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)

Uteroferrin, the purple acid phosphatase from porcine uterine fluid, is noncompetitively inhibited by vanadate in a time-dependent manner under both aerobic and anaerobic conditions. This time-dependent inhibition is observed only with the diiron enzyme and is absent when the FeZn enzyme is used. The observations are attributed to the sequential formation of two uteroferrin-vanadium complexes. The first complex forms rapidly and reversibly, while the second complex forms slowly and results in the production of catalytically inactive oxidized uteroferrin and V(IV), which is observed by EPR. The redox reaction can be reversed by treatment of the oxidized enzyme first with (V(IV)) and then EDTA to generate a catalytically active uteroferrin. Multiple inhibition kinetics suggests that vanadate is mutually exclusive with molybdate, tungstate, and vanadyl cation. The binding site for each of these anions is distinct from the site to which the competitive inhibitors phosphate and arsenate bind. The time-dependent inhibition by vanadate of uteroferrin containing the diiron core represents a new type of mechanism by which vanadium can interact with proteins and gives additional insight into the binding of anions to uteroferrin.
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PMID:Interaction of porcine uterine fluid purple acid phosphatase with vanadate and vanadyl cation. 133 69

There is continuing controversy as to whether iron can be exchanged from the purple phosphatase, uteroferrin (Uf), to fetal transferrin (Tf) and whether this process might be of physiological relevance during pregnancy in the pig. Here, iron transfer from Uf to apoTf at pH 7.1 was followed by measuring the loss of acid phosphatase activity from native Uf as a function of incubation conditions and time. In the presence of apoTf and 1 mM ascorbate (but not in the presence of either agent alone), 50% of enzyme activity was lost in about 12 h. Loss of activity was accompanied by bleaching of Uf purple color and the appearance of the characteristic visual absorption spectrum of Fe-Tf. Citrate could replace ascorbate in the reaction. Loss of Uf iron did not occur at pH 5.3, at which pH Tf cannot bind Fe. [59Fe]Uf was prepared and shown to be identical in its enzymatic and physical properties with unmodified Uf. Transfer of 59Fe from Uf to apo-Tf was promoted by conditions identical to those which led to loss of purple color and acid phosphatase activity. However, the results suggested that only one of the two iron atoms at the bi-iron center on Uf was readily lost, and that exchange of the second iron occurred more slowly. Loss of iron made Uf more susceptible to denaturation. A third technique, quantitation of the g' = 4.3 signal of iron specifically bound to Tf by EPR, was also tested as a means assaying accumulation of Fe-Tf, but the method was too insensitive to measure the kinetics of iron transfer at physiological protein concentrations. We conclude that iron can be transferred directly from Uf to apoTf in the presence of low molecular weight chelators, and that the process is likely to be of physiological significance.
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PMID:Transfer of iron from uteroferrin (purple acid phosphatase) to transferrin related to acid phosphatase activity. 216 54

Uteroferrin, an acid phosphatase with a spin-coupled and redox-active binuclear iron center, is paramagnetic in its pink, enzymatically active, mixed-valence (S = 1/2) state. Phosphate, a product and inhibitor of the enzymatic activity of uteroferrin, converts the pink, EPR-active form of the protein to a purple, EPR-silent species. In contrast, molybdate, a tetrahedral oxyanion analog of phosphate, transforms the EPR spectrum of uteroferrin from a rhombic to an axial form. With both electron spin echo envelope modulation (ESEEM) and electron nuclear double resonance (ENDOR) spectroscopies, we observe a hyperfine interaction of [95Mo]molybdate with the S = 1/2, Fe(II)-Fe(III) center of the protein. A pair of 95Mo resonances centered at the 95Mo Larmor frequency at the applied magnetic field and separated by a hyperfine coupling constant of 1.2 MHz is evident. Therefore, a single monomeric species of molybdate is close to, and likely a ligand of, the binuclear cluster. 1H ENDOR studies on uteroferrin reveal at least six sets of lines mirrored about the 1H Larmor frequency. Two pairs of these lines become reduced in intensity when the protein is exchanged against D2O. Moreover, ESEEM and 2H ENDOR spectra display resonances at the 2H Larmor frequency. Therefore, the metal-binding region of the protein is accessible to solvent. Additional deuterium lines observable by ESEEM spectroscopy provide evidence for a population of strongly coupled, readily exchangeable protons associated with the binuclear center. The measured hyperfine coupling constants for these deuterons are orientation-dependent with splittings of nearly 4 MHz at g3 = 1.59 and less than 1 MHz at g1 = 1.94. In the presence of molybdate, ESEEM spectra of D2O-exchanged samples reveal a resonance at the 2H Larmor frequency, with no evidence of spectral components due to strongly coupled deuterons. 1H ENDOR studies of the uteroferrin-molybdate complex show at least seven pairs of lines, mirrored about the 1H Larmor frequency, of which one pair becomes attenuated in amplitude upon deuteration. The active site thus remains accessible to solvent in the presence of molybdate.
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PMID:The binding of molybdate to uteroferrin. Hyperfine interactions of the binuclear center with 95Mo, 1H, and 2H. 283 15

