Identification of differential gene pathways with principal component analysis

doi:10.1093/bioinformatics/btp085

Bioinformatics Advance Access originally published online on February 17, 2009
Bioinformatics 2009 25(7):882-889; doi:10.1093/bioinformatics/btp085

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Identification of differential gene pathways with principal component analysis

Shuangge Ma ¹^,* and Michael R. Kosorok ²

¹Department of Epidemiology and Public Health, Yale University, New Haven, CT 06510 and ²Department of Biostatistics, University of North Carolina, Chapel Hill, NC 27599, USA

*To whom correspondence should be addressed.

Abstract

Motivation: Development of high-throughput technology makesit possible to measure expressions of thousands of genes simultaneously.Genes have the inherent pathway structure, where pathways arecomposed of multiple genes with coordinated biological functions.It is of great interest to identify differential gene pathwaysthat are associated with the variations of phenotypes.

Results: We propose the following approach for detecting differentialgene pathways. First, we construct gene pathways using databasessuch as KEGG or GO. Second, for each pathway, we extract a smallnumber of representative features, which are linear combinationsof gene expressions and/or their transformations. Specifically,we propose using (i) principal components (PCs) of gene expressionsets, (ii) PCs of expanded gene expression sets and (iii) expandedsets of PCs of gene expressions, as the representative features.Third, we identify differential gene pathways as those withrepresentative features significantly associated with the variationsof phenotypes, particularly disease clinical outcomes, in regressionmodels. The false discovery rate approach is used to adjustfor multiple comparisons. Analysis of three gene expressiondatasets suggests that (i) the proposed approach can effectivelyidentify differential gene pathways; (ii) PCs that explain onlya small amount of variations of gene expressions may bear significantassociations between gene pathways and phenotypes; (iii) includingsecond-order terms of gene expressions may lead to identificationof new differential gene pathways; (iv) the proposed approachis relatively insensitive to additional noises; and (v) theproposed approach can identify gene pathways missed by alternativeapproaches.

Contact: shuangge.ma{at}yale.edu

Supplementary information:Supplementary data are available atBioinformatics online.

Associate Editor: David Rocke

Received on July 22, 2008; revised on February 2, 2009; accepted on February 10, 2009

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