Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Human transcription factor TFIIB, a protein of 316 amino acids, was subjected to limited proteolysis in order to define stable structural domains. We find that the C-terminal region of TFIIB, residues 106-316, is relatively stable, while the N-terminal region is very sensitive to proteases. Like full-length TFIIB, the stable domain, which we refer to as TFIIBc, interacts with the TATA-binding protein (TBP) on DNA. However, TFIIBc is unable to substitute for TFIIB in an in vitro transcription assay. We show by gel mobility-shift experiments that TFIIBc arrests formation of the transcription complex after binding to TBP, and we conclude that the N-terminal region of TFIIB, which is missing from TFIIBc, is responsible for the recruitment of RNA polymerase II to the promoter. We also show that TFIIBc inhibits transcription by competing with full-length TFIIB for the interaction with TBP, either in the presence or in the absence of the TBP-associated factors. The acidic transcriptional activator GAL4-VP16 does not favor the assembly of the functional transcription complex over the nonfunctional complex containing TFIIBc. Thus, if the function of GAL4-VP16 is enhancement of the interaction between TFIIB and the TFIID-DNA complex, then this function can also be exerted on the protease-resistant domain TFIIBc.
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PMID:Delineation of two functional regions of transcription factor TFIIB. 851 11

Transcription factor TFIIB is an essential component of the RNA polymerase II initiation complex. TFIIB carries out at least two functions: it interacts directly with the TATA-binding protein (TBP) and helps to recruit RNA polymerase II into the initiation complex. The sequence of TFIIB reveals a potential zinc-binding domain and an imperfect duplication of approximately 70 amino acids. Mutagenesis of cysteine codons within the putative zinc finger results in mutant proteins that bind normally to TBP but are unable to recruit RNA polymerase II-TFIIF into the initiation complex. Changing the two most highly conserved amino acids in the TFIIB repeats reduces the ability of TFIIB to interact with TBP. Therefore, the two functions of TFIIB can be assigned to two separable functional domains of the protein.
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PMID:Functional domains of transcription factor TFIIB. 851 12

The proximal sequence element (PSE)-binding transcription factor (PTF) specifically recognizes the PSEs of both RNA polymerase II- and RNA polymerase III-transcribed small nuclear RNA (snRNA) genes. We previously have shown that PTF purified from human HeLa cells is a multisubunit complex of four polypeptides designated PTF alpha, -beta, -gamma, and -delta. We now report the isolation and expression of cDNAs encoding PTF gamma and PTF delta, as well as functional studies with cognate antibodies that recognize the native PTF complex in HeLa extracts. Immunoprecipitation studies confirm that the four PTF subunits originally found to copurify during conventional chromatography indeed form a tightly associated complex; they further show that the PTF so defined, including the gamma and delta subunits specifically, is essential for transcription of both class II and class III snRNA genes. Immunoprecipitation assays also show a weak substoichiometric association of the TATA-binding protein (TBP) with PTF, consistent with the previous report of a PTF-related complex (SNAPc) containing substoichiometric levels of TBP and a component (SNAPc43) identical in sequence to the PTF gamma reported here. Glutathione S-transferase pulldown assays further indicate relatively strong direct interactions of both recombinant PTF gamma and PTF delta with TBP, consistent either with the natural association of TBP with PTF in a semistable TBP-TBP-associated factor complex or with possible functional interactions between PSE-bound PTF and TATA-bound TBP during promoter activation. In addition, we show that in extracts depleted of TBP and TBP-associated factors, transcription from the U1 promoter is restored by recombinant TBP but not by TFIID or TFIIIB, indicating that transcription of class II snRNA genes requires a TBP complex different from the one used for mRNA-encoding genes.
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PMID:Cloning of two proximal sequence element-binding transcription factor subunits (gamma and delta) that are required for transcription of small nuclear RNA genes by RNA polymerases II and III and interact with the TATA-binding protein. 852 84

The universal TATA-binding protein, TBP, is an essential component of the multiprotein complex known as transcription factor IID (TFIID). This complex, which consists of TBP and TBP-associated factors (TAFs), is essential for RNA polymerase II-mediated transcription. The molecular size of human TBP (37.7 kD) is close to the passive diffusion limit along the transport channel of the nuclear pore complex (NPC). Therefore, the possibility exists that NPCs restrict TBP translocation to the nuclear interior. Here we show for the first time, with patch-clamp and atomic force microscopy (AFM), that NPCs regulate TBP movement into the nucleus and that TBP (10(-15)-10(-10)M) is capable of modifying NPC structure and function. The translocation of TBP was ATP-dependent and could be detected as a transient plugging of the NPC channels, with a concomitant transient reduction in single NPC channel conductance, gamma, to a negligible value. NPC unplugging was accompanied by permanent channel opening at concentrations greater than 250 pM. AFM images demonstrated that the TBP molecules attached to and accumulated on the NPC cytosolic side. NPC channel activity could be recorded for more than 48 hr. These observations suggest that three novel functions of TBP are: to stabilize NPC, to force the NPC channels into an open state, and to increase the number of functional channels. Since TBP is a major component of transcription, our observations are relevant to the understanding of the gene expression mechanisms underlying normal and pathological cell structure and function.
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PMID:Patch clamp and atomic force microscopy demonstrate TATA-binding protein (TBP) interactions with the nuclear pore complex. 856 41

