Scaling of gene expression with transcription-factor fugacity

Franz M Weinert; Robert C Brewster; Mattias Rydenfelt; Rob Phillips; Willem K Kegel

doi:10.1103/PhysRevLett.113.258101

Scaling of gene expression with transcription-factor fugacity

Franz M Weinert, Robert C Brewster, Mattias Rydenfelt, Rob Phillips, Willem K Kegel

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The proteins associated with gene regulation are often shared between multiple pathways simultaneously. By way of contrast, models in regulatory biology often assume these pathways act independently. We demonstrate a framework for calculating the change in gene expression for the interacting case by decoupling repressor occupancy across the cell from the gene of interest by way of a chemical potential. The details of the interacting regulatory architecture are encompassed in an effective concentration, and thus, a single scaling function describes a collection of gene expression data from diverse regulatory situations and collapses it onto a single master curve.

Original language	English
Pages (from-to)	258101
Journal	Physical Review Letters
Volume	113
Issue number	25
DOIs	https://doi.org/10.1103/PhysRevLett.113.258101
Publication status	Published - 19 Dec 2014

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abstract = "The proteins associated with gene regulation are often shared between multiple pathways simultaneously. By way of contrast, models in regulatory biology often assume these pathways act independently. We demonstrate a framework for calculating the change in gene expression for the interacting case by decoupling repressor occupancy across the cell from the gene of interest by way of a chemical potential. The details of the interacting regulatory architecture are encompassed in an effective concentration, and thus, a single scaling function describes a collection of gene expression data from diverse regulatory situations and collapses it onto a single master curve.",

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AB - The proteins associated with gene regulation are often shared between multiple pathways simultaneously. By way of contrast, models in regulatory biology often assume these pathways act independently. We demonstrate a framework for calculating the change in gene expression for the interacting case by decoupling repressor occupancy across the cell from the gene of interest by way of a chemical potential. The details of the interacting regulatory architecture are encompassed in an effective concentration, and thus, a single scaling function describes a collection of gene expression data from diverse regulatory situations and collapses it onto a single master curve.

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Scaling of gene expression with transcription-factor fugacity

Abstract

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