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

The Rhizobium meliloti two-component system FixL/FixJ regulates nitrogen fixation in response to oxygen during symbiosis. FixJ is a transcriptional activator of critical nif and fix promoters; its in vivo activity is enhanced by FixL in diminished oxygen (David, M., Daveran, M.-L., Batut, J., Dedieu, A., Domergue, O., Ghai, J., Hertig, C., Boistard, P., and Kahn, D. (1988) Cell 54, 671-683; Virts, E. L., Stanfield, S. W., Helinski, D. R., and Ditta, G. S. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3062-3065). FixL* is a soluble truncated version of FixL that contains heme; it catalyzes its autophosphorylation and the phosphorylation of FixJ (Gilles-Gonzalez, M.A., Ditta, G. S., and Helinski, D. R. (1991) Nature 350, 170-172). We examine the kinetics of phosphoryl transfer in this system. First, there is a slow autophosphorylation of FixL* in ATP that is accelerated in the absence of oxygen and in the presence of Mn2+. This reaction is reversible, i.e. phospho-FixL* reacts with ADP to generate ATP. Since the reverse reaction is faster, most FixL* is not phosphorylated at equilibrium. Next, there is a rapid phosphoryl transfer directly from phospho-FixL* to FixJ that is unaffected by oxygen. Finally, phospho-FixJ is hydrolyzed; this reaction is very fast and not controlled by oxygen. We propose that in addition to the oxygen signal previously noted in vivo, energy charge and manganese concentration are also indicators of symbiosis that impact on the induction of nitrogen fixation genes.
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PMID:Regulation of the kinase activity of heme protein FixL from the two-component system FixL/FixJ of Rhizobium meliloti. 839 56

Azotobacter vinelandii NIFL is a nitrogen fixation-specific regulatory flavoprotein that modulates the activity of the transcriptional activator NIFA in response to oxygen and fixed nitrogen in vivo. NIFL is also responsive to ADP in vitro. Limited proteolysis of NIFL indicates that it comprises a relatively stable N-terminal domain and a C-terminal domain that is protected from trypsin digestion in the presence of adenosine nucleotides. ATP protects the protein from cleavage in the vicinity of potential nucleotide-binding sites in the C-terminus, whereas ADP protects the entire C-terminal domain. NIFL has an apparent Kd of 130 microM for ATP and 16 microM for ADP. The purified N-terminal domain has an identical UV/visible absorption spectrum to the wild-type protein and is reduced by sodium dithionite, demonstrating that it is a flavin-binding domain. The isolated N-terminal domain does not inhibit NIFA activity. A subdomain fragment containing 160 residues of the C-terminal region, including the nucleotide-binding sites, is also not competent to inhibit NIFA. Removal of the first 146 residues of NIFL, which includes a conserved S-motif (PAS-like domain), found in a large family of sensory proteins from eubacteria, archea and eukarya eliminates the redox response. However, this truncated protein remains competent to inhibit NIFA activity in response to ADP in vitro and to the level of fixed nitrogen in vivo. The redox and nitrogen-sensing functions of A. vinelandii NIFL are therefore separable and are discrete functions of the protein.
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PMID:The redox- and fixed nitrogen-responsive regulatory protein NIFL from Azotobacter vinelandii comprises discrete flavin and nucleotide-binding domains. 959 6

