Structural characterization of the peroxodiiron(III) intermediate generated during oxygen activation by the W48A/D84E variant of ribonucleotide reductase protein R2 from Escherichia coli

The diiron(II) cluster in the R2 subunit of Escherichia coli ribonucleotide reductase (RNR) activates oxygen to generate a mu-oxodiiron(III) cluster and the stable tyrosyl radical that is critical for the conversion of ribonucleotides to deoxyribonucleotides. Like those in other diiron carboxylate proteins, such as methane monooxygenase (MMO), the R2 diiron cluster is proposed to activate oxygen by formation of a peroxodiiron(III) intermediate followed by an oxidizing high-valent cluster. Substitution of key active site residues results in perturbations of the normal oxygen activation pathway. Variants in which the active site ligand, aspartate (D) 84, is changed to glutamate (E) are capable of accumulating a mu-peroxodiiron(III) complex in the reaction pathway. Using rapid freeze-quench techniques, this intermediate in a double variant, R2-W48A/D84E, was trapped for characterization by M?ssbauer and X-ray absorption spectroscopy. These samples contained 70% peroxodiiron(III) intermediate and 30% diferrous R2. An Fe-Fe distance of 2.5 A was found to be associated with the peroxo intermediate. As has been proposed for the structures of the higher valent intermediates in both R2 and MMO, carboxylate shifts to a mu-(eta(1),eta(2)) or a mu-1,1 conformation would most likely be required to accommodate the short 2.5 A Fe-Fe distance. In addition, the diferrous form of the enzyme present in the reacted sample has a longer Fe-Fe distance (3.5 A) than does a sample of anaerobically prepared diferrous R2 (3.4 A). Possible explanations for this difference in detected Fe-Fe distance include an O(2)-induced conformational change prior to covalent chemistry or differing O(2) reactivity among multiple diiron(II) forms of the cluster.     

Use of a chemical trigger for electron transfer to characterize a precursor to cluster X in assembly of the iron-radical cofactor of Escherichia coli ribonucleotide reductase

A key step in generation of the catalytically essential tyrosyl radical (Y122(*)) in protein R2 of Escherichia coli ribonucleotide reductase is electron transfer (ET) from the near-surface residue, tryptophan 48 (W48), to a (Fe(2)O(2))(4+) complex formed by addition of O(2) to the carboxylate-bridged diiron(II) cluster. Because this step is rapid, the (Fe(2)O(2))(4+) complex does not accumulate and, therefore, has not been characterized. The product of the ET step is a "diradical" intermediate state containing the well-characterized Fe(IV)Fe(III) cluster, X, and a W48 cation radical (W48(+)(*)). The latter may be reduced from solution to complete the two-step transfer of an electron to the buried diiron site. In this study, a (Fe(2)O(2))(4+) state that is probably the precursor to the X-W48(+)(*) diradical state in the reaction of the wild-type protein (R2-wt) has been characterized by exploitation of the observation that in R2 variants with W48 replaced with alanine (A), the otherwise disabled ET step can be mediated by indole compounds. Mixing of the Fe(II) complex of R2-W48A/Y122F with O(2) results in accumulation of an intermediate state that rapidly converts to X upon mixing with 3-methylindole (3-MI). The state comprises at least two species, of which each exhibits an apparent M?ssbauer quadrupole doublet with parameters characteristic of high-spin Fe(III) ions. The isomer shifts of these complexes and absence of magnetic hyperfine coupling in their M?ssbauer spectra suggest that both are antiferromagnetically coupled diiron(III) clusters. The fact that both rapidly convert to X upon treatment with a molecule (3-MI) shown in the preceding paper to mediate ET in W48A R2 variants indicates that they are more oxidized than X by one electron, which suggests that they have a bound peroxide equivalent. Their failure to exhibit either the long-wavelength absorption (at 650-750 nm) or M?ssbauer doublet with high isomer shift (>0.6 mm/s) that are characteristic of the putatively mu-1,2-peroxo-bridged diiron(III) intermediates that have been detected in the reactions of methane monooxygenase (P or H(peroxo)) and variants of R2 with the D84E ligand substitution suggests that they have geometries and electronic structures different from those of the previously characterized complexes. Supporting this deduction, the peroxodiiron(III) complex that accumulates in R2-W48A/D84E is much less reactive toward 3-MI-mediated reduction than the (Fe(2)O(2))(4+) state in R2-W48A/Y122F. It is postulated that the new (Fe(2)O(2))(4+) state is either an early adduct in an orthogonal pathway for oxygen activation or, more likely, the successor to a (mu-1,2-peroxo)diiron(III) complex that is extremely fleeting in R2 proteins with the wild-type ligand set but longer lived in D84E-containing variants.     

