EC:1.7.1.2 - FACTA Search

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Query: EC:1.7.1.2 (nitrate reductase)
3,861 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The addition of nickel ions restored urease activity in vivo and ability to grow on urea in a mutant strain of Aspergillus nidulans otherwise unable to utilize urea. This train carries a mutation in the ureD locus, one of four loci involved in urea utilization. No other urease-deficient strains tested responded to the presence of nickel ions. The analogous characteristics of the ureD mutant and the nitrate reductase and xanthine dehydrogenase associated cnxE mutants in Aspergillus nidulans are discussed. It is postulated that the ureD locus is in some way involved in the production or incorporation of a nickel cofactor essential for urease activity.
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PMID:Nickel requirement of a urease-deficient mutant in Aspergillus nidulans. 698 44

The requirement of MobA for molybdoenzymes with different molybdenum cofactors was analyzed in Rhodobacter capsulatus. MobA is essential for DMSO reductase and nitrate reductase activity, both enzymes containing the molybdopterin guanine dinucleotide cofactor (MGD), but not for active xanthine dehydrogenase, harboring the molybdopterin cofactor. In contrast to the mob locus of Escherichia coli and R. sphaeroides, the mobB gene is not located downstream of mobA in R. capsulatus. The mobA gene is expressed constitutively at low levels and no increase in mobA expression could be observed even under conditions of high MGD demand.
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PMID:The molybdenum cofactor biosynthesis protein MobA from Rhodobacter capsulatus is required for the activity of molybdenum enzymes containing MGD, but not for xanthine dehydrogenase harboring the MPT cofactor. 1033 14

The flacca tomato (Lycopersicon esculentum) mutant displays a wilty phenotype as a result of abscisic acid (ABA) deficiency. The Mo cofactor (MoCo)-containing aldehyde oxidases (AO; EC 1.2.3.1) are thought to play a role in the final oxidation step required for ABA biosynthesis. AO and related MoCo-containing enzymes xanthine dehydrogenase (XDH; EC 1.2.1.37) and nitrate reductase (EC 1.6.6.1) were examined in extracts of the flacca tomato genotype and of wild-type (WT) roots and shoots. The levels of MoCo were found to be similar in both genotypes. No significant XDH or AO (MoCo-containing hydroxylases) activities were detected in flacca leaves; however, the mutant exhibited considerable MoCo-containing hydroxylase activity in the roots, which contained notable amounts of ABA. Native western blots probed with an antibody to MoCo-containing hydroxylases revealed substantial, albeit reduced, levels of cross-reactive protein in the flacca mutant shoots and roots. The ABA xylem-loading rate was significantly lower than that in the WT, indicating that the flacca is also defective in ABA transport to the shoot. Significantly, in vitro sulfurylation with Na2S reactivated preexisting XDH and AO proteins in extracts from flacca, particularly from the shoots, and superinduced the basal-level activity in the WT extracts. The results indicate that in flacca, MoCo-sulfurylase activity is impaired in a tissue-dependent manner.
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PMID:Aldehyde oxidase and xanthine dehydrogenase in a flacca tomato mutant with deficient abscisic acid and wilty phenotype 1036 9

During the screening for Rhodobacter capsulatus mutants defective in xanthine degradation, one Tn5 mutant which was able to grow with xanthine as a sole nitrogen source only in the presence of high molybdate concentrations (1 mM), a phenotype resembling Escherichia coli mogA mutants, was identified. Unexpectedly, the corresponding Tn5 insertion was located within the moeA gene. Partial DNA sequence analysis and interposon mutagenesis of regions flanking R. capsulatus moeA revealed that no further genes essential for molybdopterin biosynthesis are located in the vicinity of moeA and revealed that moeA forms a monocistronic transcriptional unit in R. capsulatus. Amino acid sequence alignments of R. capsulatus MoeA (414 amino acids [aa]) with E. coli MogA (195 aa) showed that MoeA contains an internal domain homologous to MogA, suggesting similar functions of these proteins in the biosynthesis of the molybdenum cofactor. Interposon mutants defective in moeA did not exhibit dimethyl sulfoxide reductase or nitrate reductase activity, which both require the molybdopterin guanine dinucleotide (MGD) cofactor, even after addition of 1 mM molybdate to the medium. In contrast, the activity of xanthine dehydrogenase, which binds the molybdopterin (MPT) cofactor, was restored to wild-type levels after the addition of 1 mM molybdate to the growth medium. Analysis of fluorescent derivatives of the molybdenum cofactor of purified xanthine dehydrogenase isolated from moeA and modA mutant strains, respectively, revealed that MPT is inserted into the enzyme only after molybdenum chelation, and both metal chelation and Mo-MPT insertion can occur only under high molybdate concentrations in the absence of MoeA. These data support a model for the biosynthesis of the molybdenum cofactor in which the biosynthesis of MPT and MGD are split at a stage when the molybdenum atom is added to MPT.
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PMID:Activity of the molybdopterin-containing xanthine dehydrogenase of Rhodobacter capsulatus can be restored by high molybdenum concentrations in a moeA mutant defective in molybdenum cofactor biosynthesis. 1049 4

