Pathway analysis of coronary atherosclerosis

doi:10.1152/physiolgenomics.00101.2005

Pathway analysis of coronary atherosclerosis

Jennifer Y. King ¹^,*, Rossella Ferrara ¹^,*, Raymond Tabibiazar ¹, Joshua M. Spin ¹, Mary M. Chen ¹, Allan Kuchinsky ², Aditya Vailaya ², Robert Kincaid ², Anya Tsalenko ², David Xing-Fei Deng ², Andrew Connolly ¹, Peng Zhang ¹, Eugene Yang ¹, Clifton Watt ¹, Zohar Yakhini ², Amir Ben-Dor ², Annette Adler ², Laurakay Bruhn ², Philip Tsao ¹, Thomas Quertermous ¹^,* and Euan A. Ashley ¹^,*

¹ Donald W. Reynolds Cardiovascular Research Center, Division of Cardiovascular Medicine, Falk Cardiovascular Research Center, Stanford University, Stanford; and ² Agilent Laboratories, Palo Alto, California

Large-scale gene expression studies provide significant insightinto genes differentially regulated in disease processes suchas cancer. However, these investigations offer limited understandingof multisystem, multicellular diseases such as atherosclerosis.A systems biology approach that accounts for gene interactions,incorporates nontranscriptionally regulated genes, and integratesprior knowledge offers many advantages. We performed a comprehensivegene level assessment of coronary atherosclerosis using 51 coronaryartery segments isolated from the explanted hearts of 22 cardiactransplant patients. After histological grading of vascularsegments according to American Heart Association guidelines,isolated RNA was hybridized onto a customized 22-K oligonucleotidemicroarray, and significance analysis of microarrays and geneontology analyses were performed to identify significant geneexpression profiles. Our studies revealed that loss of differentiatedsmooth muscle cell gene expression is the primary expressionsignature of disease progression in atherosclerosis. Furthermore,we provide insight into the severe form of coronary artery diseaseassociated with diabetes, reporting an overabundance of immuneand inflammatory signals in diabetics. We present a novel approachto pathway development based on connectivity, determined bylanguage parsing of the published literature, and ranking, determinedby the significance of differentially regulated genes in thenetwork. In doing this, we identify highly connected "nexus"genes that are attractive candidates for therapeutic targetingand followup studies. Our use of pathway techniques to studyatherosclerosis as an integrated network of gene interactionsexpands on traditional microarray analysis methods and emphasizesthe significant advantages of a systems-based approach to analyzingcomplex disease.

pathways; networks; systems biology; gene expression profiling; microarray; cardiovascular disease; coronary arterial disease

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				A. Ng, B. Bursteinas, Q. Gao, E. Mollison, and M. Zvelebil pSTIING: a 'systems' approach towards integrating signalling pathways, interaction and transcriptional regulatory networks in inflammation and cancer Nucleic Acids Res., January 1, 2006; 34(suppl_1): D527 - D534. [Abstract] [Full Text] [PDF]

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				M. Liang and B. Ventura Physiological genomics in PG and beyond: July to September 2005 Physiol Genomics, October 17, 2005; 23(2): 119 - 124. [Full Text] [PDF]