The exchange coupling of reduced uteroferrin has been measured (19.8(5) cm-1 S1.S2) using recently developed techniques for studying metalloprotein magnetization. A spin Hamiltonian describing the coupled binuclear Fe(II).Fe(III) center has been used to fit the low and high field magnetization data, the EPR g values, and the highly anisotropic effective hyperfine tensor of the ferric site. The exchange coupling of the phosphate complex of reduced uteroferrin has also been measured (6.0(5) cm-1 S1.S2) using the same techniques. The smaller exchange coupling of the phosphate complex is comparable with the zero field splittings of the iron sites. This results in increased sensitivity of the system g values (found by calculation from the spin Hamiltonian) to variations of the zero field splitting parameters arising from heterogeneities in the protein microenvironment. Consequently, there is a very significant (9-fold) increase in the "effective g strain" of the system compared to the situation in the absence of phosphate. This, together with the larger g anisotropy (g = (1.06, 1.51, 2.27)), gives rise to an EPR signal for the phosphate complex of reduced uteroferrin which is extremely broad and difficult to detect but which has now been identified for the first time.
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PMID:Magnetization and electron paramagnetic resonance studies of reduced uteroferrin and its "EPR-silent" phosphate complex. 284 17

The binuclear iron cluster of uteroferrin in its reduced and enzymatically active pink form is sensitive to a variety or perturbants. Orthophosphate, in the presence or absence of oxygen, rapidly shifts the absorption maximum of pink uteroferrin from 510 to 545 nm, concurrently abolishing the protein's g'av = 1.74 EPR signal. Apparently, therefore, dioxygen is not required for phosphate-induced oxidation of the pink protein's ferrous iron. Pyrophosphate and arsenate produce changes which differ only in degree from those induced by phosphate, suggesting that all of these structurally similar competitive inhibitors bind to a common site. Molybdate, an inhibitor even more potent than phosphate, quantitatively converts the rhombic EPR signal of pink uteroferrin into an axial signal that remains invariant to subsequent additions of phosphate. Thus, there can be inhibition without oxidation, as further evidenced by the complex EPR spectrum of undiminished intensity produced by sulfate. Fluoride, too, induces an axial component in the EPR signal of pink uteroferrin, but at high concentration abolishes the signal entirely. Vanadate also drives the protein to its oxidized, EPR-silent state, serving as an electron acceptor itself to yield the characteristic g' = 2 signal of the vanadyl (VO2+) cation. Remarkably, however, the protein remains pink, demonstrating a dissociation between color and oxidation state. Guanidinium, in contrast, causes a sizeable red shift in the pink protein's absorption maximum without loss of EPR signal intensity, showing dissociation of color and oxidation state in a complementary way.
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PMID:Effects of perturbants on the pink (reduced) active form of uteroferrin. Phosphate-induced anaerobic oxidation. 298 45

Uteroferrin and semimethemerythrin, proteins possessing spin-coupled binuclear iron centers, exhibit large linear electric field effects in their mixed-valence, EPR-active states. This indicates that the paramagnetic center of each protein is noncentrosymmetric and suggests that charge may be localized on one of the iron atoms. The magnetic field dependence of the linear electric field effects for both proteins demonstrates that the direction of most facile polarization of the binuclear iron centers is near the orientation giving rise to gmin. Electron spin-echo studies of uteroferrin reveal that its magnetic electron interacts with at least one and possibly two classes of nitrogen nuclei. Furthermore, comparison of echo envelope spectra for uteroferrin with that of ferric bleomycin suggests that one of these nuclei is from a histidine ligand.
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PMID:Linear electric field effect and electron spin-echo studies of uteroferrin. Evidence for iron coordination by a nitrogen-containing ligand. 298 58

A pink, high molecular weight form of uteroferrin (Uf) has been isolated from uterine secretions and allantoic fluid of pigs. This protein fraction (denoted FIII) which is relatively stable under physiological conditions of pH, ionic strength, and temperature has a molecular weight of about 80,000, a value approximately twice that of purple Uf (Mr approximately 35,000) isolated from a separate fraction (FIV) by gel filtration. The visible absorption spectrum, EPR signal, and acid phosphatase activity of Uf in FIII are almost identical to those of FIV Uf after the latter has been reduced by 2-mercaptoethanol. However, unlike reduced FIV Uf, the pink, high molecular form does not revert to purple, nor does it show loss of EPR signal and phosphatase activity in the presence of oxygen. In addition, it does not become purple at orthophosphate concentrations which inhibit Uf acid phosphatase activity. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate has shown that FIII consists of approximately equal amounts of Uf polypeptides (Mr = 35,000 and 37,000) and a group of three polypeptides (Mr = 40,000, 46,000, and 50,000) antigenically unrelated to Uf. The latter share a common epitope not found on Uf and are probably differentially processed forms of the same protein. FIII can be dissociated by pH conditions below 5.0, by exposure to antibodies raised against Uf or the associated polypeptides, and by sodium dodecyl sulfate at 100 degrees C. The polypeptides in FIII are not therefore linked by disulfide bonds. Treatment with dimethyl suberimidate, however, results in a cross-linked complex (Mr approximately 82,000) consisting of Uf and the associated polypeptides. It is concluded that this high Mr form of Uf is a heterodimer of fully activated Uf and a second polypeptide of unknown function.
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PMID:Isolation and characterization of a high molecular weight stable pink form of uteroferrin from uterine secretions and allantoic fluid of pigs. 301 91