The distribution of the Mo-enzymes aldehyde oxidase (AO; EC 1.2.3.1) xanthine dehydrogenase (XDH; EC 1.2.1.37) and nitrate reductase (NAD(P)H NR; EC 1.6.6.1-2) was studied along the longitudinal and transversal axes of maize (Zea mays L. cv. Jubily) nodal roots as affected by nitrogen sources and salinity. Activities of the Mo-enzymes were considerably enhanced under mild saline conditions. The activities of AO and XDH increased following addition of ammonium to the nutrient solution. Immunoblot analysis with antibodies raised against maize AO protein revealed increased levels of AO proteins in root tips of ammonium fed plants. Application of salinity to nitrate fed plants did not affect the enzyme protein level, although it enhanced the activity of the Mo-hydroxylases. The specific activities of the Mo-enzymes were the highest in root tips (0-1 cm segments) while on the transversal axis maximal activity was observed in the stele or vascular cylinder. Activity staining of AO after native PAGE of root extracts revealed four bands of AO proteins (AO1-4) capable of oxidizing a number of aliphatic and aromatic aldehydes. Increased AO activity in maize nodal roots grown with ammonium, and salinity were observed mainly at the AO3 and AO4 bands. Tips and stele contained primarily AO3 and AO4, and only traces of AO1 and AO2. SDS-PAGE of root extracts followed by Western blots revealed, besides the major 150 kD subunit of AO, two polypeptides with molecular masses of 72 and 85 kD located specifically in the cortex. Part of the polymorphism of AO in plant roots may be related to the allocation of distinct isoforms to different regions of the root, although the specific metabolic roles of the different bands have not been established.
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PMID:Distribution of the Mo-enzymes aldehyde oxidase, xanthine dehydrogenase and nitrate reductase in maize (Zea mays L.) nodal roots as affected by nitrogen and salinity. 1077 39

Expression of the dimethylsulfoxide respiratory (dor) operon of Rhodobacter is regulated by oxygen, light intensity and availability of substrate. Since dimethylsulfoxide reductase contains a pterin molybdenum cofactor, the role of molybdate in the regulation of dor operon expression was investigated. In this report we show that the molybdate-responsive transcriptional regulator, MopB, and molybdate are essential for maximal dimethylsulfoxide reductase activity and expression of a dorA::lacZ transcriptional fusion in Rhodobacter capsulatus. In contrast, mop genes are not required for the expression of the periplasmic nitrate reductase or xanthine dehydrogenase in R. capsulatus under conditions of molybdenum sufficiency. This is the first report demonstrating a clear functional difference between the ModE homologues MopB and MopA in this bacterium. The results suggest that MopA is primarily involved in the regulation of nitrogen fixation gene expression in response to molybdate while MopB has a role in nitrogen fixation and dimethylsulfoxide respiration.
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PMID:Molybdate-dependent expression of dimethylsulfoxide reductase in Rhodobacter capsulatus. 1103 80

The mob genes of several bacteria have been implicated in the conversion of molybdopterin to molybdopterin guanine dinucleotide. The mob locus of Rhodobacter sphaeroides WS8 comprises three genes, mobABC. Chromosomal in-frame deletions in each of the mob genes have been constructed. The mobA mutant strain has inactive DMSO reductase and periplasmic nitrate reductase activities (both molybdopterin guanine dinucleotide-requiring enzymes), but the activity of xanthine dehydrogenase, a molybdopterin enzyme, is unaffected. The inability of a mobA mutant to synthesise molybdopterin guanine dinucleotide is confirmed by analysis of cell extracts of the mobA strain for molybdenum cofactor forms following iodine oxidation. Mutations in mobB and mobC are not impaired for molybdoenzyme activities and accumulate wild-type levels of molybdopterin and molybdopterin guanine dinucleotide, indicating they are not compromised in molybdenum cofactor synthesis. In the mobA mutant strain, the inactive DMSO reductase is found in the periplasm, suggesting that molybdenum cofactor insertion is not necessarily a pre-requisite for export.
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PMID:Characterisation of the mob locus of Rhodobacter sphaeroides WS8: mobA is the only gene required for molybdopterin guanine dinucleotide synthesis. 1147 4

