Functional substitution of an essential yeast RNA polymerase subunit by a highly conserved mammalian counterpart

Intrinsically disordered proteins in the nucleus of human cells

Intrinsically disordered proteins are known to perform a variety of important functions such as macromolecular recognition, promiscuous binding, and signaling. They are crucial players in various cellular pathway and processes, where they often have key regulatory roles. Among vital cellular processes intimately linked to the intrinsically disordered proteins is transcription, an intricate biological performance predominantly developing inside the cell nucleus. With this work, we gathered information about proteins that exist in various compartments and sub-nuclear bodies of the nucleus of the human cells, with the goal of identifying which ones are highly disordered and which functions are ascribed to the disordered nuclear proteins.

Interaction with general transcription factor IIF (TFIIF) is required for the suppression of activated transcription by RPB5-mediating protein (RMP)

RMP was reported to regulate transcription via competing with HBx to bind the general transcription factor IIB (TFIIB) and interacting with RPB5 subunit of RNA polymerase II as a corepressor of transcription regulator. However, our present research uncovered that RMP also regulates the transcription through interaction with the general transcription factors IIF (TFIIF), which assemble in the preinitiation complex and function in both transcription initiation and elongation. With in vitro pull-down assay and Far-Western analysis, we demonstrated that RMP could bind with bacterially expressed recombinant RAP30 and RAP74 of TFIIF subunits. In the immunoprecipitation assay in COS1 cells cotransfected with FLAG-tagged RMP or its mutants, GST-fused RAP30 and RAP74 were co-immunoprecipitated with RMP in approximately equal molar ratio, which suggests that RAP30 and RAP74 interact with RMP as a TFIIF complex. Interestingly both RAP30 and RAP74 interact with the same domain (D5) of the C-terminal RMP of 118-amino-acid residuals which overlaps with its TFIIB-binding domain. Internal deletion of D5 region of RMP abolished its binding ability with both subunits of TFIIF, while D5 domain alone was sufficient to interact with TFIIF subunits. The result of luciferase assay showed that overexpression of RMP, but not the mutant RMP lacking D5 region, suppressed the transcription activated by Gal-VP16, suggesting that interaction with TFIIF is required for RMP to suppress the activated transcription. The interaction between RMP and TFIIF may be an additional passway for RMP to regulate the transcription, or alternatively TFIIF may cooperate with RPB5 and TFIIB for the corepressor function of RMP.

Reconstitution of transcription from the human U6 small nuclear RNA promoter with eight recombinant polypeptides and a partially purified RNA polymerase III complex

The human U6 small nuclear (sn) RNA core promoter consists of a proximal sequence element, which recruits the multisubunit factor SNAP(c), and a TATA box, which recruits the TATA box-binding protein, TBP. In addition to SNAP(c) and TBP, transcription from the human U6 promoter requires two well defined factors. The first is hB", a human homologue of the B" subunit of yeast TFIIIB generally required for transcription of RNA polymerase III genes, and the second is hBRFU, one of two human homologues of the yeast TFIIIB subunit BRF specifically required for transcription of U6-type RNA polymerase III promoters. Here, we have partially purified and characterized a RNA polymerase III complex that can direct transcription from the human U6 promoter when combined with recombinant SNAP(c), recombinant TBP, recombinant hB", and recombinant hBRFU. These results open the way to reconstitution of U6 transcription from entirely defined components.

Isolation and characterisation of a chick cDNA encoding the RNA polymerase common subunit RPB6

The RPB6 cDNA of chicken, encoding one of the small subunits common to all three nuclear DNA-dependent RNA polymerases, has been isolated from an expression cDNA library by screening with a differential display derived probe, representing a gene shown to be highly up-regulated in early heart development. The nucleotide sequence of the cDNA isolated predicts a protein sequence of 127 amino acids. This sequence shares 124 amino acids (98% homology) with the human RNA polymerase II subunit 14.4 kDa (RPB6) and hamster hRPB6 and 123 amino acids (97% homology) with Rattus norvegicus RNA polymerase II subunit RPB6. Other conserved motifs in this protein and potential functions of RPB6 are discussed.

