A Systematic Elementary Flux Mode Selection Procedure for Deriving Macroscopic Bioreaction Models From Metabolic Networks

Maton, Maxime; Bogaerts, Philippe; Vande Wouwer, Alain

doi:10.1016/j.jprocont.2022.09.002

Article (Scientific journals)

A Systematic Elementary Flux Mode Selection Procedure for Deriving Macroscopic Bioreaction Models From Metabolic Networks

Maton, Maxime; Bogaerts, Philippe; Vande Wouwer, Alain

2022 • In Journal of Process Control, 118, p. 170 - 184

Peer Reviewed verified by ORBi

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https://hdl.handle.net/20.500.12907/43669

DOI
10.1016/j.jprocont.2022.09.002

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Precision for document type :

Review article

Disciplines :

Biotechnology

Author, co-author :

Maton, Maxime ; Université de Mons - UMONS

Bogaerts, Philippe; ULB - Université Libre de Bruxelles [BE] > 3-BIO-BioControl

Vande Wouwer, Alain ; Université de Mons - UMONS > Faculté Polytechnique > Service Systèmes, Estimation, Commande et Optimisation

Language :

English

Title :

A Systematic Elementary Flux Mode Selection Procedure for Deriving Macroscopic Bioreaction Models From Metabolic Networks

Publication date :

September 2022

Journal title :

Journal of Process Control

ISSN :

0959-1524

Publisher :

Butterworth Scientific, United Kingdom

Special issue title :

ADCHEM21

Volume :

118

Pages :

170 - 184

Peer reviewed :

Peer Reviewed verified by ORBi

Research institute :

Biosciences

Available on ORBi UMONS :

