Optimisation of multi-omic genome-scale models: methodologies, hands-on tutorial and perspectives

Supreeta Vijayakumar, Max Conway, Pietro Lió, Claudio Angione

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Abstract

Genome-scale metabolic models are valuable tools for assessing the metabolic potential of living organisms. Being downstream of gene expression, metabolism is increasingly being used as an indicator of the phenotypic outcome for drugs and therapies. We here present a review of the principal methods used for constraint-based modelling in systems biology, and explore how the integration of multi-omic data can be used to improve phenotypic predictions of genome-scale metabolic models. We believe that the large-scale comparison of the metabolic response of an organism to different environmental conditions will be an important challenge for genome-scale models. Therefore, within the context of multi-omic methods, we describe a tutorial for multi-objective optimization using the metabolic and transcriptomics adaptation estimator (METRADE), implemented in MATLAB. METRADE uses microarray and codon usage data to model bacterial metabolic response to environmental conditions (e.g., antibiotics, temperatures, heat shock). Finally, we discuss key considerations for the integration of multi-omic networks into metabolic models, towards automatically extracting knowledge from such models.
Original languageEnglish
Title of host publicationMetabolic Network Reconstruction and Modeling
PublisherSpringer
Pages389-408
Number of pages0
ISBN (Print)978-1-4939-7527-3
Publication statusPublished - 1 Jan 2018

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    Vijayakumar, S., Conway, M., Lió, P., & Angione, C. (2018). Optimisation of multi-omic genome-scale models: methodologies, hands-on tutorial and perspectives. In Metabolic Network Reconstruction and Modeling (pp. 389-408). Springer.