MalT, the transcriptional activator of the Escherichia coli maltose regulon, binds the MalT-dependent promoters and activates transcription initiation only in the presence of maltotriose and ATP (or adenylyl imidodiphosphate (AMP-PNP)). Cooperative binding of MalT to the array of cognate sites present in the MalT-dependent promoters suggests that promoter binding involves MalT oligomerization. Gel filtration and sedimentation experiments were used to analyze the quaternary structure of MalT in solution in the absence or presence of maltotriose and/or AMP-PNP, ATP, or ADP. The protein is monomeric in the absence of ligands and in the presence of ADP. In the presence of maltotriose, AMP-PNP, or ATP only, the protein self-associates, but a large fraction of the protein remains monomeric. In the presence of both maltotriose and AMP-PNP (ATP or ADP), the protein is essentially oligomeric, with the difference being that the oligomerization is less favored in the presence of ADP + maltotriose than in the presence of AMP-PNP + maltotriose. We present evidence that the association pathway comprises the following steps: monomers --> dimers --> (MalT)(n) --> aggregates, where 3 </= n </= 6. From these data, we conclude that the role of maltotriose and ATP as positive effectors is to induce the multimerization of MalT, and hence its cooperative binding to the mal promoters.
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PMID:Self-association of the Escherichia coli transcription activator MalT in the presence of maltotriose and ATP. 1055 95

The presence of invasion-inhibitory activity that is regulated by the transcriptional activator ExsA of cytotoxic Pseudomonas aeruginosa has previously been proposed. The results of this study show that both ExoT and ExoS, known type III secreted effector proteins of P. aeruginosa that are regulated by ExsA, possess this activity. Invasion was reduced 94.4% by ExoT and 96.0% by ExoS. Invasion-inhibitory activity is not linked to ADP-ribosylation activity, at least for ExoS, since a noncatalytic mutant also inhibits uptake by an epithelial cell line (invasion was reduced 96. 0% by ExoSE381A).
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PMID:ExoT of cytotoxic Pseudomonas aeruginosa prevents uptake by corneal epithelial cells. 1060 17

Azospirillum represents the best characterized genus of plant growth-promoting rhizobacteria. Other free-living diazotrophs repeatedly detected in association with plant roots, include Acetobacter diazotrophicus, Herbaspirillum seropedicae, Azoarcus spp. and Azotobacter. Four aspects of the Azospirillum-plant root interaction are highlighted: natural habitat, plant root interaction, nitrogen fixation and biosynthesis of plant growth hormones. Each of these aspects is dealt with in a comparative way. Azospirilla are predominantly surface-colonizing bacteria, whereas A. diazotrophicus, H. seropedicae and Azoarcus sp. are endophytic diazotrophs. The attachment of Azospirillum cells to plant roots occurs in two steps. The polar flagellum, of which the flagellin was shown to be a glycoprotein, mediates the adsorption step. An as yet unidentified surface polysaccharide is believed to be essential in the subsequent anchoring phase. In Azoarcus sp. the attachment process is mediated by type IV pili. Nitrogen fixation structural genes (nif) are highly conserved among all nitrogen-fixing bacteria, and in all diazotrophic species of the class of proteobacteria examined, the transcriptional activator NifA is required for expression of other nif genes in response to two major environmental signals (oxygen and fixed N). However, the mechanisms involved in this control can vary in different organisms. In Azospirillum brasilense and H. seropedicae (alpha- and beta-subgroup, respectively), NifA is inactive in conditions of excess nitrogen. Activation of NifA upon removal of fixed N seems to involve, either directly or indirectly, the signal transduction protein P(II). The presence of four conserved cysteine residues in the NifA protein might be an indication that NifA is directly sensitive to oxygen. In Azotobacter vinelandii (gamma-subgroup) nifA is cotranscribed with a second gene nifL. The nifL gene product inactivates NifA in response to high oxygen tension and cellular nitrogen-status. NifL was found to be a redox-sensitive flavoprotein. The relief of NifL inhibition on NifA activity, in response to N-limitation, is suggested to involve a P(II)-like protein. Moreover, nitrogenase activity is regulated according to the intracellular nitrogen and O(2) level. In A. brasilense and Azospirillum lipoferum posttranslational control of nitrogenase, in response to ammonium and anaerobiosis, involves ADP-ribosylation of the nitrogenase iron protein, mediated by the enzymes DraT and DraG. At least three pathways for indole-3-acetic acid (IAA) biosynthesis in A. brasilense exist: two Trp-dependent (the indole-3-pyruvic acid and presumably the indole-3-acetamide pathway) and one Trp-independent pathway. The occurrence of an IAA biosynthetic pathway not using Trp (tryptophan) as precursor is highly unusual in bacteria. Nevertheless, the indole-3-pyruvate decarboxylase encoding ipdC gene is crucial in the overall IAA biosynthesis in Azospirillum. A number of genes essential for Trp production have been isolated in A. brasilense, including trpE(G) which codes for anthranilate synthase, the key enzyme in Trp biosynthesis. The relevance of each of these four aspects for plant growth promotion by Azospirillum is discussed.
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PMID:Azospirillum, a free-living nitrogen-fixing bacterium closely associated with grasses: genetic, biochemical and ecological aspects. 1097 48

