Nuclear particles containing RNA polymerase III complexes associated with the junctional plaque protein plakophilin 2

Plakophilin 2, a member of the arm-repeat protein family, is a dual location protein that occurs both in the cytoplasmic plaques of desmosomes as an architectural component and in an extractable form in the nucleoplasm. Here we report the existence of two nuclear particles containing plakophilin 2 and the largest subunit of RNA polymerase (pol) III (RPC155), both of which colocalize and are coimmunoselected with other pol III subunits and with the transcription factor TFIIIB. We also show that plakophilin 2 is present in the pol III holoenzyme, but not the core complex, and that it binds specifically to RPC155 in vitro. We propose the existence of diverse nuclear particles in which proteins known as plaque proteins of intercellular junctions are complexed with specific nuclear proteins.

Determinants of RNA polymerase alpha subunit for interaction with beta, beta', and sigma subunits: hydroxyl-radical protein footprinting.

Escherichia coli RNA polymerase (RNAP) alpha subunit serves as the initiator for RNAP assembly, which proceeds according to the pathway 2 alpha-->alpha 2-->alpha 2 beta-->alpha 2 beta beta'-->alpha 2 beta beta' sigma. In this work, we have used hydroxyl-radical protein footprinting to define determinants of alpha for interaction with beta, beta', and sigma. Our results indicate that amino acids 30-75 of alpha are protected from hydroxyl-radical-mediated proteolysis upon interaction with beta (i.e., in alpha 2 beta, alpha 2 beta beta', and alpha 2 beta beta' sigma), and amino acids 175-210 of alpha are protected from hydroxyl-radical-mediated proteolysis upon interaction with beta' (i.e., in alpha 2 beta beta' and alpha 2 beta beta' sigma). The protected regions are conserved in the alpha homologs of prokaryotic, eukaryotic, archaeal, and chloroplast RNAPs and contain sites of substitutions that affect RNAP assembly. We conclude that the protected regions define determinants of alpha for direct functional interaction with beta and beta'. The observed maximal magnitude of protection upon interaction with beta and the observed maximal magnitude of protection upon interaction with beta' both correspond to the expected value for complete protection of one of the two alpha protomers of RNAP (i.e., 50% protection). We propose that only one of the two alpha protomers of RNAP interacts with beta and that only one of the two alpha protomers of RNAP interacts with beta'.

The sigma subunit of Escherichia coli RNA polymerase senses promoter spacing.

The promoters recognized by sigma 70, the primary sigma of Escherichia coli, consist of two highly conserved hexamers located at -10 and -35 bp from the start point of transcription, separated by a preferred spacing of 17 bp. sigma factors have two distinct DNA binding domains that recognize the two hexamer sequences. However, the component of RNA polymerase recognizing the length of the spacing between hexamers has not been determined. Using an equilibrium DNA binding competition assay, we demonstrate that a polypeptide of sigma 70 carrying both DNA binding domains is very sensitive to promoter spacing, whereas a sigma 70 polypeptide with only one DNA binding domain is not. Furthermore, a mutant sigma, selected for increasing transcription of the minimal lac promoter (18-bp spacer), has an altered response to promoter spacing in vivo and in vitro. Our data support the idea that sigma makes simultaneous, productive contacts at both the -10 and the -35 regions of the promoter and discerns the spacing between these conserved regions.

Protein p4 represses phage phi 29 A2c promoter by interacting with the alpha subunit of Bacillus subtilis RNA polymerase.

Regulatory protein p4 from Bacillus subtilis phage phi 29 represses the strong viral A2c promoter (PA2c) by preventing promoter clearance; it allows RNA polymerase to bind to the promoter and form an initiated complex, but the elongation step is not reached. Protein p4 binds at PA2c immediately upstream from RNA polymerase; repression involves a contact between both proteins that holds the RNA polymerase at the promoter. This contact is held mainly through p4 residue Arg120, which is also required for activation of the phi 29 late A3 promoter. We have investigated which region of RNA polymerase contacts protein p4 at PA2c. Promoter repression was impaired when a reconstituted RNA polymerase lacking the 15 C-terminal residues of the alpha subunit C-terminal domain was used; this polymerase was otherwise competent for transcription. Binding cooperativity assays indicated that protein p4 cannot interact with this mutant RNA polymerase at PA2c. Protein p4 could form a complex at PA2c with purified wild-type alpha subunit, but not with a deletion mutant lacking the 15 C-terminal residues. Our results indicate that protein p4 represses PA2c by interacting with the C-terminal domain of the alpha subunit of RNA polymerase. Therefore, this domain of the alpha subunit can receive regulatory signals not only from transcriptional activators, but from repressors also.