Facile electron transfer during formation of cluster X and kinetic competence of X for tyrosyl radical production in protein R2 of ribonucleotide reductase from mouse.

The kinetics and mechanism of formation of the tyrosyl radical and mu-(oxo)diiron(III) cluster in the R2 subunit of ribonucleotide reductase from mouse have been examined by stopped-flow absorption and freeze-quench electron paramagnetic resonance and M?ssbauer spectroscopies. The reaction comprises (1) acquisition of Fe(II) ions by the R2 apo protein, (2) activation of dioxygen at the resulting carboxylate-bridged diiron(II) cluster to form oxidized intermediate diiron species, and (3) univalent oxidation of Y177 by one of these intermediates to form the stable radical, with concomitant or subsequent formation of the adjacent mu-(oxo)diiron(III) cluster. The data establish that an oxidized diiron intermediate spectroscopically similar to the well-characterized, formally Fe(III)Fe(IV) cluster X from the reaction of the Escherichia coli R2 protein precedes the Y177 radical in the reaction sequence and is probably the Y177 oxidant. As formation of the X intermediate (1) requires transfer of an "extra" reducing equivalent to the buried diiron cluster following the addition of dioxygen and (2) is observed to be rapid relative to other steps in the reaction, the present data indicate that the transfer of this reducing equivalent is not rate-limiting for Y177 radical formation, in contrast to what was previously proposed (Schmidt, P. P., Rova, U., Katterle, B., Thelander, L., and Gr?slund, A. (1998) J. Biol. Chem. 273, 21463-21472). Indeed, the formation of X (k(obs) = 13 +/- 3 s(-1) at 5 degrees C and 0.95 mM O(2)) and the decay of the intermediate to give the Y177 radical (k(obs) = 5 +/- 2 s(-1)) are both considerably faster than the formation of the reactive Fe(II)-R2 complex from the apo protein and Fe(II)(aq) (k(obs) = 0.29 +/- 0.03 s(-1)), which is the slowest step overall. The conclusions that cluster X is an intermediate in Y177 radical formation and that transfer of the reducing equivalent is relatively facile imply that the mouse R2 and E. coli R2 reactions are mechanistically similar.     

Addition of oxygen to the diiron(II/II) cluster is the slowest step in formation of the tyrosyl radical in the W103Y variant of ribonucleotide reductase protein R2 from mouse

