Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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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 nitrate reductase operon (narGHJI) of Escherichia coli encodes an anaerobic respiratory enzyme. Previous work has identified two cis-acting sites in the nar operon control region: a proximal site required for anaerobic induction mediated by the activator Fnr and a remote upstream site required for nitrate induction mediated by the activator NarL [Li, S. & DeMoss, J. A. (1988) J. Biol. Chem. 263, 13700-13705]. Our search for nar regulatory mutants yielded one strain with a mutation in himD, the structural gene for one of the subunits of integration host factor (IHF). Strains carrying null alleles of the IHF structural genes, himD and himA, had severe defects in nitrate induction of the nar operon but were normal for nitrate induction of the coordinately regulated fdn operon. Anaerobic expression of both operons was normal in him mutants. Gel-mobility-shift and DNase I protection experiments revealed a single IHF binding site in the nar operon control region, located midway between the upstream activation site and the promoter. We conclude that an IHF-mediated DNA bend is essential for efficient nitrate induction of the sigma 70-dependent nar operon promoter. This requirement of IHF for transcriptional activation had been noted for several sigma 54-dependent promoters.
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PMID:In vivo requirement of integration host factor for nar (nitrate reductase) operon expression in Escherichia coli K-12. 152 82

Two membrane-bound nitrate reductases, NRA and NRZ, exist in Escherichia coli. Both isoenzymes are composed of three structural subunits, alpha, beta, and gamma encoded by narG/narZ, narH/narY and narI/narV, respectively. The genes are in transcription units which also contain a fourth gene encoding a polypeptide, delta, which is not part of the final enzyme. A strain which is devoid of, or does not express, the nar genes, was used to investigate the role of the delta and gamma polypeptides in the formation and/or processing of the nitrate reductase. When only the alpha and beta polypeptides are produced, an (alpha beta) complex exists which is inactive and soluble. When the alpha, beta and delta polypeptides are produced, the (alpha beta) complex is active with artificial donors such as benzyl viologen but is soluble. When the alpha, beta and gamma polypeptides are produced, the (alpha beta) complex is inactive but partially binds the membrane. It was concluded that the gamma polypeptide is involved in the binding of the (alpha beta) complex to the membrane while the delta polypeptide is indispensable for the (alpha beta) nitrate reductase activity. The activation by the delta polypeptide does not seem to involve the insertion of the redox centres of the enzyme since the purified inactive (alpha beta) complex was shown to contain the four iron-sulphur centres and the molybdenum cofactor, which are normally present in the native purified enzyme. The extreme sensitivity of this inactive complex to thermal denaturation or tryptic treatment favours the idea that the delta polypeptide promotes the correct assembly of the alpha and beta subunits. Although this corresponds to the definition of a chaperone protein this possibility has been rejected. In this study we have also demonstrated that the delta or gamma polypeptide encoded by one nar operon can be substituted successfully for by its respective counterpart from the other nar operon to give an active membrane bound heterologous nitrate reductase enzyme.
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PMID:Involvement of the narJ or narW gene product in the formation of active nitrate reductase in Escherichia coli. 154 6

Respiratory nitrate reductase purified from the cell membrane of Escherichia coli is composed of three subunits, alpha, beta, and gamma, which are encoded, respectively, by the narG, narH, and narI genes of the narGHJI operon. The product of the narJ gene was deduced previously to be a highly charged, acidic protein which was not found to be associated with any of the purified preparations of the enzyme and which, in studies with putative narJ mutants, did not appear to be absolutely required for formation of the membrane-bound enzyme. To test this latter hypothesis, the narJ gene was disrupted in a plasmid which contained the complete narGHJI operon, and the operon was expressed in a narG::Tn10 insertion mutant. The chromosomal copy of the narJ gene of a wild-type strain was also replaced by the disrupted narJ gene. In both cases, when nar operon expression was induced, the alpha and beta subunits accumulated in a form which expressed only very low activity with either reduced methyl viologen (MVH) or formate as electron donors, although an alpha-beta complex separated from the gamma subunit is known to catalyze full MVH-linked activity but not the formate-linked activity associated with the membrane-bound complex. The low-activity forms of the alpha and beta subunits also accumulated in the absence of the NarJ protein when the gamma subunit (NarI) was provided from a multicopy plasmid, indicating that NarJ is essential for the formation of the active, membrane-bound complex. When both NarJ and NarI were provided from a plasmid in the narJ mutant, fully active, membrane-bound activity was formed. When NarJ only was provided from a plasmid in the narJ mutant, a cytosolic form of the alpha and beta subunits, which expressed significantly increased levels of the MVH-dependent activity, accumulated, and the alpha subunit appeared to be protected from the proteolytic clipping which occurred in the absence of NarJ. We conclude that NarJ is indispensible for the biogenesis of membrane-bound nitrate reductase and is involved either in the maturation of a soluble, active alpha-beta complex or in facilitating the interaction of the complex with the membrane-bound gamma subunit.
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PMID:The narJ gene product is required for biogenesis of respiratory nitrate reductase in Escherichia coli. 173 20

