Design of oscillatory dynamics in numerical simulations of compartment-based enzyme systems
Design of oscillatory dynamics in numerical simulations of compartment-based enzyme systems
Enzymatic reactions that yield non-neutral products are known to involve feedback due to the bell-shaped pH-rate curve of the enzyme. Compartmentalizing the reaction has been shown to lead to transport-driven oscillations in theory; however, there have been few reproducible experimental examples. Our objective was to determine how the conditions could be optimized to achieve pH oscillations. We employed numerical simulations to investigate the hydrolysis of ethyl acetate in a confined esterase enzyme system, examining the influence of key factors on its behavior. Specific parameter ranges that lead to bistability and self-sustained pH oscillations and the importance of fast base transport for oscillations in this acid-producing system are highlighted. Suggestions are made to expand the parameter space for the occurrence of oscillations, including modifying the maximum of the enzyme pH-rate curve and increasing the negative feedback rate. This research not only sheds light on the programmable nature of enzyme-driven pH regulation but also furthers knowledge on the optimal design of such feedback systems for experimentalists.
Leathard, Anna S.
82fc63a9-7d0c-483b-9770-da084719e40d
Beales, Paul A.
920bef12-e354-4ff6-a528-9cab2227f32e
Taylor, Annette F.
08028a29-428d-4732-b6b1-f7a93389b386
27 December 2023
Leathard, Anna S.
82fc63a9-7d0c-483b-9770-da084719e40d
Beales, Paul A.
920bef12-e354-4ff6-a528-9cab2227f32e
Taylor, Annette F.
08028a29-428d-4732-b6b1-f7a93389b386
Leathard, Anna S., Beales, Paul A. and Taylor, Annette F.
(2023)
Design of oscillatory dynamics in numerical simulations of compartment-based enzyme systems.
Chaos: An Interdisciplinary Journal of Nonlinear Science, 33 (12), [123128].
(doi:10.1063/5.0180256).
Abstract
Enzymatic reactions that yield non-neutral products are known to involve feedback due to the bell-shaped pH-rate curve of the enzyme. Compartmentalizing the reaction has been shown to lead to transport-driven oscillations in theory; however, there have been few reproducible experimental examples. Our objective was to determine how the conditions could be optimized to achieve pH oscillations. We employed numerical simulations to investigate the hydrolysis of ethyl acetate in a confined esterase enzyme system, examining the influence of key factors on its behavior. Specific parameter ranges that lead to bistability and self-sustained pH oscillations and the importance of fast base transport for oscillations in this acid-producing system are highlighted. Suggestions are made to expand the parameter space for the occurrence of oscillations, including modifying the maximum of the enzyme pH-rate curve and increasing the negative feedback rate. This research not only sheds light on the programmable nature of enzyme-driven pH regulation but also furthers knowledge on the optimal design of such feedback systems for experimentalists.
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123128_1_5.0180256
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Accepted/In Press date: 20 November 2023
Published date: 27 December 2023
Identifiers
Local EPrints ID: 499883
URI: http://eprints.soton.ac.uk/id/eprint/499883
ISSN: 1054-1500
PURE UUID: c706a864-a88a-4747-8e7b-5fd56e334e62
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Date deposited: 08 Apr 2025 16:33
Last modified: 22 Aug 2025 02:44
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Author:
Anna S. Leathard
Author:
Paul A. Beales
Author:
Annette F. Taylor
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