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)

Streptococcus thermophilus strain CNRZ 302 is unable to ferment galactose, neither that generated intracellularly by lactose hydrolysis nor the free sugar. Nevertheless, sequence analysis and complementation studies with Escherichia coli demonstrated that strain CNRZ 302 contained structurally intact genes for the Leloir pathway enzymes. These were organized into an operon in the order galKTE, which was preceded by a divergently transcribed regulator gene, galR, and followed by a galM gene and the lactose operon lacSZ. Results of Northern blot analysis showed that the structural gal genes were transcribed weakly, and only in medium containing lactose, by strain CNRZ 302. However, in a spontaneous galactose-fermenting mutant, designated NZ302G, the galKTE genes were well expressed in cells grown on lactose or galactose. In both CNRZ 302 and the Gal(+) mutant NZ302G, the transcription of the galR gene was induced by growth on lactose. Disruption of galR indicated that it functioned as a transcriptional activator of both the gal and lac operons while negatively regulating its own expression. Sequence analysis of the gal promoter regions of NZ302G and nine other independently isolated Gal(+) mutants of CNRZ 302 revealed mutations at three positions in the galK promoter region, which included substitutions at positions -9 and -15 as well as a single-base-pair insertion at position -37 with respect to the main transcription initiation point. Galactokinase activity measurements and analysis of gusA reporter gene fusions in strains containing the mutated promoters suggested that they were gal promoter-up mutations. We propose that poor expression of the gal genes in the galactose-negative S. thermophilus CNRZ 302 is caused by naturally occurring mutations in the galK promoter.
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PMID:Activation of silent gal genes in the lac-gal regulon of Streptococcus thermophilus. 1115 30

Despite major advances in characterizing the eukaryotic transcriptional machinery, the function of promoter-specific transcriptional activators (activators) is still not understood. For example, in no case have the direct in vivo targets of a transcriptional activator been unambiguously identified, nor has it been resolved whether activators have a single essential target or multiple redundant targets. Here we address these issues for the prototype acidic activator yeast Gal4p. Gal4p binds to the upstream activating sequence (UAS) of GAL1 and several other GAL genes and stimulates transcription in the presence of galactose. Previous studies have shown that GAL1 transcription is dependent on the yeast SAGA (Spt/Ada/GCN5/acetyltransferase) complex. Using formaldehyde-based in vivo cross-linking, we show that the Gal4p activation domain recruits SAGA to the GAL1 UAS. If SAGA is not recruited to the UAS, the preinitiation complex (PIC) fails to assemble at the GAL1 core promoter, and transcription does not occur. SAGA, but not other transcription components, is also recruited by the Gal4p activation domain to a plasmid containing minimal Gal4p-binding sites. Recruitment of SAGA by Gal4p and stimulation of PIC assembly is dependent on several SAGA subunits but not the SAGA histone acetyl-transferase (HAT) GCN5. Based on these and other results, we conclude that SAGA is an essential target of Gal4p that, following recruitment to the UAS, facilitates PIC assembly and transcription.
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PMID:SAGA is an essential in vivo target of the yeast acidic activator Gal4p. 1148 88

The genes of the Escherichia coli maltose regulon are controlled by MalT, the specific transcriptional activator which, together with the inducer maltotriose and ATP, is essential for mal gene transcription. Network regulation in this system affects the function of MalT and occurs on two levels. The first concerns the expression of malT. It has long been known that malT is under catabolite repression and thus under the control of the cAMP/CAP complex. We found that, in addition, the global regulator Mlc is a repressor for malT transcription. The repressor activity of Mlc is controlled by the transport status of the glucose-specific enzyme EIICB of the PTS that causes sequestration (and inactivation as a repressor) of Mlc when glucose is transported. The second level of MalT regulation affects its activity. MalT is activated by maltotriose which is not only formed when the cells are growing on any maltodextrin but also, in low amounts, endogenously when the cells grow on non-maltodextrin carbon sources. Thus, cellular metabolism, for instance degradation of galactose or trehalose, can cause mal gene induction. It was found that unphosphorylated internal glucose takes part in endogenous maltodextrin biosynthesis and is therefore a key element in endogenous mal gene expression. In addition to the maltotriose-dependent activation, MalT can interact with three different enzymes that lead to its inactivation as a transcriptional activator. The first is MaIK, the energy transducing ABC subunit of the maltodextrin transport system. Transport controls the interaction of MalK and MalT thus affecting gene expression. The second enzyme is MalY, a pyridoxal phosphate containing enzyme exhibiting cystathionase activity. The crystal structure of MalY was established and mutations in MalY that reduce mal gene repression map in a hydrophobic MalT interaction patch on the surface of the enzyme. The last enzyme is a soluble esterase of as yet unknown function. When overproduced, this enzyme specifically reduces mal gene expression and affects the activity of MalT in an in vitro transcription assay.
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PMID:Network regulation of the Escherichia coli maltose system. 1193 62

