Single‐cell zeroth‐order protein degradation enhances the robustness of synthetic oscillator

Single‐cell zeroth‐order protein degradation enhances the robustness of synthetic oscillator

Abstract In Escherichia coli, protein degradation in synthetic circuits is commonly achieved by the ssrA‐tagged degradation system. In this work, we show that the degradation kinetics for the green fluorescent protein fused with the native ssrA tag in each cell exhibits the zeroth‐order limit of the...

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Bibliographic Details
Main Authors: Wilson W Wong, Tony Y Tsai, James C Liao
Format: Article
Language:English
Published: Springer Nature 2007-07-01
Series:Molecular Systems Biology
Subjects:
population heterogeneity
protein degradation
single‐cell measurements
synthetic biological circuits
Online Access:https://doi.org/10.1038/msb4100172
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Summary:Abstract In Escherichia coli, protein degradation in synthetic circuits is commonly achieved by the ssrA‐tagged degradation system. In this work, we show that the degradation kinetics for the green fluorescent protein fused with the native ssrA tag in each cell exhibits the zeroth‐order limit of the Michaelis–Menten kinetics, rather than the commonly assumed first‐order. When measured in a population, the wide distribution of protein levels in the cells distorts the true kinetics and results in a first‐order protein degradation kinetics as a population average. Using the synthetic gene‐metabolic oscillator constructed previously, we demonstrated theoretically that the zeroth‐order kinetics significantly enlarges the parameter space for oscillation and thus enhances the robustness of the design under parametric uncertainty.
ISSN:1744-4292

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