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Reducing phenotypic instabilities of microbial population during continuous cultivation based on cell switching dynamics
  • +7
  • Thai Nguyen,
  • Samuel Telek,
  • Andrew Zicler,
  • Juan Andres Martinez,
  • Boris Zacchetti,
  • Julian Kopp,
  • Christoph Slouka,
  • Christoph Herwig,
  • Alexander Grünberger,
  • Frank Delvigne
Thai Nguyen
University of Liège

Corresponding Author:thai@student.uliege.be

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Samuel Telek
University of Liège
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Andrew Zicler
University of Liège
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Juan Andres Martinez
University of Liège
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Boris Zacchetti
University of Liège
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Julian Kopp
Vienna University of Technology
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Christoph Slouka
Vienna University of Technology
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Christoph Herwig
Inst. of Chemical Engineering
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Alexander Grünberger
Bielefeld University Faculty of Technology
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Frank Delvigne
University of Liège
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Abstract

Predicting the fate of a microbial population (i.e., growth, gene expression…) remains a challenge, especially when this population is exposed to very dynamic environmental conditions, such as those encountered during continuous cultivation. Indeed, the dynamic nature of continuous cultivation process implies the potential deviation of the microbial population involving genotypic and phenotypic diversification. This work has been focused on the induction of the arabinose operon in Escherichia coli as a model system. As a preliminary step, the GFP level triggered by an arabinose-inducible ParaBAD promoter has been tracked by flow cytometry in chemostat with glucose-arabinose co-feeding. For a large range of glucose-arabinose co-feeding, the simultaneous occurrence of GFP positive and negative subpopulation was observed. In a second set of experiments, continuous cultivation was performed by adding either glucose or arabinose, based on the ability of individual cells for switching from low GFP to high GFP states, according to a technology called segregostat. In segregostat mode of cultivation, on-line flow cytometry analysis was used for adjusting the arabinose/glucose transitions based on the phenotypic switching capabilities of the microbial population. This strategy allowed finding an appropriate arabinose pulsing frequency, leading to a prolonged maintenance of the induction level with limited impact on phenotypic diversity for more than 60 generations. This result suggests that constraining individual cells into a given phenotypic trajectory is maybe not the best strategy for directing cell population. Instead, allowing individual cells switching around a predefined threshold seems to be a robust strategy leading to oscillating, but predictable, cell population behavior.
26 Mar 2021Submitted to Biotechnology and Bioengineering
29 Mar 2021Submission Checks Completed
29 Mar 2021Assigned to Editor
06 Apr 2021Reviewer(s) Assigned
20 May 2021Review(s) Completed, Editorial Evaluation Pending
20 May 2021Editorial Decision: Revise Major
11 Jun 20211st Revision Received
11 Jun 2021Submission Checks Completed
11 Jun 2021Assigned to Editor
12 Jun 2021Review(s) Completed, Editorial Evaluation Pending
12 Jun 2021Editorial Decision: Accept