Magnetic interaction between the tyrosyl free radical and the antiferromagnetically coupled iron center in ribonucleotide reductase

Ribonucleotide reductases from Escherichia coli and from mammalian cells are heterodimeric enzymes. One of the subunits, in the bacterial enzyme protein B2 and in the mammalian enzyme protein M2, contains iron and a tyrosyl free radical that both are essential for enzyme activity. The iron center in protein B2 is an antiferromagnetically coupled pair of high-spin ferric ions. This study concerns magnetic interaction between the tyrosyl radical and the iron center in the two proteins. Studies of the temperature dependence of electron paramagnetic resonance (EPR) relaxation and line shape reveal significant differences between the free radicals in proteins B2 and M2. The observed temperature-dependent enhanced EPR relaxation and line broadening of the enzyme radicals are furthermore completely different from those of a model UV-induced free radical in tyrosine. The results are discussed in terms of magnetic dipolar as well as exchange interactions between the free radical and the iron center in both proteins. The free radical and the iron center are thus close enough in space to exhibit magnetic interaction. For protein M2 the effects are more pronounced than for protein B2, indicating a stronger magnetic interaction.     

A purple acid phosphatase from sweet potato contains an antiferromagnetically coupled binuclear Fe-Mn center

A purple acid phosphatase from sweet potato is the first reported example of a protein containing an enzymatically active binuclear Fe-Mn center. Multifield saturation magnetization data over a temperature range of 2 to 200 K indicates that this center is strongly antiferromagnetically coupled. Metal ion analysis shows an excess of iron over manganese. Low temperature EPR spectra reveal only resonances characteristic of high spin Fe(III) centers (Fe(III)-apo and Fe(III)-Zn(II)) and adventitious Cu(II) centers. There were no resonances from either Mn(II) or binuclear Fe-Mn centers. Together with a comparison of spectral properties and sequence homologies between known purple acid phosphatases, the enzymatic and spectroscopic data strongly indicate the presence of catalytic Fe(III)-Mn(II) centers in the active site of the sweet potato enzyme. Because of the strong antiferromagnetism it is likely that the metal ions in the sweet potato enzyme are linked via a mu-oxo bridge, in contrast to other known purple acid phosphatases in which a mu-hydroxo bridge is present. Differences in metal ion composition and bridging may affect substrate specificities leading to the biological function of different purple acid phosphatases.     

Tyrosyl free radical formation in the small subunit of mouse ribonucleotide reductase

Each R2 subunit of mammalian ribonucleotide reductase contains a pair of high spin ferric ions and a tyrosyl free radical essential for activity. To study the mechanism of tyrosyl radical formation, substoichiometric amounts of Fe(II) were added to recombinant mouse R2 apoprotein under strictly anaerobic conditions and then the solution was exposed to air. Low temperature EPR spectroscopy showed that the signal from the generated tyrosyl free radical correlated well with the quantity of the Fe(II) added with a stoichiometry of 3 Fe(II) needed to produce 1 tyrosyl radical: 3 Fe(II) + P + O2 + Tyr-OH + H+----Fe(III)O2-Fe(III)-P + H2O. + Tyr-O. + Fe(III), where P is an iron-binding site of protein R2 and Tyr-OH is the active tyrosyl residue. The O-O bond of a postulated intermediate O2(2-)-Fe(III)2-P state is cleaved by the extra electron provided by Fe(II) leading to formation of OH., which in turn reacts with Tyr-OH to give Tyr-O.. In the presence of ascorbate, added to reduce the monomeric Fe(III) formed, 80% of the Fe(II) added produced a radical. The results strongly indicate that each dimeric Fe(III) center during its formation can generate a tyrosyl-free radical and that iron binding to R2 apoprotein is highly cooperative.     

