Fractal Topology of Gene Promoter Networks at Phase Transitions

Preston R. Aldrich, Robert K. Horsley, Yousuf A. Ahmed, Joseph J. Williamson and Stefan M. TurcicDepartment of Biological Sciences, Benedictine University, Lisle, IL 60532, USA. AbstractMuch is known regarding the structure and logic of genetic regulatory networks. Less understood is the contextual...

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Veröffentlicht in:	Gene regulation and systems biology 2010-07, Vol.2010 (4), p.75-82
Hauptverfasser:	Aldrich, Preston R., Horsley, Robert K., Ahmed, Yousuf A., Williamson, Joseph J., Turcic, Stefan M.
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Sprache:	eng
Schlagworte:	Abundance DNA Escherichia coli Fractals Gene regulation Genes Genetic transcription Language Nodes Nuclei Original Research Phase transition Promoters Promoters (Genetics) Transcription initiation
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creator	Aldrich, Preston R. Horsley, Robert K. Ahmed, Yousuf A. Williamson, Joseph J. Turcic, Stefan M.
description	Preston R. Aldrich, Robert K. Horsley, Yousuf A. Ahmed, Joseph J. Williamson and Stefan M. TurcicDepartment of Biological Sciences, Benedictine University, Lisle, IL 60532, USA. AbstractMuch is known regarding the structure and logic of genetic regulatory networks. Less understood is the contextual organization of promoter signals used during transcription initiation, the most pivotal stage during gene expression. Here we show that promoter networks organize spontaneously at a dimension between the 1-dimension of the DNA and 3-dimension of the cell. Network methods were used to visualize the global structure of E. coli sigma (σ) recognition footprints using published promoter sequences (RegulonDB). Footprints were rendered as networks with weighted edges representing bp-sharing between promoters (nodes). Serial thresholding revealed phase transitions at positions predicted by percolation theory, and nuclei denoting short steps through promoter space with geometrically constrained linkages. The network nuclei are fractals, a power-law organization not yet described for promoters. Genome-wide promoter abundance also scaled as a power-law. We propose a general model for the development of a fractal nucleus in a transcriptional grammar.
doi_str_mv	10.4137/GRSB.S5389
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Aldrich, Robert K. Horsley, Yousuf A. Ahmed, Joseph J. Williamson and Stefan M. TurcicDepartment of Biological Sciences, Benedictine University, Lisle, IL 60532, USA. AbstractMuch is known regarding the structure and logic of genetic regulatory networks. Less understood is the contextual organization of promoter signals used during transcription initiation, the most pivotal stage during gene expression. Here we show that promoter networks organize spontaneously at a dimension between the 1-dimension of the DNA and 3-dimension of the cell. Network methods were used to visualize the global structure of E. coli sigma (σ) recognition footprints using published promoter sequences (RegulonDB). Footprints were rendered as networks with weighted edges representing bp-sharing between promoters (nodes). Serial thresholding revealed phase transitions at positions predicted by percolation theory, and nuclei denoting short steps through promoter space with geometrically constrained linkages. 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Aldrich, Robert K. Horsley, Yousuf A. Ahmed, Joseph J. Williamson and Stefan M. TurcicDepartment of Biological Sciences, Benedictine University, Lisle, IL 60532, USA. AbstractMuch is known regarding the structure and logic of genetic regulatory networks. Less understood is the contextual organization of promoter signals used during transcription initiation, the most pivotal stage during gene expression. Here we show that promoter networks organize spontaneously at a dimension between the 1-dimension of the DNA and 3-dimension of the cell. Network methods were used to visualize the global structure of E. coli sigma (σ) recognition footprints using published promoter sequences (RegulonDB). Footprints were rendered as networks with weighted edges representing bp-sharing between promoters (nodes). Serial thresholding revealed phase transitions at positions predicted by percolation theory, and nuclei denoting short steps through promoter space with geometrically constrained linkages. 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Aldrich, Robert K. Horsley, Yousuf A. Ahmed, Joseph J. Williamson and Stefan M. TurcicDepartment of Biological Sciences, Benedictine University, Lisle, IL 60532, USA. AbstractMuch is known regarding the structure and logic of genetic regulatory networks. Less understood is the contextual organization of promoter signals used during transcription initiation, the most pivotal stage during gene expression. Here we show that promoter networks organize spontaneously at a dimension between the 1-dimension of the DNA and 3-dimension of the cell. Network methods were used to visualize the global structure of E. coli sigma (σ) recognition footprints using published promoter sequences (RegulonDB). Footprints were rendered as networks with weighted edges representing bp-sharing between promoters (nodes). Serial thresholding revealed phase transitions at positions predicted by percolation theory, and nuclei denoting short steps through promoter space with geometrically constrained linkages. 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subjects	Abundance DNA Escherichia coli Fractals Gene regulation Genes Genetic transcription Language Nodes Nuclei Original Research Phase transition Promoters Promoters (Genetics) Transcription initiation
title	Fractal Topology of Gene Promoter Networks at Phase Transitions
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