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Hypergraph geometry reflects higher-order dynamics in protein interaction networks

Kevin A. Murgas, Emil Saucan, Romeil Sandhu

2022Scientific Reports59 citationsDOIOpen Access PDF

Abstract

Protein interactions form a complex dynamic molecular system that shapes cell phenotype and function; in this regard, network analysis is a powerful tool for studying the dynamics of cellular processes. Current models of protein interaction networks are limited in that the standard graph model can only represent pairwise relationships. Higher-order interactions are well-characterized in biology, including protein complex formation and feedback or feedforward loops. These higher-order relationships are better represented by a hypergraph as a generalized network model. Here, we present an approach to analyzing dynamic gene expression data using a hypergraph model and quantify network heterogeneity via Forman-Ricci curvature. We observe, on a global level, increased network curvature in pluripotent stem cells and cancer cells. Further, we use local curvature to conduct pathway analysis in a melanoma dataset, finding increased curvature in several oncogenic pathways and decreased curvature in tumor suppressor pathways. We compare this approach to a graph-based model and a differential gene expression approach.

Topics & Concepts

HypergraphCurvaturePairwise comparisonGene regulatory networkInteraction networkGraphComputer scienceSystems biologyTopology (electrical circuits)Theoretical computer scienceComputational biologyBiologyGeneMathematicsGene expressionGeneticsArtificial intelligenceCombinatoricsGeometryBioinformatics and Genomic NetworksCell Image Analysis TechniquesGene Regulatory Network Analysis