Wei-Ming Chen1, Samuel A Danziger, Jung-Hsien Chiang, John D Aitchison. 1. Institute for Systems Biology, Seattle, WA 98109-5234, USA, Department of Computer Science and Information Engineering, National Cheng Kung University, Tainan, Taiwan and Seattle Biomedical Research Institute, Seattle, WA 98109-5219, USA.
Abstract
MOTIVATION: Protein phosphorylation is critical for regulating cellular activities by controlling protein activities, localization and turnover, and by transmitting information within cells through signaling networks. However, predictions of protein phosphorylation and signaling networks remain a significant challenge, lagging behind predictions of transcriptional regulatory networks into which they often feed. RESULTS: We developed PhosphoChain to predict kinases, phosphatases and chains of phosphorylation events in signaling networks by combining mRNA expression levels of regulators and targets with a motif detection algorithm and optional prior information. PhosphoChain correctly reconstructed ∼78% of the yeast mitogen-activated protein kinase pathway from publicly available data. When tested on yeast phosphoproteomic data from large-scale mass spectrometry experiments, PhosphoChain correctly identified ∼27% more phosphorylation sites than existing motif detection tools (NetPhosYeast and GPS2.0), and predictions of kinase-phosphatase interactions overlapped with ∼59% of known interactions present in yeast databases. PhosphoChain provides a valuable framework for predicting condition-specific phosphorylation events from high-throughput data. AVAILABILITY: PhosphoChain is implemented in Java and available at http://virgo.csie.ncku.edu.tw/PhosphoChain/ or http://aitchisonlab.com/PhosphoChain
MOTIVATION: Protein phosphorylation is critical for regulating cellular activities by controlling protein activities, localization and turnover, and by transmitting information within cells through signaling networks. However, predictions of protein phosphorylation and signaling networks remain a significant challenge, lagging behind predictions of transcriptional regulatory networks into which they often feed. RESULTS: We developed PhosphoChain to predict kinases, phosphatases and chains of phosphorylation events in signaling networks by combining mRNA expression levels of regulators and targets with a motif detection algorithm and optional prior information. PhosphoChain correctly reconstructed ∼78% of the yeast mitogen-activated protein kinase pathway from publicly available data. When tested on yeast phosphoproteomic data from large-scale mass spectrometry experiments, PhosphoChain correctly identified ∼27% more phosphorylation sites than existing motif detection tools (NetPhosYeast and GPS2.0), and predictions of kinase-phosphatase interactions overlapped with ∼59% of known interactions present in yeast databases. PhosphoChain provides a valuable framework for predicting condition-specific phosphorylation events from high-throughput data. AVAILABILITY: PhosphoChain is implemented in Java and available at http://virgo.csie.ncku.edu.tw/PhosphoChain/ or http://aitchisonlab.com/PhosphoChain
Authors: Jop H van Berlo; John W Elrod; Bruce J Aronow; William T Pu; Jeffery D Molkentin Journal: Proc Natl Acad Sci U S A Date: 2011-07-11 Impact factor: 11.205
Authors: Chris Stark; Ting-Cheng Su; Ashton Breitkreutz; Pedro Lourenco; Matthew Dahabieh; Bobby-Joe Breitkreutz; Mike Tyers; Ivan Sadowski Journal: Database (Oxford) Date: 2010-01-28 Impact factor: 3.451
Authors: Eliza J R Peterson; David J Reiss; Serdar Turkarslan; Kyle J Minch; Tige Rustad; Christopher L Plaisier; William J R Longabaugh; David R Sherman; Nitin S Baliga Journal: Nucleic Acids Res Date: 2014-09-17 Impact factor: 16.971
Authors: Z Meng; X Ma; J Du; X Wang; M He; Y Gu; J Zhang; W Han; Z Fang; X Gan; C Van Ness; X Fu; D E Schones; R Xu; W Huang Journal: Oncogene Date: 2016-11-07 Impact factor: 9.867