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: UNIPROT:O14944 (EPR)
13,097 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hexaheme nitrite reductases purified to homogeneity from Escherichia coli K-12 and Wolinella succinogenes were studied by low-temperature EPR spectroscopy. In their isolated states, the two enzymes revealed nearly identical EPR spectra when measured at 12 K. Both high-spin and low-spin ferric heme EPR resonances with g values of 9.7, 3.7, 2.9, 2.3 and 1.5 were observed. These signals disappeared upon reduction by dithionite. Reaction of reduced enzyme with nitrite resulted in the formation of ferrous heme-NO complexes with distinct EPR spectral characteristics. The heme-NO complexes formed with the two enzymes differed, however, in g values and line-shapes. When reacted with hydroxylamine, reduced enzymes also showed the formation of ferrous heme-NO complexes. These results suggested the involvement of an enzyme-bound NO intermediate during the six-electron reduction of nitrite to ammonia catalyzed by these two hexaheme nitrite reductases. Heme proteins that can either expose bound NO to reduction or release it are significant components of both assimilatory and dissimilatory metabolisms of nitrate. The different ferrous heme-NO complexes detected for the two enzymes indicated, nevertheless, their subtle variation in heme reactivity during the reduction reaction.
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PMID:Comparative EPR studies on the nitrite reductases from Escherichia coli and Wolinella succinogenes. 303 90

The properties of the vanadium-containing bromoperoxidases from the seaweeds Ascophyllum nodosum, Laminaria saccharina and the lichen Xanthoria parietina were studied. Upon reduction with sodium dithionite, these bromoperoxidases show EPR spectra which are typical of a vanadyl cation (VO2+). From the spectral parameters and a comparison with inorganic vanadyl complexes, we conclude that the ligand environment largely consists of oxygen donors. The data also show that the structure of the active sites in these enzymes is very similar. Since EPR spectra of vanadium(IV) bromoperoxidase are only obtained after reduction, the metal ion is present in the native enzymes in the 5+ oxidation state. All these enzymes loose their enzymic activity upon dialysis against citrate-phosphate (PO4(3-)) buffer at pH 3.8, containing EDTA. The brominating activity could be reconstituted by the addition of vanadate (VO4(3-)). The experiments suggest that vanadate is incorporated into these enzymes. In line with the EPR data, we propose a structure of the active site in which at least 4 oxygen atoms are present as donors for the central vanadium(V) ion. Since several inorganic peroxovanadium(V) complexes have been described, we suggest that the vanadium ion in bromoperoxidases serves as a binding site for H2O2. Upon subsequent binding of bromide this ion is oxidized by the peroxo-intermediate to form hypobromite. This model does not require valence state changes of the metal ion itself and indeed no changes in the EPR spectrum of reduced bromoperoxidase are observed upon addition of H2O2 or Br-. Further, bromoperoxidase reduced with a small excess of sodium dithionite is not active in the bromination reaction. The bromoperoxidases from the various sources show similarity in the amino-acid composition with a predominance of acidic amino acids. Distinct pH optima are observed in the bromination reaction catalysed by the bromoperoxidases. Despite the presence of the same prosthetic group in these enzymes with comparable vanadium ligand-field environment, the enzymic properties are very different. The specific activity as well as the Km for bromide differ greatly. Unlike the enzymes from the seaweeds A. nodosum and L. saccharina the bromoperoxidase from the lichen X. parietina is inhibited by low concentrations (1-5 mM) of nitrate. These bromoperoxidases have a remarkable resistance towards organic solvents such as methanol, ethanol and propanol.
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PMID:Structure and function of vanadium-containing bromoperoxidases. 340 34

Nitrite causes changes in the optical and EPR spectra of cytochrome oxidase from heart and alters the spectral, redox and basic properties of cytochrome c. No utilization of nitrite by cytochrome oxidase was observed. However, nitrite inhibits the superoxide dismutase and oxidase activities of the enzyme. Changes in the properties of cytochrome oxidase were observed under effect of some products of nitrite reduction, e. g. nitric oxide, hydroxylamine, hydrazine; nitrate has no effect on the optical and EPR spectra or on the enzyme activity.
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PMID:[Effect of nitrite on cytochrome oxidase]. 627 Dec 65