The genes encoding the enzymes required for galactose metabolism in Saccharomyces cerevisiae are controlled at the level of transcription by a genetic switch consisting of three proteins: a transcriptional activator, Gal4p; a transcriptional repressor, Gal80p; and a ligand sensor, Gal3p. The switch is turned on in the presence of two small molecule ligands, galactose and ATP. Gal3p shows a high degree of sequence identity with Gal1p, the yeast galactokinase. We have mapped the interaction between Gal80p and Gal3p, which only occurs in the presence of both ligands, using protease protection experiments and have shown that this involves amino acid residue 331 of Gal80p. Gel-filtration experiments indicate that Gal3p, or the galactokinase Gal1p, interact directly with Gal80p to form a complex with 1:1 stoichiometry.
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PMID:Gal3p and Gal1p interact with the transcriptional repressor Gal80p to form a complex of 1:1 stoichiometry. 1196 51

Galactokinase (EC 2.7.1.6) catalyses the first step in the catabolism of galactose. Yeast galactokinase, Gal1p, and the closely related but catalytically inactive Gal3p, also function as ligand sensors in the GAL genetic switch. In the presence of galactose and ATP (the substrates of the reaction catalysed by Gal1p) Gal1p or Gal3p can bind to Gal80p, a transcriptional repressor. This relieves the inhibition of a transcriptional activator, Gal4p, and permits expression of the GAL genes. In order to learn more about the mechanism of ligand sensing by Gal3p and Gal1p, we studied the kinetics of the reaction catalysed by Gal1p. Galactose-1-phosphate, a product of the reaction, is a mixed inhibitor both with respect to galactose and to ATP suggesting that the reaction proceeds via a compulsory, ordered, ternary complex mechanism. There is little variation in either the turnover number or the specificity constants in the pH range 6.0-9.5, implying that no catalytic base is required in the reaction. These data are discussed both in the context of galactokinase enzymology and their implications for the mechanism of transcriptional induction.
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PMID:Kinetic analysis of yeast galactokinase: implications for transcriptional activation of the GAL genes. 1210 3

The maltose permease family of Saccharomyces cerevisiae comprises five proteins, three of which are characterized, MAL31, MAL61 and AGT1 and two putative permeases, YDL247w (MPH2) and YJR160c (MPH3). The two uncharacterized permeases share 100% identity and have 75% identity with MAL31 and MAL61 and 55% identity with AGT1. Characterization of the genes YDL247w and YJR160c confirmed that they encode alpha-glucoside permeases capable of transporting maltose, maltotriose, alpha-methylglucoside and turanose. Analysis of the promoter regions identified regulatory elements, binding sites for the transcriptional activator, Malx3p and the inhibitory protein, Mig1p. Further analysis of the flanking sequences located blocks of identity covering five open reading frames, indicating that this region was involved in chromosomal block duplication. The members of the maltose permease family are proteins that have strongly overlapping but nevertheless distinct functions, which is a selective advantage for yeast, as it reflects successful adaptation to the variety of environmental conditions to which the yeast cells are exposed; such adaptability is very important in an industrial context.
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PMID:Characterization of the putative maltose transporters encoded by YDL247w and YJR160c. 1221 Aug 97

Imp2p (Yil154c) is a transcriptional activator involved in glucose derepression of the maltose, galactose and raffinose utilization pathways and in resistance to thermal, oxidative or osmotic stress. We analysed the role of Imp2 in the regulation of GAL genes. Imp2 was shown to have a positive effect on glucose derepression of Leloir pathway genes and their activator gene GAL4. The effect of Imp2 on galactose metabolism was shown to be partially dependent on Mig1p. The Mig1-independent role depends on Nrg1p. However, disruption of both MIG1 and NRG1 only partially relieves the glucose repression of GAL genes in the Deltaimp2 mutant, indicating that Imp2 must also have other function(s). Moreover, the interaction between IMP2 and GAL6/BLH1, a recently isolated gene involved in the regulation of GAL genes that shares with Imp2 the ability to protect cells from the glycopeptide bleomycin, was also analysed. The results suggest a major role of Imp2 in a GAL6-independent pathway.
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PMID:MIG1-dependent and MIG1-independent regulation of GAL gene expression in Saccharomyces cerevisiae: role of Imp2p. 1455 42