Activation of O2 by the diiron(II/II) cluster in protein R2 of class I ribonucleotide reductase generates the enzyme's essential tyrosyl radical. A crucial step in this reaction is the transfer of an electron from solution to a diiron(II/II)-O2 adduct during formation of the radical-generating, diiron(III/IV) intermediate X. In the reaction of R2 from Escherichia coli, this electron injection is initiated by the rapid (>400 s-1 at 5 degrees C), transient oxidation of the near-surface residue, tryptophan 48, to a cation radical and is blocked by substitution of W48 with F, A, G, Y, L, or Q. By contrast, a study of the cognate reaction in protein R2 from mouse suggested that electron injection might be the slowest step in generation of its tyrosyl radical, Y177* [Schmidt, P. P., Rova, U., Katterle, B., Thelander, L., and Gr?slund, A. (1998) J. Biol. Chem. 273, 21463-21472]. The crucial evidence was the observation that Y177* production is slowed by approximately 30-fold upon substitution of W103, the cognate of the electron-shuttling W48 in E. coli R2, with tyrosine. In this work, we have applied stopped-flow absorption and freeze-quench electron paramagnetic resonance and M?ssbauer spectroscopies to the mouse R2 reaction to evaluate the possibility that an already sluggish electron-transfer step is slowed by 30-fold by substitution of this key residue. The drastically reduced accumulation of cluster X, failure of precursors to the intermediate to accumulate, and, most importantly, first-order dependence of the rate of Y177* formation on the concentration of O2 prove that addition of O2 to the diiron(II/II) cluster, rather than electron injection, is the slowest step in the R2-W103Y reaction. This finding indicates that the basis for the slowing of Y177* formation by the W103Y substitution is an unexpected secondary effect on the structure or dynamics of the protein, its diiron(II/II) cluster, or both rather than the expected chemical effect on the electron injection step.     

Effect of substrate on the diiron(III) site in stearoyl acyl carrier protein delta 9-desaturase as disclosed by cryoreduction electron paramagnetic resonance/electron nuclear double resonance spectroscopy

The diiron center in stearoyl-acyl carrier protein (ACP) desaturase (DS) from castor plant Ricinus communis catalyzes the dioxygen- and NADPH-dependent introduction of a cis double bond between C9 and C10 of stearoyl-ACP. Radiolytic reduction of diferric DS at 77 K produces an electron paramagnetic resonance (EPR)-detectable mixed-valence center (or [DS(ox)](mv)) that is trapped in the conformation of the diferric precursor and thus provides a sensitive EPR/electron nuclear double resonance (ENDOR) probe of the structure of the diamagnetic diiron(III) state. The cryoreduced DS shows two distinct EPR signals, suggesting the presence of two diiron(III) states: the mu-oxo (major)- and mu-hydroxo (minor)-bridged diiron centers. ENDOR studies show that in the dominant oxo-bridged diferric state each iron(III) coordinates a histidine and a water along with other ligands. Samples containing stoichiometric amounts of stearoyl-ACP show pronounced changes in the EPR and (1)H ENDOR spectra of cryoreduced DS. EPR spectra of the cryoreduced DS-substrate complex reveal two distinct substates of the parent. EPR and ENDOR studies show that both major conformers of the diferric cluster have a mu-oxo bridge. ENDOR shows that the major conformer has a histidine and a water bound to both Fe ions. In the minor conformer, one of the irons has lost the terminal water ligand. The structure of the trapped [DS(ox)](mv) state relaxes upon annealing to 170 K: the mu-oxo bridge in the major cryoreduced DS species protonates on annealing to 170 K; this does not occur for the major DS-substrate complex, even upon annealing to 230 K. The relaxed Fe(II)Fe(III) center in cryoreduced DS and DS-substrate show much less intense and resolved (14)N ENDOR spectra than those of the structurally similar cryoreduced diiron center in ribonucleotide reductase (RNR) protein R2. This difference may reflect some differences in His-Fe bonds. The alterations in the diferric site of DS induced by substrate are suggested to be mediated by conformational changes in the polypeptide chain produced by substrate binding. These structural alterations may provide DS with an additional mechanism for tuning the redox potential of the diferric site. The mixed-valence states of DS are unstable at temperatures above 230 K.     

