EC:1.7.1.4 - FACTA Search

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Query: EC:1.7.1.4 (nitrite reductase)
1,847 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A new method of determination of nitrate was developed, utilizing the nitrate reductase activity of Paracoccus denitrificans in which a further reduction of nitrate is blocked either by a mutation affecting formation of cytochromes c or by inhibition of the electron flow to nitrite reductase by mucidin. After deproteinization of the sample with zinc acetate the nitrite produced is determined colorimetrically.
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PMID:Determination of nitrate by conversion to nitrite using Paracoccus denitrificans. 182 47

The expression of the structural genes nit-3 and nit-6, which encode the nitrate assimilatory enzymes nitrate reductase and nitrite reductase, respectively, is highly regulated by the global-acting NIT2 regulatory protein. These structural genes are also controlled by nitrogen catabolite repression and by specific induction via nitrate. A pathway-specific regulatory protein, NIT4, appears to mediate nitrate induction of nit-3 and of nit-6. The NIT4 protein, composed of 1090 amino acids, contains a putative GAL4-like Cys-6 zinc cluster DNA-binding motif, which is joined by a short segment to a stretch of amino acids that appear to constitute a coiled-coil dimerization domain. Chemical crosslinking studies demonstrated that a truncated form of NIT4 forms homodimers. Mobility-shift and DNA-footprinting experiments have identified two NIT4-binding sites of significantly different strengths in the promoter region of the nit-3 gene. The stronger binding site contains a symmetrical octameric sequence, TCCGCGGA, whereas the weaker site has a related sequence. Sequences related to this palindromic element can be found upstream of the nit-6 gene.
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PMID:Sequence-specific DNA binding by NIT4, the pathway-specific regulatory protein that mediates nitrate induction in Neurospora. 759 94

NRE, the nitrogen regulatory protein of Penicillium chrysogenum, contains a single Cys2/Cys2-type zinc-finger motif followed immediately by a highly basic region. The zinc-finger domain was expressed to Escherichia coli as a fusion protein with beta-galactosidase. In order to test the putative DNA-binding ability of NRE, the intergenic promoter region of the nitrate reductase/nitrite reductase gene cluster (niiA-niaD) of Penicillium was sequenced. Our results show that NRE is a DNA-binding protein and binds to the intergenic promoter regions of the P. chrysogenum niiA-niaD and acvA-pcbC gene cluster, encoding the first two enzymes in penicillin biosynthesis. Three of the four high-affinity NRE-binding sites contained two GATA core elements. In one of the recognition sites for NRE, one GATA motif was replaced by GATT. The two GATA elements showed all possible orientations, head-to-head, head-to-tail and tail-to-tail, and were separated by between 4 and 27 bp. Missing-contact analysis showed that all three purines in both of the GATA core sequences and the single adenine residue in each of the complementary TATC sequences were involved in the binding of NRE. Moreover, loss of purines in the flanking regions of the GATA elements also affect binding of NRE, as their loss causes reduced affinity.
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PMID:NRE, the major nitrogen regulatory protein of Penicillium chrysogenum, binds specifically to elements in the intergenic promoter regions of nitrate assimilation and penicillin biosynthetic gene clusters. 859 Apr 70

Expression of nit-3 and nit-6, the structural genes which encode nitrate reductase and nitrite reductase in Neurospora crassa, requires the global-acting NIT2 and the pathway specific NIT4 regulatory proteins. NIT4, which consists of 1090 amino-acid residues, possesses a Cys6/Zn2 zinc cluster DNA-binding-domain. NIT4 was dissected to localize transactivation domains by fusion of various segments of NIT4 to the DNA-binding domain of GAL4 for in vivo analysis in yeast. Three separate activation subdomains, and one negative-acting region, which function in yeast were located in the carboxyl-terminal region of NIT4. The C-terminal tail of 28 amino-acid residues was identified as a minimal activation domain and consists of a novel leucine-rich, acidic region. Most deletions which removed even small segments of the NIT4 protein were found to lead to the loss of NIT4 function in vivo in N. crassa, implying that the central region of the protein which lies between the DNA-binding and activation domains is essential for function. The yeast two-hybrid system was employed to identify regions of NIT4 responsible for dimer formation. A short isoleucine-rich segment downstream from the zinc cluster, predicted to form a coiled coil, allowed dimerization in vivo; this same isoleucine-rich region also showed dimerization in vitro when examined via chemical cross linking. The enzyme nitrate reductase has been postulated to exert autogenous regulation by directly interacting with the NIT4 protein. This possible nitrate reductase-NIT4 interaction was investigated with the yeast two-hybrid system and by direct in vitro binding assays; both assays failed to identify such a protein-protein interaction.
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PMID:The regulatory protein NIT4 that mediates nitrate induction in Neurospora crassa contains a complex tripartite activation domain with a novel leucine-rich, acidic motif. 866 93

