• DocumentCode
    1640435
  • Title

    Modeling gene regulation and spatial organization of sequence based motifs

  • Author

    Supper, Jochen ; Kampe, Claasaufm ; Wanke, Dierk ; Berendzen, Kenneth W. ; Harter, Klaus ; Bonneau, Richard ; Zell, Andreas

  • Author_Institution
    Center for Bioinf. Tubingen (ZBIT), Univ. of Tubingen, Tubingen
  • fYear
    2008
  • Firstpage
    1
  • Lastpage
    7
  • Abstract
    Reconstructing and modeling regulatory networks is an active area of research in bioinformatics and systems biology. Hence, various computational methods have been published, often successfully modeling one aspect of regulatory control. Gene regulation, however, is a process that depends on many different components such as transcription factors (TFs), cis-regulatory motifs and their temporal and spatial coordination. Accordingly, a promising new direction for computational analysis is the incorporation of multiple data types to discover, for instance, cluster membership, the spatial organization of cis-regulatory motifs and TFs that bind to these motifs. Here, we present such a data-driven framework, comprising four stages, to infer gene regulatory networks (GRNs) by modeling: 1. Motif presence in the promoter; 2. Spatial motif arrangement in co-regulated genes; 3. TFs that bind the respective motifs, and: 4. Dynamic properties of the GRN. A novel method is presented in stage 2, where we optimize for the spatial motif properties: orientation, occurrence of multiple motifs, relative distance between two motifs and distance to the transcription start site (TSS). To find optimal distance based properties in efficient time we describe a dynamic programming approach. To combine multiple motif properties that are shared by genes with similar expression profiles a Hill-climber is employed. Subsequently, in stage 3 and 4, we infer GRNs by assigning TFs to the derived motifs and model time-dependent regulatory relationships between them with the inferelator approach. None of the stages require the user to manually adjust any parameter, and thus derived properties can be analyzed without the bias introduced by parametrization. We applied this approach to S. cerevisiae data and obtained insight into individual and general properties of the spatial assembly of regulatory elements and inferred the corresponding GRN.
  • Keywords
    bioinformatics; genetics; microorganisms; molecular biophysics; Hill climber; S. cerevisiae; bioinformatics; cis-regulatory motifs; cluster membership; gene regulation; gene regulatory networks; inferelator approach; motif presence; sequence based motifs; spatial motif arrangement; spatial organization; systems biology; transcription factors; transcription start site; Bioinformatics; Biological system modeling; Biology computing; DNA; Data analysis; Genomics; Proteins; RNA; Sequences; Systems biology;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    BioInformatics and BioEngineering, 2008. BIBE 2008. 8th IEEE International Conference on
  • Conference_Location
    Athens
  • Print_ISBN
    978-1-4244-2844-1
  • Electronic_ISBN
    978-1-4244-2845-8
  • Type

    conf

  • DOI
    10.1109/BIBE.2008.4696696
  • Filename
    4696696