UNIPROT:P51532 - FACTA Search

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Query: UNIPROT:P51532 (transcriptional activator)
6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We show that MalT, the transcriptional activator of the Escherichia coli maltose regulon, specifically binds ATP and dATP with a high affinity (Kd = 0.4 microM) and exhibits a weak ATPase activity. Using an abortive initiation assay, we further show that activation of open complex formation by MalT depends on the presence of ATP in addition to that of maltotriose, the inducer of the maltose system. Similar experiments in which ATP was replaced by ADP or AMP-PNP, a non-hydrolysable analogue of ATP, demonstrate that this reaction does not require ATP hydrolysis. As revealed by DNase I footprinting, both ATP and maltotriose are required for the binding of the MalT protein to the mal promoter DNA.
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PMID:MalT, the regulatory protein of the Escherichia coli maltose system, is an ATP-dependent transcriptional activator. 252 84

Human papillomavirus type 16 (HPV-16) DNA replicates episomally and requires two virally expressed proteins, E1 and E2. The E1 protein has both helicase and ATPase activities and is absolutely required for viral DNA replication. The E2 protein is a potent transcriptional activator and greatly increases viral DNA replication by colocalizing E1 to the origin of replication. Recently, we characterized a region of the E2 protein essential for the binding to E1. In this study we have analysed in further detail the nature of the association between E1 and E2. Using an extensive set of E2 mutant proteins we have identified two widely separate regions of the E2 protein which are essential for binding to E1. Interestingly, two E2 mutants which fail to bind E1 also fail to activate gene expression, indicating the existence of multifunctional domains on the E2 protein. In addition, cotransfection of E1 with E2 significantly increases E2 transcriptional activity on an heterologous promoter.
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PMID:Mutations in the human papillomavirus type 16 E2 protein identify multiple regions of the protein involved in binding to E1. 759 3

The yeast SNF-SWI complex is required for transcriptional activation of diverse genes and has been shown to alter chromatin structure. The complex has at least 10 components, including SNF2/SWI2, SNF5, SNF6, SWI1/ADR6, and SWI3, and has been widely conserved in eukaryotes. Here we report the characterization of a new component. We identified proteins that interact in the two-hybrid system with the N-terminal region of SNF2, preceding the ATPase domain. In addition to SWI3, we recovered a new 19-kDa protein, designated SNF11. Like other SNF/SWI proteins, SNF11 functions as a transcriptional activator in genetic assays. SNF11 interacts with SNF2 in vitro and copurifies with the SNF-SWI complex from yeast cells. Using a specific antibody, we showed that SNF11 coimmunoprecipitates with members of the SNF-SWI complex and that SNF11 is tightly and stoichiometrically associated with the complex. Furthermore, SNF11 was detected in purified SNF-SWI complex by staining with Coomassie blue dye; its presence previously went unrecognized because it does not stain with silver. SNF11 interacts with a 40-residue sequence of SNF2 that is highly conserved, suggesting that SNF11 homologs exist in other organisms.
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PMID:SNF11, a new component of the yeast SNF-SWI complex that interacts with a conserved region of SNF2. 762 18

NtrC is the transcriptional activator for nitrogen-regulated promoters and, as a response regulator, belongs to the protein family of two-component systems. The activity of all response regulators is modulated by phosphorylation of the conserved N-terminal receiver domain. Phosphorylation of the dimeric NtrC has two consequences: (i) a strong increase in the cooperative binding of NtrC to two adjacent binding sites and (ii) activation of NtrC as an ATPase. Here we show that phosphorylation of NtrC is not sufficient for activation of NtrC. At low protein concentrations (50 nM), phosphorylated NtrC was only active as an ATPase upon cooperative binding to DNA. At high protein concentrations (above 50 nM), NtrC was active in the absence of DNA, and activation occurred in parallel with the formation of high-molecular-weight aggregates. We infer that activation of NtrC involves an interaction between two NtrC-P dimers and proceeds in two steps. The first step is the phosphorylation of NtrC. The second step is the interaction between two NtrC-P dimers. This interaction induces the conformational change in NtrC-P to the active conformation.
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PMID:Mechanism of activation of a response regulator: interaction of NtrC-P dimers induces ATPase activity. 766 84

The initiation of transcription at the sigma 54-dependent promoter glnAp2 of Escherichia coli is activated by the protein NR1(NTRC)-phosphate, which binds to two sites located upstream of the promoter that together constitute an enhancer. The cooperative binding facilitates the oligomerization of NR1-phosphate endowing it with the ATPase activity required for its ability to serve as transcriptional activator. We show here that these sites can be replaced by sequence-dependent superhelical inserts, lacking any homology to the nucleotide sequence of the enhancers. These superhelical inserts, irrespective of their chirality, are as effective as the paired sites in binding NR1-phosphate and in stimulating its oligomerization. We conclude that a specific sequence of nucleotides and the three-dimensional structure of DNA can determine its affinity for the NR1 activator protein capable of binding to DNA.
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PMID:A sequence-induced superhelical DNA segment serves as transcriptional enhancer. 785 2