Reduced forms of the iron-containing small subunit of ribonucleotide reductase from Escherichia coli

The B2 subunit of ribonucleotide reductase from Escherichia coli contains a stable tyrosyl free radical and an antiferromagnetically coupled dimeric iron center with high-spin ferric ions. The tyrosyl radical is an oxidized form of tyrosine-122. This study shows that the B2 protein has a fully reduced state, denoted reduced B2, characterized by a normal nonradical tyrosine-122 residue and a dimeric ferrous iron center. Reduced B2 can be formed either from active B2 by a three-electron reduction in the presence of suitable mediators or from apoB2 by addition of two equimolar amounts of ferrous ions in the absence of oxygen. The oxidized tyrosyl radical and the ferric iron center can be generated from reduced B2 by the admission of air. The tyrosyl radical can be selectively reduced by one-electron reduction in the presence of a suitable mediator, yielding metB2, a form that seems identical with the form resulting from treatment of active B2 with hydroxyurea. 1H NMR was used to characterize the paramagnetically shifted resonances associated with the reduced iron center. Prominent resonances were observed around 45 ppm (nonexchangeable with solvent) and 57 ppm (exchangeable with solvent) at 37 degrees C. From the temperature dependence of the chemical shifts of these resonances it was concluded that the ferrous ions in reduced B2 are only weakly, if at all, antiferromagnetically coupled. By comparison with data on the similar iron center of deoxyhemerythrin it is suggested that the 57 ppm resonance should be assigned to protons in histidine ligands of the iron center.     

A new tyrosyl radical on Phe208 as ligand to the diiron center in Escherichia coli ribonucleotide reductase, mutant R2-Y122H. Combined x-ray diffraction and EPR/ENDOR studies

The R2 protein subunit of class I ribonucleotide reductase (RNR) belongs to a structurally related family of oxygen bridged diiron proteins. In wild-type R2 of Escherichia coli, reductive cleavage of molecular oxygen by the diferrous iron center generates a radical on a nearby tyrosine residue (Tyr122), which is essential for the enzymatic activity of RNR, converting ribonucleotides into deoxyribonucleotides. In this work, we characterize the mutant E. coli protein R2-Y122H, where the radical site is substituted with a histidine residue. The x-ray structure verifies the mutation. R2-Y122H contains a novel stable paramagnetic center which we name H, and which we have previously proposed to be a diferric iron center with a strongly coupled radical, Fe(III)Fe(III)R.. Here we report a detailed characterization of center H, using 1H/2H -14N/15N- and 57Fe-ENDOR in comparison with the Fe(III)Fe(IV) intermediate X observed in the iron reconstitution reaction of R2. Specific deuterium labeling of phenylalanine residues reveals that the radical results from a phenylalanine. As Phe208 is the only phenylalanine in the ligand sphere of the iron site, and generation of a phenyl radical requires a very high oxidation potential, we propose that in Y122H residue Phe208 is hydroxylated, as observed earlier in another mutant (R2-Y122F/E238A), and further oxidized to a phenoxyl radical, which is coordinated to Fe1. This work demonstrates that small structural changes can redirect the reactivity of the diiron site, leading to oxygenation of a hydrocarbon, as observed in the structurally similar methane monoxygenase, and beyond, to formation of a stable iron-coordinated radical.     

Paramagnetically shifted resonances in 1H NMR spectra of ribonucleotide reductase from Escherichia coli

The 400-MHz 1H NMR spectra of the subunit B2 of ribonucleotide reductase from Escherichia coli show paramagnetically shifted resonances at 24 ppm (exchangeable protons) and at 19 ppm (nonexchangeable protons). The protein contains an antiferromagnetically coupled dimeric iron center and a tyrosyl free radical. The paramagnetically shifted resonances must be due to the iron center, since they remain essentially unchanged in protein B2 with and without free radical. In analogy with recently published results for hemerythrin from Phascolopsis gouldii, which has a similar iron center, the 24-ppm resonance is suggested to arise from histidine ligands to the iron ions.     

Reduction of the Fe(III)-tyrosyl radical center of Escherichia coli ribonucleotide reductase by dithiothreitol

