Alanine radicals,part 4: relative amounts of radical species in alanine dosimeters after exposure to 6-19 MeV electrons and 10 kV-15 MV photons

The amino acid l-alpha-alanine can be used for high-precision dosimetry over a wide dose range, using EPR spectroscopy for monitoring radical concentrations. It is important, however, to understand the underlying composition of the observed EPR spectrum. In previous work, it was shown that the EPR signal from irradiated alanine consists of at least three different radical species, with the relative importance of each of these being almost independent of absorbed dose. However, it was not known whether the relative importance of each radical is independent of the radiation quality responsible for the EPR signal. In the present work, the relative contributions of the different radical species to the total EPR signal from alanine dosimeters irradiated with 6-19 MeV electrons and 10 kV-15 MV photons at a dose of 10 Gy were examined. By spectrum reconstruction using benchmark spectra generated from a simulation procedure, the relative amounts of the three different radical species were shown to be virtually independent of these radiation beam qualities.     

Structural comparisons of arachidonic acid-induced radicals formed by prostaglandin H synthase-1 and -2

Cyclooxygenase catalysis by prostaglandin H synthase (PGHS)-1 and -2 involves reaction of a peroxide-induced Tyr385 radical with arachidonic acid (AA) to form an AA radical that reacts with O₂. The potential for isomeric AA radicals and formation of an alternate tyrosyl radical at Tyr504 complicate analysis of radical intermediates. We compared the EPR spectra of PGHS-1 and -2 reacted with peroxide and AA or specifically deuterated AA in anaerobic, single-turnover experiments. With peroxide-treated PGHS-2, the carbon-centered radical observed after AA addition was consistently a pentadienyl radical; a variable wide-singlet (WS) contribution from mixture of Tyr385 and Tyr504 radicals was also present. Analogous reactions with PGHS-1 produced EPR signals consistent with varying proportions of pentadienyl and tyrosyl radicals, and two additional EPR signals. One, insensitive to oxygen exposure, is the narrow singlet tyrosyl radical with clear hyperfine features found previously in inhibitor-pretreated PGHS-1. The second type of EPR signal is a narrow singlet lacking detailed hyperfine features that disappeared upon oxygen exposure. This signal was previously ascribed to an allyl radical, but high field EPR analysis indicated that ~ 90% of the signal originates from a novel tyrosyl radical, with a small contribution from a carbon-centered species. The radical kinetics could be resolved by global analysis of EPR spectra of samples trapped at various times during anaerobic reaction of PGHS-1 with a mixture of peroxide and AA. The improved understanding of the dynamics of AA and tyrosyl radicals in PGHS-1 and -2 will be useful for elucidating details of the cyclooxygenase mechanism, particularly the H-transfer between tyrosyl radical and AA.     

A tyrosine-derived free radical in apogalactose oxidase

Oxidation of apogalactose oxidase with ferricyanide leads to the formation of a stable free radical exhibiting distinctive optical absorption and EPR spectral features. The radical is associated with absorption in both near-UV and near-IR spectral regions, and its EPR spectrum is characteristic of an aromatic free radical with gav = 2.005. Reconstitution of both the apoenzyme and the free radical-containing form with copper substantially restores both the absorption spectra and the catalytic activity of the active enzyme, indicating that the preparation of the radical species does not significantly damage the protein. The absence of a free radical EPR signal in reconstituted and activated galactose oxidase containing nearly stoichiometric copper suggests the radical is an active site species relating to the free radical-coupled copper site previously proposed for this enzyme. Isotopic labeling experiments demonstrate that the radical derives from a tyrosine residue. The distinctive spectra associated with this radical indicate an environment which is different from that associated with the tyrosyl phenoxyl sites in other free radical enzymes.     

