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Knowledge-Based Analysis for Detecting Key Signaling Events from Time-Series Phosphoproteomics Data

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  • Pengyi Yang
  • Xiaofeng Zheng
  • Vivek Jayaswal
  • Guang Hu
  • Jean Yee Hwa Yang
  • Raja Jothi

Abstract

Cell signaling underlies transcription/epigenetic control of a vast majority of cell-fate decisions. A key goal in cell signaling studies is to identify the set of kinases that underlie key signaling events. In a typical phosphoproteomics study, phosphorylation sites (substrates) of active kinases are quantified proteome-wide. By analyzing the activities of phosphorylation sites over a time-course, the temporal dynamics of signaling cascades can be elucidated. Since many substrates of a given kinase have similar temporal kinetics, clustering phosphorylation sites into distinctive clusters can facilitate identification of their respective kinases. Here we present a knowledge-based CLUster Evaluation (CLUE) approach for identifying the most informative partitioning of a given temporal phosphoproteomics data. Our approach utilizes prior knowledge, annotated kinase-substrate relationships mined from literature and curated databases, to first generate biologically meaningful partitioning of the phosphorylation sites and then determine key kinases associated with each cluster. We demonstrate the utility of the proposed approach on two time-series phosphoproteomics datasets and identify key kinases associated with human embryonic stem cell differentiation and insulin signaling pathway. The proposed approach will be a valuable resource in the identification and characterizing of signaling networks from phosphoproteomics data.Author Summary: A key goal in cell signaling studies is to identify the set of kinases that underlie key signaling events. Mass spectrometry-based technologies have emerged as a powerful tool to profile proteome-wide phosphorylation events in vivo at a single amino acid resolution with high precision. However, development of algorithms to analyze and identify signaling events from high-throughput phosphoproteomics data is still in its infancy. Here we propose a knowledge-based CLUster Evaluation (CLUE) approach for identifying key signaling cascades from time-series phosphoproteomics data. Our approach utilizes known kinase-substrate annotations from curated phosphoproteomics databases to first determine the optimal clustering of the phosphorylation sites and then identify enriched kinase(s). We apply CLUE on time-series phosphoproteomics datasets and identify key kinases associated with human embryonic stem cell differentiation and insulin signaling pathway.

Suggested Citation

  • Pengyi Yang & Xiaofeng Zheng & Vivek Jayaswal & Guang Hu & Jean Yee Hwa Yang & Raja Jothi, 2015. "Knowledge-Based Analysis for Detecting Key Signaling Events from Time-Series Phosphoproteomics Data," PLOS Computational Biology, Public Library of Science, vol. 11(8), pages 1-18, August.
  • Handle: RePEc:plo:pcbi00:1004403
    DOI: 10.1371/journal.pcbi.1004403
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    2. Daisy A. Robinton & George Q. Daley, 2012. "The promise of induced pluripotent stem cells in research and therapy," Nature, Nature, vol. 481(7381), pages 295-305, January.
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