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)

The transcriptional activator AREA is a member of the GATA family of transcription factors and mediates nitrogen metabolite repression in the fungus Aspergillus nidulans. The nutritional versatility of A. nidulans and its amenability to classical and reverse genetic manipulations make the AREA DNA binding domain (DBD) a useful model for analyzing GATA family DBDs, particularly as structures of two AREA-DNA complexes have been determined. The 109 extant mutant forms of the AREA DBD surveyed here constitute one of the highest totals of eukaryotic transcription factor DBD mutants, are discussed in light of the roles of individual residues, and are compared to corresponding mutant sequence changes in other fungal GATA factor DBDs. Other topics include delineation of the DBD using both homology and mutational truncation, use of frameshift reversion to detect regions of tolerance to mutational change, the finding that duplication of the DBD can apparently enhance AREA function, and use of the AREA system to analyze a vertebrate GATA factor DBD. Some major points to emerge from work on the AREA DBD are (i) tolerance to sequence change (with retention of function) is surprisingly great, (ii) mutational changes in a transcription factor can have widely differing, even opposing, effects on expression of different structural genes so that monitoring expression of one or even several structural genes can be insufficient and possibly misleading, and (iii) a mutational change altering local hydrophobic packing and DNA binding target specificity can markedly influence the behavior of mutational changes elsewhere in the DBD.
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PMID:Mutational analysis of AREA, a transcriptional activator mediating nitrogen metabolite repression in Aspergillus nidulans and a member of the "streetwise" GATA family of transcription factors. 972 1

Utilizing a homologous gene replacement in order to retain the native promoter and 5' and 3' untranslated messenger regions (and thereby ensure physiological validity), we have shown that deletion of the N-terminal 389 amino acids of the transcriptional activator AREA does not result in nitrogen metabolite derepression in Aspergillus nidulans. Our results provide no evidence for a modulating interaction involving the N terminus of AREA and contrast with those of H. K. Lamb, A. L. Dodds, D. R. Swatman, E. Cairns, and A. R. Hawkins (J. Bacteriol. 179:6649-6656, 1997), who used nontargeted ectopic copies of a construct containing a heterologous promoter and untranslated regions. Results obtained with this deletion mutant, nevertheless, provide further evidence for the dispensability of large portions of AREA.
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PMID:Deletion of the 389 N-terminal residues of the transcriptional activator AREA does not result in nitrogen metabolite derepression in Aspergillus nidulans. 979 Nov 30

There was a long-held belief that the gram-positive soil bacterium Bacillus subtilis is a strict aerobe. But recent studies have shown that B. subtilis will grow anaerobically, either by using nitrate or nitrite as a terminal electron acceptor, or by fermentation. How B. subtilis alters its metabolic activity according to the availability of oxygen and alternative electron acceptors is but one focus of study. A two-component signal transduction system composed of a sensor kinase, ResE, and a response regulator, ResD, occupies an early stage in the regulatory pathway governing anaerobic respiration. One of the essential roles of ResD and ResE in anaerobic gene regulation is induction of fnr transcription upon oxygen limitation. FNR is a transcriptional activator for anaerobically induced genes, including those for respiratory nitrate reductase, narGHJI.B. subtilis has two distinct nitrate reductases, one for the assimilation of nitrate nitrogen and the other for nitrate respiration. In contrast, one nitrite reductase functions both in nitrite nitrogen assimilation and nitrite respiration. Unlike many anaerobes, which use pyruvate formate lyase, B. subtilis can carry out fermentation in the absence of external electron acceptors wherein pyruvate dehydrogenase is utilized to metabolize pyruvate.
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PMID:Anaerobic growth of a "strict aerobe" (Bacillus subtilis). 989 97

In Klebsiella pneumoniae, transcription of the nitrogen fixation (nif) genes is regulated in response to molecular oxygen or availability of fixed nitrogen by the coordinated activities of the nifA and nifL gene products. NifA is a nif-specific transcriptional activator, the activity of which is inhibited by interaction with NifL. Nitrogen control of NifL occurs at two levels: transcription of the nifLA operon is regulated by the global ntr system, and the inhibitory activity of NifL is controlled in response to fixed nitrogen by an unknown factor. K. pneumoniae synthesizes two PII-like signal transduction proteins, GlnB, which we have previously shown not to be involved in the response of NifL to fixed nitrogen, and the recently identified protein GlnK. We have now cloned the K. pneumoniae glnK gene, studied its expression, and shown that a null mutation in glnK prevents NifL from responding to the absence of fixed nitrogen, i.e., from relieving the inhibition of NifA activity. Hence, GlnK appears to be involved, directly or indirectly, in NifL-dependent regulation of nif gene expression in K. pneumoniae. Comparison of the GlnB and GlnK amino acid sequences from six species of proteobacteria identifies five residues (residues 3, 5, 52, 54, and 64) which serve to distinguish the GlnB and GlnK proteins.
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PMID:The signal transduction protein GlnK is required for NifL-dependent nitrogen control of nif gene expression in Klebsiella pneumoniae. 997 41