Structural characterization of arachidonyl radicals formed by aspirin-treated prostaglandin H synthase-2

Peroxide-generated tyrosyl radicals in both prostaglandin H synthase (PGHS) isozymes have been demonstrated to couple the peroxidase and cyclooxygenase activities by serving as the immediate oxidant for arachidonic acid (AA) in cyclooxygenase catalysis. Acetylation of Ser-530 of PGHS-1 by aspirin abolishes all oxygenase activity and transforms the peroxide-induced tyrosyl radical from a functional 33-35-gauss (G) wide doublet/wide singlet to a 26-G narrow singlet unable to oxidize AA. In contrast, aspirin-treated PGHS-2 (ASA-PGHS-2) no longer forms prostaglandins but retains oxygenase activity forming 11(R)- and 15(R)-hydroperoxyeicosatetraenoic acid and also retains the EPR line-shape of the native peroxide-induced 29-30-G wide singlet radical. To evaluate the functional role of the wide singlet radical in ASA-PGHS-2, we have examined the ability of this radical to oxidize AA in single-turnover EPR studies. Anaerobic addition of AA to ASA-PGHS-2 immediately after formation of the wide singlet radical generated either a 7-line EPR signal similar to the pentadienyl AA radical obtained in native PGHS-2 or a 26-28-G singlet radical. These EPR signals could be accounted for by a pentadienyl radical and a strained allyl radical, respectively. Experiments using 11d-AA, 13(R)d-AA, 15d-AA, 13,15d(2)-AA, and octadeuterated AA (d(8)-AA) confirmed that the unpaired electron in the pentadienyl radical is delocalized over C11, C13, and C15. A 6-line EPR radical was observed when 16d(2)-AA was used, indicating only one strongly interacting C16 hydrogen. These results support a functional role for peroxide-generated tyrosyl radicals in lipoxygenase catalysis by ASA-PGHS-2 and also indicate that the AA radical in ASA-PGHS-2 is more constrained than the corresponding radical in native PGHS-2.     

Electron paramagnetic and electron nuclear double resonance of the hydrogen peroxide compound of cytochrome c peroxidase

We have collected electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectra from the hydrogen peroxide compound of yeast cytochrome c peroxidase, termed ES, employing EPR microwave frequencies of 9.6 and 11.6 GHz. We have measured and analyzed the temperature dependence of the spin-lattice relaxation rate (1/T1) of the paramagnetic center of ES over the temperature range 1.9 to 4 K. In addition, an upper bound to exchange coupling between the ferryl heme and EPR-visible centers of ES has been calculated and expressions for the dipolar interaction between a ferryl heme and a free radical have been derived. These results all confirm that the EPR signal of ES is not associated with an aromatic amino acid radical, and in particular not with a tryptophanyl radical. This conclusion has led us to consider an explanation of the EPR signal in terms of a nucleophilically stabilized methionyl radical.     

Identification of a radical formed in the reaction mixture of rat brain homogenate with a ferrous ion/ascorbic acid system using HPLC–EPR and HPLC–EPR–MS

Identification of a free radical is performed for the reaction mixture of rat brain homogenate with a ferrous ion/ascorbic acid system using EPR, high performance liquid chromatography–electron paramagnetic resonance spectrometry (HPLC–EPR) and high performance liquid chromatography–electron paramagnetic resonance–mass spectrometry (HPLC–EPR–MS). EPR measurements of the reaction mixtures showed prominent signals with hyperfine coupling constants (α^N = 1.58 mT and α^Hβ = 0.26 mT). No EPR spectrum was detectable without rat brain homogenate, suggesting that the radical is derived from rat brain homogenate. An HPLC–EPR analysis of the reaction mixture showed a peak with retention time of 33.7 min. An HPLC–EPR–MS analysis of the peak gave two ions at m/z 224 and 137, suggesting that α-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN)/ethyl radical adduct forms in the reaction mixture.     