Poly(ADP-ribose) polymerase-1 (PARP-1) catalyzes the rapid and extensive poly(ADP-ribosyl)ation of nuclear proteins in response to DNA strand breaks, and its expression, although ubiquitous, is modulated from tissue to tissue and during cellular differentiation. PARP-1 gene promoters from human, rat, and mouse have been cloned, and they share a structure common to housekeeping genes, as they lack a functional TATA box and contain multiple GC boxes, which bind the transcriptional activator Sp1. We have previously shown that, although Sp1 is important for rat PARP1 (rPARP) promoter activity, its finely tuned modulation is likely dependent on other transcription factors that bind the rPARP proximal promoter in vitro. In this study, we identified one such factor as NF1-L, a rat liver isoform of the nuclear factor 1 family of transcription factors. The NF1-L site on the rPARP promoter overlaps one of the Sp1 binding sites previously identified, and we demonstrated that binding of both factors to this composite element is mutually exclusive. Furthermore, we provide evidence that NF1-L has no effect by itself on rPARP promoter activity, but rather down-regulates the Sp1 activity by interfering with its ability to bind the rPARP promoter in order to modulate transcription of the rPARP gene.
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PMID:Nuclear factor 1 interferes with Sp1 binding through a composite element on the rat poly(ADP-ribose) polymerase promoter to modulate its activity in vitro. 1127 63

MalT, the transcriptional activator of the maltose regulon from Escherichia coli, is the prototype of a new family of transcription factors. Its activity is controlled by multiple regulatory signals. ATP and maltotriose (the inducer) are two effectors of the activator that positively control its multimerization, a critical step in promoter binding. In addition, MalK, the ABC component of the maltodextrin transport system, and the two enzymes MalY and Aes down-regulate MalT activity in vivo. By using a biochemical approach, we demonstrate here that (i) Aes controls MalT activity through direct protein-protein interaction, (ii) Aes competes with maltotriose for MalT binding, (iii) ATP and ADP differentially affect the competition between Aes and the inducer, and (iv) part, if not all, of the Aes binding site is located in DT1, the N-terminal domain of the activator, which also contains the ATP binding site. All of these characteristics point toward an identical mode of action for MalY and Aes. However, we have identified an amino acid substitution in MalT that suppresses MalT inhibition by Aes without interfering with its inhibition by MalY, suggesting that the binding sites of the two inhibitory proteins do not coincide. The differential effects of ATP and ADP on the competition between the inducer and Aes (or MalY) suggest that the ATPase activity displayed by MalT plays a role in the negative control of its activity.
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PMID:The Aes protein directly controls the activity of MalT, the central transcriptional activator of the Escherichia coli maltose regulon. 1186 39

