Journal Article10.1038/NATURE06496
Predicting expression patterns from regulatory sequence in Drosophila segmentation
TL;DR: A novel thermodynamic model is described that computes expression patterns as a function of cis-regulatory sequence and of the binding-site preferences and expression of participating transcription factors and is applied to the segmentation gene network of Drosophila melanogaster.
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Abstract: The establishment of complex expression patterns at precise times and locations is key to metazoan development, yet a mechanistic understanding of the underlying transcription control networks is still missing. Here we describe a novel thermodynamic model that computes expression patterns as a function of cis-regulatory sequence and of the binding-site preferences and expression of participating transcription factors. We apply this model to the segmentation gene network of Drosophila melanogaster and find that it predicts expression patterns of cis-regulatory modules with remarkable accuracy, demonstrating that positional information is encoded in the regulatory sequence and input factor distribution. Our analysis reveals that both strong and weaker binding sites contribute, leading to high occupancy of the module DNA, and conferring robustness against mutation; short-range homotypic clustering of weaker sites facilitates cooperative binding, which is necessary to sharpen the patterns. Our computational framework is generally applicable to most protein-DNA interaction systems.
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References
Systematic determination of genetic network architecture
TL;DR: A systematic set of statistical algorithms are applied, based on whole-genome mRNA data, partitional clustering and motif discovery, to identify transcriptional regulatory sub-networks in yeast—without any a priori knowledge of their structure or any assumptions about their dynamics.
Module networks: identifying regulatory modules and their condition-specific regulators from gene expression data
Eran Segal,Michael Y. Shapira,Aviv Regev,Aviv Regev,Dana Pe'er,David Botstein,Daphne Koller,Nir Friedman +7 more
TL;DR: The procedure identifies modules of coregulated genes, their regulators and the conditions under which regulation occurs, generating testable hypotheses in the form 'regulator X regulates module Y under conditions W'.
Genome-wide location and function of dna binding proteins
TL;DR: In this paper, a method for identifying a set of genes where cell cycle regulator binding correlates with gene expression and identifying genomic targets of cell cycle transcription activators in living cells is also encompassed.
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λ Δ -Models
Simona Ronchi Della Rocca,Luca Paolini +1 more
- 01 Jan 2004
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