A stable organic free radical in anaerobic benzylsuccinate synthase of Azoarcus sp. strain T

The novel enzyme benzylsuccinate synthase initiates anaerobic toluene metabolism by catalyzing the addition of toluene to fumarate, forming benzylsuccinate. Based primarily on its sequence similarity to the glycyl radical enzymes, pyruvate formate-lyase and anaerobic ribonucleotide reductase, benzylsuccinate synthase was speculated to be a glycyl radical enzyme. In this report we use EPR spectroscopy to demonstrate for the first time that active benzylsuccinate synthase from the denitrifying bacterium Azoarcus sp. strain T harbors an oxygen-sensitive stable organic free radical. The EPR signal of the radical was centered at g = 2.0021 and was characterized by a major 2-fold splitting of about 1.5 millitesla. The strong similarities between the EPR signal of the benzylsuccinate synthase radical and that of the glycyl radicals of pyruvate formate-lyase and anaerobic ribonucleotide reductase provide evidence that the benzylsuccinate synthase radical is located on a glycine residue, presumably glycine 828 in Azoarcus sp. strain T benzylsuccinate synthase.     

Cyclooxygenase reaction mechanism of PGHS--evidence for a reversible transition between a pentadienyl radical and a new tyrosyl radical by nitric oxide trapping

Incubation of prostaglandin H synthase-1 (PGHS-1) under anaerobic conditions with peroxide and arachidonic acid leads to two major radical species: a pentadienyl radical and a radical with a narrow EPR spectrum. The proportions of the two radicals are sensitive to temperature, favoring the narrow radical species at 22 °C. The EPR characteristics of this latter radical are somewhat similar to the previously reported narrow-singlet tyrosine radical NS1a and are insensitive to deuterium labeling of AA. To probe the origin and structure of this radical, we combined EPR analysis with nitric oxide (NO) trapping of tyrosine and substrate derived radicals for both PGHS-1 and -2. Formation of 3-nitrotyrosine in the proteins was analyzed by immunoblotting, whereas NO adducts to AA and AA metabolites were analyzed by mass spectrometry and by chromatography of ¹⁴C-labeled products. The results indicate that both nitrated tyrosine residues and NO-AA adducts formed upon NO trapping. The predominant NO-AA adduct was an oxime at C11 of AA with three conjugated double bonds, as indicated by absorption at 275 nm and by mass spectral analysis. This adduct amounted to 10% and 20% of the heme concentration of PGHS-1 and -2, respectively. For PGHS-1, the yield of NO-AA adduct matched the yield of the narrow radical signal obtained in parallel EPR experiments. High frequency EPR characterization of this narrow radical, reported in an accompanying paper, supports assignment to a new tyrosyl radical, NS1c, rather than an AA-based radical. To reconcile the results from EPR and NO-trapping studies, we propose that NS1c is in equilibrium with an AA pentadienyl radical, and that the latter reacts preferentially with NO.     

Superoxide formation as a result of interaction of L-lysine with dicarbonyl compounds and its possible mechanism

The EPR signal recorded in reaction medium containing L-lysine and methylglyoxal is supposed to come from the anion radical (semidione) of methylglyoxal and cation radical of methylglyoxal dialkylimine. These free radical inter-mediates might be formed as a result of electron transfer from dialkylimine to methylglyoxal. The EPR signal was observed in a nitrogen atmosphere, whereas only trace amounts of free radicals were registered under aerobic conditions. It has been established that the decay of methylglyoxal anion radical on aeration of the medium is inhibited by superoxide dismutase. Using the methods of EPR spectroscopy and lucigenin-dependent chemiluminescence, it has been shown that nonenzymatic generation of free radicals including superoxide anion radical takes place during the interaction of L-lysine with methylglyoxal — an intermediate of carbonyl stress — at different (including physiological) pH values. In the course of analogous reaction of L-lysine with malondialdehyde (the secondary product of the free radical derived oxidation of lipids), the formation of organic free radicals or superoxide radical was not observed.     

