The Pathway Coexpression Network: Revealing pathway relationships.

Christina S Leslie,Yered Pita-Juárez,Wenbin Wei,Rudolph E Tanzi,Sokratis Kariotis,Katjuša Koler,Gabriel Altschuler,Claire Green,Winston Hide

doi:10.1371/journal.pcbi.1006042

Abstract

A goal of genomics is to understand the relationships between biological processes. Pathways contribute to functional interplay within biological processes through complex but poorly understood interactions. However, limited functional references for global pathway relationships exist. Pathways from databases such as KEGG and Reactome provide discrete annotations of biological processes. Their relationships are currently either inferred from gene set enrichment within specific experiments, or by simple overlap, linking pathway annotations that have genes in common. Here, we provide a unifying interpretation of functional interaction between pathways by systematically quantifying coexpression between 1,330 canonical pathways from the Molecular Signatures Database (MSigDB) to establish the Pathway Coexpression Network (PCxN). We estimated the correlation between canonical pathways valid in a broad context using a curated collection of 3,207 microarrays from 72 normal human tissues. PCxN accounts for shared genes between annotations to estimate significant correlations between pathways with related functions rather than with similar annotations. We demonstrate that PCxN provides novel insight into mechanisms of complex diseases using an Alzheimer’s Disease (AD) case study. PCxN retrieved pathways significantly correlated with an expert curated AD gene list. These pathways have known associations with AD and were significantly enriched for genes independently associated with AD. As a further step, we show how PCxN complements the results of gene set enrichment methods by revealing relationships between enriched pathways, and by identifying additional highly correlated pathways. PCxN revealed that correlated pathways from an AD expression profiling study include functional clusters involved in cell adhesion and oxidative stress. PCxN provides expanded connections to pathways from the extracellular matrix. PCxN provides a powerful new framework for interrogation of global pathway relationships. Comprehensive exploration of PCxN can be performed at http://pcxn.org/.

Highlights

The advancement of high throughput, high dimensional ‘omic’ technology has enabled quantification of a vast array of cellular components
Genes do not function alone, but interact within pathways to carry out specific biological processes
We present a pathway coexpression network (PCxN) that systematically maps and quantifies these high-level interactions and establishes a unifying reference for pathway relationships

Summary

Introduction

The advancement of high throughput, high dimensional ‘omic’ technology has enabled quantification of a vast array of cellular components. We appreciate that cell states are controlled by cascades of interactions coordinated into protein complexes and pathways [4,5,6]. Pathways have become the functional building blocks on which we base interpretation of cell state. Systems approaches to interpret the relationships between omic components have focused upon development of gene based interrogation through gene-gene networks. Pathways drive biological processes through complex and poorly understood interactions, and only limited functional references for global pathway relationships exist. Mapping out pathway relationships is a fundamental challenge as we strive to influence cell development and disease [7, 8]

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