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)

Heme regulation of the activity of diverse proteins was thought to be mediated by heme-responsive motifs (HRMs). The yeast transcriptional activator Hap1 contains seven HRMs: HRM1-7. Three copies of a 17-amino-acid repeat are also located in the region encompassing HRM1 to -6. We examined the effects of these HRMs and repeats on heme regulation of Hap1 activity by deletion analysis and by Ala substitutions of key residues. We found that the effect of mutation or deletion of one HRM or 17-amino-acid repeat on Hap1 heme responsiveness is different from the effect of mutation or deletion of another HRM or repeat. Our data suggest that HRM7 plays a dominant role in mediating heme activation of Hap1 in heme-sufficient cells while HRM1-6 may scavenge heme and cause a low level of Hap1 activation in heme-deficient cells. These results may help in understanding the roles of HRMs in other hemoproteins.
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PMID:Functional analysis of heme regulatory elements of the transcriptional activator Hap1. 1087 49

The CO-sensing transcriptional activator CooA contains a six-coordinate protoheme as a CO sensor. Cys(75) and His(77) are assigned to the fifth ligand of the ferric and ferrous hemes, respectively. In this study, we carried out alanine-scanning mutagenesis and EXAFS analyses to determine the coordination structure of the heme in CooA. Pro(2) is thought to be the sixth ligand of the ferric and ferrous hemes in CooA, which is consistent with the crystal structure of ferrous CooA (Lanzilotta, W. N., Schuller, D. J., Thorsteinsson, M. V., Kerby, R. L., Roberts, G. P., and Poulos, T. L. (2000) Nat. Struct. Biol. 7, 876-880). CooA exhibited anomalous redox chemistry, i.e. hysteresis was observed in electrochemical redox titrations in which the observed reduction and oxidation midpoint potentials were -320 mV and -260 mV, respectively. The redox-controlled ligand exchange of the heme between Cys(75) and His(77) is thought to cause the difference between the reduction and oxidation midpoint potentials.
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PMID:Redox properties and coordination structure of the heme in the co-sensing transcriptional activator CooA. 1109 66

LuxR is the transcriptional activator for quorum-sensing control of luminescence in Vibrio fischeri. A series of alanine-scanning mutants spanning a predicted helix-turn-helix region in the DNA binding domain of LuxR was constructed, and the activity of each of the LuxR mutant proteins in recombinant Escherichia coli was investigated. The region covered by the mutagenesis spanned residues 190 to 224. About half of the alanine-scanning mutants showed activities similar to that of the wild-type LuxR: at least two were positive-control mutants, four appeared to be defective in DNA binding, and several others were characterized as DNA binding affinity mutants. This analysis, taken together with information about other bacterial transcription factors, provides insights into amino acid residues in LuxR that are involved in DNA binding and transcriptional activation.
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PMID:Quorum sensing in Vibrio fischeri: analysis of the LuxR DNA binding region by alanine-scanning mutagenesis. 1111 39

The transcriptional activator CooA from Rhodospirillum rubrum contains a six-coordinate protoheme that acts as a CO sensor in vivo. CO is a physiological effector of CooA and replaces one of the axial ligands of the ferrous heme to form the CO-bound CooA that is active as the transcriptional activator. Cys75 or His77 is coordinated to the ferric and ferrous hemes in CooA, respectively. The redox-controlled ligand exchange between Cys75 and His77 proceeds during the change in the redox state of the heme. The reduction and oxidation midpoint potentials of CooA have been determined to be -320 and -260 mV, respectively. The properties of a functional chimera derived from CRP and CooA suggest that CooA activates the transcription by a similar mechanism to that for CRP at Class II CRP-dependent promoters. Alanine-scanning mutagenesis has revealed that Arg24 and Arg53 of CooA, which will be concerned with the protein-protein interaction with RNA polymerase, are critical amino acid residues for the transcriptional activator activity of CooA, and that Lys26 and Asp94 modulate the activity of CooA.
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PMID:CO sensing and regulation of gene expression by the transcriptional activator CooA. 1113 38

