EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Bromodomain factor 1 (Bdf1) associates with Saccharomyces cerevisiae TFIID and corresponds to the C-terminal half of higher eukaryotic TAF1. It also associates with the SWR-C complex, which is important for Htz1 deposition. Bdf1 binds preferentially to acetylated histone H4. Bdf1 is phosphorylated, but the mechanism and significance of this modification have been unclear. Two distinct regions within Bdf1 are phosphorylated; one is just C terminal to the bromodomains and the other is near the C terminus. Mutational analysis shows that phosphorylation is necessary for Bdf1 function in vivo. Endogenous protein kinase CK2 purifies with Bdf1 and phosphorylates both domains. A similar mechanism may be responsible for phosphorylation of the C-terminal region of mammalian TAF1. These findings suggest that CK2 phosphorylation of Bdf1 may regulate RNA polymerase II transcription and/or chromatin structure.
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PMID:Bromodomain factor 1 (Bdf1) is phosphorylated by protein kinase CK2. 1514 68

The chloroplast transcription apparatus has turned out to be more complex than anticipated, with core polypeptides surrounded by multiple accessory proteins of diverse, and in part unexpected, functions. At least two different RNA-binding proteins and several redox-responsive proteins are components of the major chloroplast RNA polymerase termed PEP-A. One of the key-regulatory factors has been identified as a Ser/Thr-specific protein kinase that is sensitive to SH group modification by glutathione and by this means is able to modulate transcription. The cloned plastid transcription kinase from mustard (Sinapis alba L.) has been assigned as a member of the (mostly nucleo-cytosolic) CK2 family and hence has been termed cpCK2. Despite its apparent role in mustard chloroplast transcription, until recently no data have been available for other plant species. Using the web database resources, we find evidence for an evolutionarily conserved role of this redox-sensitive plastid transcription factor.
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PMID:Proteomics-based sequence analysis of plant gene expression--the chloroplast transcription apparatus. 1527 37

We have investigated the role of phosphorylation by vertebrate protein kinase CK2 on the activity of the General Transcription Factors TFIIA, TFIIE, TFIIF, and RNAPII. The largest subunits of TFIIA, TFIIE, and TFIIF were phosphorylated by CK2 holoenzyme. Also, RNA polymerase II was phosphorylated by CK2 in the 214,000 and 20,500 daltons subunits. Our results show that phosphorylation of TFIIA, TFIIF, and RNAPII increase the formation of complexes on the TATA box of the Ad-MLP promoter. Also, phosphorylation of TFIIF increases the formation of transcripts, where as phosphorylation of RNA polymerase II dramatically inhibits transcript formation. Furthermore, we demonstrate that CK2 beta directly interacts with RNA polymerase II, TFIIA, TFIIF, and TBP. These results strongly suggest that CK2 may play a role in regulating transcription of protein coding genes.
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PMID:Effects of phosphorylation by protein kinase CK2 on the human basal components of the RNA polymerase II transcription machinery. 1535 56

RNA polymerase III (pol III) transcription from the human U6 snRNA promoter can be reconstituted with the recombinant factors SNAPc and Brf2-TFIIIB combined with purified pol III. In this system, CK2 treatment of the pol III complex is required for transcription, whereas treatment of Brf2-TFIIIB is inhibitory. Here we show that CK2 inhibits Brf2-TFIIIB by specifically phosphorylating its Bdp1 component. Bdp1 is phosphorylated by CK2 during mitosis, and this is accompanied by Bdp1 dissociation from the U6 promoter and from chromatin in general and by transcription repression. Remarkably, whereas inhibition of CK2 in mitotic extracts restores pol III transcription, inhibition of CK2 in active S phase extracts debilitates transcription. Thus, CK2 is directed to phosphorylate different targets within the basal pol III transcription machinery at different times during the cell cycle, with opposite transcriptional effects.
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PMID:CK2 phosphorylation of Bdp1 executes cell cycle-specific RNA polymerase III transcription repression. 1546 24

