Biology – Quantitative Biology – Molecular Networks
Scientific paper
2010-09-16
Biophys. J. 95:2103-2115 (2008)
Biology
Quantitative Biology
Molecular Networks
13 pages, 8 figures; supplementary material available upon request from the authors
Scientific paper
10.1529/biophysj.107.127191
The arabinose utilization system of E. coli displays a stochastic "all or nothing" response at intermediate levels of arabinose, where the population divides into a fraction catabolizing the sugar at a high rate (ON state) and a fraction not utilizing arabinose (OFF state). Here we study this decision process in individual cells, focusing on the dynamics of the transition from the OFF to the ON state. Using quantitative time-lapse microscopy, we determine the time delay between inducer addition and fluorescence onset of a GFP reporter. Through independent characterization of the GFP maturation process, we can separate the lag time caused by the reporter from the intrinsic activation time of the arabinose system. The resulting distribution of intrinsic time delays scales inversely with the external arabinose concentration, and is compatible with a simple stochastic model for arabinose uptake. Our findings support the idea that the heterogeneous timing of gene induction is causally related to a broad distribution of uptake proteins at the time of sugar addition.
Fritz Georg
Gerland Ulrich
Jung Kirsten
Megerle Judith A.
Rädler Joachim O.
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