DeltaD transformants containing all 14 gvp genes of Haloferax mediterranei required for gas vesicle formation except for gvpD are gas vesicle overproducers (Vac(++)), whereas DeltaD/D transformants containing the gvpD reading frame under ferredoxin promoter control on a second construct in addition to DeltaD did not form gas vesicles (Vac(-)). The amino acid sequence of GvpD indicates three interesting regions (a putative nucleotide-binding site called the p-loop motif, and two basic regions); these were altered by mutation, and the resulting GvpD(mut) proteins tested in DeltaD/D(mut) transformants for their ability to repress gas vesicle formation. The exchange of amino acids at conserved positions in the p-loop motif resulted in Vac(++) DeltaD/D(mut) transformants, indicating that these GvpD(mut) proteins were unable to repress gas vesicle formation. In contrast, a GvpD(mut) protein with an alteration of a non-conserved proline in the p-loop region (P41A) was still able to repress. The repressing function of the various GvpD proteins was also investigated at the promoter level of the gvpA gene. This promoter is only activated during the stationary phase, depending on the transcriptional activator protein GvpE. Whereas the Vac(++) DeltaD transformants contained very high amounts of gvpA mRNA predominantly in the stationary growth phase, the amount of this transcript was significantly reduced in the Vac(-) transformants DeltaD/D and DeltaD/D(P41A). In contrast, the Vac(++) DeltaD/D(mut) transformants harbouring GvpD(mut) with mutations at conserved positions in the p-loop motif contained large amounts of gvpA mRNA already during exponential growth, suggesting that this motif is important for the GvpD repressor function during this growth phase. The GvpD mutants containing mutations in the two basic regions were mostly defective in the repressing function. The GvpD(mut) protein containing an exchange of the three arginine residues 494RRR496 to alanine residues was able to repress gas vesicle formation. No gvpA mRNA was detectable in this transformant, demonstrating that this GvpD protein was acting as a strong repressor. All these results imply that the GvpD protein is able to prevent the GvpE-mediated gvpA promoter activation, and that the p-loop motif as well as the two basic regions are important for this function.
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PMID:A p-loop motif and two basic regions in the regulatory protein GvpD are important for the repression of gas vesicle formation in the archaeon Haloferax mediterranei. 1116 Aug 1

FlhD is a 13.3 kDa transcriptional activator protein of flagellar genes and a global regulator. FlhD activates the transcription of class II operons in the flagellar regulon when complexed with a second protein FlhC (21.5 kDa). FlhD also regulates other expression systems in Escherichia coli. We are seeking to understand this plasticity of FlhD's DNA-binding specificity and, to this end, we have determined the crystal structure of the isolated FlhD protein. The structure was solved by substituting seleno-methionine for natural sulphur-methionine in FlhD, crystallizing the protein and determining the structure factor phases by the method of multiple-energy anomalous dispersion (MAD). The FlhD protein is dimeric. The dimer is tightly coupled, with an intimate contact surface, implying that the dimer does not easily dissociate. The FlhD monomer is predominantly alpha-helical. The C-termini of both FlhD monomers (residues 83-116) are completely disrupted by crystal packing, implying that this region of FlhD is highly flexible. However, part of the C-terminus structure in chain A (residues 83-98) was modelled using a native FlhD crystal. What is seen in chain A suggests a classic DNA-binding, helix-turn-helix (HTH) motif. FlhD does not bind DNA by itself, so it may be that the DNA-binding HTH motif becomes rigidly defined only when FlhD forms a complex with some other protein, such as FlhC. If this were true, it might explain how FlhD exhibits plasticity in its DNA-binding specificity, as each partner protein with which it forms a complex could allosterically affect the binding specificity of its HTH motif. A disulphide bridge is seen between the unique cysteine residues (Cys-65) of FlhD native homodimers. Alanine substitution at Cys-65 does not affect FlhD transcription activator activity, suggesting that the disulphide bond is not necessary for either dimer stability or this function of FlhD. Electrostatic potential analysis indicates that dimeric FlhD has a negatively charged surface.
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PMID:Crystal structure of the global regulator FlhD from Escherichia coli at 1.8 A resolution. 1116 99

The GAL4 dimerization domain (GAL4-dd) is a powerful transcriptional activator when tethered to DNA in a cell bearing a mutant of the GAL11 protein, named GAL11P. GAL11P (like GAL11) is a component of the RNA-polymerase II holoenzyme. Nuclear magnetic resonance (NMR) studies of GAL4-dd revealed an elongated dimer structure with C(2) symmetry containing three helices that mediate dimerization via coiled-coil contacts. The two loops between the three coiled coils form mobile bulges causing a variation of twist angles between the helix pairs. Chemical shift perturbation analysis mapped the GAL11P-binding site to the C-terminal helix alpha3 and the loop between alpha1 and alpha2. One GAL11P monomer binds to one GAL4-dd dimer rendering the dimer asymmetric and implying an extreme negative cooperativity mechanism. Alanine-scanning mutagenesis of GAL4-dd showed that the NMR-derived GAL11P-binding face is crucial for the novel transcriptional activating function of the GAL4-dd on GAL11P interaction. The binding of GAL4 to GAL11P, although an artificial interaction, represents a unique structural motif for an activating region capable of binding to a single target to effect gene expression.
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PMID:Recruitment of the transcriptional machinery through GAL11P: structure and interactions of the GAL4 dimerization domain. 1131 94

