Chromatin regulates genome-wide transcription factor binding affinities

Transcription factor binding across the genome is regulated by DNA sequence and chromatin features. However, it is not yet possible to quantify the impact of chromatin context on genome-wide transcription factor binding affinities. Here we report the establishment of a method to determine genome-wide absolute apparent binding affinities of transcription factors to native, chromatinized DNA. Our experiments revealed that DNA accessibility is the main determinant of transcription factor binding in the genome, which largely restricts nanomolar affinity binding of YY1, SP1 and MYC/MAX to promoters, while FOXA1 also interacts with non-promoter elements with high affinity. Furthermore, whereas consensus DNA binding motifs for transcription factors are important to establish very high-affinity binding sites, these motifs are not always strictly required to generate nanomolar affinity interactions in the genome. Finally, we uncovered transcription factor concentration dependent binding to specific gene classes, suggesting transcription factor concentration dependent effects on gene expression and cell fate. Importantly, our method adds a quantitative dimension to transcription factor biology which enables stratification of genomic targets based on transcription factor concentration and prediction of transcription factor binding sites under non-physiological conditions, such as disease associated overexpression of (onco)genes. ### Competing Interest Statement In the past 3 years, Sarah A. Teichmann has consulted for Genentech and Roche and sits on Scientific Advisory Boards for Qiagen, Foresite Labs, Biogen, and GlaxoSmithKline and is a co-founder and equity holder of Transition Bio.