Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters

Cells react to their environment through gene regulatory networks. Network integrity requires minimization of undesired crosstalk between their biomolecules. Similar constraints also limit the use of regulators when building synthetic circuits for engineering applications. Here, we mapped the promot...

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Autores principales: Rhodius, Virgil A, Segall-Shapiro, Thomas H, Sharon, Brian D, Ghodasara, Amar, Orlova, Ekaterina, Tabakh, Hannah, Burkhardt, David H, Clancy, Kevin, Peterson, Todd C, Gross, Carol A, Voigt, Christopher A
Formato: Online Artículo Texto
Lenguaje:English
Publicado: European Molecular Biology Organization 2013
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Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3817407/
https://www.ncbi.nlm.nih.gov/pubmed/24169405
http://dx.doi.org/10.1038/msb.2013.58
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author Rhodius, Virgil A
Segall-Shapiro, Thomas H
Sharon, Brian D
Ghodasara, Amar
Orlova, Ekaterina
Tabakh, Hannah
Burkhardt, David H
Clancy, Kevin
Peterson, Todd C
Gross, Carol A
Voigt, Christopher A
author_facet Rhodius, Virgil A
Segall-Shapiro, Thomas H
Sharon, Brian D
Ghodasara, Amar
Orlova, Ekaterina
Tabakh, Hannah
Burkhardt, David H
Clancy, Kevin
Peterson, Todd C
Gross, Carol A
Voigt, Christopher A
author_sort Rhodius, Virgil A
collection PubMed
description Cells react to their environment through gene regulatory networks. Network integrity requires minimization of undesired crosstalk between their biomolecules. Similar constraints also limit the use of regulators when building synthetic circuits for engineering applications. Here, we mapped the promoter specificities of extracytoplasmic function (ECF) σs as well as the specificity of their interaction with anti-σs. DNA synthesis was used to build 86 ECF σs (two from every subgroup), their promoters, and 62 anti-σs identified from the genomes of diverse bacteria. A subset of 20 σs and promoters were found to be highly orthogonal to each other. This set can be increased by combining the −35 and −10 binding domains from different subgroups to build chimeras that target sequences unrepresented in any subgroup. The orthogonal σs, anti-σs, and promoters were used to build synthetic genetic switches in Escherichia coli. This represents a genome-scale resource of the properties of ECF σs and a resource for synthetic biology, where this set of well-characterized regulatory parts will enable the construction of sophisticated gene expression programs.
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spelling pubmed-38174072013-11-06 Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters Rhodius, Virgil A Segall-Shapiro, Thomas H Sharon, Brian D Ghodasara, Amar Orlova, Ekaterina Tabakh, Hannah Burkhardt, David H Clancy, Kevin Peterson, Todd C Gross, Carol A Voigt, Christopher A Mol Syst Biol Article Cells react to their environment through gene regulatory networks. Network integrity requires minimization of undesired crosstalk between their biomolecules. Similar constraints also limit the use of regulators when building synthetic circuits for engineering applications. Here, we mapped the promoter specificities of extracytoplasmic function (ECF) σs as well as the specificity of their interaction with anti-σs. DNA synthesis was used to build 86 ECF σs (two from every subgroup), their promoters, and 62 anti-σs identified from the genomes of diverse bacteria. A subset of 20 σs and promoters were found to be highly orthogonal to each other. This set can be increased by combining the −35 and −10 binding domains from different subgroups to build chimeras that target sequences unrepresented in any subgroup. The orthogonal σs, anti-σs, and promoters were used to build synthetic genetic switches in Escherichia coli. This represents a genome-scale resource of the properties of ECF σs and a resource for synthetic biology, where this set of well-characterized regulatory parts will enable the construction of sophisticated gene expression programs. European Molecular Biology Organization 2013-10-29 /pmc/articles/PMC3817407/ /pubmed/24169405 http://dx.doi.org/10.1038/msb.2013.58 Text en Copyright © 2013, EMBO and Macmillan Publishers Limited https://creativecommons.org/licenses/by/3.0/This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. To view a copy of this license, visit http://creativecommons.org/licenses/by/3.0/ (https://creativecommons.org/licenses/by/3.0/) .
spellingShingle Article
Rhodius, Virgil A
Segall-Shapiro, Thomas H
Sharon, Brian D
Ghodasara, Amar
Orlova, Ekaterina
Tabakh, Hannah
Burkhardt, David H
Clancy, Kevin
Peterson, Todd C
Gross, Carol A
Voigt, Christopher A
Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
title Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
title_full Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
title_fullStr Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
title_full_unstemmed Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
title_short Design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
title_sort design of orthogonal genetic switches based on a crosstalk map of σs, anti-σs, and promoters
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3817407/
https://www.ncbi.nlm.nih.gov/pubmed/24169405
http://dx.doi.org/10.1038/msb.2013.58
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