Proteins that have a structure similar to those of LuxR and FixJ comprise a large subfamily of transcriptional activator proteins. Most members of the LuxR-FixJ family contain a similar amino-terminal receiver domain linked by a small region to a carboxy-terminal domain that contains an amino acid sequence similar to the helix-turn-helix (HTH) motif found in other DNA-binding proteins. GerE from Bacillus subtilis is the smallest member of the LuxR-FixJ family. Its 74-amino-acid sequence is similar over its entire length to the DNA binding region of this protein family, including the HTH motif. Therefore, GerE provides a simple model for studies of the role of this HTH domain in DNA binding. Toward this aim, we sought to identify the amino acids within this motif that are important for the specificity of binding to DNA. We examined the effects of single base pair substitutions in the high-affinity GerE binding site on the sigK promoter and found that nucleotides at positions +2, +3, and +4 relative to the transcription start site on the sigK promoter are important for a high-affinity interaction with GerE. We next examined the effects of single alanine substitutions at two positions in the HTH region of GerE on binding to wild-type or mutant target sites. We found that the substitution of an alanine for the threonine at position 42 of GerE produced a protein that binds with equal affinity to two sites that differ by 1 bp, whereas wild-type GerE binds with different affinities to these two sites. These results provide evidence that the amino acyl residues in or near the putative HTH region of GerE and potentially other members of the LuxR-FixJ family determine the specificity of DNA binding.
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PMID:Identification of a DNA binding region in GerE from Bacillus subtilis. 1141 58

CpG-binding protein is a transcriptional activator that exhibits a unique DNA binding specificity for unmethylated CpG motifs. CpG-binding protein contains a cysteine-rich CXXC domain that is conserved in DNA methyltransferase 1, methyl binding domain protein 1, and human trithorax. In vitro DNA binding assays reveal that CpG-binding protein contains a single DNA binding domain comprised of the CXXC domain and a short carboxyl extension. Specific mutation to alanine of individual conserved cysteine residues within the CXXC domain abolishes DNA binding activity. Denaturation/renaturation experiments in the presence of various metal cations demonstrate that the CXXC domain requires zinc for efficient DNA binding activity. Ligand selection of high affinity binding sites from a pool of degenerate oligonucleotides reveals that CpG-binding protein interacts with a variety of sequences that contains the CpG dinucleotide with a consensus binding site of (A/C)CpG(A/C). Mutation of the CpG motif(s) present within ligand-selected oligonucleotides ablates the interaction with CpG-binding protein, and mutation to thymine of the nucleotides flanking the CpG motifs reduces the affinity of CpG-binding protein. Hence, a CpG motif is necessary and sufficient to comprise a binding site for CpG-binding protein, although the immediate flanking sequence affects binding affinity.
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PMID:Identification and characterization of the DNA binding domain of CpG-binding protein. 1157 67

The "two-component" FixLJ system activates nitrogen fixation genes via nifA and fixK in Sinorhizobium meliloti. Like other response regulators, the FixJ protein can be decomposed into an N-terminal phosphorylatable "receiver" domain FixJN and a C-terminal transcriptional activator domain FixJC. The FixJN receiver domain was known to regulate activity of FixJC negatively at the nifA promoter. Here we show a different situation at the fixK promoter where FixJN also contributes positively to transcriptional activation. This promoter-specific effect was mapped by alanine-scanning mutagenesis to the beta2 strand of the receiver domain. This interaction with FixJN is required for the recruitment of RNA polymerase at the fixK promoter by phosphorylated FixJ. Altogether the FixJ receiver domain appears to carry at least four functions, some of which can be separated by mutation: (1) autophosphorylation; (2) inhibition of FixJC; (3) dimerization; (4) transcriptional activation at pfixK. This example illustrates the formidable functional plasticity of receiver domains.
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PMID:Promoter-specific involvement of the FixJ receiver domain in transcriptional activation. 1157 15

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