Litcius/Paper detail

Metabolic cost of rapid adaptation of single yeast cells

Gabrielle Woronoff, Philippe Nghe, Jean Baudry, Laurent Boitard, Erez Braun, Andrew D. Griffiths, Jérôme Bibette

2020Proceedings of the National Academy of Sciences26 citationsDOIOpen Access PDF

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.

Topics & Concepts

Adaptation (eye)Metabolic adaptationSaccharomyces cerevisiaeCellular adaptationYeastBiologyCoupling (piping)Cell biologyBiological systemComputational biologyMetabolismNeuroscienceBiochemistryMaterials scienceGeneMetallurgyInnovative Microfluidic and Catalytic Techniques InnovationGene Regulatory Network AnalysisMicrobial Metabolic Engineering and Bioproduction