Oxygen activation by a mixed-valent, diiron(II/III) cluster in the glycol cleavage reaction catalyzed by myo-inositol oxygenase

myo-Inositol oxygenase (MIOX) catalyzes the ring-cleaving, four-electron oxidation of its cyclohexan-(1,2,3,4,5,6-hexa)-ol substrate (myo-inositol, MI) to d-glucuronate (DG). The preceding paper [Xing, G., Hoffart, L. M., Diao, Y., Prabhu, K. S., Arner, R. J., Reddy, C. C., Krebs, C., and Bollinger, J. M., Jr. (2006) Biochemistry 45, 5393-5401] demonstrates by M?ssbauer and electron paramagnetic resonance (EPR) spectroscopies that MIOX can contain a non-heme dinuclear iron cluster, which, in its mixed-valent (II/III) and fully oxidized (III/III) states, is perturbed by binding of MI in a manner consistent with direct coordination. In the study presented here, the redox form of the enzyme that activates O(2) has been identified. l-Cysteine, which was previously reported to accelerate turnover, reduces the fully oxidized enzyme to the mixed-valent form, and O(2), the cosubstrate, oxidizes the fully reduced form to the mixed-valent form with a stoichiometry of one per O(2). Both observations implicate the mixed-valent, diiron(II/III) form of the enzyme as the active state. Stopped-flow absorption and freeze-quench EPR data from the reaction of the substrate complex of mixed-valent MIOX [MIOX(II/III).MI] with limiting O(2) in the presence of excess, saturating MI reveal the following cycle: (1) MIOX(II/III).MI reacts rapidly with O(2) to generate an intermediate (H) with a rhombic, g < 2 EPR spectrum; (2) a form of the enzyme with the same absorption features as MIOX(II/III) develops as H decays, suggesting that turnover has occurred; and (3) the starting MIOX(II/III).MI complex is then quantitatively regenerated. This cycle is fast enough to account for the catalytic rate. The DG/O(2) stoichiometry in the reaction, 0.8 +/- 0.1, is similar to the theoretical value of 1, whereas significantly less product is formed in the corresponding reaction of the fully reduced enzyme with limiting O(2). The DG/O(2) yield in the latter reaction decreases as the enzyme concentration is increased, consistent with the hypothesis that initial conversion of the reduced enzyme to the MIOX(II/III).MI complex and subsequent turnover by the mixed-valent form is responsible for the product in this case. The use of the mixed-valent, diiron(II/III) cluster by MIOX represents a significant departure from the mechanisms of other known diiron oxygenases, which all involve activation of O(2) from the II/II manifold.     

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.     

Crystal structural studies of changes in the native dinuclear iron center of ribonucleotide reductase protein R2 from mouse

Class I ribonucleotide reductase (RNR) catalyzes the de novo synthesis of deoxyribonucleotides in mammals and many other organisms. The RNR subunit R2 contains a dinuclear iron center, which in its diferrous form spontaneously reacts with O2, forming a mu-oxo-bridged diferric cluster and a stable tyrosyl radical. Here, we present the first crystal structures of R2 from mouse with its native dinuclear iron center, both under reducing and oxidizing conditions. In one structure obtained under reducing conditions, the iron-bridging ligand Glu-267 adopts the mu-(eta1,eta2) coordination mode, which has previously been related to O2 activation, and an acetate ion from the soaking solution is observed where O2 has been proposed to bind the iron. The structure of mouse R2 under oxidizing conditions resembles the nonradical diferric R2 from Escherichia coli, with the exception of the coordination of water and Asp-139 to Fe1. There are also additional water molecules near the tyrosyl radical site, as suggested by previous spectroscopic studies. Since no crystal structure of the active radical form has been reported, we propose models for the movement of waters and/or tyrosyl radical site when diferric R2 is oxidized to the radical form, in agreement with our previous ENDOR study. Compared with E. coli R2, two conserved phenylalanine residues in the hydrophobic environment around the diiron center have opposing rotameric conformations, and the carboxylate ligands of the diiron center in mouse R2 appear more flexible. Together, this might contribute to the lower affinity and cooperative binding of iron in mouse R2.     