Host cell RNA polymerase II (pol II)-mediated transcription is inhibited by poliovirus infection. We demonstrate here that both TATA- and initiator-mediated basal transcription is inhibited in extracts prepared from poliovirus-infected HeLa cells. This inhibition can be reproduced by incubation of uninfected HeLa cell extracts with purified, recombinant poliovirus protease, 3Cpro. Transient-transfection assays demonstrate that 3Cpro, in the absence of other viral proteins, is able to inhibit cellular pol II-mediated transcription in vivo. Three lines of evidence suggest that inactivation of TATA-binding protein (TBP) is the major cause of inhibition of basal transcription by poliovirus. First, RNA pol II transcription in poliovirus-infected cell extract is fully restored by bacterially expressed TBP. Second, addition of purified TBP restores transcription in heat-treated nuclear extracts from mock- and virus-infected cells to identical levels. Finally, using a gel mobility shift assay, we demonstrate that incubation of TBP with the viral protease (3Cpro) inhibits its ability to bind TATA sequence in vitro. These results suggest that inhibition of pol II transcription in mammalian cells infected with poliovirus is, at least in part, due to the inability of modified TBP to bind pol II promoter sequences.
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PMID:Inhibition of basal transcription by poliovirus: a virus- encoded protease (3Cpro) inhibits formation of TBP-TATA box complex in vitro. 862 67

The CT element is a positively acting homopyrimidine tract upstream of the c-myc gene to which the well-characterized transcription factor Spl and heterogeneous nuclear ribonucleoprotein (hnRNP) K, a less well-characterized protein associated with hnRNP complexes, have previously been shown to bind. The present work demonstrates that both of these molecules contribute to CT element-activated transcription in vitro. The pyrimidine-rich strand of the CT element both bound to hnRNP K and competitively inhibited transcription in vitro, suggesting a role for hnRNP K in activating transcription through this single-stranded sequence. Direct addition of recombinant hnRNP K to reaction mixtures programmed with templates bearing single-stranded CT elements increased specific RNA synthesis. If hnRNP K is a transcription factor, then interactions with the RNA polymerase II transcription apparatus are predicted. Affinity columns charged with recombinant hnRNP K specifically bind a component(s) necessary for transcription activation. The depleted factors were biochemically complemented by a crude TFIID phosphocellulose fraction, indicating that hnRNP K might interact with the TATA-binding protein (TBP)-TBP-associated factor complex. Coimmunoprecipitation of a complex formed in vivo between hnRNP K and epitope-tagged TBP as well as binding in vitro between recombinant proteins demonstrated a protein-protein interaction between TBP and hnRNP K. Furthermore, when the two proteins were overexpressed in vivo, transcription from a CT element-dependent reporter was synergistically activated. These data indicate that hnRNP K binds to a specific cis element, interacts with the RNA polymerase II transcription machinery, and stimulates transcription and thus has all of the properties of a transcription factor.
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PMID:Heterogeneous nuclear ribonucleoprotein K is a transcription factor. 862 2

Archaeal RNA polymerases show a weak ability in vitro to bind to promoter DNA and/or to initiate transcription with low activity independent of upstream regulatory DNA sequences. Active transcription in vitro and in vivo, however, depends strictly on a TATA box resembling the TATA box of eucaryal polII promoters. This TATA box is recognized by a polypeptide related to eucaryal TATA-binding protein (TBP) that was formerly designated aTFB. Template competition studies showed that this archaeal TATA-binding protein (aTBP) is stably sequestered at the promoter by interaction with the second archaeal transcription factor, aTFA, which is related to eucaryal transcription factor IIB (TFIIB). The association of archaeal TFIIB (aTFIIB) with the aTBP-promoter complex leads to template commitment, indicating that aTFIIB recruits archaeal RNA polymerase to the preinitiation complex. These analyses suggest the following order for assembly of transcription factors on the archaeal promoter: aTBP, aTFIIB, RNA polymerase, and provide evidence for a common molecular mechanism of transcription initiation by eucaryal RNA polymerase II and archaeal RNA polymerases. The sequence of the genes encoding aTBP and aTFIIB (TFB) showed all the characteristics conserved in their eucaryal counterparts. The degree of sequence similarity between archaeal and eucaryal transcription factors is between 27 to 35% for TFIIB and between 36 to 41% for TBP. The findings discussed here indicate that TBP and TFIIB perform analogous functions in Archaea and Eucarya and show that four essential components of archaeal and eucaryal transcriptional machineries. RNA polymerase, TATA box, TBP and TFIIB are homologous.
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PMID:Archaeal transcription factors and their role in transcription initiation. 863 26