The enzymatic reduction of molecular nitrogen to ammonia requires high amounts of energy, and the presence of oxygen causes the catalyzing nitrogenase complex to be irreversible inactivated. Thus nitrogen-fixing microorganisms tightly control both the synthesis and activity of nitrogenase to avoid the unnecessary consumption of energy. In the free-living diazotrophs Klebsiella pneumoniae and Azotobacter vinelandii, products of the nitrogen fixation nifLA operon regulate transcription of the other nifoperons. NifA activates transcription of nif genes by the alternative form of RNA-polymerase, sigma54-holoenzyme; NifL modulates the activity of the transcriptional activator NifA in response to the presence of combined nitrogen and molecular oxygen. The translationally-coupled synthesis of the two regulatory proteins, in addition to evidence from studies of NifL/NifA complex formation, imply that the inhibition of NifA activity by NifL occurs via direct protein-protein interaction in vivo. The inhibitory function of the negative regulator NifL appears to lie in the C-terminal domain, whereas the N-terminal domain binds FAD as a redox-sensitive cofactor, which is required for signal transduction of the internal oxygen status. Recently it was shown, that NifL acts as a redox-sensitive regulatory protein, which modulates NifA activity in response to the redox-state of its FAD cofactor, and allows NifA activity only in the absence of oxygen. In K. pneumoniae, the primary oxygen sensor appears to be Fnr (fumarate nitrate reduction regulator), which is presumed to transduce the signal of anaerobiosis towards NifL by activating the transcription of gene(s) whose product(s) function to relieve NifL inhibition through reduction of the FAD cofactor. In contrast, the reduction of A. vinelandii-NifL appears to occur unspecifically in response to the availability of reducing equivalents in the cell. Nitrogen status of the cells is transduced towards the NifL/NifA regulatory system by the GlnK protein, a paralogue PII-protein, which appears to interact with the NifL/NifA regulatory system via direct protein-protein interaction. It is not currently known whether GlnK interacts with NifL alone or affects the NifL/NifA-complex; moreover the effects appear to be the opposite in K. pneumoniae and A. vinelandii. In addition to these environmental signals, adenine nucleotides also affect the inhibitory function of NifL; in the presence of ATP or ADP the inhibitory effect on NifA activity in vitro is increased. The NifL proteins from the two organisms differ, however, in that stimulation of K. pneumoniae-NifL occurs only when synthesized under nitrogen excess, and is correlated with the ability to hydrolyze ATP. In general, transduction of environmental signals to the nif regulatory system appears to involve a conformational change of NifL or the NifL/NifA complex. However, experimental data suggest that K. pneumoniae and A. vinelandii employ significantly different species-specific mechanisms of signal transduction.
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PMID:Regulation of nitrogen fixation in Klebsiella pneumoniae and Azotobacter vinelandii: NifL, transducing two environmental signals to the nif transcriptional activator NifA. 1193 53

The Azotobacter vinelandii sigma(54)-dependent transcriptional activator protein NifA is regulated by the NifL protein in response to redox, carbon, and nitrogen status. Under conditions inappropriate for nitrogen fixation, NifL inhibits transcription activation by NifA through the formation of the NifL-NifA protein complex. NifL inhibits the ATPase activity of the central AAA+ domain of NifA required to drive open complex formation by sigma(54)-RNA polymerase and may also inhibit the activator-polymerase interaction. To analyze the mechanism of inhibition in greater detail, we isolated NifA mutants which are resistant to the inhibitory action of NifL. Mutations in both the amino-terminal GAF domain and the catalytic AAA+ domain of NifA were isolated. Several mutants blocked inhibition by NifL in response to both nitrogen and redox status, whereas some of the mutant NifA proteins were apparently able to discriminate between the forms of NifL present under different environmental conditions. One mutant protein, NifA-Y254N, was resistant to NifL under conditions of anaerobic nitrogen excess but was relatively sensitive to NifL under aerobic growth conditions. The properties of the purified mutant protein in vitro were consistent with the in vivo phenotype and indicate that NifA-Y254N is not responsive to the nitrogen signal conveyed by the interaction of NifL with A. vinelandii GlnK but is responsive to the oxidized form of NifL when ADP is present. Our observations suggest that different conformers of NifL may be generated in response to discrete signal transduction events and that both the GAF and AAA+ domains of NifA are involved in the response to NifL.
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PMID:Mutant forms of the Azotobacter vinelandii transcriptional activator NifA resistant to inhibition by the NifL regulatory protein. 1244 27

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