Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P51532 (transcriptional activator)
6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A transgenic position effect that causes activator-independent gene expression has been described previously for three Neurospora crassa phosphate-repressible genes. We report analogous findings for two additional positively regulated genes, qa-2+ and ars-1+, indicating that such position effects are not limited to genes involved in phosphorus metabolism. In addition, we have characterized a number of mutants that display activator-independent gene expression. Each of these mutants contains a chromosomal rearrangement with one breakpoint located in the 5'-upstream region of the affected gene. This suggests that the rearrangements are associated with activator-independent gene expression and that these cis-acting mutations may represent a position effect similar to that responsible for rendering some transgenes independent of their transcriptional activators. We suggest that positively regulated genes in N. crassa are normally held in a transcriptionally repressed state by a cis-acting mechanism until specifically activated. Disruption of this cis-acting mechanism, either by random integration of a gene by transformation or by chromosomal rearrangement, renders these genes independent or partly independent of the transcriptional activator on which they normally depend.
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PMID:Activator-independent gene expression in Neurospora crassa. 885 41

ArcA protein bearing an amino-terminal, oligohistidine extension has been purified, and its DNA binding activity has been characterized with or without prior incubation with carbamoyl phosphate. Electrophoretic mobility shift assays and DNase I protection assays indicate that where the phosphorylated form of the ArcA protein (ArcA-P) is expected to act as a transcriptional repressor (e.g., of lctPRD and gltA-sdhCDAB), the effect is likely to be mediated by sequestration of cis-controlling transcriptional regulatory elements. In contrast, in the case of cydAB, for which ArcA-P is expected to function as a transcriptional activator, two discrete binding sites have been identified upstream of a known promoter, and activation from these sites is likely to be mediated by a mechanism typical of the type I class of prokaryotic transcriptional activators. An additional ArcA-P binding site has also been located downstream of the known promoter, and a distinct role for this site in the regulation of the cydAB operon during anoxic growth transitions is suggested. These results are discussed within the framework of an overall model of signaling by the Arc two-component signal transduction system in response to changes in aerobiosis.
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PMID:Transcriptional control mediated by the ArcA two-component response regulator protein of Escherichia coli: characterization of DNA binding at target promoters. 889 25

The production of the red-pigmented tripyrrole antibiotic undecylprodigiosin (Red) by Streptomyces coelicolor A3(2) depends on two pathway-specific regulatory genes, redD and redZ. RedD is homologous to several other proteins that regulate antibiotic production in streptomycetes; RedZ is a member of the response regulator family. redZ transcripts were detected during exponential growth and increased in amount during transition and stationary phases; transcription of redD was confined to the two latter stages of growth. Whereas mutation of redD had no effect on redZ transcription, transcription of redD was highly dependent on redZ, suggesting that RedZ is a transcriptional activator of redD. bldA, which encodes the only tRNA of S. coelicolor that can efficiently translate the rare leucine codon UUA, is required for Red production at higher phosphate concentrations. While the redD transcript contains no UUA codons, the redZ mRNA contains one. Transcription of redZ appeared to be unaffected in a bldA mutant; in contrast, redD transcription was undetectable, consistent with the translational dependence of redZ on bldA and the transcriptional dependence of redD on redZ. Red production in a bldA mutant was restored by multiple copies of redZ, presumably reflecting a low level of mistranslation of the redZ UUA codon, while multiple copies of redD had no effect, presumably a consequence of the severe dependence of redD transcription on RedZ. Transcription of redZ appears to be negatively autoregulated.
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PMID:bldA dependence of undecylprodigiosin production in Streptomyces coelicolor A3(2) involves a pathway-specific regulatory cascade. 900 13

The expression of virulence factor genes in Bordetella pertussis is mediated by the BvgA-BvgS two-component signal transduction system. The response regulator, BvgA, acts directly as a transcriptional activator at the loci encoding pertussis toxin (ptx) and filamentous hemagglutinin (fha). Previous studies have demonstrated that these two loci are differentially regulated by BvgA. As an initial step in gaining insight into the mechanism underlying this differential regulation, we initiated DNA binding and in vitro transcription analyses to examine the activities of BvgA and RNA polymerase (RNAP) purified from both B. pertussis and Escherichia coli at the fha promoter. We discovered that unphosphorylated BvgA binds to a single region (-100 to -70, relative to the start of transcription), whereas phosphorylated BvgA binds both this region and another, farther downstream, that extends to the -35 nucleotide. In the absence of BvgA, RNAP binds a region farther upstream than expected (-104 to -35). However, occupation of both sites by BvgA phosphate repositions RNAP to the site used in vivo. The binding of BvgA phosphate to the downstream site correlates with in vitro transcriptional activity at the fha promoter. As the DNA binding and transcription activities of the E. coli-derived RNAP are similar to those observed for the B. pertussis enzyme, we employed several mutant E. coli proteins in in vitro transcription analyses. We observed that polymerases carrying either a deletion of the C-terminal domain of the alpha subunit or substitution of alanine at either of two critical residues within this domain were severely impaired in the ability to mediate BvgA-activated transcription at fha.
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PMID:Nature of DNA binding and RNA polymerase interaction of the Bordetella pertussis BvgA transcriptional activator at the fha promoter. 904 38

