Abstract
The objective of gene set enrichment analysis (GSEA) in modern biological studies is to identify functional profiles in huge sets of biomolecules generated by high-throughput measurements of genes, transcripts, metabolites, and proteins. GSEA is based on a two-stage process using classical statistical analysis to score the input data and subsequent testing for overrepresentation of the enrichment score within a given functional coherent set. However, enrichment scores computed by different methods are merely statistically motivated and often elusive to direct biological interpretation. Here, we propose a novel approach, called Thermodynamically Motivated Enrichment Analysis (TMEA), to account for the energy investment in biological relevant processes. Therefore, TMEA is based on surprisal analysis, which offers a thermodynamic-free energy-based representation of the biological steady state and of the biological change. The contribution of each biomolecule underlying the changes in free energy is used in a Monte Carlo resampling procedure resulting in a functional characterization directly coupled to the thermodynamic characterization of biological responses to system perturbations. To illustrate the utility of our method on real experimental data, we benchmark our approach on plant acclimation to high light and compare the performance of TMEA with the most frequently used method for GSEA.
Highlights
Within the frame of their genetic capacity, organisms are able to acclimate to changes in environmental conditions
We present Thermodynamically Motivated Enrichment Analysis (TMEA), which coupled with surprisal analysis (SA) provides an unbiased functional description for the thermodynamic constraints prevailing on a biological system
We presented a novel approach to gene set enrichment analysis that is based on surprisal analysis (SA) and captures both biological functional knowledge and thermodynamic state description
Summary
Within the frame of their genetic capacity, organisms are able to acclimate to changes in environmental conditions. Acclimation responses thereby represent a complex dynamic adjustment of the entire molecular cellular network. The ability to acclimate ensures the survival of all living organisms and is fundamental for the understanding of biological systems. Due to their mainly sessile lifestyle, plant systems have to face fluctuating environmental conditions, including biotic and abiotic stresses [1,2]. A comprehensive understanding of plant acclimation responses allows the development of strategies to stabilize or enhance yields in increasingly hostile environments. Acclimation dynamics occur on different time scales—from minutes to days—and act on all system levels involving the modification of gene expression, protein activity, and metabolite profiles
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