RNA polymerase II in Cajal bodies of amphibian oocytes

Cajal bodies (coiled bodies) are nuclear organelles that contain a variety of components required for transcription and processing of RNA. Cajal bodies in amphibian oocytes are stained by mAb H14, which recognizes the carboxy-terminal domain (CTD) of the largest subunit of RNA polymerase II when the heptapeptide repeat is phosphorylated on serine-5. Oocytes were treated with the transcription inhibitor 5, 6-dichloro-1-beta-d-ribofuranosylbenzimidazole (DRB), which prevents phosphorylation of the CTD. Cajal bodies from oocytes that had been treated for 2-3 h with DRB no longer stained with mAb H14, but staining reappeared when the inhibitor was washed out. Epitope-tagged transcripts of two small subunits of polymerase II, RPB6 and RPB9, were injected into the cytoplasm of Xenopus and Triturus oocytes. Newly translated RPB6 and RPB9 were specifically targeted to Cajal bodies within 4 h, and Cajal bodies remained the site of highest concentration of tagged protein during the next 2 days. These data suggest that polymerase subunits pass through the Cajal bodies with a transit time no greater than a few hours. We discuss the possibility that Cajal bodies are sites of assembly or modification of the transcription machinery of the nucleus.

Functional conservation of RNA polymerase II in fission and budding yeasts

The complementary DNAs of the 12 subunits of fission yeast (Schizosaccharomyces pombe) RNA polymerase II were expressed from strong promoters in Saccharomyces cerevisiae and tested for heterospecific complementation by monitoring their ability to replace in vivo the null mutants of the corresponding host genes. Rpb1 and Rpb2, the two largest subunits and Rpb8, a small subunit shared by all three polymerases, failed to support growth in S. cerevisiae. The remaining nine subunits were all proficient for heterospecific complementation and led in most cases to a wild-type level of growth. The two alpha-like subunits (Rpb3 and Rpb11), however, did not support growth at high (37 degrees C) or low (25 degrees C) temperatures. In the case of Rpb3, growth was restored by increasing the gene dosage of the host Rpb11 or Rpb10 subunits, confirming previous evidence of a close genetic interaction between these three subunits.

The RNA polymerase II core subunit 11 interacts with keratin 19, a component of the intermediate filament proteins

We have previously cloned the human RNA polymerase II subunit 11, as a doxorubicin sensitive gene product. We suggested multiple tasks for this subunit, including structural and regulatory roles. With the aim to clarify the human RNA polymerase II subunit 11 function, we have identified its interacting protein partners using the yeast two-hybrid system. Here, we show that human RNA polymerase II subunit 11 specifically binds keratin 19, a component of the intermediate filament protein family, which is expressed in a tissue and differentiation-specific manner. In particular, keratin 19 is a part of the nuclear matrix intermediate filaments. We provide evidence that human RNA polymerase II subunit 11 interacts with keratin 19 via its N-terminal alpha motif, the same motif necessary for its interaction with the human RNA polymerase II core subunit 3. We found that keratin 19 contains two putative leucine zipper domains sharing peculiar homology with the alpha motif of human RNA polymerase II subunit 3. Finally, we demonstrate that keratin 19 can compete for binding human RNA polymerase II subunit 11/human RNA polymerase II subunit 3 in vitro, suggesting a possible regulatory role for this molecule in RNA polymerase II assembly/activity.

A serine residue in the N-terminal acidic region of rat RPB6, one of the common subunits of RNA polymerases, is exclusively phosphorylated by casein kinase II in vitro

RPB6 is one of the common subunits of all eukaryotic RNA polymerases and is indispensable for the enzyme function. Here, we isolated a rat cDNA encoding RPB6. It contained 127 amino acid (a.a.) residues. From alignment of RPB6 homologues of various eukaryotes, we defined two conserved regions, i.e. an N-terminal acidic region and a C-terminal core. In this study, we investigated in vitro phosphorylation of rat RPB6 by casein kinase II (CKII), a pleiotropic regulator of numerous cellular proteins. Three putative CKII-phosphorylated a.a. within rat RPB6 were assigned. We found that serines were phosphorylated by CKII in vitro. Mutagenesis studies provided evidence that a serine at a.a. position 2 was exclusively phosphorylated. Finally, an RPB6-engaged in-gel kinase assay clarified that CKII was a prominent protein kinase in rat liver nuclear extract that phosphorylates RPB6. Therefore, RPB6 was implied to be phosphorylated by CKII in the nucleus. We postulate that the N-terminal acidic region of the RPB6 subunit has some phosphorylation-coupled regulatory functions.

