Analysis of human metabolism by reducing the complexity of the genome-scale models using redHUMAN

Masid, María; Ataman, Meriç; Hatzimanikatis, Vassily

doi:10.1038/s41467-020-16549-2

Cited by 26 publications

(35 citation statements)

References 76 publications

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“…Moreover, more abstract models sometimes permit identifying components (species or mechanisms) whose kinetics contribute little to the behavior of a model or that can be lumped with other species to simplify its computational representation (Rao et al, 2014). This can be particularly useful for very large systems with welldefined constraints, such as metabolic network models (Masid et al, 2020). With decreasing complexity of a model, it also becomes easier to perform robust parameter estimations and to determine how well the model is justified based on the available data (Raue et al, 2009).…”

Section: Modeling Approachesmentioning

confidence: 99%

Quantifying the roles of space and stochasticity in computer simulations for cell biology and cellular biochemistry

Johnson

Chen

Faeder

et al. 2021

MBoC

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Most of the fascinating phenomena studied in cell biology emerge from interactions among highly organized multi-molecular structures embedded into complex and frequently dynamic cellular morphologies. For the exploration of such systems, computer simulation has proved to be an invaluable tool, and many researchers in this field have developed sophisticated computational models for application to specific cell biological questions. However, it is often difficult to reconcile conflicting computational results that use different approaches to describe the same phenomenon. To address this issue systematically, we have defined a series of computational test cases ranging from very simple to moderately complex, varying key features of dimensionality, reaction type, reaction speed, crowding, and cell size. We then quantified how explicit spatial and/or stochastic implementations alter outcomes, even when all methods use the same reaction network, rates, and concentrations. For simple cases we generally find minor differences in solutions of the same problem. However, we observe increasing discordance as the effects of localization, dimensionality reduction, and irreversible enzymatic reactions are combined. We discuss the strengths and limitations of commonly used computational approaches for exploring cell biological questions and provide a framework for decision-making by researchers developing new models. As computational power and speed continue to increase at a remarkable rate, the dream of a fully comprehensive computational model of a living cell may be drawing closer to reality, but our analysis demonstrates that it will be crucial to evaluate the accuracy of such models critically and systematically.

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Section: Modeling Approachesmentioning

confidence: 99%

Quantifying the roles of space and stochasticity in computer simulations for cell biology and cellular biochemistry

Johnson

Chen

Faeder

et al. 2021

MBoC

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“…The pyTFA package [46], https://github.com/EPF L-LCSB/pytfa, formulates thermodynamic flux analysis (TFA) of GSMM as a mixed-integer linear programming problem that incorporates metabolite concentrations as thermodynamic constraints into a traditional flux balance analysis (FBA) model. Masid et al [48] have recently constructed an extensive thermodynamic database containing the thermodynamic information for compounds, reactions and compartments in human metabolism; this includes the Gibbs free energy formation of compounds and the associated error estimation, the pH, ionic strength and membrane potentials. Using Biopython (Version 1.78) we annotated the GSMM with SEED identifiers which allowed us to match the information in the GSMM to the thermodynamic database of Masid et al [48].…”

Section: Thermodynamic Metabolic Modelingmentioning

confidence: 99%

“…Thermodynamic flux analysis (TFA) imposes additional constraints on stoichiometric models to ensure thermodynamically valid fluxes and provides a framework for integrating metabolomics data into GSMMs [45,46]; extracellular metabolite data are used to constraint the directionality of exchange reactions of the model and intracellular metabolite data can be used to constraint reactions in the model. Both intra-and extracellular metabolite data have previously been integrated into system-specific metabolic models to draw physiological conclusions about cancerous and healthy cells [47,48,49,50]. In this work, we integrate experimentally determined absolute concentrations of intracellular metabolites and medium-based metabolites and growth rates of the colorectal cancer cell-line HCT116 into a cellline specific, thermodynamic, genome-scale metabolic model (GSMM).…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic genome-scale metabolic modeling of metallodrug resistance in colorectal cancer

Herrmann

Rusz

Baier

et al. 2021

Preprint

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Background: Mass spectrometry-based metabolomics approaches provide an immense opportunity to enhance our understanding of the mechanisms that underpin the cellular reprogramming of cancers. Accurate comparative metabolic profiling of heterogeneous conditions, however, is still a challenge. Methods: Measuring both intracellular and extracellular metabolite concentrations, we constrain four instances of a thermodynamic genome-scale metabolic model of the HCT116 colorectal carcinoma cell line to compare the metabolic flux profiles of cells that are either sensitive or resistant to ruthenium- or platinum-based treatments with BOLD-100/KP1339 and oxaliplatin, respectively. Results: Normalizing according to growth rate and normalizing resistant cells according to their respective sensitive controls, we are able to dissect metabolic responses specific to the drug and to the resistance states. We find the normalization steps to be crucial in the interpretation of the metabolomics data and show that the metabolic reprogramming in resistant cells is limited to a select number of pathways. Conclusions: Here we elucidate the key importance of normalization steps in the interpretation of metabolomics data, allowing us to uncover drug-specific metabolic reprogramming during acquired metal-drug resistance.

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“…This can lead to mass flows that are not thermodynamically possible because they violate the second law of thermodynamics. Such non-physical flows can be detected and eliminated by adding additional thermodynamic constraints, as in thermodynamics-based metabolic flux analysis (TFA) [14,15], energy balance analysis (EBA) and expression, thermodynamics-enabled flux models (ETFL) [16–20] and loopless FBA [21]. Whereas constraint-based models provide metabolic fluxes, they generally do not explicitly account for metabolite concentrations, or how fluxes vary over time, both of which are required for dynamic whole-cell modelling.…”

Section: Introductionmentioning

confidence: 99%

Modular dynamic biomolecular modelling with bond graphs: the unification of stoichiometry, thermodynamics, kinetics and data

Gawthrop

Pan

Crampin

2021

J. R. Soc. Interface.

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Renewed interest in dynamic simulation models of biomolecular systems has arisen from advances in genome-wide measurement and applications of such models in biotechnology and synthetic biology. In particular, genome-scale models of cellular metabolism beyond the steady state are required in order to represent transient and dynamic regulatory properties of the system. Development of such whole-cell models requires new modelling approaches. Here, we propose the energy-based bond graph methodology, which integrates stoichiometric models with thermodynamic principles and kinetic modelling. We demonstrate how the bond graph approach intrinsically enforces thermodynamic constraints, provides a modular approach to modelling, and gives a basis for estimation of model parameters leading to dynamic models of biomolecular systems. The approach is illustrated using a well-established stoichiometric model of Escherichia coli and published experimental data.

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Analysis of human metabolism by reducing the complexity of the genome-scale models using redHUMAN

Cited by 26 publications

References 76 publications

Quantifying the roles of space and stochasticity in computer simulations for cell biology and cellular biochemistry

Quantifying the roles of space and stochasticity in computer simulations for cell biology and cellular biochemistry

Thermodynamic genome-scale metabolic modeling of metallodrug resistance in colorectal cancer

Modular dynamic biomolecular modelling with bond graphs: the unification of stoichiometry, thermodynamics, kinetics and data

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