Modelling bacteria-inspired dynamics with networks of interacting chemicals
Modelling bacteria-inspired dynamics with networks of interacting chemicals
One approach to understanding how life-like properties emerge involves building synthetic cellular systems that mimic certain dynamical features of living cells such as bacteria. Here, we developed a model of a reaction network in a cellular system inspired by the ability of bacteria to form a biofilm in response to increasing cell density. Our aim was to determine the role of chemical feedback in the dynamics. The feedback was applied through the enzymatic rate dependence on pH, as pH is an important parameter that controls the rates of processes in cells. We found that a switch in pH can be used to drive base-catalyzed gelation or precipitation of a substance in the external solution. A critical density of cells was required for gelation that was essentially independent of the pH-driven feedback. However, the cell pH reached a higher maximum as a result of the appearance of pH oscillations with feedback. Thus, we conclude that while feedback may not play a vital role in some density-dependent behavior in cellular systems, it nevertheless can be exploited to activate internally regulated cell processes at low cell densities.
Bánsági, Tamás
3984187d-60fd-47f2-b6cb-f312dcedadae
Taylor, Annette F.
08028a29-428d-4732-b6b1-f7a93389b386
29 July 2019
Bánsági, Tamás
3984187d-60fd-47f2-b6cb-f312dcedadae
Taylor, Annette F.
08028a29-428d-4732-b6b1-f7a93389b386
Bánsági, Tamás and Taylor, Annette F.
(2019)
Modelling bacteria-inspired dynamics with networks of interacting chemicals.
Life, 9 (3), [63].
(doi:10.3390/life9030063).
Abstract
One approach to understanding how life-like properties emerge involves building synthetic cellular systems that mimic certain dynamical features of living cells such as bacteria. Here, we developed a model of a reaction network in a cellular system inspired by the ability of bacteria to form a biofilm in response to increasing cell density. Our aim was to determine the role of chemical feedback in the dynamics. The feedback was applied through the enzymatic rate dependence on pH, as pH is an important parameter that controls the rates of processes in cells. We found that a switch in pH can be used to drive base-catalyzed gelation or precipitation of a substance in the external solution. A critical density of cells was required for gelation that was essentially independent of the pH-driven feedback. However, the cell pH reached a higher maximum as a result of the appearance of pH oscillations with feedback. Thus, we conclude that while feedback may not play a vital role in some density-dependent behavior in cellular systems, it nevertheless can be exploited to activate internally regulated cell processes at low cell densities.
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life-09-00063
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Accepted/In Press date: 25 July 2019
Published date: 29 July 2019
Identifiers
Local EPrints ID: 499296
URI: http://eprints.soton.ac.uk/id/eprint/499296
ISSN: 2075-1729
PURE UUID: 3139831f-36b0-4d56-8cf6-3a16048a481e
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Date deposited: 14 Mar 2025 17:36
Last modified: 22 Aug 2025 02:44
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Author:
Tamás Bánsági
Author:
Annette F. Taylor
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