The transcriptional regulation of two energy metabolism operons, hya and cbdAB-appA, has been investigated during carbon and phosphate starvation. The hya operon encodes hydrogenase 1, and the cbdAB-appA operon encodes cytochrome bd-II oxidase and acid phosphatase, pH 2.5. Both operons are targets for the transcriptional activator AppY. In exponential growth, expression of the hya and cbd operons was reduced in an rpoS mutant lacking the RNA polymerase sigmaS factor, and the induction of the two operons by entry into stationary phase in rich medium was strongly dependent on sigmaS. Both operons were induced by carbon starvation, but only induction of the hya operon was dependent on sigmaS, whereas that of the cbd promoter was dependent on AppY. The appY gene also showed sigmaS-dependent induction by carbon starvation. The cbd and hya operons were also found to exhibit a sigmaS-dependent transient twofold induction by osmotic upshift. Like the cbd operon, the hya operon was highly induced by phosphate starvation. For both operons the induction was strongly dependent on AppY. The induction ratio of the two operons was the same in rpoS+ and rpoS mutant strains, indicating that the phosphate starvation-induced increase in sigmaS concentration is not involved in the phosphate regulation of these operons.
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PMID:Effects of sigmaS and the transcriptional activator AppY on induction of the Escherichia coli hya and cbdAB-appA operons in response to carbon and phosphate starvation. 907 97

Nuclear respiratory factor 1 (NRF-1) is a transcriptional activator that acts on a diverse set of nuclear genes required for mitochondrial respiratory function in mammalian cells. These genes encode respiratory proteins as well as components of the mitochondrial transcription, replication, and heme biosynthetic machinery. Here, we establish that NRF-1 is a phosphoprotein in vivo. Phosphorylation occurs on serine residues within a concise NH2-terminal domain with the major sites of phosphate incorporation at serines 39, 44, 46, 47, and 52. The in vivo phosphorylation pattern can be approximated in vitro by phosphorylating recombinant NRF-1 with purified casein kinase II. Phosphate incorporation at the sites utilized in vivo results in a marked stimulation of DNA binding activity which is not observed in mutated proteins lacking these sites. Pairwise expression of the wild-type protein with each of a series of truncated derivatives in transfected cells results in the formation of a dimer between wild-type and mutant forms demonstrating that a homodimer is the active binding species. Although NRF-1 can dimerize in the absence of DNA, phosphorylation does not enhance the formation of these dimers. These findings suggest that phosphorylation results in an intrinsic change in the NRF-1 dimer enhancing its ability to bind DNA.
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PMID:Serine phosphorylation within a concise amino-terminal domain in nuclear respiratory factor 1 enhances DNA binding. 922 45

An Escherichia coli K-12 model system was developed for studying the VanS-VanR two-component regulatory system required for high-level inducible vancomycin resistance in Enterococcus faecium BM4147. Our model system is based on the use of reporter strains with lacZ transcriptional and translational fusions to the PvanR or PvanH promoter of the vanRSHAX gene cluster. These strains also express vanR and vanS behind the native PvanR promoter, the arabinose-inducible ParaB promoter, or the rhamnose-inducible PrhaB promoter. Our reporter strains have the respective fusions stably recombined onto the chromosome in single copy, thereby avoiding aberrant regulatory effects that may occur with plasmid-bearing strains. They were constructed by using allele replacement methods or a conditionally replicative attP plasmid. Using these reporter strains, we demonstrated that (i) the response regulator VanR activates PvanH, but not PvanR, expression upon activation (phosphorylation) by the partner kinase VanS, the noncognate kinase PhoR, or acetyl phosphate, indicating that phospho-VanR (P-VanR) is a transcriptional activator; (ii) VanS interferes with activation of VanR by PhoR or acetyl phosphate, indicating that VanS also acts as a P-VanR phosphatase; and (iii) the conserved, phosphate-accepting histidine (H164) of VanS is required for activation (phosphorylation) of VanR but not for deactivation (dephosphorylation) of P-VanR. Similar reporter strains may be useful in new studies on these and other interactions of the VanS-VanR system (and other systems), screening for inhibitors of these interactions, and deciphering the molecular logic of the signal(s) responsible for activation of the VanS-VanR system in vivo. Advantages of using an E. coli model system for in vivo studies on VanS and VanR are also discussed.
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PMID:Transcriptional regulation of the Enterococcus faecium BM4147 vancomycin resistance gene cluster by the VanS-VanR two-component regulatory system in Escherichia coli K-12. 929 51

