Irene M Ong1, Jeremy D Glasner, David Page. 1. Department of Computer Sciences, Department of Biostatistics & Medical Informatics Department of Genetics, University of Wisconsin, Madison 53706, USA. ong@cs.wisc.edu
Abstract
MOTIVATION: Cells continuously reprogram their gene expression network as they move through the cell cycle or sense changes in their environment. In order to understand the regulation of cells, time series expression profiles provide a more complete picture than single time point expression profiles. Few analysis techniques, however, are well suited to modelling such time series data. RESULTS: We describe an approach that naturally handles time series data with the capabilities of modelling causality, feedback loops, and environmental or hidden variables using a Dynamic Bayesian network. We also present a novel way of combining prior biological knowledge and current observations to improve the quality of analysis and to model interactions between sets of genes rather than individual genes. Our approach is evaluated on time series expression data measured in response to physiological changes that affect tryptophan metabolism in E. coli. Results indicate that this approach is capable of finding correlations between sets of related genes.
MOTIVATION: Cells continuously reprogram their gene expression network as they move through the cell cycle or sense changes in their environment. In order to understand the regulation of cells, time series expression profiles provide a more complete picture than single time point expression profiles. Few analysis techniques, however, are well suited to modelling such time series data. RESULTS: We describe an approach that naturally handles time series data with the capabilities of modelling causality, feedback loops, and environmental or hidden variables using a Dynamic Bayesian network. We also present a novel way of combining prior biological knowledge and current observations to improve the quality of analysis and to model interactions between sets of genes rather than individual genes. Our approach is evaluated on time series expression data measured in response to physiological changes that affect tryptophan metabolism in E. coli. Results indicate that this approach is capable of finding correlations between sets of related genes.
Authors: Jun Zhu; Bin Zhang; Erin N Smith; Becky Drees; Rachel B Brem; Leonid Kruglyak; Roger E Bumgarner; Eric E Schadt Journal: Nat Genet Date: 2008-06-15 Impact factor: 38.330
Authors: Fulvia Ferrazzi; Felix B Engel; Erxi Wu; Annie P Moseman; Isaac S Kohane; Riccardo Bellazzi; Marco F Ramoni Journal: J Biomed Inform Date: 2011-02-16 Impact factor: 6.317