Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P20226 (TATA-binding protein)
 1,297 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A new gene, RRN11, has been defined by certain rrn mutants of Saccharomyces cerevisiae which are defective specifically in the transcription of 35 S rRNA gene by RNA polymerase I (pol I). We have cloned the gene and found that it encodes a protein of 507 amino acids. We have used a strain with the chromosomal RRN11 deleted and carrying HA1 epitope-tagged RRN11 on a plasmid to isolate a protein complex containing the protein encoded by RRN11. This protein complex complemented rrn6 mutant extracts, which were previously shown to be deficient in the essential pol I transcription factor called Rrn6/7 complex or core factor (CF). The CF complex was previously shown to consist of three proteins, the 102- and 60-kDa subunits encoded by RRN6 and RRN7, respectively, and the 66-kDa subunit. The results of the above complementation experiments combined with mobility of Rrn11p in SDS-polyacrylamide gel electrophoresis analysis relative to Rrn6p and Rrn7p led to the conclusion that RRN11 encodes the 66-kDa subunit of CF. Glutathione S-transferase-Rrn11p fusion protein was found to bind strongly to 35S-labeled Rrn6p and Rrn7p but only weakly to 35S-labeled TATA-binding protein. Similarly, glutathione S-transferase-Rrn7p fusion protein bound strongly to 35S-labeled Rrn6p and Rrn11p but only weakly to 35S-labeled TATA-binding protein. These results are consistent with the fact that one can purify CF consisting of Rrn6p, Rrn7p, and Rrn11p from yeast cell extracts, but the purified complex does not contain TATA-binding protein. RRN11 was shown to be an essential gene, and [3H]uridine pulse experiments demonstrated directly that RRN11 is essential for rDNA transcription by pol I in vivo. Thus all three subunits of CF are essential for rDNA transcription. Because of the resemblance of CF to mammalian essential pol I transcription factor SL1, the amino acid sequences of Rrn11p and the other two subunits of CF were compared with those of the three TATA-binding protein-associated factors (TAFs) in the human SL1, TAFI48, TAFI63, and TAFI110. No significant similarity was detected between two sets of the proteins. Similarity as well as differences between CF and SL1 are discussed.
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PMID:RRN11 encodes the third subunit of the complex containing Rrn6p and Rrn7p that is essential for the initiation of rDNA transcription by yeast RNA polymerase I. 870 72

The TATA-binding protein (TBP) is common to the basal transcription factors of all three RNA polymerases, being associated with polymerase-specific TBP-associated factors (TAFs). Simian virus 40 large T antigen has previously been shown to interact with the TBP-TAFII complexes, TFIID (B. Damania and J. C. Alwine, Genes Dev. 10:1369-1381, 1996), and the TBP-TAFI complex, SL1 (W. Zhai, J. Tuan, and L. Comai, Genes Dev. 11: 1605-1617, 1997), and in both cases these interactions are critical for transcriptional activation. We show a similar mechanism for activation of the class 3 polymerase III (pol III) promoter for the U6 RNA gene. Large T antigen can activate this promoter, which contains a TATA box and an upstream proximal sequence element but cannot activate the TATA-less, intragenic VAI promoter (a class 2, pol III promoter). Mutants of large T antigen that cannot activate pol II promoters also fail to activate the U6 promoter. We provide evidence that large T antigen can interact with the TBP-containing pol III transcription factor human TFIIB-related factor (hBRF), as well as with at least two of the three TAFs in the pol III-specific small nuclear RNA-activating protein complex (SNAPc). In addition, we demonstrate that large T antigen can cofractionate and coimmunoprecipitate with the hBRF-containing complex TFIIIB derived from HeLa cells infected with a recombinant adenovirus which expresses large T antigen. Hence, similar to its function with pol I and pol II promoters, large T antigen interacts with TBP-containing, basal pol III transcription factors and appears to perform a TAF-like function.
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PMID:Simian virus 40 large T antigen interacts with human TFIIB-related factor and small nuclear RNA-activating protein complex for transcriptional activation of TATA-containing polymerase III promoters. 948 48