Identification of the 1,2-propanediol-1-yl radical as an intermediate in adenosylcobalamin-dependent diol dehydratase reaction

The reaction catalyzed by adenosylcobalamin-dependent diol dehydratase proceeds by a radical mechanism. A radical pair consisting of the Co(II) of cob(II)alamin and an organic radical intermediate formed during catalysis gives EPR spectra. The high-field doublet and the low-field broad signals arise from the weak interaction of an organic radical with the low-spin Co(II) of cob(II)alamin. To characterize the organic radical intermediate in the diol dehydratase reaction, several deuterated and (13)C-labeled 1,2-propanediols were synthesized, and the EPR spectra observed in the catalysis were measured using them as substrate. The EPR spectra with the substrates deuterated on C1 showed significant line width narrowing of the doublet signal. A distinct change in the hyperfine coupling was seen with [1-(13)C]-1,2-propanediol, but not with the [2-(13)C]-counterpart. Thus, the organic radical intermediate observed by EPR spectroscopy was identified as the 1,2-propanediol-1-yl radical, a C1-centered substrate-derived radical.     

Structure of a substrate radical intermediate in the reaction of lysine 2,3-aminomutase.

Electron paramagnetic resonance (EPR) spectroscopy has been used to characterize an organic radical that appears in the steady state of the reaction catalyzed by lysine 2,3-aminomutase from Clostridium SB4. Results of a previous electron paramagnetic resonance (EPR) study [Ballinger, M. D., Reed, G. H., & Frey, P. A. (1992) Biochemistry 31, 949-953] demonstrated the presence of EPR signals from an organic radical in reaction mixtures of the enzyme. The materialization of these signals depended upon the presence of the enzyme, all of its cofactors, and the substrate, lysine. Changes in the EPR spectrum in response to deuteration in the substrate implicated the carbon skeleton of lysine as host for the radical center. This radical has been further characterized by EPR measurements on samples with isotopically substituted forms of lysine and by analysis of the hyperfine splittings in resolution-enhanced spectra by computer simulations. Changes in the hyperfine splitting patterns in EPR spectra from samples with [2-2H]lysine and [2-13C]-lysine show that the paramagnetic species is a pi-radical with the unpaired spin localized primarily in a p orbital on C2 of beta-lysine. In the EPR spectrum of this radical, the alpha-proton, the beta-nitrogen, and the beta-proton are responsible for the hyperfine structure. Analysis of spectra for reactions initiated with L-lysine, [3,3,4,4,5,5,6,6-2H8]lysine, [2-2H]lysine, perdeuteriolysine, [alpha-15N]lysine, and [alpha-15N,2-2H]lysine permit a self-consistent assignment of hyperfine splittings.(ABSTRACT TRUNCATED AT 250 WORDS)     

Direct EPR detection of the carbonate radical anion produced from peroxynitrite and carbon dioxide

The biological effects of peroxynitrite have been recently considered to be largely dependent on its reaction with carbon dioxide, which is present in high concentrations in intra- and extracellular compartments. Peroxynitrite anion (ONOO-) reacts rapidly with carbon dioxide, forming an adduct, nitrosoperoxocarboxylate (ONOOCO2-), whose decomposition has been proposed to produce reactive intermediates such as the carbonate radical (CO-3). Here, by the use of rapid mixing continuous flow electron paramagnetic resonance (EPR), we directly detected the carbonate radical in flow mixtures of peroxynitrite with bicarbonate-carbon dioxide over the pH range of 6-9. The radical was unambiguously identified by its EPR parameters (g = 2.0113; line width = 5.5 G) and by experiments with bicarbonate labeled with 13C. In this case, the singlet EPR signal obtained with 12C bicarbonate splits into the expected doublet because of 13C (a(13C)= 11.7 G). The singlet spectrum of the unlabeled radical was invariant between pH 6 and 9, confirming that in this pH range the detected radical is the carbonate radical anion (CO-3). Importantly, in addition to contributing to the understanding of nitrosoperoxocarboxylate decomposition pathways, this is the first report unambiguously demonstrating the formation of the carbonate radical anion at physiological pHs by direct EPR spectroscopy.     

