Structural and functional homology between the RNAP(I) subunits A14/A43 and the archaeal RNAP subunits E/F

In the archaeal RNA polymerase and the eukaryotic RNA polymerase II, two subunits (E/F and RPB4/RPB7, respectively) form a heterodimer that reversibly associates with the core of the enzyme. Recently it has emerged that this heterodimer also has a counterpart in the other eukaryotic RNA polymerases: in particular two subunits of RNA polymerase I (A14 and A43) display genetic and biochemical characteristics that are similar to those of the RPB4 and RPB7 subunits, despite the fact that only A43 shows some sequence homology to RPB7. We demonstrate that the sequence of A14 strongly suggests the presence of a HRDC domain, a motif that is found at the C-terminus of a number of helicases and RNases. The same motif is also seen in the structure of the F subunit, suggesting a structural link between A14 and the RPB4/C17/subunit F family, even in the absence of direct sequence homology. We show that it is possible to co-express and co-purify large amounts of the recombinant A14/A43 heterodimer, indicating a tight and specific interaction between the two subunits. To shed light on the function of the heterodimer, we performed gel mobility shift assays and showed that the A14/A43 heterodimer binds single-stranded RNA in a similar way to the archaeal E/F complex.     

Duplication and paralog sorting of RPB2 and RPB1 genes in core eudicots

RPB1 and RPB2, which encode the largest and second largest subunits of RNA polymerase II, respectively, are essential single copy genes in fungi, animals and most plants. Two paralogs of the RPB2 gene have been found in some groups of angioperms [Oxelman, B., Yoshikawa, N., McConaughy, B.L., Luo, J., Denton, A.L., Hall, B.D., 2004. RPB2 gene phylogeny in flowering plants, with particular emphasis on asterids. Mol. Phylogenet. Evol. 32, 462-479]. Here, we report the results of experiments designed to identify the evolutionary origin of the RPB2 duplicate copies. Through careful sampling and phylogenetic analysis, we were able to construct the RPB2 gene tree in angiosperms and infer the phylogenetic positions of the gene duplication and gene loss events that occurred. Our study shows that an RPB2 gene duplication occurred early in core eudicot evolution, at or near the time of the Buxaceae/Trochodendraceae divergence. Subsequently, multiple gene duplication and paralog sorting events happened independently in different core eudicot taxa. Differential expression of the two RPB2 gene paralogs may explain the preservation of both paralogs in the asterids. One gene (RPB2-i) accounts for most of the RPB2 mRNA made in the flower organs while the other gene (RPB2-d) is predominantly used in the vegetative tissues. We also found two paralogs of the RPB1 gene in some core eudicot species. The RPB1 gene duplication occurred before core eudicot divergence, around the time of RPB2 gene duplication. Several independent RPB1 paralog sorting events happened in different core eudicot taxa; their occurrence was independent of the RPB2 paralog sorting events. Our results suggest that a polyploidization event happened at or near the time of the Buxaceae/Trochodendraceae divergence. We propose that this polyploidization and the partial diploidization processes thereafter may have been the driving force of core eudicot radiation.     

Yeast RNA polymerase II subunit RPB9 is essential for growth at temperature extremes

The Saccharomyces cerevisiae RNA polymerase II subunit gene RPB9 was isolated and sequenced. RPB9 is a single copy gene on chromosome VII. The RPB9 sequence predicts a protein of 122 amino acids with a molecular mass of 14,200 Da. The yeast RPB9 subunit is similar in size and sequence to a protein encoded by DNA adjacent to the suppressor of the Hairy Wing gene in Drosophila melanogaster. Deletion of the RPB9 gene produced cells that were heat- and cold-sensitive. The RPB9 subunit, like the previously described RNA polymerase II subunit RPB4, is not essential for synthesis of mRNA, but is required for normal cell growth over a wide temperature range.     

RNA polymerase II subunit RPB4 is essential for high- and low-temperature yeast cell growth.

RPB4 encodes the fourth-largest RNA polymerase II subunit in Saccharomyces cerevisiae. The RPB4 gene was cloned and sequenced, and its identity was confirmed by amino acid sequence analysis of tryptic peptides from the purified subunit. The RPB4 DNA sequence predicted a protein of 221 amino acids with a molecular mass of 25,414 daltons. The central 100 amino acids of the RPB4 protein were found to be similar to a segment of the major sigma subunit in Escherichia coli RNA polymerase. Deletion of RPB4 produced cells that were heat and cold sensitive but could grow, albeit slowly, at intermediate temperatures. RNA polymerase II lacking the RPB4 subunit exhibited markedly reduced activity in crude extracts in vitro. The RPB4 subunit, although not essential for mRNA synthesis or enzyme assembly, was essential for normal levels of RNA polymerase II activity and indispensable for cell viability over a wide temperature range.     

