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Bacterial metabolic heterogeneity: from stochastic to deterministic models

  • Received: 21 May 2020 Accepted: 10 July 2020 Published: 29 July 2020
  • We revisit the modeling of the diauxic growth of a pure microorganism on two distinct sugars which was first described by Monod. Most available models are deterministic and make the assumption that all cells of the microbial ecosystem behave homogeneously with respect to both sugars, all consuming the first one and then switching to the second when the first is exhausted. We propose here a stochastic model which describes what is called "metabolic heterogeneity". It allows to consider small populations as in microfluidics as well as large populations where billions of individuals coexist in the medium in a batch or chemostat. We highlight the link between the stochastic model and the deterministic behavior in real large cultures using a large population approximation. Then the influence of model parameter values on model dynamics is studied, notably with respect to the lag-phase observed in real systems depending on the sugars on which the microorganism grows. It is shown that both metabolic parameters as well as initial conditions play a crucial role on system dynamics.

    Citation: Carl Graham, Jérôme Harmand, Sylvie Méléard, Josué Tchouanti. Bacterial metabolic heterogeneity: from stochastic to deterministic models[J]. Mathematical Biosciences and Engineering, 2020, 17(5): 5120-5133. doi: 10.3934/mbe.2020276

    Related Papers:

  • We revisit the modeling of the diauxic growth of a pure microorganism on two distinct sugars which was first described by Monod. Most available models are deterministic and make the assumption that all cells of the microbial ecosystem behave homogeneously with respect to both sugars, all consuming the first one and then switching to the second when the first is exhausted. We propose here a stochastic model which describes what is called "metabolic heterogeneity". It allows to consider small populations as in microfluidics as well as large populations where billions of individuals coexist in the medium in a batch or chemostat. We highlight the link between the stochastic model and the deterministic behavior in real large cultures using a large population approximation. Then the influence of model parameter values on model dynamics is studied, notably with respect to the lag-phase observed in real systems depending on the sugars on which the microorganism grows. It is shown that both metabolic parameters as well as initial conditions play a crucial role on system dynamics.


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    [8] M. Barthe, J. Tchouanti, P. H. Gomes, C. Bideaux, D. Lestrade, C. Graham, et al., Duration of the glucose-xylose lag is controlled stochastically by the molecular switch XylR in Escherichia coli., Submitted, 2020.
    [9] S. N. Ethier, T. G. Kurtz, Markov Processes: Characterization and Convergence, John Wiley & Sons, 1986.
    [10] D. F. Anderson, T. G. Kurtz, Stochastic Analysis of Biochemical Systems, Springer, 2015.
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