Electron paramagnetic resonance and magnetic susceptibility studies of dimanganese concanavalin A. Evidence for antiferromagnetic exchange coupling.

The double Mn2+ complex of concanavalin A with bound saccharide (SMMPL) was examined by electron paramagnetic resonance (EPR) spectroscopy and magnetic susceptibility measurements. A room temperature X-band (9 GHz) EPR spectrum of SMMPL revealed a relatively weak, broad resonance in contrast to the spectrum with a six-line hyperfine-split pattern observed for the mononuclear, high-spin Mn2+ complex found in Ca2+-Mn2+-concanavalin A with saccharide present (SCMPL). The EPR spectrum of SMMPL at 77 K, however, consisted of a series of overlapping patterns of 11 hyperfine-split lines near g = 2.0 with members of each pattern separated by 47 G, half the value of the hyperfine splitting of SCMPL. These 11-line patterns are preserved at Q-band (35 GHz), indicating that the manganese ions in SMMPL form a spin-coupled, binuclear center. As expected for an exchange-coupled system, the EPR signal of SMMPL at 77 K saturates at a higher microwave power than those for SCMPL or Mn2+ aquoion. There is also a marked loss of EPR signal intensity for SMMPL between 4.2 and 1.4 K, which supports the view that the pair of manganese ions is exchanged-coupled. The temperature dependence of both the magnetic susceptibility and the low-temperature EPR spectral intensity can be explained by a model in which the two high-spin Mn2+ ions of SMMPL are antierromagnetically exchanged-coupled with an isotropic coupling constant J = 1.8 cm-1 (for the spin Hamiltonian Hex = JS1.S2). Zero-field splitting D' was estimated to be 375 G from the EPR spectrum.(ABSTRACT TRUNCATED AT 250 WORDS)

Absence of iron transfer from uteroferrin to transferrin.

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.

Linear electric field effect and electron spin-echo studies of uteroferrin. Evidence for iron coordination by a nitrogen-containing ligand.

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.

Iron deposition in apoferritin. Evidence for the formation of a mixed valence binuclear iron complex.

A preliminary EPR investigation of iron accumulation in apoferritin has identified paramagnetic species generated during the early stage of iron deposition within the apoprotein shell. A featureless resonance at g' = 4.3, attributable to solitary high spin Fe3+ ions bound to the protein, is generated when Fe(II) is added to apoferritin at a level of 0.5 Fe/subunit (12 Fe/molecule) followed by air oxidation. This resonance accounts for 36% of the added iron. The remainder is EPR-silent and is probably present as oligomeric Fe3+ species. The intensity of the g' = 4.3 signal is reduced 3-fold upon anaerobic addition of 5 Fe(II)/subunit as a new iron resonance with g' values of 1.94, 1.87, and 1.80 is generated. This signal is observable only at temperatures near that of liquid helium and resists saturation at power levels of 100 milliwatts. Its distinctive g-factors, temperature dependence, and saturation characteristics suggest that it arises from a spin-coupled Fe(II)-Fe(III) dimer having a net electron spin of 1/2. In accord with this idea, the signal disappears when air is admitted, presumably because of oxidation of the Fe(II). The proposed mixed valence dimer may be an important intermediate formed during the initiation of core formation within the protein shell.

Effects of perturbants on the pink (reduced) active form of uteroferrin. Phosphate-induced anaerobic oxidation.

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.

Stoichiometry of iron binding by uteroferrin and its relationship to phosphate content.

The analysis of uteroferrin's iron content by an acid-release method used in previous studies shows a critical dependence on phosphate, i.e. the native phosphate-free enzyme yields two irons/molecule, while enzyme with one tightly bound phosphate gives closer to one iron. In contrast, two irons/molecule of protein are found in samples assayed by a wet ash method. When iron assays are carried out on samples of purple two-iron protein reductively stripped of their phosphate, both methods again yield two iron atoms/molecule. However, the discrepancy between the two methods recurs when phosphate is added to samples of pink protein which were formerly free of phosphate. These results suggest that phosphate bound to native uteroferrin may have interfered with iron determinations in some earlier studies. Furthermore, enzyme samples with one tightly bound phosphate have the optical purity index (i.e.A280/A545 approximately less than 14.0) and extinction coefficient at 280 nm, characteristic of putative one-iron preparations. There is little doubt, therefore, that previous EPR, magnetic susceptibility, and iron titration experiments thought to have been carried out on genuine one-iron preparations were in fact done on samples of two-iron protein bearing a single tightly bound phosphate. Reassessment of earlier studies indicates that the properties of putative one-iron preparations may be reconciled with those of the two-iron phosphate-laden protein studied here.

1H NMR studies of porcine uteroferrin. Magnetic interactions and active site structure.

