Abstract
Zebrafish is a useful modeling organism for the study of vertebrate development, immune response, and metabolism. Metabolic studies can be aided by mathematical reconstructions of the metabolic network of zebrafish. These list the substrates and products of all biochemical reactions that occur in the zebrafish. Mathematical techniques such as flux-balance analysis then make it possible to predict the possible metabolic flux distributions that optimize, for example, the turnover of food into biomass. The only available genome-scale reconstruction of zebrafish metabolism is ZebraGEM. In this study, we present ZebraGEM 2.0, an updated and validated version of ZebraGEM. ZebraGEM 2.0 is extended with gene-protein-reaction associations (GPRs) that are required to integrate genetic data with the metabolic model. To demonstrate the use of these GPRs, we performed an in silico genetic screening for knockouts of metabolic genes and validated the results against published in vivo genetic knockout and knockdown screenings. Among the single knockout simulations, we identified 74 essential genes, whose knockout stopped growth completely. Among these, 11 genes are known have an abnormal knockout or knockdown phenotype in vivo (partial), and 41 have human homologs associated with metabolic diseases. We also added the oxidative phosphorylation pathway, which was unavailable in the published version of ZebraGEM. The updated model performs better than the original model on a predetermined list of metabolic functions. We also determined a minimal feed composition. The oxidative phosphorylation pathways were validated by comparing with published experiments in which key components of the oxidative phosphorylation pathway were pharmacologically inhibited. To test the utility of ZebraGEM2.0 for obtaining new results, we integrated gene expression data from control and Mycobacterium marinum-infected zebrafish larvae. The resulting model predicts impeded growth and altered histidine metabolism in the infected larvae.
Highlights
The zebrafish (Danio rerio) has become a widely used model organism for the study of vertebrate metabolism.[1,2] Its genome has been sequenced and annotated[3] and the CRIPSR-Cas technique has made it easier than ever to study the role of specific metabolic genes.[4]
We extended the model by putting these gene products into a gene-protein-reaction associations (GPRs), and added this to the model according to the Systems Biology Markup Language (SBML) guidelines
To check whether the changes in the model network improved the performance of the model, we tested the model predictions as follows: (1) we checked whether the model performed the metabolic functions reported in Bekaert 22; (2) we checked for biological validity of the minimal set of metabolites required for model growth; (3) we checked whether the model could reproduce pharmacological interference with respiration
Summary
The zebrafish (Danio rerio) has become a widely used model organism for the study of vertebrate metabolism.[1,2] Its genome has been sequenced and annotated[3] and the CRIPSR-Cas technique has made it easier than ever to study the role of specific metabolic genes.[4] For example, zebrafish have been used to test the toxicity of drugs on liver metabolism and the effect of liver metabolism on internal drug concentration.[5] Zebrafish have been used in studies of metabolic diseases such as diabetes, obesity, and fatty liver disease, often combining sequencing with visualization of gene expression.[1]. Mathematical and computational techniques make it possible to use such metabolic gene expression data to predict the flux of metabolites through single cells or even whole organisms. Genome-scale metabolic reconstructions, or metabolic maps for short, are models that consist of two parts:
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