When transcription from the human U6 snRNA gene is reconstituted with recombinant factors and purified RNA polymerase III (pol III), pol III must be treated with CK2 to be active. We show that highly purified pol III contains associated beta-actin, and beta-actin localizes to an active U6 promoter in vivo. Pol III immunoprecipitated from IMR90 cells treated with a genotoxic agent lacks associated beta-actin and is inactive in the reconstituted assay. Transcription is regained upon treatment of pol III with CK2 and addition of beta-actin. This suggests that beta-actin associated with pol III is essential for basal pol III transcription.
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PMID:A role for beta-actin in RNA polymerase III transcription. 1557 86

FCP1, a phosphatase specific for the carboxyl-terminal domain of the largest subunit of RNA polymerase II, is regulated by the HIV-1 Tat protein, CK2, TFIIB, and the large subunit of TFIIF (RAP74). We have characterized the interactions of Tat and RAP74 with the BRCT-containing central domain of FCP1 (FCP1(562)(-)(738)). We demonstrated that FCP1 is required for Tat-mediated transactivation in vitro and that amino acids 562-685 of FCP1 are necessary for Tat interaction in yeast two-hybrid studies. From sequence alignments, we identified a conserved acidic/hydrophobic region in FCP1 adjacent to its highly conserved BRCT domain. In vitro binding studies with purified proteins indicate that HIV-1 Tat interacts with both the acidic/hydrophobic region and the BRCT domain of FCP1, whereas RAP74(436)(-)(517) interacts solely with a portion of the acidic/hydrophobic region containing a conserved LXXLL-like motif. HIV-1 Tat inhibits the binding of RAP74(436)(-)(517) to FCP1. In a companion paper (K. Abbott et al. (2005) Enhanced Binding of RNAPII CTD Phosphatase FCP1 to RAP74 Following CK2 Phosphorylation, Biochemistry 44, 2732-2745, we identified a novel CK2 site adjacent to this conserved LXXLL-like motif. Phosphorylation of FCP1(562)(-)(619) by CK2 at this site increases binding to RAP74(436)(-)(517), but this phosphorylation is inhibited by Tat. Our results provide insights into the mechanisms by which Tat inhibits the FCP1 CTD phosphatase activity and by which FCP1 mediates transcriptional activation by Tat. In addition to increasing our understanding of the role of HIV-1 Tat in transcriptional regulation, this study defines a clear role for regions adjacent to the BRCT domain in promoting important protein-protein interactions.
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PMID:Interactions of the HIV-1 Tat and RAP74 proteins with the RNA polymerase II CTD phosphatase FCP1. 1572 17

FCP1 (TFIIF-associated CTD phosphatase) is the first identified CTD-specific phosphatase required to recycle RNA polymerase II (RNAP II). FCP1 activity has been shown to be regulated by the general transcription factors TFIIF (RAP74) and TFIIB, protein kinase CK2 (CK2), and the HIV-1 transcriptional activator Tat. Phosphorylation of FCP1 by CK2 stimulates FCP1 phosphatase activity and enhances binding of RAP74 to FCP1. We have examined consensus CK2 phosphorylation sites (acidic residue n + 3 to serine or threonine residue) located immediately adjacent to both RAP74-binding sites of FCP1. We demonstrate that both of these consensus CK2 sites can be phosphorylated in vitro and that phosphorylation at either CK2 site results in enhanced binding of RAP74 to FCP1. The CK2 site adjacent to the RAP74-binding site in the central domain of FCP1 is phosphorylated at a single threonine site (T584). The CK2 site adjacent to the RAP74-binding site in the carboxyl-terminal domain can be phosphorylated at three successive serine residues (S942-S944), with phosphorylations at S942 and S944 both contributing to enhanced binding to RAP74. With the use of tandem Fourier transform-ion cyclotron resonance mass spectrometry (FT-ICR), we demonstrate that the phosphorylation of S942-S944 occurs in a semiordered fashion with the initial phosphorylation occurring at either S942 or S944 followed by a second phosphorylation to yield the S942/S944 diphosphorylated species. Using nuclear magnetic resonance (NMR) spectroscopy, we identify and map chemical shift changes onto the solution structure of the carboxyl-terminal domain of RAP74 (RAP74(436)(-)(517)) on complexation of RAP74(436)(-)(517) with phosphorylated FCP1 peptides. These results provide new functional and structural information on the role of phosphorylation in the recognition of acidic-rich activation domains involved in transcriptional regulation, and bring insights into how CK2 and TFIIF regulate FCP1 function.
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PMID:Enhanced binding of RNAP II CTD phosphatase FCP1 to RAP74 following CK2 phosphorylation. 1572 18