The active form of protein B2, the small subunit of ribonucleotide reductase from Escherichia coli, contains a binuclear ferric center and a free radical localized to tyrosine 122 of the polypeptide chain. MetB2 is an inactive form that lacks the tyrosine radical but retains the Fe(III) center. We earlier reported (Fontecave, M., Eliasson, R., and Reichard, P. (1989) J. Biol. Chem. 264, 9164-9170) that enzymes from E. coli interconvert B2 and metB2, possibly as part of a regulatory mechanism. Introduction of the tyrosyl radical into metB2 occurred in two steps: first, the Fe(III) center was reduced to Fe(II), generating "reduced B2"; next oxygen regenerated non-enzymatically both Fe(III) and the tyrosyl radical. Here we demonstrate that dithiothreitol (DTT) between pH 8 and 9.5 also slowly converts metB2 to B2 in the presence of oxygen. Also in this case the reaction occurs stepwise with reduced B2 as an intermediate. DTT reduces Fe(III) of both metB2 and B2. In the latter case this reaction is accompanied by the immediate loss of the tyrosyl radical. Our results indicate that the tyrosyl radical can exist only in the presence of an intact Fe(III) center. In reduced B2 iron is loosely bound to the protein, dissociates on standing and is readily removed by chelating agents. Binding decreases at higher pH. Loss of iron from reduced B2 explains why ferrous iron stimulates and iron chelators inhibit reactivation of metB2. We propose that the reactivation of mammalian ribonucleotide reductase by DTT (Thelander, M., Gr?slund, A., and Thelander, L. (1983) Biochem. Biophys. Res. Commun. 110, 859-865) may proceed via a mechanism similar to the one found here for E. coli protein B2.     

Electron transfer associated with oxygen activation in the B2 protein of ribonucleotide reductase from Escherichia coli

Each of the two beta peptides which comprise the B2 protein of Escherichia coli ribonucleotide reductase (RRB2) possesses a nonheme dinuclear iron cluster and a tyrosine residue at position 122. The oxidized form of the protein contains all high spin ferric iron and 1.0-1.4 tyrosyl radicals per RRB2 protein. In order to define the stoichiometry of in vitro dioxygen reduction catalyzed by fully reduced RRB2 we have quantified the reactants and products in the aerobic addition of Fe(II) to metal-free RRB2apo utilizing an oxygraph to quantify oxygen consumption, electron paramagnetic resonance to measure tyrosine radical generation, and M?ssbauer spectroscopy to determine the extent of iron oxidation. Our data indicate that 3.1 Fe(II) and 0.8 Tyr122 are oxidized per mol of O2 reduced. M?ssbauer experiments indicate that less than 8% of the iron is bound as mononuclear high spin Fe(III). Further, the aerobic addition of substoichiometric amounts of 57Fe to RRB2apo consistently produces dinuclear clusters, rather than mononuclear Fe(III) species, providing the first direct spectroscopic evidence for the preferential formation of the dinuclear units at the active site. These stoichiometry studies were extended to include the phenylalanine mutant protein (Y122F)RRB2 and show that 3.9 mol-equivalents of Fe(II) are oxidized per mol of O2 consumed. Our stoichiometry data has led us to propose a model for dioxygen activation catalyzed by RRB2 which invokes electron transfer between iron clusters.     

EPR evidence of two structurally different diferric sites in Mycobacterium tuberculosis R2-2 ribonucleotide reductase protein

Mixed-valent species were generated in the diiron site of active (with tyrosyl free radical) and met (without radical) forms of protein R2-2 in a class Ib ribonucleotide reductase from Mycobacterium tuberculosis by low temperature reduction (γ-irradiation) at 77 K. The primary mixed-valent EPR signal is a mixture of two components with axial symmetry and g_av<2.0, observable at temperatures up to 77 K, and assigned to antiferromagnetically coupled high spin ferric/ferrous sites. The two components in the primary EPR signal can be explained by the existence of two structurally distinct μ-oxo-bridged diferric centers, possibly related to structural heterogeneity around the iron site, and/or different properties of the two polypeptide chains in the homodimeric protein after the radical reconstitution reaction. Annealing of the irradiated R2-2 samples to 143 K transforms the primary EPR signal into a rhombic spectrum characterized by g_av<1.8 and observable only below 25 K. This spectrum is assigned to a partially relaxed form with a μ-hydroxo-bridge. Further annealing at 228 K produces a new complex rhombic EPR spectrum composed of at least two components. An identical EPR spectrum was observed and found to be stable upon chemical reduction of Mycobacterium tuberculosis RNR R2-2 at 293 K by dithionite.     

Reduction of the small subunit of Escherichia coli ribonucleotide reductase by hydrazines and hydroxylamines.

