Architecture of Protein and DNA Contacts within the TFIIIB-DNA Complex

The RNA polymerase III factor TFIIIB forms a stable complex with DNA and can promote multiple rounds of initiation by polymerase. TFIIIB is composed of three subunits, the TATA binding protein (TBP), TFIIB-related factor (BRF), and B". Chemical footprinting, as well as mutagenesis of TBP, BRF, and promoter DNA, was used to probe the architecture of TFIIIB subunits bound to DNA. BRF bound to TBP-DNA through the nonconserved C-terminal region and required 15 bp downstream of the TATA box and as little as 1 bp upstream of the TATA box for stable complex formation. In contrast, formation of complete TFIIIB complexes required 15 bp both upstream and downstream of the TATA box. Hydroxyl radical footprinting of TFIIIB complexes and modeling the results to the TBP-DNA structure suggest that BRF and B" surround TBP on both faces of the TBP-DNA complex and provide an explanation for the exceptional stability of this complex. Competition for binding to TBP by BRF and either TFIIB or TFIIA suggests that BRF binds on the opposite face of the TBP-DNA complex from TFIIB and that the binding sites for TFIIA and BRF overlap. The positions of TBP mutations which are defective in binding BRF suggest that BRF binds to the top and N-terminal leg of TBP. One mutation on the N-terminal leg of TBP specifically affects the binding of the B" subunit.     

The amino-terminal tails of the core histones and the translational position of the TATA box determine TBP/TFIIA association with nucleosomal DNA.

We establish that the TATA binding protein (TBP) in the presence of TFIIA recognizes the TATA box in nucleosomal DNA dependent on the dissociation of the amino-terminal tails of the core histones from the nucleosome and the position of the TATA box within the nucleosome. We examine TBP/TFIIA access to the TATA box with this sequence placed in four distinct rotational frames with reference to the histone surface and at three distinct translational positions at the edge, side and dyad axis of the nucleosome. Under our experimental conditions, we find that the preferential translational position at which TBP/TFIIA can bind the TATA box is within linker DNA at the edge of the nucleosome and that binding is facilitated if contacts made by the amino-terminal tails of the histones with nucleosomal DNA are eliminated. TBP/TFIIA binding to DNA at the edge of the nucleosome occurs with the TATA box in all four rotational positions. This is indicative of TBP/TFIIA association directing the dissociation of the TATA box from the surface of the histone octamer.