Arabidopsis thaliana RNA polymerase II subunits related to yeast and human RPB5

Arabidopsis thaliana contains at least four genes that are predicted to encode polypeptides related to the RPB5 subunit found in yeast and human RNA polymerase II. This subunit has been shown to be the largest subunit common to yeast RNA polymerases I, II, and III (RPABC27). More than one of these genes is expressed in Arabidopsis suspension culture cells, but only one of the encoded polypeptides is found in purified RNA polymerases II and III. This polypeptide has a predicted pI of 9.6, matches 14 of 16 amino acids in the amino terminus of cauliflower RPB5 that was microsequenced, and shows 42 and 53% amino acid sequence identity with the yeast and human RPB5 subunits, respectively.     

Distinct regions of RPB11 are required for heterodimerization with RPB3 in human and yeast RNA polymerase II

In Saccharomyces cerevisiae, RNA polymerase II assembly is probably initiated by the formation of the RPB3–RPB11 heterodimer. RPB3 is encoded by a single copy gene in the yeast, mouse and human genomes. The RPB11 gene is also unique in yeast and mouse, but in humans a gene family has been identified that potentially encodes several RPB11 proteins differing mainly in their C-terminal regions. We compared the abilities of both yeast and human proteins to heterodimerize. We show that the yeast RPB3/RPB11 heterodimer critically depends on the presence of the C-terminal region of RPB11. In contrast, the human heterodimer tolerates significant changes in RPB11 C-terminus, allowing two human RPB11 variants to heterodimerize with the same efficiency with RPB3. In keeping with this observation, the interactions between the conserved N-terminal ‘α-motifs’ is much more important for heterodimerization of the human subunits than for those in yeast. These data indicate that the heterodimerization interfaces have been modified during the course of evolution to allow a recent diversification of the human RPB11 subunits that remains compatible with heterodimerization with RPB3.     

The Rpb4 Subunit of Fission Yeast Schizosaccharomyces pombe RNA Polymerase II Is Essential for Cell Viability and Similar in Structure to the Corresponding Subunits of Higher Eukaryotes

Both the gene and the cDNA encoding the Rpb4 subunit of RNA polymerase II were cloned from the fission yeast Schizosaccharomyces pombe. The cDNA sequence indicates that Rpb4 consists of 135 amino acid residues with a molecular weight of 15,362. As in the case of the corresponding subunits from higher eukaryotes such as humans and the plant Arabidopsis thaliana, Rpb4 is smaller than RPB4 from the budding yeast Saccharomyces cerevisiae and lacks several segments, which are present in the S. cerevisiae RPB4 subunit, including the highly charged sequence in the central portion. The RPB4 subunit of S. cerevisiae is not essential for normal cell growth but is required for cell viability under stress conditions. In contrast, S. pombe Rpb4 was found to be essential even under normal growth conditions. The fraction of RNA polymerase II containing RPB4 in exponentially growing cells of S. cerevisiae is about 20%, but S. pombe RNA polymerase II contains the stoichiometric amount of Rpb4 even at the exponential growth phase. In contrast to the RPB4 homologues from higher eukaryotes, however, S. pombe Rpb4 formed stable hybrid heterodimers with S. cerevisiae RPB7, suggesting that S. pombe Rpb4 is similar, in its structure and essential role in cell viability, to the corresponding subunits from higher eukaryotes. However, S. pombe Rpb4 is closer in certain molecular functions to S. cerevisiae RPB4 than the eukaryotic RPB4 homologues.     

Lower level relationships in the mushroom genus Cortinarius (Basidiomycota, Agaricales): a comparison of RPB1, RPB2, and ITS phylogenies

We sampled and analyzed approximately 2900bp across the three loci from 54 taxa belonging to a taxonomically difficult group of Cortinarius subgenus Phlegmacium. The combined analyses of ITS and variable regions of RPB1 and RPB2 greatly increase the resolution and nodal support for phylogenies of these closely related species belonging to clades that until now have proven very difficult to resolve with the ribosomal markers, nLSU and ITS. We present the first study of the utility of variable regions of the genes encoding the two largest subunits of RNA polymerase II (RPB1 and RPB2) for inferring the phylogeny of mushroom-forming fungi in combination with and compared to the widely used ribosomal marker ITS. The studied region of RPB1 contains an intron of the size and variability of ITS along with many variable positions in coding regions. Though almost entirely coding, the studied region of RPB2 is more variable than ITS. Both RNA polymerase II genes were alignable across all taxa. Our results indicate that several sections of Cortinarius need redefinition, and that several taxa treated at subspecific and varietal level should be treated at specific level. We suggest a new section for the two species, C. caesiocortinatus and C. prasinocyaneus, which constitute a well-supported separate lineage. We speculate that sequence information from RNA polymerase II genes have the potential for resolving phylogenetic problems at several levels of the diverse and taxonomically very challenging genus Cortinarius.