Integrated microfluidic approach for quantitative high-throughput measurements of transcription factor binding affinities.

Yair Glick,Yaron Orenstein,Dorit Avrahami,Tsaffrir Zor,Dana Chen,Doron Gerber,Ron Shamir

doi:10.1093/nar/gkv1327

Yair Glick, Yaron Orenstein + Show 5 more

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https://doi.org/10.1093/nar/gkv1327

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Abstract

Protein binding to DNA is a fundamental process in gene regulation. Methodologies such as ChIP-Seq and mapping of DNase I hypersensitive sites provide global information on this regulation in vivo. In vitro methodologies provide valuable complementary information on protein–DNA specificities. However, current methods still do not measure absolute binding affinities. There is a real need for large-scale quantitative protein–DNA affinity measurements. We developed QPID, a microfluidic application for measuring protein–DNA affinities. A single run is equivalent to 4096 gel-shift experiments. Using QPID, we characterized the different affinities of ATF1, c-Jun, c-Fos and AP-1 to the CRE consensus motif and CRE half-site in two different genomic sequences on a single device. We discovered that binding of ATF1, but not of AP-1, to the CRE half-site is highly affected by its genomic context. This effect was highly correlated with ATF1 ChIP-seq and PBM experiments. Next, we characterized the affinities of ATF1 and ATF3 to 128 genomic CRE and CRE half-site sequences. Our affinity measurements explained that in vivo binding differences between ATF1 and ATF3 to CRE and CRE half-sites are partially mediated by differences in the minor groove width. We believe that QPID would become a central tool for quantitative characterization of biophysical aspects affecting protein–DNA binding.

Highlights

IntroductionMany proteins interact with DNA to modulate and affect a wide variety of cellular processes including DNA replication, repair and recombination
Protein–DNA interaction is a fundamental process in the living cell
We found that binding of ATF1, but not of AP-1, to cAMP response element (CRE) half-site is highly affected by the genomic context, in concordance with protein binding microarrays (PBMs) and Chromatin immunoprecipitation (ChIP)-seq experiments

Summary

Introduction

Many proteins interact with DNA to modulate and affect a wide variety of cellular processes including DNA replication, repair and recombination. The expression of genes requires transcription by RNA polymerase. The transcription process is regulated by a variety of associated proteins, referred to generally as transcription factors (TFs). Transcription factors are found in all living organisms and their number increases with genome size. Larger genomes tend to have higher fraction of TFs among their genes. 10% of genes in the human genome encode for TFs, which makes them the largest family in the proteome [1,2]. There are about 1,400 transcription factors with sequence-specific DNA-binding preferences that regulate only a subset of genes by binding to site-specific cis-elements [3]. The sitespecific factors tend to be expressed either in all (or most) tissues or in one or two tissues, suggesting either a very broad or very specific function [4]

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