TY - GEN
T1 - Computational strategy for discovering druggable gene networks from genome-wide RNA expression profiles
AU - Imoto, Seiya
AU - Tamada, Yoshinor
AU - Araki, Hiromitsu
AU - Yasuda, Kaori
AU - Print, Cristin G.
AU - Charnock-Jones, Stephen D.
AU - Sanders, Deborah
AU - Savoie, Christopher J.
AU - Tashiro, Kousuke
AU - Kuhara, Satoru
AU - Miyano, Satoru
PY - 2006
Y1 - 2006
N2 - We propose a computational strategy for discovering gene networks affected by a chemical compound. Two kinds of DNA microarray data are assumed to be used: One dataset is short time-course data that measure responses of genes following an experimental treatment. The other dataset is obtained by several hundred single gene knock-downs. These two datasets provide three kinds of information; (i) A gene network is estimated from time-course data by the dynamic Bayesian network model, (ii) Relationships between the knocked-down genes and their regulatees are estimated directly from knock-down microarrays and (iii) A gene network can be estimated by gene knock-down data alone using the Bayesian network model. We propose a method that combines these three kinds of information to provide an accurate gene network that most strongly relates to the mode-of-action of the chemical compound in cells. This information plays an essential role in pharmacogenomics. We illustrate this method with an actual example where human endothelial cell gene networks were generated from a novel time course of gene expression following treatment with the drug fenofibrate, and from 270 novel gene knock-downs. Finally, we succeeded in inferring the gene network related to PPAR-a, which is a known target of fenofibrate.
AB - We propose a computational strategy for discovering gene networks affected by a chemical compound. Two kinds of DNA microarray data are assumed to be used: One dataset is short time-course data that measure responses of genes following an experimental treatment. The other dataset is obtained by several hundred single gene knock-downs. These two datasets provide three kinds of information; (i) A gene network is estimated from time-course data by the dynamic Bayesian network model, (ii) Relationships between the knocked-down genes and their regulatees are estimated directly from knock-down microarrays and (iii) A gene network can be estimated by gene knock-down data alone using the Bayesian network model. We propose a method that combines these three kinds of information to provide an accurate gene network that most strongly relates to the mode-of-action of the chemical compound in cells. This information plays an essential role in pharmacogenomics. We illustrate this method with an actual example where human endothelial cell gene networks were generated from a novel time course of gene expression following treatment with the drug fenofibrate, and from 270 novel gene knock-downs. Finally, we succeeded in inferring the gene network related to PPAR-a, which is a known target of fenofibrate.
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M3 - Conference contribution
C2 - 17094269
AN - SCOPUS:33746616957
SN - 9812564632
SN - 9789812564634
T3 - Proceedings of the Pacific Symposium on Biocomputing 2006, PSB 2006
SP - 559
EP - 571
BT - Proceedings of the Pacific Symposium on Biocomputing 2006, PSB 2006
T2 - 11th Pacific Symposium on Biocomputing 2006, PSB 2006
Y2 - 3 January 2006 through 7 January 2006
ER -