Hypoxia-inducible factor (HIF)-1alpha is a transcription factor that controls expression of genes responsive to low oxygen tension, including vascular endothelial growth factor (VEGF), erythropoietin, and glycolytic enzymes. The activity of HIF-1alpha is regulated by binding to the transcriptional co-activator cAMP-response element-binding protein-binding protein (CBP)/p300. Using the yeast two-hybrid screening system, we found that the inhibitory domain of HIF-1alpha strongly interacted with the C-terminal domain of histone deacetylase (HDAC) 7. The o-nitrophenyl beta-d-galactopyranoside assay revealed that regions containing amino acids 735-785 of HIF-1alpha and amino acids 669-952 of HDAC7 were minimum contact sites of the interaction. The binding of HDAC7 with HIF-1alpha was reproduced in HEK293 cells grown under normoxic and hypoxic conditions (2% O(2)). HDAC7 bound solely to HIF-1alpha among other HIF-alpha family members, including HIF-2alpha and HIF-3alpha, whereas HIF-1alpha only interacted with HDAC7 in the class II HDAC family. Although HDAC7 was localized dominantly in the cytoplasm at normal oxygen concentrations, HDAC7 co-translocated to the nucleus with HIF-1alpha under hypoxic conditions. In the nucleus, HDAC7 increased transcriptional activity of HIF-1alpha through the formation of a complex with HIF-1alpha, HDAC7, and p300. Taken together, these results indicate that HDAC7 is a novel transcriptional activator of HIF-1alpha
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PMID:Histone deacetylase 7 associates with hypoxia-inducible factor 1alpha and increases transcriptional activity. 1528 Mar 64

A new esterase-encoding gene was found in the draft genome sequence of Lactobacillus casei BL23 (CECT5275). It is located in an operon together with genes encoding the EIIA, EIIB, EIIC, and EIID proteins of a mannose class phosphoenolpyruvate:sugar phosphotransferase system. After overproduction in Escherichia coli and purification, the esterase could hydrolyze acetyl sugars, hence the operon was named esu for esterase-sugar uptake genes. Upstream of the genes encoding the EII components (esuABCD) and the esterase (esuE), two genes transcribed in the opposite sense were found which encode a Bacillus subtilis LevR-like transcriptional activator (esuR) and a sigma54-like transcriptional factor (rpoN). As compared with the wild-type strain, elevated fructose phosphorylation was detected in L. casei mutants constitutively expressing the esu operon. However, none of the many sugars tested could induce the esu operon. The fact that EsuE exhibits esterase activity on acetyl sugars suggests that this operon could be involved in the uptake and metabolism of esterified sugars. Expression of the esu operon is similar to that of the B. subtilis lev operon: it contains a -12,-24 consensus promoter typical of sigma54-regulated genes, and EsuR and RpoN are essential for its transcription which is negatively regulated by EIIB(Esu). The esuABCDE transcription unit represents the first sigma54-regulated operon in lactobacilli. Furthermore, replacement of His852 in the phosphoenolpyruvate:sugar phosphotransferase system regulation domain II of EsuR with Ala indicated that the transcription activator function of EsuR is inhibited by EIIB(Esu)-mediated phosphorylation at His852.
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PMID:An esterase gene from Lactobacillus casei cotranscribed with genes encoding a phosphoenolpyruvate:sugar phosphotransferase system and regulated by a LevR-like activator and sigma54 factor. 1592 3

The ability of Saccharomyces cerevisiae to utilize galactose is regulated by the nucleo-cytoplasmic shuttling of a transcriptional repressor, the Gal80 protein. Gal80 interacts with the transcriptional activator Gal4 in the nucleus and inhibits its function, preventing induction of the GAL genes. In response to galactose, the relative amounts of Gal80 in the cytoplasm and the nucleus are modulated by the action of a signal transducer, Gal3. Although it has been speculated that Gal3 binds galactose, this has not been experimentally demonstrated. In this study, we show that replacement of a conserved tyrosine in Gal3 by tryptophan leads to a reduction of its constitutive activity in the absence of galactose. In addition, this mutant protein was fully functional in vivo only when high concentrations of galactose were present in the medium. When overexpressed, the mutant was found to activate the genes GAL1 and GAL7/10 differentially. The implications of these findings for the fine regulation of GAL genes, and its physiological significance, are discussed.
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PMID:Replacement of a conserved tyrosine by tryptophan in Gal3p of Saccharomyces cerevisiae reduces constitutive activity: implications for signal transduction in the GAL regulon. 1616 Aug 53

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