Dioxygen activation at non-heme diiron centers: oxidation of a proximal residue in the I100W variant of toluene/o-xylene monooxygenase hydroxylase

At its carboxylate-bridged diiron active site, the hydroxylase component of toluene/o-xylene monooxygenase activates dioxygen for subsequent arene hydroxylation. In an I100W variant of this enzyme, we characterized the formation and decay of two species formed by addition of dioxygen to the reduced, diiron(II) state by rapid-freeze quench (RFQ) EPR, M?ssbauer, and ENDOR spectroscopy. The dependence of the formation and decay rates of this mixed-valent transient on pH and the presence of phenol, propylene, or acetylene was investigated by double-mixing stopped-flow optical spectroscopy. Modification of the alpha-subunit of the hydroxylase after reaction of the reduced protein with dioxygen-saturated buffer was investigated by tryptic digestion coupled mass spectrometry. From these investigations, we conclude that (i) a diiron(III,IV)-W* transient, kinetically linked to a preceding diiron(III) intermediate, arises from the one-electron oxidation of W100, (ii) the tryptophan radical is deprotonated, (iii) rapid exchange of either a terminal water or hydroxide ion with water occurs at the ferric ion in the diiron(III,IV) cluster, and (iv) the diiron(III,IV) core and W* decay to the diiron(III) product by a common mechanism. No transient radical was observed by stopped-flow optical spectroscopy for reactions of the reduced hydroxylase variants I100Y, L208F, and F205W with dioxygen. The absence of such species, and the deprotonated state of the tryptophanyl radical in the diiron(III,IV)-W* transient, allow for a conservative estimate of the reduction potential of the diiron(III) intermediate as lying between 1.1 and 1.3 V. We also describe the X-ray crystal structure of the I100W variant of ToMOH.     

Resonance Raman studies of the stoichiometric catalytic turnover of a substrate-stearoyl-acyl carrier protein delta(9) desaturase complex

Resonance Raman spectroscopy has been used to study the effects of substrate binding (stearoyl-acyl carrier protein, 18:0-ACP) on the diferric centers of Ricinus communis 18:0-ACP Delta(9) desaturase. These studies show that complex formation produces changes in the frequencies of nu(s)(Fe-O-Fe) and nu(as)(Fe-O-Fe) consistent with a decrease in the Fe-O-Fe angle from approximately 123 degrees in the oxo-bridged diferric centers of the as-isolated enzyme to approximately 120 degrees in oxo-bridged diferric centers of the complex. Analysis of the shifts in nu(s)(Fe-O-Fe) and nu(as)(Fe-O-Fe) as a function of 18:0-ACP concentration also suggests that 4e(-)-reduced Delta9D containing two diferrous centers has a higher affinity for 18:0-ACP than resting Delta9D containing two diferric centers. Catalytic turnover of a stoichiometric complex of 18:0-ACP and Delta9D was used to investigate whether an O-atom from O(2) would be incorporated into a bridging position of the resultant mu-oxo-bridged diferric centers during the desaturation reaction. Upon formation of approximately 70% yield of 18:1-ACP product in the presence of (18)O(2), no incorporation of an (18)O atom into the mu-oxo bridge position was detected. The result with 18:0-ACP Delta(9) desaturase differs from that obtained during the tyrosyl radical formation reaction of the diiron enzyme ribonucleotide reductase R2 component, which proceeds with incorporation of an O-atom from O(2) into the mu-oxo bridge of the resting diferric site. The possible implications of these results for the O-O bond cleavage reaction and the nature of intermediates formed during Delta9D catalysis are discussed.     

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.     