Probing interactions from solvent-exchangeable protons and monovalent cations with the 1,2-propanediol-1-yl radical intermediate in the reaction of dioldehydrase

The reaction of adenosylcobalamin-dependent dioldehydrase with 1,2-propanediol gives rise to a radical intermediate observable by EPR spectroscopy. This reaction requires a monovalent cation such as potassium ion. The radical signal arises from the formation of a radical pair comprised of the Co(II) of cob(II)alamin and a substrate-related radical generated upon hydrogen abstraction by the 5'-deoxyadenosyl radical. The high-field asymmetric doublet arising from the organic radical has allowed investigation of its composition and environment through the use of EPR spectroscopic techniques. To characterize the protonation state of the oxygen substituents in the radical intermediate, X-band EPR spectroscopy was performed in the presence of D(2)O and compared to the spectrum in H(2)O. Results indicate that the unpaired electron of the steady-state radical couples to a proton on the C(1) hydroxyl group. Other spectroscopic experiments were performed, using either potassium or thallous ion as the activating monovalent cation, in an attempt to exploit the magnetic nature of the (205,203)Tl nucleus to identify any intimate interaction of the radical intermediate with the activating cation. The radical intermediate in complex with dioldehydrase, cob(II)alamin and one of the activating monovalent cations was observed using EPR, ENDOR, and ESEEM spectroscopy. The spectroscopic evidence did not implicate a direct coordination of the activating cation and the substrate derived radical intermediate.     

Nature of the free radical in ribonucleotide reductase from Escherichia coli.

Ribonucleotide reductase from Escherichia coli consists of two nonidentical subunits, proteins B1 and B2. The active site of the enzyme is made up from both subunits. Protein B2 contributes inter alia an organic free radical which gives a characteristic EPR signal. This radical was now located by isotope substitution experiments to the beta position of a tyrosine residue. The EPR spectrum of protein B2 from bacteria grown in a completely deuterated medium was drastically changed. The change was reversed by the addition of other protonated amino acids. The involvement in radical formation of the beta position of tyrosine was demonstrated from EPR spectra of protein B2 from bacteria grown in the presence of specifically deuterated tyrosine.     

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.     

Evidence for variable metal-radical spin coupling in oxoferrylporphyrin cation radical complexes

Oxoferrylporphyrin cation radical complexes were generated by m-chloroperoxybenzoic acid oxidation of the chloro and trifluoromethanesulfonato complexes of tetramesitylporphyrinatoiron(III) [(TMP)Fe] and the trifluoromethanesulfonato complex of tetra(2,6-dichlorophenyl)porphyrinatoiron(III) [TPP(2,6-Cl)Fe]. Coupling between ferryl iron (S = 1) and porphyrin radical (S' = 1/2) spin systems was investigated by M?ssbauer and EPR spectroscopy. The oxoferrylporphyrin cation radical systems generated from the TMP complexes show strong ferromagnetic coupling. Analysis of the magnetic M?ssbauer spectra, using a spin Hamiltonian explicitly including a coupling tensor J, suggests an exchange-coupling constant J greater than 80 cm-1. The EPR spectra show non-zero rhombicity, the origin of which is discussed in terms of contributions from the usual zero-field effects of iron and from iron-radical spin-dipolar interaction. A consistent estimate of zero-field splitting parameter D approximately + 6 cm-1 was obtained by EPR and M?ssbauer measurements. EPR and M?ssbauer parameters are shown to be slightly dependent on solvent, but not on the axial ligand in the starting (TMP)Fe complex. In contrast to the TMP complex, the oxoferrylporphyrin cation radical system generated from [TPP(2,6-Cl)FeOSO2CF3] exhibits M?ssbauer and EPR spectra consistent with weak iron-porphyrin radical coupling of magnitude of J approximately 1 cm-1.     

