Polymerase (Pol) III TATA box-binding protein (TBP)-associated factor Brf binds to a surface on TBP also required for activated Pol II transcription.

Abstract

The TATA box-binding protein (TBP) plays an essential role in transcription by all three eukaryotic nuclear RNA polymerases, polymerases (Pol) I, II, and III. In each case, TBP interacts with class-specific TBP-associated factors (TAFs) to form class-specific transcription initiation factors. For yeast Pol III transcription, TBP associates with Brf (from TFIIB-related factor) and B", two Pol III TAFs, to form Pol III transcription factor TFIIIB. Here, we identify TBP surface residues that are required for interaction with yeast Pol III TAFs. Ninety-one human TBP surface residue mutants with radical substitutions were analyzed for the ability to form stable gel shift complexes with purified Brf and B" and for their activities for in vitro synthesis of yeast U6 snRNA. Mutations in a large positively charged epitope extending from the top (that is, on the surface opposite the DNA-facing "saddle" of TBP) and onto the side of the first TBP repeat inhibited binding to Brf (residues K181, L185, R186, E206, R231, L232, R235, K236, R239, Q242, K243, K249, and F250). A triple-mutant TBP (R231E + R235E + R239S) had greatly reduced activity for yeast U6 snRNA gene transcription while remaining active for Pol II basal transcription. Similar results were observed when selected mutations were introduced into yeast TBP at equivalent positions. A C-terminal fragment of Brf lacking the region of homology with TFIIB retains the ability to bind TBP-DNA complexes (G. Kassavetis, C. Bardeleben, A. Kumar, E. Ramirez, and E. P. Geiduschek, Mol. Cell. Biol. 17:5299-5306, 1997); the same TBP mutations reduced binding by this fragment. Mutations in TBP residues that interact with TFIIB did not affect Brf binding or U6 gene transcription. These results indicate that Brf and TFIIB interact differently with TBP. An extensively overlapping epitope on the top surface of TBP was found previously to be required for activated Pol II transcription and has been hypothesized to interact with Pol II TAFs. Our results map the surface of TBP that interacts with Brf and suggest that Pol II and Pol III TAFs interact with the same surface of TBP.