Restoring proper radical generation by azide binding to the iron site of the E238A mutant R2 protein of ribonucleotide reductase from Escherichia coli

The enzyme activity of Escherichia coli ribonucleotide reductase requires the presence of a stable tyrosyl free radical and diiron center in its smaller R2 component. The iron/radical site is formed in a reconstitution reaction between ferrous iron and molecular oxygen in the protein. The reaction is known to proceed via a paramagnetic intermediate X, formally a Fe(III)-Fe(IV) state. We have used 9.6 GHz and 285 GHz EPR to investigate intermediates in the reconstitution reaction in the iron ligand mutant R2 E238A with or without azide, formate, or acetate present. Paramagnetic intermediates, i.e. a long-living X-like intermediate and a transient tyrosyl radical, were observed only with azide and under none of the other conditions. A crystal structure of the mutant protein R2 E238A/Y122F with a diferrous iron site complexed with azide was determined. Azide was found to be a bridging ligand and the absent Glu-238 ligand was compensated for by azide and an extra coordination from Glu-204. A general scheme for the reconstitution reaction is presented based on EPR and structure results. This indicates that tyrosyl radical generation requires a specific ligand coordination with 4-coordinate Fe1 and 6-coordinate Fe2 after oxygen binding to the diferrous site.     

Mediation by indole analogues of electron transfer during oxygen activation in variants of Escherichia coli ribonucleotide reductase R2 lacking the electron-shuttling tryptophan 48

Activation of dioxygen by the carboxylate-bridged diiron(II) cluster in the R2 subunit of class I ribonucleotide reductase from Escherichia coli results in the one-electron oxidation of tyrosine 122 (Y122) to a stable radical (Y122*). A key step in this reaction is the rapid transfer of a single electron from a near-surface residue, tryptophan 48 (W48), to an adduct between O(2) and diiron(II) cluster to generate a readily reducible cation radical (W48(+)(*)) and the formally Fe(IV)Fe(III) intermediate known as cluster X. Previous work showed that this electron injection step is blocked in the R2 variant with W48 replaced by phenylalanine [Krebs, C., Chen, S., Baldwin, J., Ley, B. A., Patel, U., Edmondson, D. E., Huynh, B. H., and Bollinger, J. M., Jr. (2000) J. Am. Chem. Soc. 122, 12207-12219]. In this study, we show that substitution of W48 with alanine similarly disables the electron transfer (ET) but also permits its chemical mediation by indole compounds. In the presence of an indole mediator, O(2) activation in the R2-W48A variant produces approximately 1 equiv of stable Y122* and more than 1 equiv of the normal (micro-oxo)diiron(III) product. In the absence of a mediator, the variant protein generates primarily altered Fe(III) products and only one-fourth as much stable Y122* because, as previously reported for R2-W48F, most of the Y122* that is produced decays as a consequence of the inability of the protein to mediate reductive quenching of one of the two oxidizing equivalents of the initial diiron(II)-O(2) complex. Mediation of ET is effective in W48A variants containing additional substitutions that also impact the reaction mechanism or outcome. In the reaction of R2-W48A/F208Y, the presence of mediator suppresses formation of the Y208-derived diiron(III)-catecholate product (which is predominant in R2-F208Y in the absence of reductants) in favor of Y122*. In the reaction of R2-W48A/D84E, the presence of mediator affects the outcome of decay of the peroxodiiron(III) intermediate known to accumulate in D84E variants, increasing the yield of Y122* by as much as 2.2-fold to a final value of 0.75 equiv and suppressing formation of a 490 nm absorbing product that results from decay of the two-electron oxidized intermediate in the absence of a functional ET apparatus.     

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.     