In the nitrate reductase system of Escherichia coli, the maximal expression of the nar operon is obtained under anaerobiosis in the presence of nitrate. Mudl (Ap,lac) insertion mutants, which only grew on lactose anaerobically if supplemented with nitrate were mapped at the chlC locus at min 27 of the map. In these fusion strains which lack benzyl viologen dependent nitrate reductase (NR) activity as well as the formiate-linked NR activity, the synthesis of beta-galactosidase reflects the regulation of the wild type nar operon at the transcriptional level. From these strains, two classes of spontaneous regulatory mutants were isolated: class I mutants which synthesized beta-galactosidase in anaerobiosis in the absence of nitrate and class II mutants in which the synthesis of that enzyme was partially independent of nitrate and it was no longer repressed by oxygen. The class I regulatory mutation was tightly linked to the nar operon as shown by bacteriophage P1 transductions. It probably affects either a closely linked cis-active element or a gene coding for a negative regulatory protein.
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PMID:Isolation and characterization of mutants affected in the expression of the nar operon Escherichia coli. 213 55

Escherichia coli has two terminal oxidases for its respiratory chain: cytochrome o (low O2 affinity) and cytochrome d (high O2 affinity). Expression of the cyo operon, encoding cytochrome o, is decreased by anaerobic growth, whereas expression of the cyd operon, encoding cytochrome d, is increased by anaerobic growth. We show by the use of lac gene fusion that the expressions of cyo and cyd are under the control of the two-component arc system. In a cyo+ cyd+ background, expression of phi(cyo-lac) is higher when the organism is grown aerobically than when it is grown anaerobically. A mutation in either the sensor gene arcB or the pleiotropic regulator gene arcA almost abolishes the anaerobic repression. In the same background, expression of phi(cyd-lac) is higher under anaerobic growth conditions than under aerobic growth conditions. A mutation in arcA or arcB lowers both the aerobic and anaerobic expressions, suggesting that ArcA plays an activating role instead of the typical repressing role. Under aerobic growth conditions, double deletions of cyo and cyd lower phi(cyo-lac) expression but enhance phi(cyd-lac) expression. The double deletions also prevent elevated aerobic induction of the lct operon (encoding L-lactate dehydrogenase), another target operon of the arc system. In contrast, these deletions do not circumvent aerobic repression of the nar operon (encoding the anaerobic respiratory enzyme nitrate reductase) under the control of the pleiotropic fnr gene product. It thus appears that ArcB senses the presence of O2 by level of an electron transport component in reduced form or that of an nonautoxidizable compound linked to the process by a redox reaction, whereas Fnr senses O2 by a different mechanism.
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PMID:Requirement for terminal cytochromes in generation of the aerobic signal for the arc regulatory system in Escherichia coli: study utilizing deletions and lac fusions of cyo and cyd. 217 Mar 37

In previous studies it has been established that in Escherichia coli the three known subunits of anaerobic nitrate reductase are encoded by the narGHI operon. From the nucleotide sequence of the narI region of the operon we conclude that, in addition to the narG and narH genes, the nar operon contains two other open reading frames (ORFs), ORF1 and ORF2, that encode proteins of 26.5 and 25.5 kilodaltons, respectively. Protein fusions to each of the genes in the operon showed that expression of all four genes was similarly regulated. The reading frames of ORF1 and ORF2 were verified, and the N-terminal sequence for the ORF1 fusion protein was determined. The nar operon therefore contains four genes designated and ordered as narGHJI.
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PMID:narI region of the Escherichia coli nitrate reductase (nar) operon contains two genes. 283 76