Each polypeptide chain of protein R2, the small subunit of ribonucleotide reductase from Escherichia coli, contains a stable tyrosyl radical and an antiferromagnetically coupled diferric center. Recent crystallographic studies [Nordlund, P., Eklund, H., & Sj?berg, B.-M. (1990) Nature 345, 593-598] have shown that both the radical and the diiron site are deeply buried inside the protein and thus strongly support the hypothesis of long-range electron-transfer processes within protein R2. This study shows that monosubstituted hydrazines and hydroxylamines are able to reduce the tyrosyl radical and the ferric ions, under anaerobic conditions. It allows characterization of the site from which those compounds transfer their electrons to the iron/radical center. The efficiency of any given reducing agent is not solely governed by its redox potential but also by its size, its charge, and its hydrophobicity. We suggest, as a possible alternative to the long-range electron-transfer hypothesis, that conformational flexibility of the polypeptide chain might exist in solution and allow small molecules to penetrate the protein and react with the iron/radical center. This study also shows that two reduction mechanisms are possible, depending on which center, the radical or the metal, is reduced first. Full reduction of protein R2 yields reduced R2, characterized by a normal tyrosine residue and a diferrous center. Both the radical and the diferric center are regenerated from reduced R2 by reaction with oxygen, while only the diferric center is formed by reaction with hydrogen peroxide.     

EPR evidence of two structurally different diferric sites in Mycobacterium tuberculosis R2-2 ribonucleotide reductase protein

Mixed-valent species were generated in the diiron site of active (with tyrosyl free radical) and met (without radical) forms of protein R2-2 in a class Ib ribonucleotide reductase from Mycobacterium tuberculosis by low temperature reduction (γ-irradiation) at 77 K. The primary mixed-valent EPR signal is a mixture of two components with axial symmetry and g_av<2.0, observable at temperatures up to 77 K, and assigned to antiferromagnetically coupled high spin ferric/ferrous sites. The two components in the primary EPR signal can be explained by the existence of two structurally distinct μ-oxo-bridged diferric centers, possibly related to structural heterogeneity around the iron site, and/or different properties of the two polypeptide chains in the homodimeric protein after the radical reconstitution reaction. Annealing of the irradiated R2-2 samples to 143 K transforms the primary EPR signal into a rhombic spectrum characterized by g_av<1.8 and observable only below 25 K. This spectrum is assigned to a partially relaxed form with a μ-hydroxo-bridge. Further annealing at 228 K produces a new complex rhombic EPR spectrum composed of at least two components. An identical EPR spectrum was observed and found to be stable upon chemical reduction of Mycobacterium tuberculosis RNR R2-2 at 293 K by dithionite.     

Iron detoxification properties of Escherichia coli bacterioferritin. Attenuation of oxyradical chemistry

Bacterioferritin (EcBFR) of Escherichia coli is an iron-mineralizing hemoprotein composed of 24 identical subunits, each containing a dinuclear metal-binding site known as the "ferroxidase center." The chemistry of Fe(II) binding and oxidation and Fe(III) hydrolysis using H(2)O(2) as oxidant was studied by electrode oximetry, pH-stat, UV-visible spectrophotometry, and electron paramagnetic resonance spin trapping experiments. Absorption spectroscopy data demonstrate the oxidation of two Fe(II) per H(2)O(2) at the ferroxidase center, thus avoiding hydroxyl radical production via Fenton chemistry. The oxidation reaction with H(2)O(2) corresponds to [Fe(II)(2)-P](Z) + H(2)O(2) --> [Fe(III)(2)O-P](Z) + H(2)O, where [Fe(II)(2)-P](Z) represents a diferrous ferroxidase center complex of the protein P with net charge Z and [Fe(III)(2)O-P](Z) a micro-oxo-bridged diferric ferroxidase complex. The mineralization reaction is given by 2Fe(2+) + H(2)O(2) + 2H(2)O --> 2FeOOH((core)) + 4H(+), where two Fe(II) are again oxidized by one H(2)O(2). Hydrogen peroxide is shown to be an intermediate product of dioxygen reduction when O(2) is used as the oxidant in both the ferroxidation and mineralization reactions. Most of the H(2)O(2) produced from O(2) is rapidly consumed in a subsequent ferroxidase reaction with Fe(II) to produce H(2)O. EPR spin trapping experiments show that the presence of EcBFR greatly attenuates the production of hydroxyl radical during Fe(II) oxidation by H(2)O(2), consistent with the ability of the bacterioferritin to facilitate the pairwise oxidation of Fe(II) by H(2)O(2), thus avoiding odd electron reduction products of oxygen and therefore oxidative damage to the protein and cellular components through oxygen radical chemistry.     

