehensively understanding proteins through the study of protein structures, functions, and interactions [1,2,3,4,5,6]. The static PINs, in which the interactions are accumulated in different conditions and time points, cannot reflect the real dynamic PIN networks in cell, and has certain influence on the accuracy of protein complex prediction. Some researchers have tried to construct dynamic networks by incorporating time-course (dynamic) gene expression data with PINs. the inevitable background noise exists in the gene expression array, which could degrade the quality of dynamic networkds. It is needed to filter out contaminated gene expression data before further data integration and analysis
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