A hyperphosphorylated form of the large subunit of RNA polymerase II is associated with splicing complexes and the nuclear matrix.

A hyperphosphorylated form of the largest subunit of RNA polymerase II (pol IIo) is associated with the pre-mRNA splicing process. Pol IIo was detected in association with a subset of small nuclear ribonucleoprotein particle and Ser-Arg protein splicing factors and also with pre-mRNA splicing complexes assembled in vitro. A subpopulation of pol IIo was localized to nuclear "speckle" domains enriched in splicing factors, indicating that it may also be associated with RNA processing in vivo. Moreover, pol IIo was retained in a similar pattern following in situ extraction of cells and was quantitatively recovered in the nuclear matrix fraction. The results implicate nuclear matrix-associated hyperphosphorylated pol IIo as a possible link in the coordination of transcription and splicing processes.

Increased accommodation of nascent RNA in a product site on RNA polymerase II during arrest.

RNA polymerases encounter specific DNA sites at which RNA chain elongation takes place in the absence of enzyme translocation in a process called discontinuous elongation. For RNA polymerase II, at least some of these sequences also provoke transcriptional arrest where renewed RNA polymerization requires elongation factor SII. Recent elongation models suggest the occupancy of a site within RNA polymerase that accommodates nascent RNA during discontinuous elongation. Here we have probed the extent of nascent RNA extruded from RNA polymerase II as it approaches, encounters, and departs an arrest site. Just upstream of an arrest site, 17-19 nucleotides of the RNA 3'-end are protected from exhaustive digestion by exogenous ribonuclease probes. As RNA is elongated to the arrest site, the enzyme does not translocate and the protected RNA becomes correspondingly larger, up to 27 nucleotides in length. After the enzyme passes the arrest site, the protected RNA is again the 18-nucleotide species typical of an elongation-competent complex. These findings identify an extended RNA product groove in arrested RNA polymerase II that is probably identical to that emptied during SII-activated RNA cleavage, a process required for the resumption of elongation. Unlike Escherichia coli RNA polymerase at a terminator, arrested RNA polymerase II does not release its RNA but can reestablish the normal elongation mode downstream of an arrest site. Discontinuous elongation probably represents a structural change that precedes, but may not be sufficient for, arrest by RNA polymerase II.

The C-terminal domain of the largest subunit of RNA polymerase II interacts with a novel set of serine/arginine-rich proteins.

Although transcription and pre-mRNA processing are colocalized in eukaryotic nuclei, molecules linking these processes have not previously been described. We have identified four novel rat proteins by their ability to interact with the repetitive C-terminal domain (CTD) of RNA polymerase II in a yeast two-hybrid assay. A yeast homolog of one of the rat proteins has also been shown to interact with the CTD. These CTD-binding proteins are all similar to the SR (serine/arginine-rich) family of proteins that have been shown to be involved in constitutive and regulated splicing. In addition to alternating Ser-Arg domains, these proteins each contain discrete N-terminal or C-terminal CTD-binding domains. We have identified SR-related proteins in a complex that can be immunoprecipitated from nuclear extracts with antibodies directed against RNA polymerase II. In addition, in vitro splicing is inhibited either by an antibody directed against the CTD or by wild-type but not mutant CTD peptides. Thus, these results suggest that the CTD and a set of CTD-binding proteins may act to physically and functionally link transcription and pre-mRNA processing.

Transcription activation by phage phi29 protein p4 is mediated by interaction with the alpha subunit of Bacillus subtilis RNA polymerase.

Regulatory protein p4 from Bacillus subtilis phage phi29 activates transcription from the viral late A3 promoter by stabilizing sigmaA-RNA polymerase at the promoter as a closed complex. Activation requires an interaction between protein p4 and RNA polymerase mediated by the protein p4 carboxyl-end, mainly through residue Arg-120. We have obtained derivatives of B. subtilis RNA polymerase alpha subunit with serial deletions at the carboxyl-end and reconstituted RNA polymerase holoenzymes harboring the mutant alpha subunits. Protein p4 promoted the binding of purified B. subtilis RNA polymerase alpha subunit to the A3 promoter in a cooperative way. Binding was abolished by deletion of the last 15 amino acids of the alpha subunit. Reconstituted RNA polymerases with deletions of 15 to 59 residues at the alpha subunit carboxyl-end could recognize and transcribe viral promoters not activated by protein p4, but they had lost their ability to recognize the A3 promoter in the presence of protein p4. In addition, these mutant reconstituted RNA polymerases could not interact with protein p4. We conclude that protein p4 activation of the viral A3 promoter requires an interaction between the carboxyl-end of protein p4 and the carboxyl-end of the alpha subunit of B. subtilis RNA polymerase that stabilizes the RNA polymerase at the promoter.

