Abstract
The yeast Gal11 protein is an important component of the Mediator complex in RNA polymerase II-directed transcription. Gal11 and the general transcription factor (TF) IIE are involved in regulation of the protein kinase activity of TFIIH that phosphorylates the carboxyl-terminal domain of RNA polymerase II. We have previously shown that Gal11 binds the small and large subunits of TFIIE at two Gal11 domains, A and B, respectively, which are important for normal function of Gal11 in vivo. Here we demonstrate that Gal11 binds directly to TFIIH through domain A in vitro. A null mutation in GAL11 caused lethality of cells when combined with temperature-sensitive mutations in the genes encoding TFIIE or the carboxyl-terminal domain kinase, indicating the presence of genetic interactions between Gal11 and these proteins. Mutational depletion of Gal11 or TFIIE caused inefficient opening of the transcription initiation region, but had no significant effect on TATA-binding protein occupancy of the TATA sequence in vivo. These results suggest that the functions of Gal11 and TFIIE are necessary after recruitment of TATA-binding protein to the TATA box presumably at the step of stable preinitiation complex formation and/or promoter melting. We illustrate genetic interactions between Gal11 and other Mediator components such as Med2 and Pgd1/Hrs1/Med3.
Highlights
The yeast Gal11 protein is an important component of the Mediator complex in RNA polymerase II-directed transcription
We show that the functions of Gal11 and TFIIE are necessary after the binding of TATA-binding protein (TBP) to the TATA box using an in vivo potassium permanganate footprint technique
These results strongly suggest that Gal11 directly binds to TFIIH via its genuine subunit(s), but not via the contaminating proteins, even though we were unable to identify definitively all of the TFIIH subunits in the Gal11-bound fraction for technical reasons
Summary
Yeast Strains and Media—The wild-type TFA1 (HS33), mutant tfa (HS46), wild-type GAL11 (NOY396), and null mutant gal (HS16) strains were described previously [18, 23]. Null mutations were constructed by the gene disruption technique and confirmed by polymerase chain reaction (PCR) analysis of the chromosomal DNA. The plasmid shuffling experiment was done using medium containing 5-fluoroorotic acid (5-FOA)
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