The conformational state of the nucleosome entry-exit site modulates TATA box-specific TBP binding.

Aaron R Hieb,Jörg Langowski,Vera Böhm,Alexander Gansen

doi:10.1093/nar/gku423

Aaron R Hieb, Jörg Langowski + Show 2 more

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https://doi.org/10.1093/nar/gku423

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Abstract

The TATA binding protein (TBP) is a critical transcription factor used for nucleating assembly of the RNA polymerase II machinery. TBP binds TATA box elements with high affinity and kinetic stability and in vivo is correlated with high levels of transcription activation. However, since most promoters use less stable TATA-less or TATA-like elements, while also competing with nucleosome occupancy, further mechanistic insight into TBP's DNA binding properties and ability to access chromatin is needed. Using bulk and single-molecule FRET, we find that TBP binds a minimal consensus TATA box as a two-state equilibrium process, showing no evidence for intermediate states. However, upon addition of flanking DNA sequence, we observe non-specific cooperative binding to multiple DNA sites that compete for TATA-box specificity. Thus, we conclude that TBP binding is defined by a branched pathway, wherein TBP initially binds with little sequence specificity and is thermodynamically positioned by its kinetic stability to the TATA box. Furthermore, we observed the real-time access of TBP binding to TATA box DNA located within the DNA entry–exit site of the nucleosome. From these data, we determined salt-dependent changes in the nucleosome conformation regulate TBP's access to the TATA box, where access is highly constrained under physiological conditions, but is alleviated by histone acetylation and TFIIA.

Highlights

Gene-specific transcription is complex, requiring the concerted effort of many factors to recognize specific DNA loci and make them accessible to the transcription machinery
To gain a better grasp of TATA binding protein (TBP) binding properties in the presence of extended DNA, we compared TBP binding to a minimal TATA-box and one with flanking DNA, in real time using FRET
As TBP binds the TATA box, it bends the DNA, bringing the two fluorophores closer together, increasing the FRET signal, or proximity ratio (Supplementary Figure S1E); this method is a proven read-out for TBP-DNA association [10,35,36,37]

Summary

Introduction

Gene-specific transcription is complex, requiring the concerted effort of many factors to recognize specific DNA loci and make them accessible to the transcription machinery. This process requires at least the ordered assembly of the general transcription machinery (TATA binding protein (TBP), TFIIB, TFIIA, TFIIF and RNA polymerase II) to the promoter, forming the preinitiation complex (PIC). Assembly occurs in the context of chromatin, which limits access to the genomic DNA and acts as a key regulator of PIC formation. The majority of this regulation occurs around the nucleosome, the basic repeating unit of chromatin. Evidence is growing that the nucleosome is highly dynamic and modular [4,5,6], which defines a competition between nucleosome and transcription factor occupancy [7]

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