A synthetic growth switch based on controlled expression of RNA polymerase

Izard, Jérôme; Balderas, Cindy D C Gomez; Ropers, Delphine; Lacour, Stéphan; Song, Xiaohu; Yang, Yifan; Lindner, Ariel B.; Geiselmann, Johannes; Jong, Hidde de

doi:10.15252/msb.20156382

Cited by 83 publications

(102 citation statements)

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“…Regulations of an external inducer (based on specific chemical or light effects) can modify cellular processes [3]. Then it seems promising to consider the problem of finding an inducing strategy that maximizes the biotechnological production.…”

Section: Resultsmentioning

confidence: 99%

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Optimal feedback strategies for bacterial growth with degradation, recycling, and effect of temperature

Yegorov

Mairet

Gouzé

2018

Optim Control Appl Methods

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For both fundamental biology and engineering applications, it is relevant to investigate how microorganisms adapt to changing environmental conditions. In this work, we consider a continuous-time dynamic problem of resource allocation between metabolic and gene expression machineries for a self-replicating prokaryotic cell population. In compliance with evolutionary principles, the criterion is to maximize the accumulated structural biomass. In the model, we include both degradation of proteins into amino acids and recycling of the latter (i. e., using as precursors again). Based on the analytical investigation of our problem by Pontryagin's maximum principle, we develop a numerical algorithm for approximating the switching curve of the optimal feedback control strategy. The obtained field of extremal state trajectories consists of chattering arcs and one steadystate singular arc. The constructed feedback control law can serve as a benchmark for comparing actual bacterial strategies of resource allocation. We also study the influence of temperature, whose increase intensifies protein degradation. While the growth rate suddenly decreases with the increase of temperature in a certain range, the optimal control synthesis appears to be essentially less sensitive.1 BIOCORE team, INRIA Sophia-Antipolis Méditerranée (as a part

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Section: Resultsmentioning

confidence: 99%

“…For both fundamental biology and engineering applications, it is relevant to investigate how microorganisms adapt to changing environmental conditions [1][2][3]. In compliance with evolutionary principles, internal regulation mechanisms of bacteria are expected to maximize appropriate fitness criteria.…”

Section: Introductionmentioning

confidence: 99%

Optimal feedback strategies for bacterial growth with degradation, recycling, and effect of temperature

Yegorov

Mairet

Gouzé

2018

Optim Control Appl Methods

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“…As the circuits get larger, one can imagine implementing complex control over a metabolic pathway by turning on different portions of the pathway at different times, coordinating stress responses, and staging a process to including steps before (seeding and growth) and after (biomass recycling or disposal) the production phase. Examples of advanced approaches include the following: (i) only expressing oxygen‐sensitive enzymes under anaerobic conditions (Burgard et al , ; Immethun et al , ), (ii) transiently responding to localized stresses within larger bioreactors (Bylund et al , ; Enfors et al , ), (iii) lysis system for product recovery (Borrero‐de Acuna et al , ), (iv) flocculation for sedimentation for biomass removal and inhibition of cell growth (You et al , ; Izard et al , ), and (iv) elimination of synthetic DNA before disposal (Caliando & Voigt, ; Chan et al , ). Such approaches have been implemented individually, but one can envision linking many together into one large system.…”

Section: Discussionmentioning

confidence: 99%

Dynamic control of endogenous metabolism with combinatorial logic circuits

Moser

Borujeni

Ghodasara

et al. 2018

Molecular Systems Biology

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Controlling gene expression during a bioprocess enables real‐time metabolic control, coordinated cellular responses, and staging order‐of‐operations. Achieving this with small molecule inducers is impractical at scale and dynamic circuits are difficult to design. Here, we show that the same set of sensors can be integrated by different combinatorial logic circuits to vary when genes are turned on and off during growth. Three Escherichia coli sensors that respond to the consumption of feedstock (glucose), dissolved oxygen, and by‐product accumulation (acetate) are constructed and optimized. By integrating these sensors, logic circuits implement temporal control over an 18‐h period. The circuit outputs are used to regulate endogenous enzymes at the transcriptional and post‐translational level using CRISPRi and targeted proteolysis, respectively. As a demonstration, two circuits are designed to control acetate production by matching their dynamics to when endogenous genes are expressed (pta or poxB) and respond by turning off the corresponding gene. This work demonstrates how simple circuits can be implemented to enable customizable dynamic gene regulation.

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“…Finally, the relatively small size, functionality on the genome, and gene-independent regulation could make STARs ideally suited as a tool for strain engineering and reprogramming of cellular phenotypes. For example, STARs could be used to create synthetic switches for decoupling biomass and pathway production 57,58 .…”

Section: Discussionmentioning

confidence: 99%