ICP4 of herpes simplex virus is responsible for the activation of viral transcription during infection. It also efficiently activates and represses transcription in vitro depending on the promoter context. The contacts made between ICP4 and the cellular proteins that result in activated transcription have not been identified. The inability of ICP4 to activate transcription with TATA-binding protein in place of TFIID and the requirement for an initiator element for efficient ICP-4-activated transcription suggest that coactivators, such as TBP-associated factors, are involved (B. Gu and N. DeLuca, J. Virol. 68:7953-7965, 1994). In this study we showed that ICP4 activates transcription in vitro using an immunopurified TFIID, indicating that TBP-associated factors may be a sufficient subset of coactivators for ICP4-activated transcription. Similar to results seen in vivo, the presence of the ICP4 C-terminal region (amino acids 774 to 1298) was important for activation in vitro. With epitope-tagged ICP4 molecules in immunoaffinity experiments, it was shown that the C-terminal region was also required for ICP4 to interact with TFIID present in a crude transcription factor fraction. In the same assay, ICP4 was unable to interact with the basal transcription factors, TFIIB, TFIIE, TFIIF, and TFIIH and RNA polymerase II. ICP4 could also interact with TBP, independent of the C-terminal region. However, reflective of the interaction between ICP4 and TFIID, the ICP4 C-terminal region was required for an interaction with FAF250-TBP complexes and with TAF250 alone. Therefore, the interfaces or conformation of TBP mediating the interaction between ICP4 and TBP in solution is probably masked when TBP is bound to TAF250. With a series of mutant ICP4 molecules purified from herpes simplex virus-infected cells, it was shown that ICP4 molecules that can bind DNA and interact with TAF250 could activate transcription. Taken together, these results demonstrate that ICP4 interaction with TFIID involves the TAF250 molecule and the C-terminal region of ICP4 and that this interaction is part of the mechanism by which ICP4 activates transcription.
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PMID:Interaction of the viral activator protein ICP4 with TFIID through TAF250. 864 20

Signals from transcriptional activators to the general mRNA transcription apparatus are communicated by factors associated with RNA polymerase II or the TATA-binding protein (TBP). Currently, little is known about how gene-specific transcription repressors communicate with RNA polymerase II. We have analyzed the requirements for repression by the saccharomyces cerevisiae Leu3 protein (Leu3p) in a reconstituted transcription system. We have identified a complex form of TBP which is required for communication of the repressing signal. This TFIID-like complex contains a known TBP-associated protein, Mot1p, which has been implicated in the repression of a subset of yeast genes by genetic analysis. Leu3p-dependent repression can be reconstituted with purified Mot1p and recombinant TBP. In addition, a mutation in the Mot1 gene leads to partial derepression of the Leu3p-dependent LEU2 promoter. These in vivo and in vitro observations define a role for Mot1p as a transcriptional corepressor.
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PMID:Transcriptional corepression in vitro: a Mot1p-associated form of TATA-binding protein is required for repression by Leu3p. 865 39

We describe the cloning and analysis of TAF25, a previously uncharacterized yeast gene that encodes a yeast TATA-binding protein-associated factor or yTAF of Mr = 25,000. The gene encoding yTAF25 is a single copy essential gene, and the protein sequence deduced from TAF25 exhibits sequence similarity to a metazoan hTAFII. The results from immunological studies confirm that yTAF25 is a subunit of a large multiprotein TATA-binding protein-yeast TATA-binding protein-associated factor complex that contains a subset of the total number of the yTAFs present in yeast cell extracts. Both genetic and biochemical analyses demonstrate that yTAF25 can interact directly with itself. Transcriptional data show that the activity of the multiprotein complex containing yTAF25 is RNA polymerase II-specific, thus indicating that TAF25 encodes a bona fide yeast RNA polymerase II TAF. Hence the protein encoded by TAF25 has been termed yTAFII25.
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PMID:Isolation and characterization of TAF25, an essential yeast gene that encodes an RNA polymerase II-specific TATA-binding protein-associated factor. 866 25


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