Dramatic changes in the patterns of transcription are a common feature of early development. We have used F9 embryonal carcinoma cells as a model system to study gene regulation during an early stage of murine embryogenesis. We find that transcription by RNA polymerase I decreases when F9 cells differentiate into parietal endoderm. The reduced rate of transcription is associated with a down-regulation of several components of the class I transcription apparatus. The most substantial change involves the essential factor SL1, which is a multisubunit complex that contains the TATA-binding protein and three TATA-binding protein-associated factors (TAFs). The abundance of two of these TAFs, TAFI48 and TAFI95, decreases during F9 cell differentiation. Developmental regulation of a specific class of genes may therefore be achieved through changes in the availability of TAFs.
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PMID:Regulation of RNA polymerase I transcription in response to F9 embryonal carcinoma stem cell differentiation. 993 34

Human rRNA synthesis by RNA polymerase I requires at least two auxiliary factors, upstream binding factor (UBF) and SL1. UBF is a DNA binding protein with multiple HMG domains that binds directly to the CORE and UCE elements of the ribosomal DNA promoter. The carboxy-terminal region of UBF is necessary for transcription activation and has been shown to be extensively phosphorylated. SL1, which consists of TATA-binding protein (TBP) and three associated factors (TAFIs), does not have any sequence-specific DNA binding activity, and its recruitment to the promoter is mediated by specific protein interactions with UBF. Once on the promoter, the SL1 complex makes direct contact with the DNA promoter and directs promoter-specific initiation of transcription. To investigate the mechanism of UBF-dependent transcriptional activation, we first performed protein-protein interaction assays between SL1 and a series of UBF deletion mutants. This analysis indicated that the carboxy-terminal domain of UBF, which is necessary for transcriptional activation, makes direct contact with the TBP-TAFI complex SL1. Since this region of UBF can be phosphorylated, we then tested whether this modification plays a functional role in the interaction with SL1. Alkaline phosphatase treatment of UBF completely abolished the ability of UBF to interact with SL1; moreover, incubation of the dephosphorylated UBF with nuclear extracts from exponentially growing cells was able to restore the UBF-SL1 interaction. In addition, DNase I footprinting analysis and in vitro-reconstituted transcription assays with phosphatase-treated UBF provided further evidence that UBF phosphorylation plays a critical role in the regulation of the recruitment of SL1 to the ribosomal DNA promoter and stimulation of UBF-dependent transcription.
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PMID:Recruitment of TATA-binding protein-TAFI complex SL1 to the human ribosomal DNA promoter is mediated by the carboxy-terminal activation domain of upstream binding factor (UBF) and is regulated by UBF phosphorylation. 1008 53

The tumor suppressor protein p53 is frequently inactivated in tumors. It functions as a transcriptional activator as well as a repressor for a number of viral and cellular promoters transcribed by RNA polymerase II (Pol II) and by RNA Pol III. Moreover, it appears that p53 also suppresses RNA Pol I transcription. In this study, we examined the molecular mechanism of Pol I transcriptional inhibition by p53. We show that wild-type, but not mutant, p53 can repress Pol I transcription from a human rRNA gene promoter in cotransfection assays. Furthermore, we show that recombinant p53 inhibits rRNA transcription in a cell-free transcription system. In agreement with these results, p53-null epithelial cells display an increased Pol I transcriptional activity compared to that of epithelial cells that express p53. However, both cell lines display comparable Pol I factor protein levels. Our biochemical analysis shows that p53 prevents the interaction between SL1 and UBF. Protein-protein interaction assays indicate that p53 binds to SL1, and this interaction is mostly mediated by direct contacts with TATA-binding protein and TAF(I)110. Moreover, template commitment assays show that while the formation of a UBF-SL1 complex can partially relieve the inhibition of transcription, only the assembly of a UBF-SL1-Pol I initiation complex on the rDNA promoter confers substantial protection against p53 inhibition. In summary, our results suggest that p53 represses RNA Pol I transcription by directly interfering with the assembly of a productive transcriptional machinery on the rRNA promoter.
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PMID:Repression of RNA polymerase I transcription by the tumor suppressor p53. 1091 76

The TATA-binding protein, TBP, is used by all three RNA polymerases and is therefore central to the process of gene expression. TBP associates with several subsets of proteins, called TATA-binding protein-associated factors (TAFs). This results in the formation of at least three distinct complexes, SL1, TFIID, and TFIIIB, which dictates whether TBP functions in RNA polymerase (pol) I, pol II, or pol III transcription, respectively. The regulation of gene expression has focused largely on proteins that serve to modulate the efficiency by which the general transcription components, such as TBP, interact with promoters. The possibility of a basal transcription factor, itself, being regulated, and influencing cellular homeostasis, has not been extensively considered. However, recent studies have indicated that TBP is indeed regulated, and that modulation of its cellular concentration has a profound, and surprisingly selective, impact on gene expression that can mediate the normal proliferative responses of cells to growth stimuli as well as the transformation potential of cells.
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PMID:The TATA-binding protein as a regulator of cellular transformation. 1296 38