Circular dichroism and magnetic circular dichroism studies of the active site of p53R2 from human and mouse: iron binding and nature of the biferrous site relative to other ribonucleotide reductases

Ribonucleotide reductases (RNR) catalyze the rate-limiting step in the synthesis of deoxyribonucleotides from the corresponding ribonucleotides in the synthesis of DNA. Class I RNR has two subunits: R1 with the substrate binding and active site and R2 with a stable tyrosyl radical and diiron cluster. Biferrous R2 reacts with oxygen to form the tyrosyl radical needed for enzymatic activity. A novel R2 form, p53R2, is a 351-amino acid protein induced by the "tumor suppressor gene" p53. p53R2 has been studied using a combination of circular dichroism, magnetic circular dichroism, variable-temperature variable-field MCD, and EPR spectroscopies. The active site of biferrous p53R2 in both the human (hp53R2) and mouse (mp53R2) forms is found to have one five-coordinate and one four-coordinate iron, which are weakly antiferromagnetically coupled through mu-1,3-carboxylate bridges. These spectroscopic data are very similar to those of Escherichia coli R2, and mouse R2, with a stronger resemblance to data of the former. Titrations of apo-hp53R2 and apo-mp53R2 with Fe(II) were pursued for the purpose of comparing their metal binding affinities to those of other R2s. Both p53R2s were found to have a high affinity for Fe(II), which is different from that of mouse R2 and may reflect differences in the regulation of enzymatic activity, as p53R2 is mainly triggered during DNA repair. The difference in ferrous affinity between mammalian R2 and p53R2 suggests the possibility of specific inhibition of DNA precursor synthesis during cell division.     

Structure of superoxide reductase bound to ferrocyanide and active site expansion upon X-ray-induced photo-reduction

Some sulfate-reducing and microaerophilic bacteria rely on the enzyme superoxide reductase (SOR) to eliminate the toxic superoxide anion radical (O2*-). SOR catalyses the one-electron reduction of O2*- to hydrogen peroxide at a nonheme ferrous iron center. The structures of Desulfoarculus baarsii SOR (mutant E47A) alone and in complex with ferrocyanide were solved to 1.15 and 1.7 A resolution, respectively. The latter structure, the first ever reported of a complex between ferrocyanide and a protein, reveals that this organo-metallic compound entirely plugs the SOR active site, coordinating the active iron through a bent cyano bridge. The subtle structural differences between the mixed-valence and the fully reduced SOR-ferrocyanide adducts were investigated by taking advantage of the photoelectrons induced by X-rays. The results reveal that photo-reduction from Fe(III) to Fe(II) of the iron center, a very rapid process under a powerful synchrotron beam, induces an expansion of the SOR active site.     

High catalytic activity achieved with a mixed manganese-iron site in protein R2 of Chlamydia ribonucleotide reductase

Ribonucleotide reductase (class I) contains two components: protein R1 binds the substrate, and protein R2 normally has a diferric site and a tyrosyl free radical needed for catalysis. In Chlamydia trachomatis RNR, protein R2 functions without radical. Enzyme activity studies show that in addition to a diiron cluster, a mixed manganese-iron cluster provides the oxidation equivalent needed to initiate catalysis. An EPR signal was observed from an antiferromagnetically coupled high-spin Mn(III)-Fe(III) cluster in a catalytic reaction mixture with added inhibitor hydroxyurea. The manganese-iron cluster in protein R2 confers much higher specific activity than the diiron cluster does to the enzyme.     

