Zinc stoichiometry of yeast RNA polymerase II and characterization of mutations in the zinc-binding domain of the largest subunit

Atomic absorption spectroscopy demonstrated that highly purified RNA polymerase II from the yeast Saccharomyces cerevisiae binds seven zinc ions. This number agrees with the number of potential zinc-binding sites among the 12 different subunits of the enzyme and with our observation that the ninth largest subunit alone is able to bind two zinc ions. The zinc-binding motif in the largest subunit of the enzyme was investigated using mutagenic analysis. Altering any one of the six conserved residues in the zinc-binding motif conferred either a lethal or conditional phenotype, and zinc blot analysis indicated that mutant forms of the domain had a 2-fold reduction in zinc affinity. Mutations in the zinc-binding domain reduced RNA polymerase II activity in cell-free extracts, even though protein blot analysis indicated that the mutant subunit was present in excess of wild-type levels. Purification of one mutant RNA polymerase revealed a subunit profile that was wild-type like with the exception of two subunits not required for core enzyme activity (Rpb4p and Rpb7p), which were missing. Core activity of the mutant enzyme was reduced 20-fold. We conclude that mutations in the zinc-binding domain can reduce core activity without altering the association of any of the subunits required for this activity.     

The Rpb9 subunit of RNA polymerase II binds transcription factor TFIIE and interferes with the SAGA and elongator histone acetyltransferases.

Rpb9 is a small subunit of yeast RNA polymerase II participating in elongation and formed of two conserved zinc domains. rpb9 mutants are viable, with a strong sensitivity to nucleotide-depleting drugs. Deleting the C-terminal domain down to the first 57 amino acids has no detectable growth defect. Thus, the critical part of Rpb9 is limited to a N-terminal half that contacts the lobe of the second largest subunit (Rpb2) and forms a beta-addition motif with the "jaw" of the largest subunit (Rpb1). Rpb9 has homology to the TFIIS elongation factor, but mutants inactivated for both proteins are indistinguishable from rpb9 single mutants. In contrast, rpb9 mutants are lethal in cells lacking the histone acetyltransferase activity of the RNA polymerase II Elongator and SAGA factors. In a two-hybrid test, Rpb9 physically interacts with Tfa1, the largest subunit of TFIIE. The interacting fragment, comprising amino acids 62-164 of Tfa1, belongs to a conserved zinc motif. Tfa1 is immunoprecipitated by RNA polymerase II. This co-purification is strongly reduced in rpb9-Delta, suggesting that Rpb9 contributes to the recruitment of TFIIE on RNA polymerase II.     

Rpa12p, a conserved RNA polymerase I subunit with two functional domains

Rpa12p is a subunit of RNA polymerase I formed of two zinc-binding domains. The N-terminal zinc region (positions 1-60) is poorly conserved from yeast to man. The C-terminal domain contains an invariant Q.RSADE.T.F motif shared with the TFIIS elongation factor of RNA polymerase II and its archaeal counterpart. Deletions removing the N-terminal domain fail to grow at 34 degrees C, are sensitive to nucleotide-depleting drugs and become lethal in rpa14-Delta mutants lacking the non-essential RNA polymerase I subunit Rpa14p. They also strongly alter the immunofluorescent properties of RNA polymerase I in the nucleolus. Finally, they prevent the binding of Rpa12p to immunopurified polymerase I and impair a specific two-hybrid interaction with the second largest subunit. In all these respects, N-terminal deletions behave like full deletions. In contrast, C-terminal deletions retaining only the first N-terminal 60 amino acids are indistinguishable from wild type. Thus, the N-terminal zinc domain of Rpa12p determines its anchoring to RNA polymerase I and is the only critical part of that subunit in vivo.