The INS-r3-GK27 insulinoma cells are endowed with artificially inducible glucokinase under control of the reverse tetracycline-dependent transcriptional activator. Moderate induction of glucokinase has been shown to result in proportionate increases in glycolytic flux and in potentiation of glucose effects on insulin secretion and pyruvate kinase gene expression. In cells with 20-fold overexpression of glucokinase, however, glucose activation of secretion and gene expression was severely impaired. Measurements of the glycolytic flux in cells with 7- and 21-fold increases in glucokinase activity and determination of the flux control coefficient of this enzyme showed that control of glycolysis at the glucokinase step was lost in the cells at the higher level of overexpression. Challenging the cells with glucose above 6 mM resulted in massive accumulation of glucose 6-phosphate and caused a rapid and sustained depletion of cellular ATP, in contrast with the glucose-induced rise in ATP in cells with wild-type glucokinase levels. Loss of cell viability ensued upon prolonged culture in high glucose. In summary, in insulinoma beta cells strongly overexpressing glucokinase, an imbalance between glucose phosphorylation and turnover of glucose 6-phosphate resulted in acute glucose intolerance due to trapping of cellular orthophosphate in dead-end product and severe paralysis of energy metabolism.
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PMID:Acute glucose intolerance in insulinoma cells with unbalanced overexpression of glucokinase. 932 99

The GvpE protein involved in the regulation of gas vesicles synthesis in halophilic archaea has been identified as the transcriptional activator for the promoter located upstream of the gvpA gene encoding the major gas vesicle structural protein GvpA. A closer inspection of the GvpE protein sequence revealed that GvpE resembles basic leucine-zipper proteins typically involved in the gene regulation of eukarya. A molecular modelling study of the C-terminal part implied a cluster of basic amino acid residues constituting the DNA-binding site (DNAB) followed by an amphiphilic helix, suitable for the formation of a leucine-zipper structure within a GvpE dimer. The model of a GvpE dimer docked onto DNA indicated that the side-chains of the basic residues could perfectly interact with the negatively charged phosphate groups of the DNA backbone. Substitution of three basic amino acid residues of this putative DNAB by alanine and/or glutamate generated mutated GvpE proteins. None of these was able to activate the c-gvpA promoter in vivo, indicating that these basic residues are required for GvpE activity. This identification of an archaeal gene regulator displaying similarity to eukaryal regulatory proteins implies that the basic transcription machinery of eukarya and archaea are closely related, and that the regulatory proteins have evolved according to common principles.
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PMID:The transcriptional activator GvpE for the halobacterial gas vesicle genes resembles a basic region leucine-zipper regulatory protein. 964 59

The first molecular and genetic characterization of a biochemical pathway for oxidation of the reduced phosphorus (P) compounds phosphite and hypophosphite is reported. The pathway was identified in Pseudomonas stutzeri WM88, which was chosen for detailed studies from a group of organisms isolated based on their ability to oxidize hypophosphite (+1 valence) and phosphite (+3 valence) to phosphate (+5 valence). The genes required for oxidation of both compounds by P. stutzeri WM88 were cloned on a single ca. 30-kbp DNA fragment by screening for expression in Escherichia coli and Pseudomonas aeruginosa. Two lines of evidence suggest that hypophosphite is oxidized to phosphate via a phosphite intermediate. First, plasmid subclones that conferred oxidation of phosphite, but not hypophosphite, upon heterologous hosts were readily obtained. All plasmid subclones that failed to confer phosphite oxidation also failed to confer hypophosphite oxidation. No subclones that conferred only hypophosphite expression were obtained. Second, various deletion derivatives of the cloned genes were made in vitro and recombined onto the chromosome of P. stutzeri WM88. Two phenotypes were displayed by individual mutants. Mutants with the region encoding phosphite oxidation deleted (based upon the subcloning results) lost the ability to oxidize either phosphite or hypophosphite. Mutants with the region encoding hypophosphite oxidation deleted lost only the ability to oxidize hypophosphite. The phenotypes displayed by these mutants also demonstrate that the cloned genes are responsible for the P oxidation phenotypes displayed by the original P. stutzeri WM88 isolate. The DNA sequences of the minimal regions implicated in oxidation of each compound were determined. The region required for oxidation of phosphite to phosphate putatively encodes a binding-protein-dependent phosphite transporter, an NAD+-dependent phosphite dehydrogenase, and a transcriptional activator of the lysR family. The region required for oxidation of hypophosphite to phosphite putatively encodes a binding-protein-dependent hypophosphite transporter and an alpha-ketoglutarate-dependent hypophosphite dioxygenase. The finding of genes dedicated to oxidation of reduced P compounds provides further evidence that a redox cycle for P may be important in the metabolism of this essential, and often growth-limiting, nutrient.
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PMID:Molecular genetic analysis of phosphite and hypophosphite oxidation by Pseudomonas stutzeri WM88. 979 Nov 2


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