Abstract
BackgroundGenome-wide reconstructions of metabolism opened the way to thorough investigations of cell metabolism for health care and industrial purposes. However, the predictions offered by Flux Balance Analysis (FBA) can be strongly affected by the choice of flux boundaries, with particular regard to the flux of reactions that sink nutrients into the system. To mitigate possible errors introduced by a poor selection of such boundaries, a rational approach suggests to focus the modeling efforts on the pivotal ones.MethodsIn this work, we present a methodology for the automatic identification of the key fluxes in genome-wide constraint-based models, by means of variance-based sensitivity analysis. The goal is to identify the parameters for which a small perturbation entails a large variation of the model outcomes, also referred to as sensitive parameters. Due to the high number of FBA simulations that are necessary to assess sensitivity coefficients on genome-wide models, our method exploits a master-slave methodology that distributes the computation on massively multi-core architectures. We performed the following steps: (1) we determined the putative parameterizations of the genome-wide metabolic constraint-based model, using Saltelli’s method; (2) we applied FBA to each parameterized model, distributing the massive amount of calculations over multiple nodes by means of MPI; (3) we then recollected and exploited the results of all FBA runs to assess a global sensitivity analysis.ResultsWe show a proof-of-concept of our approach on latest genome-wide reconstructions of human metabolism Recon2.2 and Recon3D. We report that most sensitive parameters are mainly associated with the intake of essential amino acids in Recon2.2, whereas in Recon 3D they are associated largely with phospholipids. We also illustrate that in most cases there is a significant contribution of higher order effects.ConclusionOur results indicate that interaction effects between different model parameters exist, which should be taken into account especially at the stage of calibration of genome-wide models, supporting the importance of a global strategy of sensitivity analysis.
Highlights
Genome-wide reconstructions of metabolism opened the way to thorough investigations of cell metabolism for health care and industrial purposes
We systematically and simultaneously perturbed the input variables represented by the boundaries of the exchange fluxes, which are known to greatly influence Flux Balance Analysis (FBA) outcomes [33]
Such parametrizations were distributed to independent FBA optimizations, performed on several processing units according to Message Passing Interface (MPI) standard
Summary
Genome-wide reconstructions of metabolism opened the way to thorough investigations of cell metabolism for health care and industrial purposes. Detailed computational models of metabolism are increasingly being reconstructed and simulated for many organisms, ranging from prokaryotes to Homo sapiens, with the aim of connecting genotype with metabolic phenotype [1] They have extensively being applied within metabolic engineering, for instance to optimize the cells’ production of a certain substance, and hold great potential in unraveling the fragility points of complex pathological diseases in which a rearrangement of metabolism plays an essential role [2] (e.g., cancer, diabetes, or neurodegenerative disorders). Notwithstanding the advancements in dynamic simulation [4, 5], using reaction-based or hybrid approaches [6], the analysis of large-scale biochemical models can still be challenging because some mandatory information (e.g., kinetic parameters of rate laws, the amounts of chemical species) is still largely undetermined [7] For this reason, these networks are typically investigated by means of constraint-based models (CBMs) [8], and in particular of Flux Balance Analysis [1] (FBA)
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