A bottom-up approach to gene regulation

The ability to construct synthetic gene networks enables experimental investigations of deliberately simplified systems that can be compared to qualitative and quantitative models. If simple, well-characterized modules can be coupled together into more complex networks with behaviour that can be pre...

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Bibliographic Details
Published in:Nature 2006-02, Vol.439 (7078), p.856-860
Main Authors: Guido, Nicholas J, Collins, J. J, McMillen, David, Wang, Xiao, Adalsteinsson, David, Cantor, Charles R, Elston, Timothy C, Hasty, Jeff
Format: Article
Language:English
Subjects:
Arabinose - metabolism
Bacteriology
Biological and medical sciences
Cell division
Cell growth
E coli
Escherichia coli
Escherichia coli - drug effects
Escherichia coli - genetics
Escherichia coli - growth & development
Escherichia coli - metabolism
Feedback, Physiological
Fundamental and applied biological sciences. Psychology
Gene Expression Regulation - drug effects
Gene Expression Regulation, Bacterial - drug effects
Genes, Bacterial - genetics
Genetics
Humanities and Social Sciences
Isopropyl Thiogalactoside - pharmacology
letter
Microbiology
Models, Genetic
multidisciplinary
Plasmids - genetics
Promoter Regions, Genetic - genetics
Proteins
Random variables
Repressor Proteins - genetics
Repressor Proteins - metabolism
RNA polymerase
Science
Science (multidisciplinary)
Stochastic models
Stochastic Processes
Trans-Activators - genetics
Trans-Activators - metabolism
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Summary:The ability to construct synthetic gene networks enables experimental investigations of deliberately simplified systems that can be compared to qualitative and quantitative models. If simple, well-characterized modules can be coupled together into more complex networks with behaviour that can be predicted from that of the individual components, we may begin to build an understanding of cellular regulatory processes from the 'bottom up'. Here we have engineered a promoter to allow simultaneous repression and activation of gene expression in Escherichia coli. We studied its behaviour in synthetic gene networks under increasingly complex conditions: unregulated, repressed, activated, and simultaneously repressed and activated. We develop a stochastic model that quantitatively captures the means and distributions of the expression from the engineered promoter of this modular system, and show that the model can be extended and used to accurately predict the in vivo behaviour of the network when it is expanded to include positive feedback. The model also reveals the counterintuitive prediction that noise in protein expression levels can increase upon arrest of cell growth and division, which we confirm experimentally. This work shows that the properties of regulatory subsystems can be used to predict the behaviour of larger, more complex regulatory networks, and that this bottom-up approach can provide insights into gene regulation.
ISSN:0028-0836
1476-4687
1476-4679
DOI:10.1038/nature04473