Oxygen cleavage with manganese and iron in ribonucleotide reductase from <Emphasis Type="Italic">Chlamydia trachomatis</Emphasis>

The oxygen cleavage in Chlamydia trachomatis ribonucleotide reductase (RNR) has been studied using B3LYP* hybrid density functional theory. Class Ic C. trachomatis RNR lacks the radical-bearing tyrosine, crucial for activity in conventional class I (subclass a and b) RNR. Instead of the Fe(III)Fe(III)–Tyr(rad) active state, C. trachomatis RNR has a mixed Mn(IV)Fe(III) metal center in subunit II (R2). A mixed MnFe metal center has never been observed as a radical cofactor before. The active state is generated by reductive oxygen cleavage at the metal site. On the basis of calculated barriers for oxygen cleavage in C. trachomatis R2 and R2 from Escherichia coli with a diiron, a mixed manganese–iron, and a dimanganese center, conclusions can be drawn about the effect of changing metals in R2. The oxygen cleavage is found to be governed by two factors: the redox potentials of the metals and the relative stability of the different peroxides. Mn(IV) has higher stability than Fe(IV), and the barrier is therefore lower with a mixed metal center than with a diiron center. With a dimanganese center, an asymmetric peroxide is more stable than the symmetric peroxide, and the barrier therefore becomes too high. Calculated proton-coupled redox potentials are compared to identify three possible R2 active states, the Fe(III)Fe(III)–Tyr(rad) state, the Mn(IV)Fe(III) state, and the Mn(IV)Mn(IV) state. A tentative energy profile of the thermodynamics of the radical transfer from R2 to subunit I is constructed to illustrate how the stability of the active states can be understood from a thermodynamical point of view.     

Redox-dependent open and closed forms of the active site of the bacterial respiratory nitric-oxide reductase revealed by cyanide binding studies

The bacterial respiratory nitric-oxide reductase (NOR) catalyzes the respiratory detoxification of nitric oxide in bacteria and Archaea. It is a member of the well known super-family of heme-copper oxidases but has a [heme Fe-non-heme Fe] active site rather than the [heme Fe-Cu(B)] active site normally associated with oxygen reduction. Paracoccus denitrificans NOR is spectrally characterized by a ligand-to-metal charge transfer absorption band at 595 nm, which arises from the high spin ferric heme iron of a micro-oxo-bridged [heme Fe(III)-O-Fe(III)] active site. On reduction of the nonheme iron, the micro-oxo bridge is broken, and the ferric heme iron is hydroxylated or hydrated, depending on the pH. At present, the catalytic cycle of NOR is a matter of much debate, and it is not known to which redox state(s) of the enzyme nitric oxide can bind. This study has used cyanide to probe the nature of the active site in a number of different redox states. Our observations suggest that the micro-oxo-bridged [heme Fe(III)-O-Fe(III)] active site represents a closed or resting state of NOR that can be opened by reduction of the non-heme iron.     

The binding of molybdate to uteroferrin. Hyperfine interactions of the binuclear center with 95Mo, 1H, and 2H

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.     

Characterization of the free radical of mammalian ribonucleotide reductase

Mouse fibroblast 3T6 cells, selected for resistance to hydroxyurea, were shown to overproduce protein M2, one of the two nonidentical subunits of mammalian ribonucleotide reductase. Packed resistant cells gave an EPR signal at 77 K very much resembling the signal given by the tyrosine-free radical of the B2 subunit of Escherichia coli ribonucleotide reductase. Also, the M2-specific free radical was shown to be located at a tyrosine residue. Of the known tyrosine-free radicals of ribonucleotide reductases from E. coli, bacteriophage T4 infected E. coli and pseudorabies virus infected mouse L cells, the M2-specific EPR signal is most closely similar to the signal of the T4 radical. The small differences in the low temperature EPR signals between these four highly conserved tyrosine-free radical structures can be explained by slightly different angles of the beta-methylene group in relation to the plane of the aromatic ring of tyrosine, reflecting different conformations of the polypeptide chain around the tyrosines. The pronounced difference in microwave saturation between the E. coli B2 tyrosine radical EPR signal and the M2 signal could be due to their different interactions with unspecific paramagnetic ions or with the antiferromagnetically coupled iron pair, shown to be present in the E. coli enzyme and postulated also for the mammalian enzyme. A difference in the iron-radical center between the bacterial and mammalian ribonucleotide reductase is also observed in the ability to regenerate the free radical structure. In contrast to the B2 radical, the M2 tyrosine free radical could be regenerated by merely adding dithiothreitol in the presence of O2 to a cell extract where the radical had previously been destroyed by hydroxyurea treatment.