Whole-cell Energy Modeling Reveals Quantitative Changes of Predicted Energy Flows in RAS Mutant Cancer Cell Lines

Overview

Journal iScience

Publisher Cell Press

Date 2023 Jan 30

PMID 36711246

Authors

Thomas Sevrin

Lisa Strasser

Camille Ternet

Philipp Junk

Miriam Caffarini

Stella Prins

Cian DArcy

Simona Catozzi

Giorgio Oliviero

Kieran Wynne

Christina Kiel

Philip J Luthert

Affiliations

Soon will be listed here.

Abstract

Cellular utilization of available energy flows to drive a multitude of forms of cellular "work" is a major biological constraint. Cells steer metabolism to address changing phenotypic states but little is known as to how bioenergetics couples to the richness of processes in a cell as a whole. Here, we outline a whole-cell energy framework that is informed by proteomic analysis and an energetics-based gene ontology. We separate analysis of metabolic supply and the capacity to generate high-energy phosphates from a representation of demand that is built on the relative abundance of ATPases and GTPases that deliver cellular work. We employed mouse embryonic fibroblast cell lines that express wild-type KRAS or oncogenic mutations and with distinct phenotypes. We observe shifts between energy-requiring processes. Calibrating against Seahorse analysis, we have created a whole-cell energy budget with apparent predictive power, for instance in relation to protein synthesis.

Citing Articles

"Energetics of the outer retina II: Calculation of a spatio-temporal energy budget in retinal pigment epithelium and photoreceptor cells based on quantification of cellular processes".

Kiel C, Prins S, Foss A, Luthert P PLoS One. 2025; 20(1):e0311169.

PMID: 39869549 PMC: 11771881. DOI: 10.1371/journal.pone.0311169.

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