The ntrC gene codes for a transcriptional activator protein that modulates gene expression in response to nitrogen. The cytochrome production pattern of a Rhizobium etli ntrC mutant (CFN2012) was studied. CO difference spectral analysis of membranes showed that CFN2012 produced a terminal oxidase similar to the symbiotic terminal oxidase of bacteroids in free-living cells under aerobic conditions, with a characteristic trough at 553 nm. CFN2012 produced two c-type cytochromes with molecular masses of 27 and 32 kDa, in contrast with the wild-type strain, which produced only a 32-kDa c-type cytochrome. The expression levels of the R. etli fixNOQP operon, which codes for terminal oxidase cbb3, were not affected by the ntrC mutation. However, the production levels of the two c-type cytochromes (27 and 32 kDa) were enhanced at least eightfold when the Bradyrhizobium japonicum fixNOQP operon was expressed in CFN2012 from the nptII promoter (pMSfixc), suggesting that these proteins are subunits FixO (27 kDa) and FixP (32 kDa) of cbb3 and that CFN2012/pMSfixc overproduced this terminal oxidase. CFN2012/pMSfixc showed a significant increase in its symbiotic performance as judged by the determination of nitrogenase activities of plants inoculated with this strain, suggesting that the overproduction of cbb3 terminal oxidase correlates with an enhancement in symbiotic nitrogen fixation.
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PMID:Enhanced nitrogen fixation in a rhizobium etli ntrC mutant that overproduces the bradyrhizobium japonicum symbiotic terminal oxidase cbb3 1022 93

In Klebsiella pneumoniae, NifL modulates the activity of the transcriptional activator NifA in response to combined nitrogen or external molecular oxygen. We recently showed that K. pneumoniae NifL is a flavoprotein which apparently senses oxygen through a redox-sensitive, conformational change. In order to study whether the nitrogen signal might be transmitted to NifA through a stable modification of NifL we characterized the redox properties of NifL synthesized in Escherichia coli in the presence of different nitrogen sources. FAD analyses showed that purified NifL carried FAD as cofactor independent of nitrogen and oxygen availability. The redox potential of NifL synthesized in the presence of ammonium was -277+/-5 mV at pH 8.0 and 25 degrees C, as determined by reduction with dithionite or with enzymatic reduction by xanthine oxidase in the presence of methyl viologen as redox mediator. When synthesized under nitrogen-limiting conditions, NifL showed a redox potential of -274+/-6 mV at pH 8.0 and 25 degrees C. Fully reduced NifL fractions, synthesized under either condition listed above, reoxidized rapidly in the presence of molecular oxygen. These results indicate that for NifL synthesized in E. coli, the redox potential of the NifL-bound FAD is not influenced by the nitrogen source. The two NifL fractions differed, however, in that a non-flavin specific absorbance at 420 nm was found only in NifL synthesized in the presence of ammonium.
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PMID:NifL of Klebsiella pneumoniae: redox characterization in relation to the nitrogen source. 1035 Jun 21

Under low oxygen conditions, induction of many genes required for nitrogen fixation in Bradyrhizobium japonicum depends on the redox-responsive transcriptional activator NifA which is encoded in the fixR-nifA operon. Basal expression of this operon depends on the response regulator RegR and a DNA element located around position -68 in the fixR-nifA promoter region. To investigate the functional properties of RegR and the interaction with its putative cognate kinase, RegS, we overproduced and affinity-purified RegR and a truncated soluble variant of RegS (RegS(C)), both as N-terminally His(6)-tagged proteins. RegS(C) autophosphorylated when incubated with [gamma-(32)P]ATP, and it catalyzed the transfer of the phosphoryl label to RegR. The phosphorylated form of RegS(C) exhibited phosphatase activity on RegR-phosphate. Chemical stability tests and site-specific mutagenesis identified amino acids H219 and D63 of RegS and RegR, respectively, as the phosphorylated residues. Competition experiments with isolated domains demonstrated that the N-terminal but not the C-terminal domain of RegR interacts with RegS(C). Band-shift experiments revealed that phosphorylated RegR had at least eightfold enhanced DNA-binding activity compared with dephosphorylated RegR or the mutant protein RegR-D63N, which cannot be phosphorylated. In conclusion, the RegSR proteins of B. japonicum exhibit functional properties in vitro that are typical of two-component regulatory systems.
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PMID:Phosphorylation, dephosphorylation and DNA-binding of the Bradyrhizobium japonicum RegSR two-component regulatory proteins. 1040 54