Measuring distances in proteins by saturation-recovery EPR

We describe a protocol for detecting electron spin-spin interactions between a radical and a metal ion in a protein or protein complex by saturation-recovery electron paramagnetic resonance (EPR). This protocol can be used with a protein containing an endogenous metal center and either an endogenous or synthetic radical species. We suggest a two-step approach whereby dipole-dipole or exchange interactions are first detected by continuous-wave EPR experiments and then quantified by saturation-recovery EPR. The latter measurements make it possible to measure long distances to within a few Angstroms. The protocol for making distance measurements by saturation-recovery EPR will take approximately 6 days to complete.     

Electron paramagnetic resonance characterization of tyrosine radical, M+, in site-directed mutants of photosystem II(t).

Photosystem II contains two well-characterized tyrosine radicals, D(.) and Z(.). Z is an electron carrier between the primary chlorophyll donor and the manganese catalytic site and is essential for enzymatic function. On the other hand, D forms a stable radical with no known role in oxygen evolution. D(.) and Z(.) give rise to similar, but not identical, room temperature electron paramagnetic resonance (EPR) signals, which can be distinguished by their decay kinetics. A third room temperature EPR signal has also been observed in site-directed mutants in which a nonredox active amino acid is substituted at the D or Z site. This four-line EPR signal has been shown to have a tyrosine origin by isotopic labeling (Boerner and Barry, 1994, J. Biol. Chem. 269:134-137), but such an EPR signal has never before been observed from a tyrosyl radical. The radical giving rise to this third unique signal has been named M+. Here we provide kinetic evidence that this signal arises from a third redox active tyrosine, distinct from tyrosine D and Z, in the photosystem II reaction center. Isotopic labeling and EPR spectroscopy provide evidence that M is a covalently modified tyrosine.     

Direct evidence for a tyrosine radical in the reaction of cytochrome c oxidase with hydrogen peroxide.

Cytochrome c oxidase (COX) catalyzes the reduction of oxygen to water, a process which is accompanied by the pumping of four protons across the membrane. Elucidation of the structures of intermediates in these processes is crucial for understanding the mechanism of oxygen reduction. In the work presented here, the reaction of H(2)O(2) with the fully oxidized protein at pH 6.0 has been investigated with electron paramagnetic resonance (EPR) spectroscopy. The results reveal an EPR signal with partially resolved hyperfine structure typical of an organic radical. The yield of this radical based on comparison with other paramagnetic centers in COX was approximately 20%. Recent crystallographic data have shown that one of the Cu(B) ligands, His 276 (in the bacterial case), is cross-linked to Tyr 280 and that this cross-linked tyrosine is ideally positioned to participate in dioxygen activation. Here selectively deuterated tyrosine has been incorporated into the protein, and a drastic change in the line shape of the EPR signal observed above has been detected. This would suggest that the observed EPR signal does indeed arise from a tyrosine radical species. It would seem also quite possible that this radical is an intermediate in the mechanism of oxygen reduction.     

Measurement of oxygen concentrations in the intact beating heart using electron paramagnetic resonance spectroscopy: A technique for measuring oxygen concentrationsin situ

Electron paramagnetic resonance (EPR) spectroscopy can be applied to measure oxygen concentrations in cells and tissues. Oxygen is paramagnetic, and thus it interacts with a free radical label resulting in a broadening of the observed linewidth. Recently we have developed instrumentation in order to enable the performance of EPR spectroscopy and EPR oximetry in the intact beating heart. This spectrometer consists of 1–2-GHz microwave bridge with the source locked to the resonant frequency of a specially designed lumped circuit resonator. This technique is applied to measure the kinetics of the uptake and clearance of different free radical labels. It is demonstrated that this technique can be used to noninvasively measure tissue oxygen concentration. In addition, rapid scan EPR measurements can be performed enabling gated millisecond measurements of oxygen concentrations to be performed over the cardiac cycle. Thus, low-frequency EPR spectroscopy offers great promise in the study of tissue oxygen concentrations and the role of oxygen in metabolic control.