since 21 October 2022

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Bibliography

Sidoli, F., Mantalaris, A., Asprey, S., Modelling of mammalian cells and cell culture processes. Cytotechnology 44:1-2 (2004), 27–46.
Vester, D., Rapp, E., Kluge, S., Genzel, Y., Reichl, U., Virus-host cell interactions in vaccine production cell lines infected with different human influenza a virus variants : A proteomic approach. J. Proteomics 73:9 (2010), 1656–1669.
Niklas, J., Heinzle, E., Metabolic flux analysis in systems biology of mammalian cells. Genom. Syst. Biol. Mammalian Cell Culture, Springer, 2012, 109–132.
Niu, H., Amribt, Z., Fickers, P., Tan, W., Bogaerts, P., Metabolic pathway analysis and reduction for mammalian cell cultures - towards macroscopic modeling. Chem. Eng. Sci. 102 (2013), 461–473.
Hodgson, B., Taylor, C., Ushio, J., Leigh, J., Intelligent modelling of bioprocesses : A comparison of structured and unstructured approaches. Bioprocess Biosyst. Eng. 26:6 (2005), 353–359.
Haag, J., Vande Wouwer, A., Bogaerts, P., Systematic procedure for the reduction of complex biological reaction pathways and the generation of macroscopic equivalents. Chem. Eng. Sci. 60:2 (2005), 459–465.
Haag, J., Vande Wouwer, A., Bogaerts, P., Dynamic modeling of complex biological systems : a link between metabolic and macroscopic description. Math. Biosci. 193:1 (2005), 25–49.
Baroukh, C., Bernard, O., Metabolic modeling of c. sorokiniana diauxic heterotrophic growth. IFAC-PapersOnLine 49:26 (2016), 330–335.
Schuster, S., Hilgetag, C., On elementary flux modes in biochemical reaction systems at steady state. J. Biol. Systems 2:2 (1994), 165–182.
Stelling, J., Klamt, S., Bettenbrock, K., Schuster, S., Gilles, E.D., Metabolic network structure determines key aspects of functionality and regulation. Nature 420:6912 (2002), 190–193.
Gao, J., Gorenflo, V., Scharer, J., Budman, H., Dynamic metabolic modeling for a mab bioprocess. Biotechnol. Prog. 23:1 (2007), 168–181.
von Kamp, A., Schuster, S., Metatool 5.0 : fast and flexible elementary modes analysis. Bioinformatics 22 (2006), 1930–1931.
Terzer, M., Stelling, J., Large-scale computation of elementary flux modes with bit pattern trees. Bioinformatics 24:19 (2008), 2229–2235.
Naderi, S., Meshram, M., Wei, C., McConkey, B., Ingalls, B., Budman, H., Scharer, J., Metabolic flux and nutrient uptake modeling of normal and apoptotic CHO cells. IFAC Proc. Vol. 43:6 (2010), 395–400.
Klamt, S., Stelling, J., Combinatorial complexity of pathway analysis in metabolic networks. Mol. Biol. Rep. 29 (2002), 233–236.
Figueiredo, L., Podhorski, A., Rubio, A., Kaleta, C., Beasley, J., Schuster, S., Planes, F., Computing the shortest elementary flux modes in genome-scale metabolic networks. Bioinformatics 25 (2009), 3158–3165.
Kaleta, C., de Figueiredo, L., Schuster, S., Can the whole be less than the sum of its parts ? Pathway analysis in genome-scale metabolic networks using elementary flux patterns. Genome Res., 2009, 1872–1883.
Jungers, R., Zamorano, F., Blondel, V., Vande Wouwer, A., Bastin, G., Fast computation of minimal elementary decompositions of metabolic vectors. Automatica 47:6 (2011), 1255–1259.
Machado, D., Soons, Z., Patil, K.R., Ferreira, E.C., Rocha, I., Random sampling of elementary flux modes in large-scale metabolic networks. Bioinformatics 28:18 (2012), i515–i521.
Tabe-Bordbar, S., Marashi, S., Finding elementary flux modes in metabolic networks based on flux balance analysis and flux coupling analysis : application to the analysis of escherichia coli metabolism. Biotechnology Letters 35 (2013), 2039–2044.
Oddsdottir, H., Hagrot, E., Chotteau, V., Forsgren, A., On dynamically generating relevant elementary flux modes in a metabolic network using optimization. J. Math. Biol. 71:4 (2015), 903–920.
Provost, A., Bastin, G., Dynamic metabolic modelling under the balanced growth condition. J. Process Control 14:7 (2004), 717–728.
Zamorano, F., Vande Wouwer, A.V., Jungers, R.M., Bastin, G., Dynamic metabolic models of CHO cell cultures through minimal sets of elementary flux modes. J. Biotechnol. 164:3 (2013), 409–422.
Soons, Z., Rocha, E., Ferreira, I., Selection of elementary modes for bioprocess control. Comput. Appl. Biotechnol. 11 (2010), 156–161.
Soons, Z., Ferreira, I., Rocha, E., Identification of minimal metabolic pathway models consistent with phenotypic data. J. Process Control 21 (2011), 1483–1492.
Hebing, L., Neymann, T., Thüte, T., Jockwer, A., Engell, S., Efficient generation of models of fed-batch fermentations for process design and control. IFAC-PapersOnLine 49:7 (2016), 621–626.
Oddsdottir, H., Hagrot, E., Chotteau, V., Forsgren, A., Robustness analysis of elementary flux modes generated by column generation. Math. Biosci. 273 (2016), 45–56.
Hagrot, E., Oddsdottir, H., Hosta, J., Jacobsen, E., Chotteau, V., Poly-pathway model, a novel approach to simulate multiple metabolic states by reaction network-based model - application to amino acid depletion in CHO cell culture. J. Biotechnol. 259 (2017), 235–247.
Abbate, T., Fernandes de Sousa, S., Dewasme, L., Bastin, G., Vande Wouwer, A., Inference of dynamical macroscopic models of cell metabolism based on elementary flux modes analysis. Biochem. Eng. J. 151 (2019), 1–11.
Maton, M., Vande Wouwer, A., Bogaerts, P., Selection of a minimal suboptimal set of EFMs for dynamic metabolic modelling. IFAC-PapersOnLine 54–3 (2021), 667–672.
Hagrot, E., Oddsdottir, H., Makinen, M., Forsgren, A., Chotteau, V., Novel column generation-based optimization approach for poly-pathway kinetic model applied to CHO cell culture. Metab. Eng. Commun., 8, 2019, e00083.
Bastin, G., Metabolic flux analysis and metabolic design of bioreaction systems. Tutorial, 2019.
Richelle, A., Bogaerts, P., Systematic methodology for bioprocess model identification based on generalized kinetic functions. Biochem. Eng. J. 100 (2015), 41–49.