The hepatitis C virus (HCV) core protein has been implicated in the transregulation of various RNA polymerase (Pol) II dependent genes as well as in the control of cellular growth and proliferation. In this study, we show that the core protein, whether individually expressed or produced as part of the HCV viral polyprotein, is the only viral product that has the potential to activate RNA Pol I transcription. Deletion analysis demonstrated that the fragment containing the N-terminal 1-156 residues, but not the 1-122 residues, of HCV core protein confers the same level of transactivation activity as the full-length protein. Moreover, the integrity of the Ser(116) and Arg(117) residues of HCV core protein was found to be critical for its transregulatory functions. We used DNA affinity chromatography to analyze the human ribosomal RNA promoter associated transcription machinery, and the results indicated that recruitment of the upstream binding factor and RNA Pol I to the ribosomal RNA promoter is enhanced in the presence of HCV core protein. Additionally, the HCV core protein mediated activation of ribosomal RNA transcription is accompanied by the hyperphosphorylation of upstream binding factor on serine residues, but not on threonine residues. Moreover, HCV core protein is present within the RNA Pol I multiprotein complex, indicating its direct involvement in facilitating the formation of a functional transcription complex. Protein-protein interaction studies further indicated that HCV core protein can associate with the selectivity factor (SL1) via direct contact with a specific component, TATA-binding protein (TBP). Additionally, the HCV core protein in cooperation with TBP is able to activate RNA Pol II and Pol III mediated transcription, in addition to RNA Pol I transcription. Thus, the results of this study suggest that HCV has evolved a mechanism to deregulate all three nuclear transcription systems, partly through targeting of the common transcription factor, TBP. Notably, the ability of the HCV core protein to upregulate RNA Pol I and Pol III transcription supports its active role in promoting cell growth, proliferation, and the progression of liver carcinogenesis during HCV infection.
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PMID:Activation of RNA polymerase I transcription by hepatitis C virus core protein. 1473 Feb 12

An important characteristic of the transcription of a ribosomal RNA gene (rDNA) mediated by DNA-dependent RNA polymerase (Pol) I is its stringent species specificity. SL1/TIF-IB is a key complex for species specificity, but its functional complex has not been reconstituted. Here, we established a novel and highly sensitive monitoring system for Pol I transcription to reconstitute the SL1 activity in which a transcript harboring a reporter gene synthesized by Pol I is amplified and converted into translatable mRNA by the influenza virus RNA-dependent RNA polymerase. Using this monitoring system, we reconstituted Pol I transcription from the human rDNA promoter in mouse cells by expressing four human TATA-binding protein (TBP)-associated factors (TAFIs) in the SL1 complex. The reconstituted SL1 also re-activated human rDNA transcription in mouse A9 cells carrying an inactive human chromosome 21 that contains the rDNA cluster. Chimeric SL1 complexes containing human and mouse TAFIs could be formed, but these complexes were inactive for human rDNA transcription. We conclude that four human TAFIs are necessary and sufficient to overcome the barrier of species specificity for human rDNA transcription in mouse cells.
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PMID:Reconstitution of human rRNA gene transcription in mouse cells by a complete SL1 complex. 2492 1

Core Factor (CF) is a conserved RNA polymerase (Pol) I general transcription factor comprising Rrn6, Rrn11 and the TFIIB-related subunit Rrn7. CF binds TATA-binding protein (TBP), Pol I and the regulatory factors Rrn3 and upstream activation factor. We used chemical cross-linking-MS to determine the molecular architecture of CF and its interactions with TBP. The CF subunits assemble through an interconnected network of interactions between five structural domains that are conserved in orthologous subunits of the human Pol I factor SL1. We validated the cross-linking-derived model through a series of genetic and biochemical assays. Our combined results show the architecture of CF and the functions of the CF subunits in assembly of the complex. We extend these findings to model how CF assembles into the Pol I preinitiation complex, providing new insight into the roles of CF, TBP and Rrn3.
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PMID:Architecture of the Saccharomyces cerevisiae RNA polymerase I Core Factor complex. 2513 80


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