We have sequenced downstream of the last previously sequenced gene of the glucitol operon (gutABDMRQ) in E. coli and have found that gutQ is the last gene of this operon. Downstream of the gutQ gene is found a palindromic unit (PU or REP sequence), followed by a large open reading frame of 1515 (or possibly 1590) bps transcribed in the direction opposite to that of the gut operon. This open reading frame encodes a protein of 504 (or possibly 529) amino acids with a tripartite structure. The N-terminal "receiver" domain of 187 (or possibly 212) residues is homologous to the FhlA protein of E. coli, a transcriptional activator of formate hydrogen lyase. It may possess a short domain at its extreme N-terminus exhibiting sequence similarity to carbohydrate binding proteins. The central ATPase domain (236 residues) exhibits greatest sequence similarity to the HydG protein of E. coli, a transcriptional activator of labile hydrogenase. The C-terminal DNA binding domain (81 residues) is homologous to NtrX of Azorhizobium caulinodans, a protein involved in transcriptional regulation of nitrogen fixation. Sequence comparisons with well-characterized transcription factors suggest that ORF504 encodes a protein that hydrolyzes ATP to generate the open transcriptional initiation complex of sigma 54-dependent promoters, possibly in response to redox conditions and/or ligand binding. We propose that this tripartite transcription factor arose by fusion of gene fragments encoding its three constituent modules.
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PMID:DNA sequence of a gene in Escherichia coli encoding a putative tripartite transcription factor with receiver, ATPase and DNA binding domains. 789 55

The Drosophila brahma (brm) gene encodes an activator of homeotic genes that is highly related to the yeast transcriptional activator SWI2 (SNF2), a potential helicase. To determine whether brm is a functional homolog of SWI2 or merely a member of a family of SWI2-related genes, we searched for additional Drosophila genes related to SWI2 and examined their function in yeast cells. In addition to brm, we identified one other Drosophila relative of SWI2: the closely related ISWI gene. The 1,027-residue ISWI protein contains the DNA-dependent ATPase domain characteristic of the SWI2 protein family but lacks the three other domains common to brm and SWI2. In contrast, the ISWI protein is highly related (70% identical) to the human hSNF2L protein over its entire length, suggesting that they may be functional homologs. The DNA-dependent ATPase domains of brm and SWI2, but not ISWI, are functionally interchangeable; a chimeric SWI2-brm protein partially rescued the slow growth of swi2- cells and supported transcriptional activation mediated by the glucocorticoid receptor in vivo in yeast cells. These findings indicate that brm is the closest Drosophila relative of SWI2 and suggest that brm and SWI2 play similar roles in transcriptional activation.
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PMID:Identification and characterization of Drosophila relatives of the yeast transcriptional activator SNF2/SWI2. 790 17

The ANFA protein is the transcriptional activator of the sigma 54-dependent anfHDGK operon, which codes for the structural genes of the third nitrogenase system in Azotobacter vinelandii. We have purified, in soluble active form, an N-terminally truncated form of the protein, delta ANFA, which activates transcription from the anfH promoter and other sigma 54-dependent promoters in a purified transcription system. Sequences upstream of the anfH promoter and the presence of the integration host factor protein stimulate transcription, and we have shown that delta ANFA binds to sites situated between 200 and 300 base pairs upstream of the anfH promoter. In common with other sigma 54-dependent activators, ANFA has a highly conserved ATP binding motif in its central domain, and we have demonstrated that ATP or GTP is required for productive complex formation and that the purified truncated protein has a constitutive ATPase activity, which is presumably required to drive open complex formation.
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PMID:Purification and in vitro activity of a truncated form of ANFA. Transcriptional activator protein of alternative nitrogenase from Azotobacter vinelandii. 802 76

The tumour suppressor p53 is required to induce programmed cell death (apoptosis) by DNA-damaging agents. As p53 is a transcriptional activator that mediates gene induction after DNA damage, it has been proposed to be a genetic switch that activates apoptosis-mediator genes. Here we evaluate the role of p53 in DNA-damage-induced apoptosis by establishing derivatives of GHFT1 cells, that are somatotropic progenitors immortalized by expression of SV40 T-antigen, which express a temperature-sensitive p53 mutant. In these cells induction of apoptosis by DNA damage depends strictly on p53 function. A shift to the permissive temperature triggers apoptosis following DNA damage, but this is independent of new RNA or protein synthesis. The extent of apoptotic DNA cleavage is directly proportional to the period during which p53 is functional. These results do not support the proposal that p53 is an activator of apoptosis-mediator genes but rather indicate that p53 either represses genes necessary for cell survival or is a component of the enzymatic machinery for apoptotic cleavage or repair of DNA.
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PMID:p53-dependent apoptosis in the absence of transcriptional activation of p53-target genes. 802 56

Heat shock proteins of the 82-90 kDa class (hsp82 and hsp90) are abundant, conserved, and ubiquitous from prokaryotes to eukaryotes. Although proposed to be chaperones, they had not been reported to possess enzymatic activity until our recent observation that pure trypanosomatid hsp83 had potent ATPase activity (Nadeau, K., Sullivan, M., Engman, D., and Walsh, C. T. (1992) Protein Sci. 1, 970-979). We have now purified the hsp90 homolog from Escherichia coli (HtpG) and from Saccharomyces cerevisiae (hsp82) to homogeneity and observe ATPase activity with kcat values of 3 min-1 and 140 min-1. In addition, examinations of purified rat hsp90 and human hsp90 detect ATPase activity with a kcat of 0.6 min-1 and 10 min-1. Each of these hsp90s undergoes autophosphorylation on serine or threonine residues. In prokaryotes and eukaryotes, the induction of hsps during heat shock is controlled, respectively, by the binding of an alternate sigma 32 or a transcriptional activator (heat shock factor or HSF) at heat shock promoter elements. Here we show that E. coli HtpG immobilized to Affi-Gel beads selectively retains sigma 32 while the yeast hsp90 and rat hsp90 retain HSF. The peptidyl prolyl isomerase hsp59 of the FK506 binding class is known to bind to hsp90. We also detect binding of the other family of PPIases, the cyclophilins, to immobilized hsp90, consistent with a functional convergence of protein foldases.
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PMID:Hsp90 chaperonins possess ATPase activity and bind heat shock transcription factors and peptidyl prolyl isomerases. 841 47

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