Regulation of aflatoxin (AF) biosynthesis likely involves a complex interplay of positive- and negative-acting factors that are affected by physiological cues responsive to internal and external stimuli. These factors, presumably, modulate the expression of the AF pathway-specific regulatory gene, aflR, whose product, AFLR, a zinc cluster transcription factor, then turns on or off the transcription of other AF genes. To determine if the AFLR carboxyl region (AFLRC) interacts with positive- or negative-acting proteins, we fused the Aspergillus parasiticus aflR carboxyl coding region (aflRC) to the promoter of A. parasiticus nitrite reductase gene (niiA(p)::aflRC), and transformed it into A. parasiticus SRRC 2043. Transformants that contained two copies of niiA(p)::aflRC, one at the niaD locus and another at the aflR locus, overproduced AF precursors independent of the nitrogen source. The higher copy number of the integrated niiA(p)::aflRC correlated with increased production of AF precursors by the transformants as well as increased expression of both aflRC and native aflR in potato dextrose broth and A&M medium. Since aflRC does not encode a DNA-binding domain, the expressed AFLRC should not bind to the promoters of AF pathway genes and affect transcription directly. The results are consistent with AFLRC titrating out a putative repressor that interacts with AFLR under different growth conditions and modulates AF biosynthesis. This interaction also indirectly affects sclerotial development.
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PMID:Repressor-AFLR interaction modulates aflatoxin biosynthesis in Aspergillus parasiticus. 1096 69

A subtractive tomato (Lycopersicon esculentum) root cDNA library enriched in genes up-regulated by changes in plant mineral status was screened with labeled mRNA from roots of both nitrate-induced and mineral nutrient-deficient (-nitrogen [N], -phosphorus, -potassium [K], -sulfur, -magnesium, -calcium, -iron, -zinc, and -copper) tomato plants. A subset of cDNAs was selected from this library based on mineral nutrient-related changes in expression. Additional cDNAs were selected from a second mineral-deficient tomato root library based on sequence homology to known genes. These selection processes yielded a set of 1,280 mineral nutrition-related cDNAs that were arrayed on nylon membranes for further analysis. These high-density arrays were hybridized with mRNA from tomato plants exposed to nitrate at different time points after N was withheld for 48 h, for plants that were grown on nitrate/ammonium for 5 weeks prior to the withholding of N. One hundred-fifteen genes were found to be up-regulated by nitrate resupply. Among these genes were several previously identified as nitrate responsive, including nitrate transporters, nitrate and nitrite reductase, and metabolic enzymes such as transaldolase, transketolase, malate dehydrogenase, asparagine synthetase, and histidine decarboxylase. We also identified 14 novel nitrate-inducible genes, including: (a) water channels, (b) root phosphate and K(+) transporters, (c) genes potentially involved in transcriptional regulation, (d) stress response genes, and (e) ribosomal protein genes. In addition, both families of nitrate transporters were also found to be inducible by phosphate, K, and iron deficiencies. The identification of these novel nitrate-inducible genes is providing avenues of research that will yield new insights into the molecular basis of plant N nutrition, as well as possible networking between the regulation of N, phosphorus, and K nutrition.
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PMID:Nitrate-induced genes in tomato roots. Array analysis reveals novel genes that may play a role in nitrogen nutrition. 1155 62

Nitrate assimilation genes encoding a nitrate transporter (YNT1), nitrite reductase (YNI1), a Zn(II)(2)Cys(6) transcriptional factor involved in nitrate induction (YNA1) and the nitrate reductase (YNR1) are clustered in the yeast Hansenula polymorpha. A second gene, termed YNA2 (yeast nitrate assimilation), was located seven nucleotides away from the 3' region of YNR1 gene. The cluster is flanked by an ORF encoding a protein with similarity to glutathione-S-transferase on the YNT1 side and an ORF with similarity to Saccharomyces cerevisiae Rad3p on the YNA2 side. The disruption of YNA2 confers the resulting null mutant strain with inability to grow in nitrate. The YNA2 gene encodes a putative protein of 618 residues bearing in the N-terminus the consensus sequence Cys-X(2)-Cys-X(6)-Cys-X(5-16)-Cys-X(2)-Cys-X(6-8)-Cys characteristic of the Zn(II)(2)Cys(6) transcriptional factors. YNA2 is therefore a member of the H. polymorpha nitrate assimilation gene cluster which is transcribed in the opposite direction to the rest of the members. Yna2p shares about 27% similarity with the H. polymorpha Yna1p Zn(II)(2)Cys(6) transcriptional factor involved in nitrate induction. Unlike the wild-type, the yna2::URA3 strain showed no expression of the nitrate assimilation genes when incubated in nitrate for 2 h. With regard to YNA2 expression, similar YNA2 transcript levels were observed in ammonium and in ammonium plus nitrate, but about a four-fold higher expression was observed in nitrate. However, this induction by nitrate of the YNA2 gene was not observed in the Deltayna1::URA3 strain. On the contrary, the pattern of YNA1 expression was the same in the wild-type as in the yna2::URA3 strain, indicating that YNA2 does not affect YNA1 expression.
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PMID:A second Zn(II)(2)Cys(6) transcriptional factor encoded by the YNA2 gene is indispensable for the transcriptional activation of the genes involved in nitrate assimilation in the yeast Hansenula polymorpha. 1192 Nov 2