Transfer of iron from native porcine uteroferrin to apotransferrin was investigated using EPR spectroscopy. Purple (oxidized) or pink (reduced) forms of uteroferrin were incubated with porcine or human apotransferrin under conditions of temperature (37 degrees C) and pH (6.8) approximating those found in the allantoic fluid of the pregnant sow. Studies were also performed in the presence of mediators such as ascorbate, citrate, and ATP in concentrations previously claimed to be effective in promoting large-scale transfer of iron (Buhi, W. C., Ducsay, C. A., Bazer, F. W., and Roberts, R. M. (1982) J. Biol. Chem. 257, 1712-1723). Our experiments indicate that even in the presence of mediators, less than 20% of the iron in uteroferrin is transferred to apotransferrin at the end of 24 h and such transfer may be accompanied by denaturation of uteroferrin. We therefore conclude that the direct transfer of iron to apotransferrin is unlikely to be a physiological role of uteroferrin.
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PMID:Absence of iron transfer from uteroferrin to transferrin. 302 57

The effect of phosphate on the binuclear iron center of pink (reduced) uteroferrin was examined by magnetic resonance and optical spectroscopy. The purple (oxidized) protein, which contains 1 mol of tightly bound phosphate per mol of enzyme at isolation, does not give rise to a 31P NMR signal. Phosphate binding to phosphate-stripped pink uteroferrin is indistinguishable from that in the native purple phosphoprotein. As measured by EPR and optical spectroscopy, the rate of reaction between phosphate and pink uteroferrin is pH-dependent, decreasing as the pH increases. Phosphate is capable of binding to the reduced protein between pH 3 and 7.8, resulting in formation of the purple uteroferrin-phosphate complex. Evans susceptibility measurements at pH 4.9 indicate that the EPR silent species with a maximum absorption at 535 nm, generated upon phosphate addition to pink uteroferrin, is diamagnetic. Moreover, phosphate causes disappearance of the hyperfine-shifted resonances in the 1H NMR spectra of the reduced protein. We therefore have not been able to identify the paramagnetic "purple reduced enzyme-phosphate complex" reported by Pyrz et al. (Pyrz, J. W., Sage, J. T., Debrunner, P. G., and Que, Jr., L. (1986) J. Biol Chem. 261, 11015-11020) using Mossbauer spectroscopy and dithionite-reduced 57Fe-reconstituted uteroferrin. Our present data with native unmodified enzyme are in accord with our earlier results (Antanaitis, B. C., and Aisen, P. (1985) J. Biol. Chem. 260, 751-756) and with the results of Burman et al. (Burman, S., Davis, J. C., Weber, M. J., and Averill, B. A. (1986) Biochem. Biophys. Res. Commun. 136, 490-497) on bovine spleen phosphatase, suggesting that phosphate binding to reduced protein rapidly induces oxidation of the binuclear iron center.
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PMID:Spectroscopic studies on the interaction of phosphate with uteroferrin. 303 75

Low temperature (T less than or equal to 20 K) EPR measurements have revealed the presence of a heretofore undetected signal in uteroferrin, a purple protein bearing a single iron atom per molecule. All three of its principal g values (1.923, 1.738, and 1.583) lie well below the free electron value of 2.0023. Magnetic susceptibility data from 2-77 K confirm that the novel EPR spectrum arises from a paramagnetic center with a single unpaired electron spin. Quantitative correlation of the EPR, susceptibility, and optical data point to chromophoric iron as the source of the rhombic EPR spectrum. Furthermore, close agreement between the concentration of iron and the integrated intensity of the rhombic EPR signal show that the iron in the paramagnetic center is mononuclear. Reduction of the protein to its pink form leaves the rhombic signal essentially unaltered. The previously reported g' = 4.3 EPR signal accounts for only a small fraction of the total iron in the protein and undoubtedly arises from adventitious iron. Collectively, these results strongly suggest that uteroferrin represents a new class of low spin iron proteins.
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PMID:The novel "g' = 1.74" EPR spectrum of pink and purple uteroferrin. 625 63


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