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© Inria / Photo C. Morel
Quantitative biology: numbers and fluorescent cells. InBio team (Inria/Institut Pasteur)
Publication : Proceedings of the National Academy of Sciences of the United States of America

Using single-cell models to predict the functionality of synthetic circuits at the population scale

Team: InBio: Experimental and Computational Methods for Modeling Cellular Processes
Member: Chetan Aditya
Member: François Bertaux
Member: Grégory Batt
Member: Jakob Ruess
Scientific Fields
Diseases
Organisms
Applications
Technique

Published in Proceedings of the National Academy of Sciences of the United States of America - 15 Mar 2022

Aditya C, Bertaux F, Batt G, Ruess J

Link to Pubmed [PMID] – 35271387

Link to DOI – 10.1073/pnas.2114438119

Proc Natl Acad Sci U S A 2022 Mar; 119(11): e2114438119

SignificanceAt the single-cell level, biochemical processes are inherently stochastic. For many natural systems, the resulting cell-to-cell variability is exploited by microbial populations. In synthetic biology, however, the interplay of cell-to-cell variability and population processes such as selection or growth often leads to circuits not functioning as predicted by simple models. Here we show how multiscale stochastic kinetic models that simultaneously track single-cell and population processes can be obtained based on an augmentation of the chemical master equation. These models enable us to quantitatively predict complex population dynamics of a yeast optogenetic differentiation system from a specification of the circuit’s components and to demonstrate how cell-to-cell variability can be exploited to purposefully create unintuitive circuit functionality.