Involvement of multiple subunit-subunit contacts in the assembly of RNA polymerase II

RNA polymerase II from the fission yeast Schizosaccharomyces pombe consists of 12 species of subunits, Rpb1–Rpb12. We expressed these subunits, except Rpb4, simultaneously in cultured insect cells with baculovirus expression vectors. For the isolation of subunit complexes formed in the virus-infected cells, a glutathione S-transferase (GST) sequence was fused to the rpb3 cDNA to produce GST–Rpb3 fusion protein and a decahistidine-tag sequence was inserted into the rpb1 cDNA to produce Rpb1H protein. After successive affinity chromatography on glutathione and Ni²⁺ columns, complexes consisting of the seven subunits, Rpb1H, Rpb2, GST–Rpb3, Rpb5, Rpb7, Rpb8 and Rpb11, were identified. Omission of the GST–Rpb3 expression resulted in reduced assembly of the Rpb11 into the complex. Direct interaction between Rpb3 and the other six subunits was detected by pairwise coexpression experiments. Coexpression of various combinations of a few subunits revealed that Rpb11 enhances Rpb3–Rpb8 interaction and consequently Rpb8 enhances Rpb1–Rpb3 interaction to some extent. We propose a mechanism in which the assembly of RNA poly-merase II is stabilized through multiple subunit–subunit contacts.     

Isolation and characterization of temperature-sensitive mutations in the gene ( rpb3? ) for subunit 3 of RNA polymerase II in the fission yeast Schizosaccharomyces pombe

Subunit 3 (Rpb3) of eukaryotic RNA polymerase II is a homologue of the α subunit of prokaryotic RNA polymerase, which plays a key role in subunit assembly of this complex enzyme by providing the contact surfaces for both β and β′ subunits. Previously we demonstrated that the Schizosaccharomyces pombe Rpb3 protein forms a core subassembly together with Rpb2 (the β homologue) and Rpb11 (the second α homologue) subunits, as in the case of the prokaryotic α₂β complex. In order to obtain further insight into the physiological role(s) of Rpb3, we subjected the S. pombe rpb3 gene to mutagenesis. A total of nine temperature-sensitive (Ts) and three cold-sensitive (Cs) S. pombe mutants have been isolated, each (with the exception of one double mutant) carrying a single mutation in the rpb3 gene in one of the four regions (A–D) that are conserved between the homologues of eukaryotic subunit 3. The three Cs mutations were all located in region A, in agreement with the central role of the corresponding region in the assembly of prokaryotic RNA polymerase; the Ts mutations, in contrast, were found in all four regions. Growth of the Ts mutants was reduced to various extents at non-permissive temperatures. Since the metabolic stability of most Ts mutant Rpb3 proteins was markedly reduced at non-permissive temperature, we predict that these mutant Rpb3 proteins are defective in polymerase assembly or the mutant RNA polymerases containing mutant Rpb3 subunits are unstable. In accordance with this prediction, the Ts phenotype of all the mutants was suppressed to varying extents by over-expression of Rpb11, the pairing partner of Rpb3 in the core subassembly. We conclude that the majority of rpb3 mutations affect the assembly of Rpb3, even though their effects on subunit assembly vary depending on the location of the mutation considered. Received: 25 January 1999 / Accepted: 27 April 1999     

Isolation and characterization of temperature-sensitive mutations in the gene (rpb3 ) for subunit 3 of RNA polymerase II in the fission yeast Schizosaccharomyces pombe

Subunit 3 (Rpb3) of eukaryotic RNA polymerase II is a homologue of the α subunit of prokaryotic RNA polymerase, which plays a key role in subunit assembly of this complex enzyme by providing the contact surfaces for both β and β′ subunits. Previously we demonstrated that the Schizosaccharomyces pombe Rpb3 protein forms a core subassembly together with Rpb2 (the β homologue) and Rpb11 (the second α homologue) subunits, as in the case of the prokaryotic α₂β complex. In order to obtain further insight into the physiological role(s) of Rpb3, we subjected the S. pombe rpb3 gene to mutagenesis. A total of nine temperature-sensitive (Ts) and three cold-sensitive (Cs) S. pombe mutants have been isolated, each (with the exception of one double mutant) carrying a single mutation in the rpb3 gene in one of the four regions (A–D) that are conserved between the homologues of eukaryotic subunit 3. The three Cs mutations were all located in region A, in agreement with the central role of the corresponding region in the assembly of prokaryotic RNA polymerase; the Ts mutations, in contrast, were found in all four regions. Growth of the Ts mutants was reduced to various extents at non-permissive temperatures. Since the metabolic stability of most Ts mutant Rpb3 proteins was markedly reduced at non-permissive temperature, we predict that these mutant Rpb3 proteins are defective in polymerase assembly or the mutant RNA polymerases containing mutant Rpb3 subunits are unstable. In accordance with this prediction, the Ts phenotype of all the mutants was suppressed to varying extents by over-expression of Rpb11, the pairing partner of Rpb3 in the core subassembly. We conclude that the majority of rpb3 mutations affect the assembly of Rpb3, even though their effects on subunit assembly vary depending on the location of the mutation considered.     