In contrast to its parent strain, transposon Tn5-Mob insertion mutant HB6 of the facultative chemoautotroph Ralstonia eutropha was unable to grow organoautotrophically on formate and exhibited no activity of Mo-dependent, membrane-bound formate dehydrogenase (M-FDH) when cultivated mixotrophically on fructose plus formate. The activity of another molybdoenzyme, the soluble, NAD+-linked formate dehydrogenase which is the key enzyme of formate utilization in R. eutropha, was greatly diminished in the mutant. HB6 also lacked the W-dependent M-FDH activities that were newly discovered in organoautotrophically, lithoautotrophically, or mixotrophically grown wildtype cells. However, an additional W-dependent M-FDH activity, observed in heterotrophically grown stationary-phase cells, was present in the mutant although at a considerably reduced level. Sequence analyses of the complementing chromosomal wildtype and the corresponding mutant DNA fragment revealed the transposon insertion to be located in moeA, a gene involved in the biosynthesis of the molybdopterin cofactor (MoCo). Nevertheless, mutant HB6 was able to grow on xanthine as carbon and energy source and with nitrate as nitrogen source. The utilization of these substrates requires the function of the MoCo-containing enzymes xanthine dehydrogenase and assimilatory nitrate reductase, respectively, that were still active in the mutant. A moeA deletion mutant exhibited the same phenotype as that of HB6. The moeA gene belongs to an unusual mol operon consisting of four genes (moeA, moaD, moaE, and moaF) and being constitutively expressed at low level. Unlike MoeA, the large subunit of molybdopterin synthase encoded by moaE is essential for molybdopterin biosynthesis as was evident by the phenotype of a moaE deletion mutant. MoaF is a novel gene product which showed no similarity to proteins with known function but was indispensable for reconstituting organoautotrophic growth in HB6. The findings suggest that MoeA of R. eutropha is differentially involved in the biosynthesis or incorporation of pterin cofactors of/into the various molybdo- and tungstoenzymes.
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PMID:Involvement of an unusual mol operon in molybdopterin cofactor biosynthesis in Ralstonia eutropha. 1154 79

We report the identification of a number of mutations that result in amino acid replacements (and their phenotypic characterization) in either the MogA-like domain or domains 2 and 3 of the MoeA-like region of the Aspergillus nidulans cnxE gene. These domains are functionally required since mutations that result in amino acid substitutions in any one domain lead to the loss or to a substantial reduction in all three identified molybdoenzyme activities (i.e., nitrate reductase, xanthine dehydrogenase, and nicotinate hydroxylase). Certain cnxE mutants that show partial growth with nitrate as the nitrogen source in contrast do not grow on hypoxanthine or nicotinate. Complementation between mutants carrying lesions in the MogA-like domain or the MoeA-like region, respectively, most likely occurs at the protein level. A homology model of CnxE based on the dimeric structure of E. coli MoeA is presented and the position of inactivating mutations (due to amino acid replacements) in the MoeA-like functional region of the CnxE protein is mapped to this model. Finally, the activity of nicotinate hydroxylase, unlike that of nitrate reductase and xanthine dehydrogenase, is not restored in cnxE mutants grown in the presence of excess molybdate.
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PMID:Mutational analysis of the gephyrin-related molybdenum cofactor biosynthetic gene cnxE from the lower eukaryote Aspergillus nidulans. 1207 59

The transition element molybdenum (Mo) is essential for (nearly) all organisms and occurs in more than 40 enzymes catalysing diverse redox reactions, however, only four of them have been found in plants. (1) Nitrate reductase catalyses the key step in inorganic nitrogen assimilation, (2) aldehyde oxidase(s) have been shown to catalyse the last step in the biosynthesis of the phytohormone abscisic acid, (3) xanthine dehydrogenase is involved in purine catabolism and stress reactions, and (4) sulphite oxidase is probably involved in detoxifying excess sulphite. Among Mo-enzymes, the alignment of amino acid sequences permits domains that are well conserved to be defined. With the exception of bacterial nitrogenase, Mo-enzymes share a similar pterin compound at their catalytic sites, the molybdenum cofactor. Mo itself seems to be biologically inactive unless it is complexed by the cofactor. This molybdenum cofactor combines with diverse apoproteins where it is responsible for the correct anchoring and positioning of the Mo-centre within the holo-enzyme so that the Mo-centre can interact with other components of the enzyme's electron transport chain. A model for the three-step biosynthesis of Moco involving the complex interaction of six proteins will be described. A putative Moco-storage protein distributing Moco to the apoproteins of Mo-enzymes will be discussed. After insertion, xanthine dehydrogenase and aldehyde oxidase, but not nitrate reductase and sulphite oxidase, require the addition of a terminal sulphur ligand to their Mo-site, which is catalysed by the sulphur transferase ABA3.
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PMID:Molybdoenzymes and molybdenum cofactor in plants. 1214 19

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