Pink (reduced) uteroferrin exhibits well resolved paramagnetic NMR spectra with resonances ranging from 90 ppm downfield to 70 ppm upfield. The intensities of these signals depend on the degree of reduction and correlate well with the intensity of the EPR signals with gave = 1.74. Analyses of chemical shifts and the temperature dependence of the paramagnetically shifted resonances indicate that the Fe(III)-Fe(II) cluster in the reduced protein exhibits weak antiferromagnetic exchange coupling (-J approximately equal to 10 cm-1), in agreement with the estimate derived from the temperature dependence of the EPR signal intensity. Purple (oxidized) uteroferrin, on the other hand, exhibits no discernible paramagnetically shifted resonances, reflecting either strong antiferromagnetic coupling or an unfavorable electron spin-lattice relaxation time. Evans susceptibility comparisons between pink and purple uteroferrin show that the Fe(III)-Fe(III) cluster in the oxidized protein is more strongly coupled (-J greater than 40 cm-1). This value concurs with low temperature magnetic susceptibility measurements on both the porcine and splenic purple acid phosphatases. The isotropically shifted protons of tyrosine coordinated to the cluster are assigned by comparison with synthetic complexes. Tyrosine, earlier implicated as a ligand by resonance Raman spectroscopy, appears to coordinate only to the ferric site in pink uteroferrin. This is consistent with the relatively invariant extinction coefficients of uteroferrin in its oxidized and reduced forms and the ease of reduction of the nonchromophoric iron compared to its chromophoric partner. Other possible ligands to the cluster include histidine, suggested by the presence of downfield-shifted solvent-exchangeable resonances with appropriate isotropic shifts.

Detection of a g' = 1.74 EPR signal in bovine spleen purple acid phosphatase.

When purified with hydroxylapatite, bovine spleen purple acid phosphatase, bearing two iron atoms/molecule, is EPR-silent. In contrast, enzyme purified without hydroxylapatite exhibits the distinctive g' = 1.74 EPR signal characteristic of porcine uteroferrin, with an intensity accounting for about 10% of the total iron. The intensity of the signal is increased 8-fold by the addition of ferrous iron. This treatment, while shifting the visible absorption maximum of the protein from 550 to 525 nm, does not significantly alter the intensity of its visible absorption. Loss of the g' = 1.74 EPR signal upon addition of phosphate to EPR-active preparations and the detection of virtually stoichiometric amounts of phosphate in the protein as isolated suggest that phosphate-binding may abolish the g' = 1.75 EPR signal. Such binding may bring the two iron atoms of the enzyme into juxtaposition, causing loss of EPR signal intensity either through spin-lattice relaxation broadening or antiferromagnetic exchange coupling, perhaps involving phosphate or other ligands intercalated between the two paramagnetic iron atoms.

EPR signal, purple color, and iron binding in porcine uteroferrin.

Titration of purple uteroferrin with two reducing equivalents of ferrous ion doubles the intensity of its g' = 1.74 EPR signal while inducing only minor changes in spectral characteristics. Unexpectedly, intensification of the EPR signal is not accompanied by a commensurate increase in visible absorption: only a small shift in peak position from 545 to 525 nm is observed. These observations suggest that uteroferrin can bind a second iron to form a paramagnetic complex that is essentially nonchromophoric. Titration of the pink protein with one oxidizing equivalent of ferric ion also doubles the intensity of its g' = 1.74 EPR signal, again shifting the primary visible absorption band to 525 nm. In either case, therefore, it is possible to augment the g' = 1.74 EPR signal without a corresponding augmentation of purple-pink color. Conversely, the addition of hydrogen peroxide (but not ferricyanide) to purple uteroferrin obliterates the g' = 1.74 EPR signal without abolishing the protein's visible absorption spectrum. Hence, it is also possible to have purple color without a corresponding g' = 1.74 EPR signal. To explain these curious results, two possible models, one involving low spin ferric iron exclusively and the other a combination of low spin ferric and high spin ferrous, are adduced.

The novel "g' = 1.74" EPR spectrum of pink and purple uteroferrin.

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.

Characterization and stability of hydrogenase from Chromatium.

The absorption spectrum of the hydrogenase from Chromatium, which contains four iron atoms and four atoms of acid-labile sulfide, in 80% dimethylsulfoxide or hexamethylphosphoramide suggests the presence of a single [4Fe-4S] cluster. The EPR spectra of the oxidized enzyme in air, argon or carbon monoxide are the same with signals centered at g = 2.01. The enzyme reduced by hydrogen is EPR silent. The EPR spectrum is consistent with a [4Fe-4S] cluster. Chromatium hydrogenase and the hydrogenase from Proteus vulgaris show relative stability towards denaturation by sodium dodecyl sulfate (SDS), urea, guanidine and organic solvents.

Magnetic studies of the four-iron high-potential, non-heme protein from Chromatium vinosum.

Extensive EPR studies on high-potential, iron-sulfur protein from Chromatium vinosum indicate that the singular spectrum of this four-iron, non-heme protein consists of a superposition of three distinct signals; namely, two principal signals of equal weight, one reflecting axial and the other rhombic symmetry, and a third nearly isotropic minority component. In addition, magnetic susceptibility experiments on two oxidation states of the protein from 4.2 to approx. 260 degrees K indicate antiferromagnetic exchange coupling between iron atoms. Possible origins of the complex EPR signals are discussed, and a preferred model that is consistent with EPR, magnetic susceptibility, NMR, X-ray, and Mössbauer data is presented.