The combination of UV/visible/near-IR variable-temperature magnetic circular dichroism (VTMCD) and EPR spectroscopies has been used to investigate the spin states and axial ligation of the heme group in oxidized, reduced, and CO-bound reduced forms of the Rhodospirillum rubrum CO oxidation transcriptional activator protein (CooA) and its H77Y and C75S variants. The energy of the porphyrin(pi)-to-Fe(III) charge-transfer band (8930 cm(-)(1)) and the presence of cysteinate S-to-Fe(III) charge-transfer bands between 600 and 700 nm confirm cysteinate axial ligation to the low-spin Fe(III) hemes in oxidized wild-type and H77Y CooA. In contrast, the major component in the oxidized C75S variant is shown to be a low-spin Fe(III) heme with bis-histidine or histidine/amine axial ligation on the basis of the energy of the porphyrin(pi)-to-Fe(III) charge-transfer band (6240 cm(-)(1)) and the anisotropy of the EPR signal, g = 3.23, approximately 2.06, approximately 1.14. These results confirm Cys75 as the cysteinyl axial ligand in oxidized CooA, indicate that it is replaced as an axial ligand by a histidine in the C75S variant, and reveal the presence of a hitherto unidentified histidine or neutral nitrogen ligand trans to Cys75 in wild-type CooA. Evidence for a Cys75-to-His77 axial ligand switch on reduction of CooA comes from VTMCD studies of the reduced proteins. The VTMCD spectra of reduced wild-type and C75S CooA are dominated by bands characteristic of bis-histidine low-spin Fe(II) hemes, whereas the reduced H77Y variant is predominantly high-spin with MCD characteristics typical of a five-coordinate, histidine-ligated ferrous heme. VTMCD studies show that the CO-bound reduced forms of wild-type, H77Y, and C75S contain low-spin Fe(II) hemes and that the Fe-CO bonds can be photolytically cleaved at temperatures <50 K. Strong evidence that CO binding to the heme group in reduced CooA occurs with displacement of His77 comes from the VTMCD spectra of the low-temperature photoproducts of CO-bound reduced forms of wild-type, H77Y, and C75S CooA. The spectra are almost identical to each other and closely correspond to those of the low-temperature photoproducts of well characterized CO-bound ferrous hemes with His/CO axial ligation.
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PMID:Probing the heme axial ligation in the CO-sensing CooA protein with magnetic circular dichroism spectroscopy. 1050 50

In diazotrophic organisms, nitrogenase synthesis and activity are tightly regulated. Two genes, nifL and nifA, are implicated as playing a major role in this regulation. NifA is a transcriptional activator, and its activity is inhibited by NifL in response to availability of excess fixed nitrogen and high O(2) tension. It was postulated that NifL binds to NifA to inhibit NifA-mediated transcriptional activation of nif genes. Mutational analysis combined with transcriptional activation studies clearly is in agreement with the proposal that NifL interacts with NifA. However, several attempts to identify NifA-NifL interactions by using methods such as coimmunoprecipitations and chemical cross-linking experiments failed to detect direct interactions between these proteins. Here we have taken a genetic approach, the use of a yeast two-hybrid protein-protein interaction assay system, to investigate NifL interaction with NifA. A DNA fragment corresponding to the kinase-like domain of nifL was PCR amplified and was used to generate translation fusions with the DNA binding domain and the DNA activation domain of the yeast transcriptional activator GAL4 in yeast two-hybrid vectors. Similarly, a DNA fragment corresponding to the catalytic domain of nifA was PCR amplified and used to generate translation fusions with the DNA-binding domain and the DNA-activation domain of GAL4 in yeast two-hybrid vectors. After introducing appropriate plasmid combinations in yeast cells, the existance of direct interaction between NifA and NifL was analyzed with the MATCHMAKER yeast two-hybrid system by testing for the expression of lacZ and his3 genes. These analyses showed that the kinase-like domain of NifL directly interacts with the catalytic domain of NifA.
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PMID:Genetic analysis of nif regulatory genes by utilizing the yeast two-hybrid system detected formation of a NifL-NifA complex that is implicated in regulated expression of nif genes. 1051 47

This review discusses various mechanisms that regulatory proteins use to control gene expression in response to alterations in redox. The transcription factor SoxR contains stable [2Fe-2S] centers that promote transcription activation when oxidized. FNR contains [4Fe-4S] centers that disassemble under oxidizing conditions, which affects DNA-binding activity. FixL is a histidine sensor kinase that utilizes heme as a cofactor to bind oxygen, which affects its autophosphorylation activity. NifL is a flavoprotein that contains FAD as a redox responsive cofactor. Under oxidizing conditions, NifL binds and inactivates NifA, the transcriptional activator of the nitrogen fixation genes. OxyR is a transcription factor that responds to redox by breaking or forming disulfide bonds that affect its DNA-binding activity. The ability of the histidine sensor kinase ArcB to promote phosphorylation of the response regulator ArcA is affected by multiple factors such as anaerobic metabolites and the redox state of the membrane. The global regulator of anaerobic gene expression in alpha-purple proteobacteria, RegB, appears to directly monitor respiratory activity of cytochrome oxidase. The aerobic repressor of photopigment synthesis, CrtJ, seems to contain a redox responsive cysteine. Finally, oxygen-sensitive rhizobial NifA proteins presumably bind a metal cofactor that senses redox. The functional variability of these regulatory proteins demonstrates that prokaryotes apply many different mechanisms to sense and respond to alterations in redox.
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PMID:Mechanisms for redox control of gene expression. 1054 99

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