Simultaneous Integration of Gene Expression and Nutrient Availability for Studying the Metabolism of Hepatocellular Carcinoma Cell Lines.

Ewelina Weglarz-Tomczak,Thierry D G A Mondeel,Hans V Westerhoff,Diewertje G E Piebes

doi:10.3390/biom11040490

Ewelina Weglarz-Tomczak, Thierry D G A Mondeel + Show 2 more

Open Access

https://doi.org/10.3390/biom11040490

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Abstract

How cancer cells utilize nutrients to support their growth and proliferation in complex nutritional systems is still an open question. However, it is certainly determined by both genetics and an environmental-specific context. The interactions between them lead to profound metabolic specialization, such as consuming glucose and glutamine and producing lactate at prodigious rates. To investigate whether and how glucose and glutamine availability impact metabolic specialization, we integrated computational modeling on the genome-scale metabolic reconstruction with an experimental study on cell lines. We used the most comprehensive human metabolic network model to date, Recon3D, to build cell line-specific models. RNA-Seq data was used to specify the activity of genes in each cell line and the uptake rates were quantitatively constrained according to nutrient availability. To integrated both constraints we applied a novel method, named Gene Expression and Nutrients Simultaneous Integration (GENSI), that translates the relative importance of gene expression and nutrient availability data into the metabolic fluxes based on an observed experimental feature(s). We applied GENSI to study hepatocellular carcinoma addiction to glucose/glutamine. We were able to identify that proliferation, and lactate production is associated with the presence of glucose but does not necessarily increase with its concentration when the latter exceeds the physiological concentration. There was no such association with glutamine. We show that the integration of gene expression and nutrient availability data into genome-wide models improves the prediction of metabolic phenotypes.

Highlights

Cancer cells adapt their metabolism to promote fast cellular proliferation and longterm maintenance [1,2,3,4], facilitating the uptake and conversion of nutrients into biomass
Most metabolic signatures are shared across different kinds of cancer cells, including one of the best recognizable, namely changes in glucose metabolism that give rise to the Warburg effect [1,2,3,4,5,6,7], and an increase in biosynthetic activities
Environmental nutrient availability (NA) is an important regulator of cancer cell metabolism, and an important environmental determinant of cancer cell metabolism is diet, which can affect the availability of nutrients within tumours [37,38,46,50]

Summary

Introduction

Cancer cells adapt their metabolism to promote fast cellular proliferation and longterm maintenance [1,2,3,4], facilitating the uptake and conversion of nutrients into biomass. The Warburg effect is characterized by an increased rate of glucose uptake and part of glycolysis-derived pyruvate is diverted to lactate [1,2,3,4,5,6,7,8,9], which produces much less ATP per glucose than its oxidation to carbon dioxide would. This metabolic signature enables fast-dividing cells to satisfy anabolic needs for biomass. Some rapidly proliferating cells are dependent on glutamine, and undergo necrosis upon glutamine depletion [19]

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