An EPR study of the dinuclear iron site in the soluble methane monooxygenase from Methylococcus capsulatus (Bath) reduced by one electron at 77 K: the effects of component interactions and the binding of small molecules to the diiron(III) center

Reduction of the soluble methane monooxygenase hydroxylase (MMOH) from Methylococcus capsulatus (Bath) in frozen 4:1 buffer/glycerol solutions at 77 K by mobile electrons generated by gamma-irradiation produces an EPR-detectable, mixed-valent Fe(II)Fe(III) center. At this temperature the conformation of the enzyme remains essentially unaltered during reduction, so the mixed-valent EPR spectra serve to probe the active site structure of the EPR-silent, diiron(III) state. The EPR spectra of the cryoreduced samples reveal that the diiron(III) cluster of the resting hydroxylase has at least two chemically distinct forms, the structures of which differ from that of the equilibrium Fe(II)Fe(III) site. Their relative populations depend on pH, the presence of component B, and formation of the MMOH/MMOB complex by reoxidation of the reduced, diiron(II) hydroxylase. The formation of complexes between MMOB, MMOR, and the oxidized hydroxylase does not measurably affect the structure of the diiron(III) site. Cryogenic reduction in combination with EPR spectroscopy has also provided information about interaction of MMOH in the diiron(III) state with small molecules. The diiron(III) center binds methanol and phenols, whereas DMSO and methane have no measurable effect on the EPR properties of cryoreduced hydroxylase. Addition of component B favors the binding of some exogenous ligands, such as DMSO and glycerol, to the active site diiron(III) state and markedly perturbs the structure of the diiron(III) cluster complexed with methanol or phenol. The results reveal different reactivity of the Fe(III)Fe(III) and Fe(II)Fe(III) redox states of MMOH toward exogenous ligands. Moreover, unlike oxidized hydroxylase, the binding of exogenous ligands to the protein in the mixed-valent state is allosterically inhibited by MMOB. The differential reactivity of the hydroxylase in its diiron(III) and mixed-valent states toward small molecules, as well as the structural basis for the regulatory effects of component B, is interpreted in terms of a model involving carboxylate shifts of a flexible glutamate ligand at the Fe(II)Fe(III) center.     

Reactivity of a cobalt(III)-peroxo complex in oxidative nucleophilic reactions

A mononuclear cobalt(III)-peroxo complex bearing a macrocyclic tetradentate N₄ ligand, [Co^III(TMC)(O₂)]⁺ (TMC = 1,4,8,11-tetramethyl-1,4,8,11-tetraazacyclotetradecane), was generated in the reaction of [Co^II(TMC)]²⁺ and H₂O₂ in the presence of triethylamine in CH₃CN. The reactivity of the cobalt(III)-peroxo complex was investigated in aldehyde deformylation with various aldehydes and compared with that of iron(III)- and manganese(III)-peroxo complexes, such as [Fe^III(TMC)(O₂)]⁺ and [Mn^III(TMC)(O₂)]⁺. In this reactivity comparison, the reactivities of metal-peroxo species were found to be in the order of [Mn^III(TMC)(O₂)]⁺ > [Co^III(TMC)(O₂)]⁺ > [Fe^III(TMC)(O₂)]⁺. A positive Hammett ρ value of 1.8, obtained in the reactions of [Co^III(TMC)(O₂)]⁺ and para-substituted benzaldehydes, demonstrates that the aldehyde deformylation by the cobalt(III)-peroxo species occurs via a nucleophilic reaction.     

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.     

Ribonucleotide reductase inhibition by metal complexes of Triapine (3-aminopyridine-2-carboxaldehyde thiosemicarbazone): a combined experimental and theoretical study