Expression and purification of recombinant hRPABC25, hRPABC17, and hRPABC14.4, three essential subunits of human RNA polymerases I, II, and III

Transcription of eukaryotic genes is performed by RNA polymerases I, II, and III, which synthesize ribosomal, messenger, and transfer RNAs, respectively. Eukaryotic RNA polymerases are large macromolecular complexes composed of multiple subunits. Among these subunits, five are shared by all RNA polymerases and are essential for cell growth and viability. Remarkably, the human common subunits are structurally conserved and functionally interchangeable with their yeast homologues and are believed to play an important role in the assembly of the three transcription complexes. To understand the structure and function of human RNA polymerases, we overexpressed the common subunits hRPABC25, hRPABC17, and hRPABC14.4 as hexahistidine fusions in Escherichia coli. The recombinant proteins were purified using metal-chelate affinity chromatography on Ni-NTA resin and gel filtration. Depending on the subunit, the yield was 5-17 mg of purified recombinant protein per liter of culture medium. The purified proteins were of high quality and sufficient quantity for structural studies, as demonstrated by the successful crystallization of hRPABC17 and hRPABC14.4. The expression and purification of the common subunits hRPABC25, hRPABC17, and hRPABC14. 4 will make possible their structural analysis with X-ray crystallography and nuclear magnetic resonance, providing important insights into the structure and function of the three human RNA polymerases.

Levels of expression of hRPB11, a core subassembly subunit of human RNA polymerase II, affect doxorubicin sensitivity and cellular differentiation

We have previously shown that the human RNA polymerase II subunit 11 (hRPB11) is among the proteins specifically downregulated upon Doxorubicin (Dox) treatment of human cancer cell lines, and that Dox resistant clones derived upon drug selection express about 20% of the protein present in the original parental cell line. Given the prominent role that this subunit appears to have in eukaryotic cells, and the fact that its deletion causes lethality in yeast, we wanted to test the effect of the reintroduction of parental cell line levels of this subunit in Dox resistant colon cancer cells (LoVoDX). Stable transfectants of LoVoDX expressing parental (LoVoH) levels of hRPB11 showed a reduced sensitivity to the drug without changing the response of these cells to other chemotherapeutic agents, confirming a specific inverse correlation between cellular Dox sensitivity anti-hRPB11 levels of expression. In addition we show here that the levels of expression of this same RNA polymerase II subunit directly affect cellular differentiation, reducing the rate of cell proliferation, clonogenicity and increasing the expression of E-cadherin, a marker of epithelial cell differentiation. As expected from cells with these characteristics, upon in vivo administration of these clones in nude mice, we detected a significant reduction in the size and time of appearance of the primary tumors and overall metastatic capability. Finally, the role played by hRPB11 in regulating the transcription of specific genes is underlined by transient transfection experiments that show transactivation of the E-cadherin promoter by this protein.

Two small subunits in Arabidopsis RNA polymerase II are related to yeast RPB4 and RPB7 and interact with one another

An Arabidopsis cDNA (AtRPB15.9) that encoded a protein related to the RPB4 subunit in yeast RNA polymerase II was cloned. The predicted molecular mass of 15.9 kDa for the AtRPB15.9 protein was significantly smaller than 25 kDa for yeast RBP4. In SDS-PAGE, AtRPB15.9 migrated as the seventh or eighth largest subunit (i.e. apparent molecular mass of 14-15 kDa) in Arabidopsis RNA polymerase II, whereas RPB4 migrates as the fourth largest subunit (i.e. apparent molecular mass of 32 kDa) in yeast RNA polymerase II. Unlike yeast RPB4 and RPB7, which dissociate from RNA polymerase II under mildly denaturing conditions, plant subunits related to RPB4 and RPB7 are more stably associated with the enzyme. Recombinant AtRPB15.9 formed stable complexes with AtRPB19.5 (i.e. a subunit related to yeast RPB7) in vitro as did recombinant yeast RPB4 and RPB7 subunits. Stable heterodimers were also formed between AtRPB15. 9 and yeast RPB7 and between yeast RPB4 and AtRPB19.5.

Interactions between the human RNA polymerase II subunits

As an initial approach to characterizing the molecular structure of the human RNA polymerase II (hRPB), we systematically investigated the protein-protein contacts that the subunits of this enzyme may establish with each other. To this end, we applied a glutathione S-transferase-pulldown assay to extracts from Sf9 insect cells, which were coinfected with all possible combinations of recombinant baculoviruses expressing hRPB subunits, either as untagged polypeptides or as glutathione S-transferase fusion proteins. This is the first comprehensive study of interactions between eukaryotic RNA polymerase subunits; among the 116 combinations of hRPB subunits tested, 56 showed significant to strong interactions, whereas 60 were negative. Within the intricate network of interactions, subunits hRPB3 and hRPB5 play a central role in polymerase organization. These subunits, which are able to homodimerize and to interact, may constitute the nucleation center for polymerase assembly, by providing a large interface to most of the other subunits.