Downstream core promoter elements are an expanding class of regulatory sequences that add considerable diversity to the promoter architecture of RNA polymerase II-transcribed genes. We set out to determine the factors necessary for downstream promoter element (DPE)-dependent transcription and find that, against expectations, TFIID and the GTFs are not sufficient. Instead, the protein kinase CK2 and the coactivator PC4 establish DPE-specific transcription in an in vitro transcription system containing TFIID, Mediator, and the GTFs. Chromatin immunoprecipitation analyses using the DPE-dependent IRF-1 and TAF7 promoters demonstrated that CK2, and PC4 are present on these promoters in vivo. In contrast, neither PC4 nor CK2 were detected on the TAF1-dependent cyclin D promoter, which contains a DCE type of downstream element. Our findings also demonstrate that CK2 activity alters TFIID-dependent recognition of DCE sequences. These data establish that CK2 acts as a switch, converting the transcriptional machinery from functioning on one type of downstream element to another.
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PMID:Functional characterization of core promoter elements: DPE-specific transcription requires the protein kinase CK2 and the PC4 coactivator. 1589 30

Protein kinase CK2 regulates RNA polymerase III transcription of human U6 small nuclear RNA (snRNA) genes both negatively and positively depending upon whether the general transcription machinery or RNA polymerase III is preferentially phosphorylated. Human U1 snRNA genes share similar promoter architectures as that of U6 genes but are transcribed by RNA polymerase II. Herein, we report that CK2 inhibits U1 snRNA gene transcription by RNA polymerase II. Decreased levels of endogenous CK2 correlates with increased U1 expression, whereas CK2 associates with U1 gene promoters, indicating that it plays a direct role in U1 gene regulation. CK2 phosphorylates the general transcription factor small nuclear RNA-activating protein complex (SNAP(C)) that is required for both RNA polymerase II and III transcription, and SNAP(C) phosphorylation inhibits binding to snRNA gene promoters. However, restricted promoter access by phosphorylated SNAP(C) can be overcome by cooperative interactions with TATA-box-binding protein at a U6 promoter but not at a U1 promoter. Thus, CK2 may have the capacity to differentially regulate U1 and U6 transcription even though SNAP(C) is universally utilized for human snRNA gene transcription.
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PMID:Cooperation between small nuclear RNA-activating protein complex (SNAPC) and TATA-box-binding protein antagonizes protein kinase CK2 inhibition of DNA binding by SNAPC. 1595 16

The tumor suppressor p53 is an important cellular protein, which controls cell cycle progression. Phosphorylation is one of the mechanisms by which p53 is regulated. Here we report the interaction of p53 with another key regulator, cdk9, which together with cyclin T1 forms the positive transcription elongation complex, p-TEFb. This complex cooperates with the HIV-1 Tat protein to cause the phosphorylation of the carboxyl terminal domain (CTD) of RNA polymerase II and this facilitates the elongation of HIV-1 transcription. We demonstrate that cdk9 phosphorylates p53 on serine 392 through their direct physical interaction. Results from protein-protein interaction assays revealed that cdk9 interacts with the C-terminal domain (aa 361-393) of p53, while p53 interacts with the N-terminal domain of cdk9. Transfection and protein binding assays (EMSA and ChIP) demonstrated the ability of p53 to bind and activate the cdk9 promoter. Interestingly, cdk9 phosphorylates serine 392 of p53, which could be also phosphorylated by casein kinase II. Kinase assays demonstrated that cdk9 phosphorylates p53 independently of CKII. These studies demonstrate the existence of a feedback-loop between p53 and cdk9, pinpointing a novel mechanism by which p53 regulates the basal transcriptional machinery.
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PMID:Cdk9 phosphorylates p53 on serine 392 independently of CKII. 1674 55

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