Identification of the gene and the protein of RNA polymerase II subunit 9 (Rpb9) from the fission yeast Schizosaccharomyces pombe

Both the rpb9 gene and its cDNA encoding the subunit 9 of RNA polymerase II were cloned from the fission yeast Schizosaccharomyces pombe. From the DNA sequences, Rpb9 was predicted to consist of 113 amino acid residues with a molecular mass of 13 175. S. pombe Rpb9 is 47, 40 and 36% identical in amino acid sequence to the corresponding subunits from Saccharomyces cerevisiae, human and Drosophila melanogaster, respectively. Previously, we failed to detect Rpb9 in the purified RNA polymerase II by amino-terminal micro-sequencing of proteolytic fragments of subunits separated by SDS-gel electrophoresis. After Western blot analysis using antibodies raised against the protein product of the newly isolated rpb9 gene, we found that the purified RNA polymerase II contains Rpb9.     

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.     

Mapping of Rpb3 and Rpb5 contact sites on two large subunits, Rpb1 and Rpb2, of the RNA polymerase II from fission yeast

[Rpb1 and Rpb2] Mapping of the contact sites␣on two large subunits of the fission yeast Schizosaccharomyces pombe RNA polymerase II with two small subunits, Rpb3 and Rpb5, was carried out using the two-hybrid screening system in the budding yeast Saccharomyces cerevisiae. Rpb5 was found to interact with any fragment of Rpb1 that contained the region H, which is conserved among the subunit 1 homologues of all RNA polymerases, including the β' subunit of prokaryotic RNA polymerases. In agreement with the fact that Rpb5 is shared among all three forms of eukaryotic RNA polymerases, the region H of RNA polymerase I subunit 1 (Rpa190) was also found to interact with Rpb5. On the other hand, two-hybrid screening of Rpb2 fragments from RNA polymerase II indicated the presence of an Rpb3 contact site in the region H which is conserved among the subunit 2 homologues of all RNA polymerases, including the β subunit of prokaryotic RNA polymerases. Possible functions of the regions H in the subunits 1 and 2 are discussed. Received: 10 December 1997 / Accepted: 14 April 1998     

Crystal structure of the C17/25 subcomplex from Schizosaccharomyces pombe RNA polymerase III

Eukaryotic RNA polymerase III (Pol III) is a multisubunit enzyme responsible for transcribing tRNA, 5S rRNA, and several small RNAs. Of the 17 subunits in Pol III, the C17 (Rpc17) and C25 (Rpc25) subunits form a stable subcomplex that protrudes from the core polymerase. In this study, we determined the crystal structure of the C17/25 subcomplex from Schizosaccharomyces pombe. The subcomplex adopts an elongated shape, and each subunit has two domains. The two subunits in the subcomplex are tightly packed and extensively interact, with a contact area of 2080 Ų. The overall conformation of S. pombe C17/25 is considerably different from the previously reported structure of C17/25 from Saccharomyces cerevisiae, with respect to the position of the C17 HRDC domain, a helix bundle essential for cell viability. In contrast, the S. pombe C17/25 structure is quite similar to those of the Pol II and archaeal counterparts, Rpb4/7 and RpoE/F, respectively, despite the low sequence similarity. A phylogenetic comparison of the C17 subunits among eukaryotes revealed that they can be classified into three groups, according to the length of the interdomain linker. S. pombe C17, as well as Rpb4 and RpoF, belongs to the largest group, with the short linker. On the other hand, S. cerevisiae C17 belongs to the smallest group, with the long linker, which probably enables the subcomplex to assume the alternative conformation.     

Rescue of the fission yeast snRNA synthesis mutant snm1 by overexpression of the double-strand-specific Pac1 ribonuclease

The Schizosaccharomyces pombe temperature-sensitive mutant snm1 maintains reduced steady-state quantities of the spliceosomal small nuclear RNAs (snRNAs) and the RNA subunit of the tRNA processing enzyme RNase P. We report here the isolation of the pac1 ⁺ gene as a multi-copy suppressor of snm1. The pac1 ⁺ gene was previously identified as a suppressor of the ran1 mutant and by its ability to cause sterility when overexpressed. The pac1 ⁺ gene encodes a double-strand-specific ribonuclease that is similar to RNase III, an RNA processing and turnover enzyme in Escherichia coli. To investigate the essential structural features of the Pac1 RNase, we altered the pac1 ⁺ gene by deletion and point mutation and tested the mutant constructs for their ability to complement the snm1 and ran1 mutants and to cause sterility. These experiments identified four essential amino acids in the Pac1 sequence: glycine 178, glutamic acid 251, and valines 346 and 347. These amino acids are conserved in all RNase III-like proteins. The glycine and glutamic acid residues were previously identified as essential for E. coli RNase III activity. The valines are conserved in an element found in a family of double-stranded RNA binding proteins. Our results support the hypothesis that the Pac1 RNase is an RNase III homolog and suggest a role for the Pac1 RNase in snRNA metabolism.