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Metabolic cost of rapid adaptation of single yeast cells.


ABSTRACT: Cells can rapidly adapt to changing environments through nongenetic processes; however, the metabolic cost of such adaptation has never been considered. Here we demonstrate metabolic coupling in a remarkable, rapid adaptation process (1 in 1,000 cells adapt per hour) by simultaneously measuring metabolism and division of thousands of individual Saccharomyces cerevisiae cells using a droplet microfluidic system: droplets containing single cells are immobilized in a two-dimensional (2D) array, with osmotically induced changes in droplet volume being used to measure cell metabolism, while simultaneously imaging the cells to measure division. Following a severe challenge, most cells, while not dividing, continue to metabolize, displaying a remarkably wide diversity of metabolic trajectories from which adaptation events can be anticipated. Adaptation requires a characteristic amount of energy, indicating that it is an active process. The demonstration that metabolic trajectories predict a priori adaptation events provides evidence of tight energetic coupling between metabolism and regulatory reorganization in adaptation. This process allows S. cerevisiae to adapt on a physiological timescale, but related phenomena may also be important in other processes, such as cellular differentiation, cellular reprogramming, and the emergence of drug resistance in cancer.

SUBMITTER: Woronoff G 

PROVIDER: S-EPMC7245094 | biostudies-literature | 2020 May

REPOSITORIES: biostudies-literature

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Metabolic cost of rapid adaptation of single yeast cells.

Woronoff Gabrielle G   Nghe Philippe P   Baudry Jean J   Boitard Laurent L   Braun Erez E   Griffiths Andrew D AD   Bibette Jérôme J  

Proceedings of the National Academy of Sciences of the United States of America 20200505 20


Cells can rapidly adapt to changing environments through nongenetic processes; however, the metabolic cost of such adaptation has never been considered. Here we demonstrate metabolic coupling in a remarkable, rapid adaptation process (1 in 1,000 cells adapt per hour) by simultaneously measuring metabolism and division of thousands of individual <i>Saccharomyces cerevisiae</i> cells using a droplet microfluidic system: droplets containing single cells are immobilized in a two-dimensional (2D) arr  ...[more]

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