In Aspergillus nidulans, the genes coding for nitrate reductase (niaD) and nitrite reductase (niiA), are transcribed divergently from a common promoter region of 1200 basepairs. We have previously characterized the relevant cis-acting elements for the two synergistically acting transcriptional activators NirA and AreA. We have further shown that AreA is constitutively bound to a central cluster of four GATA sites, and is involved in opening the chromatin structure over the promoter region thus making additional cis-acting binding sites accessible. Here we show that the asymmetric mode of NirA-DNA interaction determined in vitro is also found in vivo. Binding of the NirA transactivator is not constitutive as in other binuclear C6-Zn2+-cluster proteins but depends on nitrate induction and, additionally, on the presence of a wild-type areA allele. Dissecting the role of AreA further, we found that it is required for intracellular nitrate accumulation and therefore could indirectly exert its effect on NirA via inducer exclusion. We have tested this possibility in a strain accumulating nitrate in the absence of areA. We found that in such a strain the intracellular presence of inducer is not sufficient to promote either chromatin rearrangement or NirA binding, implying that both processes are directly dependent on AreA.
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PMID:Nitrate and the GATA factor AreA are necessary for in vivo binding of NirA, the pathway-specific transcriptional activator of Aspergillus nidulans. 1197 92

Preparation of a nitrate reductase lysate of Escherichia coli MC1061 to measure nitrate and nitrite in biologic fluids is described. To obtain the crude bacterial lysate containing nitrate reductase activity, E. coli MC1061 was subjected to 16-20 freeze-thawing cycles, from -70 to 60 degrees C, until nitrite reductase activity was < or = 25%. Nitrate reductase activity was detected mainly in the crude preparation. To validate the nitrate reduction procedure, standard nitrate solutions (1.6-100 microM) were incubated with the nitrate reductase preparation for 3 h at 37 degrees C, and nitrite was estimated by the Griess reaction in a microassay. Nitrate solutions were reduced to nitrite in a range of 60-70%. Importantly, no cofactors were necessary to perform nitrate reduction. The biological samples were first reduced with the nitrate reductase preparation. After centrifugation, samples were deproteinized with either methanol/ether or zinc sulfate and nitrite was quantified. The utility of the nitrate reductase preparation was assessed by nitrate+nitrite determination in serum of animals infected with the protozoan Entamoeba histolytica or the bacteria E. coli and in the supernatant of cultured lipopolysaccharide-stimulated RAW 264.7 mouse macrophages. Our results indicate that the nitrate reductase-containing lysate provides a convenient tool for the reduction of nitrate to determine nitrate+nitrite in biological fluids by spectrophotometric methods.
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PMID:Indirect determination of nitric oxide production by reduction of nitrate with a freeze-thawing-resistant nitrate reductase from Escherichia coli MC1061. 1508 2

Cytochrome cd(1) is a respiratory nitrite reductase found in the periplasm of denitrifying bacteria. When fully reduced Paracoccus pantotrophus cytochrome cd(1) is mixed with nitrite in a stopped-flow apparatus in the absence of excess reductant, a kinetically stable complex of enzyme and product forms, assigned as a mixture of cFe(II) d(1)Fe(II)-NO(+) and cFe(III) d(1)Fe(II)-NO (cd(1)-X). However, in order for the enzyme to achieve steady-state turnover, product (NO) release must occur. In this work, we have investigated the effect of a physiological electron donor to cytochrome cd(1), the copper protein pseudoazurin, on the mechanism of nitrite reduction by the enzyme. Our data clearly show that initially oxidized pseudoazurin causes rapid further turnover by the enzyme to give a final product that we assign as all-ferric cytochrome cd(1) with nitrite bound to the d(1) heme (i.e. from which NO had dissociated). Pseudoazurin catalyzed this effect even when present at only one-tenth the stoichiometry of cytochrome cd(1). In contrast, redox-inert zinc pseudoazurin did not affect cd(1)-X, indicating a crucial role for electron movement between monomers or individual enzyme dimers rather than simply a protein-protein interaction. Furthermore, formation of cd(1)-X was, remarkably, accelerated by the presence of pseudoazurin, such that it occurred at a rate consistent with cd(1)-X being an intermediate in the catalytic cycle. It is clear that cytochrome cd(1) functions significantly differently in the presence of its two substrates, nitrite and electron donor protein, than in the presence of nitrite alone.
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PMID:Pseudoazurin dramatically enhances the reaction profile of nitrite reduction by Paracoccus pantotrophus cytochrome cd1 and facilitates release of product nitric oxide. 1831 Jul 70

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