Predicting transcription factor affinities to DNA from a biophysical model

HG Roider, A Kanhere, T Manke, M Vingron - Bioinformatics, 2007 - academic.oup.com
Bioinformatics, 2007academic.oup.com
Motivation: Theoretical efforts to understand the regulation of gene expression are
traditionally centered around the identification of transcription factor binding sites at specific
DNA positions. More recently these efforts have been supplemented by experimental data
for relative binding affinities of proteins to longer intergenic sequences. The question arises
to what extent these two approaches converge. In this paper, we adopt a physical binding
model to predict the relative binding affinity of a transcription factor for a given sequence …
Abstract
Motivation: Theoretical efforts to understand the regulation of gene expression are traditionally centered around the identification of transcription factor binding sites at specific DNA positions. More recently these efforts have been supplemented by experimental data for relative binding affinities of proteins to longer intergenic sequences. The question arises to what extent these two approaches converge. In this paper, we adopt a physical binding model to predict the relative binding affinity of a transcription factor for a given sequence.
Results: We find that a significant fraction of genome-wide binding data in yeast can be accounted for by simple count matrices and a physical model with only two parameters. We demonstrate that our approach is both conceptually and practically more powerful than traditional methods, which require selection of a cutoff. Our analysis yields biologically meaningful parameters, suitable for predicting relative binding affinities in the absence of experimental binding data.
Availability: The C source code for our TRAP program is freely available for non-commercial use at
Contact:  vingron@molgen.mpg.de
Oxford University Press