The stereochemical configuration of the Mn(II) . ADP complex at the active site of creatine kinase has been elucidated by EPR using chirally labeled [alpha-17O]ADP. Superhyperfine coupling between the 17O nucleus and Mn(II) produces a characteristic inhomogeneous broadening of the EPR signals for Mn(II) whenever the 17O is in the first coordination sphere of the metal ion. Previous experiments with ADP regio-specifically labeled with 17O in the phosphate groups had shown that Mn(II) was coordinated to the alpha and beta positions of ADP in transition state analog complexes with creatine kinase that involved enzyme, Mn(II), ADP, creatine, and anions such as formate and thiocyanate (Reed, G. H., and Leyh, T. S. (1980) Biochemistry 19, 5472-5480). The present experiments were initiated to determine the stereochemical configuration of the Mn(II) . ADP complex at the active site of the enzyme. EPR spectra for Mn(II) in transition state analog complexes with formate, thiocyanate, and nitrate as the stabilizing anions show inhomogeneous broadening from 17O in Sp [alpha-17O]ADP whereas the spectra obtained with Rp [alpha-17O]ADP are indistinguishable from those for matched samples with unlabeled ADP. The precision of the measurements indicates that the stereoselectivity of the enzyme for the delta configuration of the alpha, beta chelate of Mn(II) . ADP is greater than 15:1. The delta configuration is also preferred in fully active enzymic complexes involving the equilibrium mixture of substrates.
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PMID:The stereochemical configuration of Mn(II) . ADP at the active site of creatine kinase elucidated by electron paramagnetic resonance with Rp [alpha-17O]ADP and Sp [alpha-17O]ADP. 629 89

The assimilatory nitrate reductase from Chlorella contains flavin, heme, and molybdenum as prosthetic groups. The molybdenum in assimilatory nitrate reductase is associated with a pterin moiety (molybdopterin) as evidenced by the ability of the enzyme to donate active molybdenum cofactor to the Neurospora nitrate reductase mutant nit-1 and by the oxidative conversion of the pterin to two well characterized fluorescent derivatives. The properties of the molybdenum center have been examined by EPR spectroscopy. A molybdenum V signal, absent in the resting enzyme, is elicited upon reduction with NADH and abolished upon reoxidation with nitrate. Reaction of the reduced enzyme with cyanide also abolishes the molybdenum V signal. The line shape and g values of the signal show pH dependence analogous to those observed previously with hepatic sulfite oxidase. The gav for molybdenum V at pH 7.0 was 1.977 and at pH 9.0, 1.961. The signal observed at pH 7.0 exhibits interaction with a single exchangeable proton. Potentiometric titration of the molybdenum center at pH 7.0 indicates that the oxidation-reduction potentials of the molybdenum VI/V and molybdenum V/IV couples are -34 and -54 mV, respectively. These potentials are significantly different from the potentials of the molybdenum center of respiratory-type nitrate reductase and in fact quite closely resemble those of hepatic sulfite oxidase. The oxidized enzyme exhibits the EPR signal of a low spin ferric heme which is abolished upon reduction with NADH.
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PMID:Electron paramagnetic resonance studies on the molybdenum center of assimilatory NADH:nitrate reductase from Chlorella vulgaris. 631 88

Endogenous nitric oxide biosynthesis in mice receiving allogeneic heterotopic heart transplants was monitored as a function of time post-transplant. Nitric oxide production was measured by daily urine nitrate levels and by formation of paramagnetic heme-nitrosyl complexes in the cardiac tissue. Exogenous sources of urine nitrate and EPR signal were minimized by maintaining the animals on a low nitrite/nitrate diet. Urine nitrate peaked on postoperative day 7. A heme-nitrosyl EPR signal also appeared in the cardiac tissue on postoperative day 7 and remained unchanged in size until rejection on postoperative day 9 at which time the peak height of the signal nearly tripled. Some of the animals in the study were treated with the nitric oxide synthase inhibitor, N omega-monomethyl-L-arginine which caused marked inhibition of urinary nitrate excretion and prevented heme-nitrosyl complex formation in beating hearts. However, administration of the inhibitor did not increase graft survival time. Low intensity heme-nitrosyl signals were identified in inhibitor-treated allogeneic hearts after rejection. Syngeneic heart transplants did not induce urinary nitrate excretion nor EPR signal formation. These results show that cytokine induced high output nitric oxide synthesis from L-arginine is a prominent biochemical component of the cell-mediated immune response to cardiac allografts in mice. However, nitric oxide production was not essential for rejection of cardiac allografts mismatched at the major histocompatibility locus.
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PMID:N omega -monomethyl-L-arginine inhibits nitric oxide production in murine cardiac allografts but does not affect graft rejection. 751 90

