Adaptive laboratory evolution of a thermophile toward a reduced growth temperature optimum

Lehmann, Maria; Prohaska, Christoph; Zeldes, Benjamin; Poehlein, Anja; Daniel, Rolf; Basen, Mirko

doi:10.3389/fmicb.2023.1265216

Cited by 5 publications

(1 citation statement)

References 66 publications

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“…This was not observed in any of our experiments, which maintained control for at least 7 days of exponential growth (>250 generations assuming an average species doubling time of 40 minutes), significantly July 4, 2024 16/25 longer than other cybernetically controlled bacterial co-cultures to-date. Nevertheless, past studies of microbial adaptation to temperature extremes indicate significant changes in growth optimum are possible [33,34], though these would need to be very significant to eliminate our controller's ability to adapt. More broadly, all exploited natural characteristics may drift over the course of long experiments, but combining several measurements, of which some are tied to the cellular growth rate (e.g.…”

Section: Discussionmentioning

confidence: 99%

Cybernetic control of a natural microbial co-culture

Lee,

Morlock,

Allan

et al. 2024

Preprint

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A key obstacle in the widespread application of microbial co-cultures in bioprocesses is their compositional instability, as faster-growing species outcompete and dominate the culture. While several synthetic biology approaches have demonstrated control over co-culture composition, there has been an increased interest in computer-based cybernetic control approaches that can offload burdensome genetic control circuitry to computers and enable dynamic control and real-time noise rejection. This work extends that approach, demonstrating a cybernetic control method that is not reliant on any genetic engineering, instead interfacing cells with computers by exploiting their natural characteristics to measure and actuate the composition. We apply this to aPseudomonas putida(P. putida) andEscherichia coli(E. coli) co-culture grown in Chi.Bio bioreactors, first showing how composition estimates calculated from different bioreactor measurements can be combined with a system model using an extended Kalman filter to generate accurate estimates of a noisy system. We also demonstrate that because the species have different optimal temperature niches, adjusting the temperature of the culture can drive the composition in either direction. By using a proportional-integral control algorithm to calculate the temperature that would bring the measured composition towards the desired composition, we are able to track dynamic references and stabilised the co-culture for 7 days (∼250 generations), with the experiment ending before the cells could adapt out of the control. This cybernetic framework is broadly applicable, with different microbes’ unique features and specific growth niches enabling robust control over diverse co-cultures.

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Section: Discussionmentioning

confidence: 99%

Cybernetic control of a natural microbial co-culture

Lee,

Morlock,

Allan

et al. 2024

Preprint

View full text Add to dashboard Cite

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Long-term acclimation to organic carbon enhances the production of loliolide from Scenedesmus deserticola

Cho,

Yun,

Choi

et al. 2024

Bioresource Technology

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Rational and Semirational Approaches for Engineering Salicylate Production in Escherichia coli

Chen,

Gao,

et al. 2024

ACS Synth. Biol.

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Salicylate plays a pivotal role as a pharmaceutical intermediate in drugs, such as aspirin and lamivudine. The low catalytic efficiency of key enzymes and the inherent toxicity of salicylates to cells pose significant challenges to large-scale microbial production. In this study, we introduced the salicylate synthase Irp9 into an L-phenylalanine-producing Escherichia coli, constructing the shortest salicylate biosynthetic pathway. Subsequent protein engineering increased the catalytic efficiency of Irp9 by 33.5%. Furthermore, by integrating adaptive evolution with transcriptome analysis, we elucidated the crucial mechanism of efflux proteins in salicylate tolerance. The elucidation of this mechanism guided us in the targeted modification of these transport proteins, achieving a reported maximum level of 3.72 g/L of salicylate in a shake flask. This study highlights the importance of efflux proteins for enhancing the productivity of microbial cell factories in salicylate production, which also holds potential for application in the green synthesis of other phenolic acids.

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Adaptive laboratory evolution of a thermophile toward a reduced growth temperature optimum

Cited by 5 publications

References 66 publications

Cybernetic control of a natural microbial co-culture

Cybernetic control of a natural microbial co-culture

Long-term acclimation to organic carbon enhances the production of loliolide from Scenedesmus deserticola

Rational and Semirational Approaches for Engineering Salicylate Production in Escherichia coli

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