Purification of the Drosophila RNA polymerase II general transcription factors.

We describe a fractionation and purification scheme for the Drosophila RNA polymerase II general transcription factors. Drosophila TFIIE, TFIIF, TFIIH, and RNA polymerase II have been purified to greater than 50% homogeneity from Drosophila embryo nuclear extracts. TFIID has been purified 80-fold and is not significantly contaminated with any of the other general factors. This is the first reported identification and purification of Drosophila TFIIH and TFIIE. Further analysis shows that, similar to their mammalian counterparts, Drosophila TFIIH is composed of eight polypeptides sized between 30 and 100 kDa, and Drosophila TFIIE is composed of two polypeptides sized at 34 and 60 kDa. When all of these fractions are combined with recombinant Drosophila TFlIB, a highly purified in vitro transcription system is generated that has not previously been available in Drosophila. The TFIID fraction can be replaced with recombinant Drosophila TBP to give a transcription system that is nearly free of contaminating proteins.

Binding of the sigma 70 protein to the core subunits of Escherichia coli RNA polymerase, studied by iron-EDTA protein footprinting.

We have used a nonspecific protein cleaving reagent to map the interactions between subunits of the multisubunit enzyme RNA polymerase (Escherichia coli). We developed suitable conditions for using an untethered Fe-EDTA reagent, which does not bind significantly to proteins. Comparison of the cleaved fragments of the subunits from the core enzyme (alpha 2 beta beta') and the holoenzyme (core+sigma 70) shows that absence of the sigma 70 subunit is associated with the appearance of several cleavage sites on the subunits beta (within 10 residues of sequence positions 745, 764, 795, and 812) and beta' (within 10 residues of sequence positions 581, 613, and 728). A cleavage site near beta residue 604 is present in the holoenzyme but absent in the core, demonstrating that a conformational change occurs when sigma 70 binds. No differences are observed for the alpha subunit.

Yeast global transcriptional regulators Sin4 and Rgr1 are components of mediator complex/RNA polymerase II holoenzyme.

Sin4 and Rgr1 proteins, previously shown by genetic studies to play both positive and negative roles in the transcriptional regulation of many genes, are identified here as components of mediator and RNA polymerase II holoenzyme complexes. Results with Sin4 deletion and Rgr1 truncation strains indicate the association of these proteins in a subcomplex comprising Sin4, Rgr1, Gal11, and a 50-kDa polypeptide. Taken together with the previous genetic evidence, our findings point to a role of the mediator in repression as well as in transcriptional activation.

Transcription termination of RNA polymerase I due to a T-rich element interacting with Reb1p.

All transcription terminators for RNA polymerase I (pol I) that have been studied so far, ranging from yeast to humans, require a specific DNA binding protein to cause termination. In yeast, this terminator protein has been identified as Reb1p. We now show that, in addition to the binding site for Reb1p, the yeast pol I terminator also requires the presence of a T-rich region coding for the last 12 nucleotides of the transcript. Reb1p cooperates with this T-rich element, both to pause the polymerase and to effect release of the transcript. These findings have implications for the termination mechanism used by all three nuclear RNA polymerases, since all three are known to pause at this terminator.

RNA polymerase II/III transcription specificity determined by TATA box orientation.

The TATA box sequence in eukaryotes is located about 25 bp upstream of many genes transcribed by RNA polymerase II (Pol II) and some genes transcribed by RNA polymerase III (Pol III). The TATA box is recognized in a sequence-specific manner by the TATA box-binding protein (TBP), an essential factor involved in the initiation of transcription by all three eukaryotic RNA polymerases. We have investigated the recognition of the TATA box by the Pol II and Pol III basal transcription machinery and its role in establishing the RNA polymerase specificity of the promoter. Artificial templates were constructed that contained a canonical TATA box as the sole promoter element but differed in the orientation of the 8-bp TATA box sequence. As expected, Pol II initiated transcription in unfractionated nuclear extracts downstream of the "forward" TATA box. In distinct contrast, transcription that initiated downstream of the "reverse" TATA box was carried out specifically by Pol III. Importantly, this effect was observed regardless of the source of the DNA either upstream or downstream of the TATA sequence. These findings suggest that TBP may bind in opposite orientations on Pol II and Pol III promoters and that opposite, yet homologous, surfaces of TBP may be utilized by the Pol II and Pol III basal machinery for the initiation of transcription.