Rpb4, a subunit of RNA polymerase II, enables the enzyme to transcribe at temperature extremes in vitro

Rpb4 is a subunit of Saccharomyces cerevisiae RNA polymerase II (Pol II). It associates with the polymerase preferentially in stationary phase and is essential for some stress responses. Using the promoter-independent initiation and chain elongation assay, we monitored Pol II enzymatic activity in cell extracts. We show here that Rpb4 is required for the polymerase activity at temperature extremes (10 and 35 degreesC). In contrast, at moderate temperature (23 degreesC) Pol II activity is independent of Rpb4. These results are consistent with the role previously attributed to Rpb4 as a subunit whose association with Pol II helps Pol II to transcribe during extreme temperatures. The enzymatic inactivation of Pol II lacking Rpb4 at the nonoptimal temperature was prevented by the addition of recombinant Rpb4 produced in Escherichia coli prior to the in vitro reaction assay. This finding suggests that modification of Rpb4 is not required for its functional association with the other Pol II subunits. Sucrose gradient and immunoprecipitation experiments demonstrated that Rpb4 is present in the cell in excess over the Pol II complex during all growth phases. Nevertheless, the rescue of Pol II activity at the nonoptimal temperature by Rpb4 is possible only when cell extracts are obtained from postlogarithmic cells, not from logarithmically growing cells. This result suggests that Pol II molecules should be modified in order to recruit Rpb4; the portion of the modified Pol II molecules is small during logarithmic phase and becomes predominant in stationary phase.     

Gene organization and protein sequence of the small subunits of Schizosaccharomyces pombe RNA polymerase II

RNA polymerase II purified from the fission yeast Schizosaccharomyces pombe contains 10 different species of polypeptides. Previously, we cloned and sequenced both cDNA and the genes encoding the four large subunits, Rpb1, Rpb2, Rpb3 and Rpb5. Later, other groups isolated the genes for Rpb6 and Rpb12 and cDNA for Rpb10. Here, we cloned both cDNA and the genes encoding four small subunits, Rpb7, Rpb8, Rpb10 and Rpb11. These genes were found to encode Rpb7, Rpb8, Rpb10 and Rpb11 consisting of 172 (19,103 Da), 125 (14,300 Da), 71 (8276 Da) and 123 (14,127 Da) amino acid residues, respectively. All these four subunits are homologous to the corresponding subunits of Saccharomyces cerevisiae RNA polymerase II. The rpb7 gene contains one intron, whereas the rpb8, rpb10 and rpb11 genes contain two introns. Taken altogether, the gene organization and the predicted protein sequence have been determined for all 10 subunits of the S. pombe RNA polymerase II.     

Rpb3, stoichiometry and sequence determinants of the assembly into yeast RNA polymerase II in vivo

Stoichiometry of the third largest subunit (Rpb3) of the yeast RNA polymerase II is a subject of continuing controversy. In this work we utilized immunoaffinity and nickel-chelate chromatographic techniques to isolate the RNA polymerase II species assembled in vivo in the presence of the His6-tagged and untagged Rpb3. The distribution pattern of tagged and untagged subunits among the RNA polymerase II molecules is consistent with a stoichiometry of 1 Rpb3 polypeptide per molecule of RNA polymerase. Deletion of either alpha-homology region (amino acids 29-55 or 226-267) from the Rpb3 sequence abolished its ability to assemble into RNA polymerase II in vivo.     

Sequence divergence of the RNA polymerase shared subunit ABC14.5 (Rpb8) selectively affects RNA polymerase III assembly in Saccharomyces cerevisiae

ABC14.5 (Rpb8) is a eukaryotic subunit common to all three nuclear RNA polymerases. In Saccharomyces cerevisiae, ABC14.5 (Rpb8) is essential for cell viability, however its function remains unknown. We have cloned and characterised the Schizosaccharomyces pombe rpb8(+) cDNA. We found that S.pombe rpb8, unlike the similarly diverged human orthologue, cannot substitute for S.cerevisiae ABC14. 5 in vivo. To obtain information on the function of this RNA polymerase shared subunit we have used S.pombe rpb8 as a naturally altered molecule in heterologous expression assays in S.cerevisiae. Amino acid residue differences within the 67 N-terminal residues contribute to the functional distinction of the two yeast orthologues in S.cerevisiae. Overexpression of the S.cerevisiae largest subunit of RNA polymerase III C160 (Rpc1) allows S.pombe rpb8 to functionally replace ABC14.5 in S.cerevisiae, suggesting a specific genetic interaction between the S.cerevisiae ABC14.5 (Rpb8) and C160 subunits. We provide further molecular and biochemical evidence showing that the heterologously expressed S.pombe rpb8 molecule selectively affects RNApolymerase III but not RNA polymerase I complex assembly. We also report the identification of a S.cerevisiae ABC14.5-G120D mutant which affects RNA polymerase III.     

The large subunit of RNA polymerase II is a substrate of the Rsp5 ubiquitin-protein ligase

The E3 ubiquitin-protein ligases play an important role in controlling substrate specificity of the ubiquitin proteolysis system. A biochemical approach was taken to identify substrates of Rsp5, an essential hect (homologous to E6-AP carboxyl terminus) E3 of Saccharomyces cerevisiae. We show here that Rsp5 binds and ubiquitinates the largest subunit of RNA polymerase II (Rpb1) in vitro. Stable complex formation between Rsp5 and Rpb1 was also detected in yeast cell extracts, and repression of RSP5 expression in vivo led to an elevated steady-state level of Rpb1. The amino-terminal domain of Rsp5 mediates binding to Rpb1, while the carboxyl-terminal domain of Rpb1, containing the heptapeptide repeats characteristic of polymerase II, is necessary and sufficient for binding to Rsp5. Fusion of the Rpb1 carboxyl-terminal domain to another protein also causes that protein to be ubiquitinated by Rsp5. These findings indicate that Rsp5 targets at least a subset of cellular Rpb1 molecules for ubiquitin-dependent degradation and may therefore play a role in regulating polymerase II activities. In addition, the results support a model for hect E3 function in which the amino-terminal domain mediates substrate binding, while the carboxyl-terminal hect domain catalyzes ubiquitination of bound substrates.