Mouse RNA polymerase I 16-kDa subunit able to associate with 40-kDa subunit is a homolog of yeast AC19 subunit of RNA polymerases I and III

We have previously isolated a mouse RPA40 (mRPA40) cDNA encoding the 40-kDa subunit of mouse RNA polymerase I and demonstrated that mRPA40 is a mouse homolog of the yeast subunit AC40, which is a subunit of RNA polymerases I and III, having a limited homology to bacterial RNA polymerase subunit alpha (Song, C. Z., Hanada, K., Yano, K., Maeda, Y., Yamamoto, K., and Muramatsu, M. (1994) J. Biol. Chem. 269, 26976-26981). In an extension of the study we have now cloned mouse RPA16 (mRPA16) cDNA encoding the 16-kDa subunit of mouse RNA polymerase I by a yeast two-hybrid system using mRPA40 as a bait. The deduced amino acid sequence shows 45% identity to the yeast subunit AC19 of RNA polymerases I and III, known to associate with AC40, and a local similarity to bacterial alpha subunit. We have shown that mRPA40 mutants failed to interact with mRPA16 and that neither mRPA16 nor mRPA40 can interact by itself in the yeast two-hybrid system. These results suggest that higher eukaryotic RNA polymerase I conserves two distinct alpha-related subunits that function to associate with each other in an early stage of RNA polymerase I assembly.

Mutations in an Abf1p binding site in the promoter of yeast RPO26 shift the transcription start sites and reduce the level of RPO26 mRNA

A binding site for the transcription factor Abf1p was identified as an important promoter element of the gene that encodes Rpo26, a subunit common to all three yeast nuclear RNA polymerases (RNAP). Mutations in the Abf1p binding site were identified among a pool of rpo26 mutant alleles that confer synthetic lethality in combination with a temperature-sensitive mutation (rpo21-4) in the gene that encodes the largest subunit of RNAPII (Rpo21p). In the presence of the wild-type allele of RPO21 these rpo26 promoter mutations confer a cold-sensitive growth defect. Electrophoretic mobility-shift assays using purified Abf1p demonstrated that Abf1p binds to the RPO26 promoter and that the promoter mutations abolish this binding in vitro. Quantitation of the amount of RPO26 mRNA showed that mutations in the Abf1p binding site reduce the expression of RPO26 by approximately 60%. Mutations that affect Abf1p binding also result in a shift of the RPO26 transcriptional start sites to positions further upstream than normal. These results suggest that binding of the Abf1p transcription factor to the RPO26 promoter is important not only in establishing the level of transcription for this gene, but also in positioning the initiation sites of transcription.

RNA polymerase I associated factor 53 binds to the nucleolar transcription factor UBF and functions in specific rDNA transcription

Mouse RNA polymerase I (Pol I) has, besides its 11 bona fide subunits, three polymerase associated factors, termed PAF53, 51 and 49 with respect to the size of each molecule. In order to analyze the function of PAFs, cDNA encoding PAF53 was isolated using an oligonucleotide probe derived from an oligopeptide sequence. The cDNA of PAF53 predicts a polypeptide of 434 amino acids with a sequence similarity to yeast Pol 1 49 kDa subunit. Anti-PAF53 antibody does not block the random transcription activity of Pol I, but blocks specific transcription from mouse ribosomal RNA promoter, demonstrating the requirement of PAF53 in the accurate initiation of Pol I transcription. Moreover, PAF53 interacted with mouse UBF in vitro, as revealed by Far-Western blotting and GST pull down assays. These results, together with the accumulation of PAF53 in the nucleolus of growing cells, suggest that PAF53 is involved in the formation of the initiation complex at the promoter by mediating the interaction between Pol I and UBF for the active rRNA synthesis.

Cloning of a novel human RNA polymerase II subunit downregulated by doxorubicin: new potential mechanisms of drug related toxicity

Using the differential display PCR method, we have isolated an mRNA downregulated in doxorubicin resistant human cell lines. The full length cDNA clone was identified as the human homologue of yeast RPB11 subunit of RNA polymerase II. Northern blot analysis of normal tissues detected a particularly high expression of RPB11 mRNA in heart and skeletal muscle. Reduction of this mRNA expression was observed in all the cell lines tested after drug treatment and was paralleled by a similar decrease of the protein levels. These findings suggest that doxorubicin may exert in vivo specific inhibitory effects on a major component of the transcription machinery.