A detailed restriction site map was determined for an 8.4-kilobase DNA fragment containing the 5' regulatory and promoter region of the nar operon of Escherichia coli. The 5' end of the nar operon was subcloned as a 2.5-kilobase fragment, and an intact nar operon was constructed from this subcloned fragment and an EcoRI fragment containing the remainder of the nar operon. A set of Bal 31 deletions extending into the 5' region of the intact operon was selected, mapped, and characterized. Based on the synthesis of the alpha and beta subunits of nitrate reductase in a nar::Tn5 mutant, three categories of deletions were found: (i) those which permitted normal expression, (ii) those which completely prevented expression, and (iii) those which permitted anaerobic expression of the operon but prevented any additional induction by nitrate. The nucleotide sequence was determined for a segment of the nar promoter region starting at one of the latter deletion end points and extending into the first structural gene of the operon. The position of the deletion end point relative to the translation start site for the first structural gene, narG, was defined by identifying the nucleotide sequence for the first 20 N-terminal amino acid residues of the alpha subunit of nitrate reductase. Deletions terminating 161 base pairs (bp) and approximately 200 bp upstream from the narG translation start site permitted anaerobic formation of nitrate reductase but interfered with the stimulation of nar operon expression by nitrate. A maximum size for the regulatory region was defined by two Tn5 insertions, which mapped approximately 550 bp 5' from the translation start site and did not interfere with the normal expression of nitrate reductase under anaerobic conditions with or without nitrate. We conclude that the nar operon 5' regulatory region is divided into two distinct regions: the 100 to 150 bp immediately 5' to the narG gene include a transcriptional start site and the signals necessary for anaerobic expression of the operon, and an adjacent region of 50 to 400 bp is required for the stimulation of operon expression by nitrate.
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PMID:Delineation of two distinct regulatory domains in the 5' region of the nar operon of Escherichia coli. 299 9

In Escherichia coli, aerobiosis inhibits the synthesis of enzymes for anaerobic respiration (e.g., nitrate reductase and fumarate reductase) and for fermentation (e.g., formate-hydrogen lyase). Anaerobically, nitrate induces nitrate reductase synthesis and inhibits the formation of both fumarate reductase and formate-hydrogen lyase. Previous work has shown that narL+ is required for the effects of nitrate on synthesis of both nitrate reductase and fumarate reductase. Another gene, narK (whose function is unknown), has no observable effect on formation of these enzymes. We report here our studies on the role of nar genes in fumarate reductase and formate-hydrogen lyase gene expression. We observed that insertions in narX (also of unknown function) significantly relieved nitrate inhibition of fumarate reductase gene expression. This phenotype was distinct from that of narL insertions, which abolished this nitrate effect under certain growth conditions. In contrast, insertion mutations in narK and narGHJI (the structural genes for the nitrate reductase enzyme complex) significantly relieved nitrate inhibition of formate-hydrogen lyase gene expression. Insertions in narL had a lesser effect, and insertions in narX had no effect. We conclude that nitrate affects formate-hydrogen lyase synthesis by a pathway distinct from that for nitrate reductase and fumarate reductase.
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PMID:Influence of nar (nitrate reductase) genes on nitrate inhibition of formate-hydrogen lyase and fumarate reductase gene expression in Escherichia coli K-12. 304 31

Nitrate reductase, released and purified from membrane fractions of Escherichia coli, is composed of three subunits. Formation of the enzyme depends on induction of the nar operon, narGHJI, which is composed of four open reading frames (ORF). Previous studies established that the first two genes in the operon narG and narH encode the alpha and beta subunits, respectively, while formation of the gamma subunit, cytochrome bNR, depends on expression of the promoter distal genes. The narJ and narI genes were subcloned separately into plasmids where each was under the control of the nar promoter. Expression of these plasmids in a mutant which forms only alpha and beta subunits revealed that expression of the narI gene is sufficient to restore normal levels of cytochrome bNR, but expression of both genes is required for assembly of fully active, membrane-bound nitrate reductase. The amino acid composition, the N-terminal sequence, and the sequence of cyanogen bromide fragments derived from the isolated gamma subunit corresponds to that expected for a protein produced by the narI ORF. A protein corresponding to the narJ ORF did not appear to be associated with the purified nitrate reductase complex or with the complex immunoprecipitated from Triton X-100-solubilized membrane preparations. We conclude that narI encodes the gamma subunit (cytochrome bNR) and that while the product of the narJ gene is required for assembly of fully active membrane-bound enzyme it is not tightly associated with the active enzyme.
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PMID:Roles of the narJ and narI gene products in the expression of nitrate reductase in Escherichia coli. 305 88

Nitrate reductase is demonstrated to exert an autogenous control on its own synthesis. This effect requires the participation of the molybdenum cofactor. Use of strains in which the control region of the nar operon is mutated reveals two loci in this region: one, affected in strain LCB94, is common to both autoregulation and induction by nitrate while the other, mutated in strain LCB188, is specific for the induction by nitrate. It is proposed that the autogenous control prevents the unnecessary accumulation of the nitrate reductase subunits in the cytoplasm.
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PMID:Autoregulation of the nar operon encoding nitrate reductase in Escherichia coli. 309 94


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