Cardinality optimization in constraint-based modelling: application to human metabolism
Cardinality optimization in constraint-based modelling: application to human metabolism
Motivation: Several applications in constraint-based modelling can be mathematically formulated as cardinality optimization problems involving the minimization or maximization of the number of nonzeros in a vector. These problems include testing for stoichiometric consistency, testing for flux consistency, testing for thermodynamic flux consistency, computing sparse solutions to flux balance analysis problems and computing the minimum number of constraints to relax to render an infeasible flux balance analysis problem feasible. Such cardinality optimization problems are computationally complex, with no known polynomial time algorithms capable of returning an exact and globally optimal solution. Results: By approximating the zero-norm with nonconvex continuous functions, we reformulate a set of cardinality optimization problems in constraint-based modelling into a difference of convex functions. We implemented and numerically tested novel algorithms that approximately solve the reformulated problems using a sequence of convex programs. We applied these algorithms to various biochemical networks and demonstrate that our algorithms match or outperform existing related approaches. In particular, we illustrate the efficiency and practical utility of our algorithms for cardinality optimization problems that arise when extracting a model ready for thermodynamic flux balance analysis given a human metabolic reconstruction.
Fleming, Ronan M.T.
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Haraldsdottir, Hulda
d4873a2a-0f30-418f-8ac6-6b692c59671d
Hoai Minh, Le
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Vuong, Phan Tu
52577e5d-ebe9-4a43-b5e7-68aa06cfdcaf
Hankemeier, Thomas
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Thiele, Ines
20791c83-a6d9-454f-9e93-e63aeb4e9f8e
11 September 2023
Fleming, Ronan M.T.
8ee22afd-fc39-4e83-9e1b-5078c9569ab8
Haraldsdottir, Hulda
d4873a2a-0f30-418f-8ac6-6b692c59671d
Hoai Minh, Le
3e7b7985-9346-4b87-82ad-358d01656370
Vuong, Phan Tu
52577e5d-ebe9-4a43-b5e7-68aa06cfdcaf
Hankemeier, Thomas
f6c6633a-36b1-4ef6-a549-aca34dd47472
Thiele, Ines
20791c83-a6d9-454f-9e93-e63aeb4e9f8e
Fleming, Ronan M.T., Haraldsdottir, Hulda, Hoai Minh, Le, Vuong, Phan Tu, Hankemeier, Thomas and Thiele, Ines
(2023)
Cardinality optimization in constraint-based modelling: application to human metabolism.
Bioinformatics, 39 (9), [btad450].
(doi:10.1093/bioinformatics/btad450).
Abstract
Motivation: Several applications in constraint-based modelling can be mathematically formulated as cardinality optimization problems involving the minimization or maximization of the number of nonzeros in a vector. These problems include testing for stoichiometric consistency, testing for flux consistency, testing for thermodynamic flux consistency, computing sparse solutions to flux balance analysis problems and computing the minimum number of constraints to relax to render an infeasible flux balance analysis problem feasible. Such cardinality optimization problems are computationally complex, with no known polynomial time algorithms capable of returning an exact and globally optimal solution. Results: By approximating the zero-norm with nonconvex continuous functions, we reformulate a set of cardinality optimization problems in constraint-based modelling into a difference of convex functions. We implemented and numerically tested novel algorithms that approximately solve the reformulated problems using a sequence of convex programs. We applied these algorithms to various biochemical networks and demonstrate that our algorithms match or outperform existing related approaches. In particular, we illustrate the efficiency and practical utility of our algorithms for cardinality optimization problems that arise when extracting a model ready for thermodynamic flux balance analysis given a human metabolic reconstruction.
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e-pub ahead of print date: 11 September 2023
Published date: 11 September 2023
Additional Information:
Funding Information:
R.M.T.F., H.S.H., and P.T.V. received funding from the Inter-agency Modelling and Analysis Group, Multi-scale Modelling Consortium U01 awards from the U.S. Department of Energy, Office of Science, Biological and Environmental Research Program [DE-SC0010429]. H.M.L. received funding from the European Union’s Horizon 2020 research and innovation programme, for the SysMedPD project [668738]. R.M.T.F. and T.H. received funding from Dutch Research Council for the The Netherlands X-Omics Initiative [184.034.019]. I.T. received funding from the European Research Council under the European Unions Horizon 2020 research and innovation programme [757922], and by the National Institute on Ageing grants [1RF1AG058942-01 and 1U19AG063744-01]. R.M.T.F. recieved funding from Horizon Europe for the Recon4IMD project [101080997].
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© 2023 The Author(s).
Identifiers
Local EPrints ID: 482448
URI: http://eprints.soton.ac.uk/id/eprint/482448
ISSN: 1367-4803
PURE UUID: 5f7a675e-1fa0-4328-91c7-e65d40236735
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Date deposited: 05 Oct 2023 16:37
Last modified: 18 Mar 2024 03:54
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Contributors
Author:
Ronan M.T. Fleming
Author:
Hulda Haraldsdottir
Author:
Le Hoai Minh
Author:
Thomas Hankemeier
Author:
Ines Thiele
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