Triapine (3-aminopyridine-2-carboxaldehyde thiosemicarbazone, 3-AP) is currently the most promising chemotherapeutic compound among the class of α-N-heterocyclic thiosemicarbazones. Here we report further insights into the mechanism(s) of anticancer drug activity and inhibition of mouse ribonucleotide reductase (RNR) by Triapine. In addition to the metal-free ligand, its iron(III), gallium(III), zinc(II) and copper(II) complexes were studied, aiming to correlate their cytotoxic activities with their effects on the diferric/tyrosyl radical center of the RNR enzyme in vitro. In this study we propose for the first time a potential specific binding pocket for Triapine on the surface of the mouse R2 RNR protein. In our mechanistic model, interaction with Triapine results in the labilization of the diferric center in the R2 protein. Subsequently the Triapine molecules act as iron chelators. In the absence of external reductants, and in presence of the mouse R2 RNR protein, catalytic amounts of the iron(III)–Triapine are reduced to the iron(II)–Triapine complex. In the presence of an external reductant (dithiothreitol), stoichiometric amounts of the potently reactive iron(II)–Triapine complex are formed. Formation of the iron(II)–Triapine complex, as the essential part of the reaction outcome, promotes further reactions with molecular oxygen, which give rise to reactive oxygen species (ROS) and thereby damage the RNR enzyme. Triapine affects the diferric center of the mouse R2 protein and, unlike hydroxyurea, is not a potent reductant, not likely to act directly on the tyrosyl radical.     

Formation of mu-oxo dimer by the reaction of (meso-tetraphenylporphyrinato)iron(III) with various imidazoles

Reactions between (meso-tetraphenylporphyrinato)iron(III) perchlorate [Fe(tpp)]ClO4 and various imidazoles have been examined in CD2Cl2 solutions. 1H NMR analysis revealed the formation of three kinds of complex; mu-oxo dimer, mono-imidazole adduct, and bis-imidazole adduct. The product ratios changed to a great extent depending on the amount and nature of imidazoles. In general, addition of less than 1.0 equiv of imidazole relative to [Fe(tpp)]ClO4 led to the formation of both mu-oxo dimer and mono-imidazole adduct. However, by the addition of excess amount of imidazole, either the mu-oxo dimer or bis-imidazole adduct was formed exclusively depending on the bulkiness of the imidazole used. In the case of bulky imidazole such as 2-methylbenzimidazole or 2-isopropyl-1-methylimidazole, the mu-oxo dimer was formed quantitatively. In the case of less bulky imidazole such as parent imidazole or 1-methylimidazole, bis-imidazole adduct became the sole product. The results have been explained in terms of the difference in steric interactions between the axial ligands and porphyrin core; the severe steric repulsion prohibits the formation of bis-adduct in the case of bulky imidazoles. As a result, bulky imidazoles prefer to behave as a base; they abstract a proton from coordinated water, and lead to the formation of mu-oxo dimer. Thus, the role of bulky imidazoles in these reactions has some relevance to that of distal histidine in hemoglobin and peroxidase.     

The iron-oxygen reconstitution reaction in protein R2-Tyr-177 mutants of mouse ribonucleotide reductase. Epr and electron nuclear double resonance studies on a new transient tryptophan radical.

The ferrous iron/oxygen reconstitution reaction in protein R2 of mouse and Escherichia coli ribonucleotide reductase (RNR) leads to the formation of a stable protein-linked tyrosyl radical and a mu-oxo-bridged diferric iron center, both necessary for enzyme activity. We have studied the reconstitution reaction in three protein R2 mutants Y177W, Y177F, and Y177C of mouse RNR to investigate if other residues at the site of the radical forming Tyr-177 can harbor free radicals. In Y177W we observed for the first time the formation of a tryptophan radical in protein R2 of mouse RNR with a lifetime of several minutes at room temperature. We assign it to an oxidized neutral tryptophan radical on Trp-177, based on selective deuteration and EPR and electron nuclear double resonance spectroscopy in H2O and D2O solution. The reconstitution reaction at 22 degrees C in both Y177F and Y177C leads to the formation of a so-called intermediate X which has previously been assigned to an oxo (hydroxo)-bridged Fe(III)/Fe(IV) cluster. Surprisingly, in both mutants that do not have successor radicals as Trp. in Y177W, this cluster exists on a much longer time scale (several seconds) at room temperature than has been reported for X in E. coli Y122F or native mouse protein R2. All three mouse R2 mutants were enzymatically inactive, indicating that only a tyrosyl radical at position 177 has the capability to take part in the reduction of substrates.