18-Nitro-oxyandrostenedione (18-ONO2A), a potential mechanism-based inhibitor of the last steps of aldosterone biosynthesis, is well recognized by different cytochrome P-450s, which are able to metabolize it reductively into nitric oxide (NO) and 18-hydroxyandrostenedione. Rat liver microsomal P-450s are able to carry out this reaction with increased efficiency under anaerobic conditions. P-450 3A isozymes induced upon treatment of rats with dexamethasone or troleandomycin were best able to bind and metabolize 18-ONO2A. This reaction was shown to occur in the presence of dioxygen as well, suggesting that it may be of physiological relevance. The formation of NO was detected as a transient P-450-Fe(II)NO complex by UV-visible and EPR spectroscopy. In addition, steroidogenic tissues containing cytochrome P-450s such as bovine adrenal mitochondria or human placental microsomes also were capable of binding and metabolizing 18-ONO2A as judged by the formation of an Fe(II)NO complex. This recognition of a steroid nitrate, a potential antialdosterone and its subsequent metabolism under reductive conditions to generate NO both in hepatic and steroidogenic tissues, can be of pharmacological interest, because NO has been demonstrated to modulate steroidogenesis in addition to other processes such as vascular relaxation, neurotransmission or cytostasis. A nitrate derivative of a steroid could perhaps act as a vectorized NO precursor in which the steroid moiety is targeted specifically to steroid receptors or steroidogenic tissues, thus leading to localized NO liberation.
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PMID:Nitric oxide formation during the cytochrome P-450-dependent reductive metabolism of 18-nitro-oxyandrostenedione. 763 22

We have examined the time course of appearance of mRNA for nitric oxide synthase (NOS), intracellular nonheme iron-nitrosyl complexes (NHFeNO, detected by EPR spectroscopy), and rates of medium appearance of NO2- + NO3- in cultured rat and human hepatocytes stimulated with a combination of cytokines (TNF-alpha, IFN-gamma, IL-1 beta) and LPS. In both cells types, NOS mRNA precedes NHFeNO formation which in turn precedes maximum rates of NO2- + NO3- (NOx) formation. This profile occurs earlier in human hepatocytes than rat hepatocytes and the appearance of NOS mRNA is also more transient. These results indicate that (1) NOS is stable intracellularly (peak NOx production occurs substantially after peak mRNA levels), (2) intracellular iron is an early target (preceding maximum NOx production) for NO in both human and rat hepatocytes, and (3) decline in NHFeNO in the face of maximum NOx production indicates the presence of a "repair" or "removal" mechanism for these intracellular iron-nitrosyl complexes.
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PMID:Induction of nitric oxide synthesis and its reactions in cultured human and rat hepatocytes stimulated with cytokines plus LPS. 768 28

In the facultative anaerobe Escherichia coli, the transcription factor FNR (fumarate nitrate reduction) regulates gene expression in response to oxygen deprivation. To investigate how the activity of FNR is regulated by oxygen availability, two mutant proteins, DA154 and LH28-DA154, which have enhanced in vivo activity in the presence of oxygen, were purified and compared. Unlike other previously examined FNR preparations, the absorption spectrum of LH28-DA154 had two maxima at 324 nm and 419 nm, typical of iron-sulfur (Fe-S)-containing proteins. Consistent with these data, metal analysis showed that only the LH28-DA154 protein contained a significant amount of iron and acid-labile sulfide, and, by low temperature EPR spectroscopy, a signal typical of a [3Fe-4S]+ cluster was detected. The LH28-DA154 protein that contained the Fe-S cluster also contained a higher proportion of dimers and had a 3- to 4-fold higher apparent affinity for the target DNA than the DA154 protein. In agreement with this, we found that when the LH28-DA154 protein was treated with an iron chelator (alpha,alpha'-dipyridyl), it lost its characteristic absorption and the apparent affinity for DNA was reduced 6-fold. However, increased DNA binding and the characteristic absorption spectrum could be restored by in vitro reconstitution of the Fe-S center. DNA binding of the LH28-DA154 protein was also affected by the redox state of the Fe-S center, since protein exposed to oxygen bound 1/10th as much DNA as the protein reduced anaerobically with dithionite. The observation that DNA binding is enhanced when the Fe-S center is reduced indicates that the redox state of the Fe-S center affects the DNA-binding activity of this protein and suggests a possible mechanism for regulation of the wild-type protein.
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PMID:Association of a polynuclear iron-sulfur center with a mutant FNR protein enhances DNA binding. 770 73

A c-type monohemic ferricytochrome C552 (11 kDa) was isolated from the soluble extract of a marine denitrifier, Pseudomonas nautica strain 617, grown under anaerobic conditions with nitrate as final electron acceptor. The NH2-terminal sequence and the amino acid composition of the cytochrome were determined. The heme iron of the cytochrome C552 has histidine-methionine as axial ligands, and a pH-dependent mid-point redox potential, equal to 250 mV at pH 7.6. The presence of methionine was demonstrated by visible, EPR and NMR spectroscopies. The assignment of most of the hemic protons was performed applying two-dimensional NOE spectroscopy (NOESY), and the aromatic region was assigned through two-dimensional correlated spectroscopy (COSY) experiments. The EPR spectrum of the oxidised form of the cytochrome C552 is typical of a low-spin ferric heme.
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PMID:Physico-chemical and spectroscopic properties of the monohemic cytochrome C552 from Pseudomonas nautica 617. 792 98


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