Radiation-induced free radicals in solid 5-halouracil derivatives: single crystals of 5-iododeoxyuridine

X-irradiation of single crystals of 5-iododeoxyuridine (IUdR) in the temperature range 8-300 K produces mainly four different radicals which have been studied by electron spin resonance (e.s.r.) and electron nuclear double resonance (ENDOR)-spectroscopy. At low temperatures, a pi-anion is formed which shows predominantly an interaction of the unpaired electron with a proton at carbon C6 of the base (-11.8 G, -23.9 G, -4.6 G). Above 10-20 K, the anion protonates at C6 to yield a RC-I(CH2)-R' radical comprising alpha-iodo and beta-methylene proton hyperfine interactions. The primary oxidation product is an O5'-situated alkoxy radical RCH2O which shows inequivalent beta-proton couplings of about 100 G and 35 G together with a highly anisotropic g-tensor. Upon warming to 265 K, a C2'-located radical on the deoxyribose is formed which is stable at room temperature. A detailed account of its spectral features as obtained by ENDOR exhibits three different alpha-type couplings, two small beta-protons and a dipolar interaction. Other radicals, not reproducibly observed, involve a C5'-hydroxyalkyl radical and a species related to the base cation at low temperatures.     

A C5'-centred deoxyribose radical in single crystals of 5-chloro-and 5-bromodeoxyuridine X-irradiated at low temperatures.

X-irradiation at 77 K and subsequent warming to 150 K of single crystals of 5-chloro-and 5-bromodeoxyuridine produces a radical located at position C5' of the deoxyribose moiety. The radical exhibits identical spectral properties in both crystal systems. It is characterized by interaction of the unpaired electron with an alpha-proton(-17-0, -8-7, -33-7G), a beta-proton (18-6, 21-3, 17-5 G) as well as an OH-proton (4-8, 7-9, 12-8 G). The principal values of the g-tensor are 2-0034, 2-0049 and 2-0042. The spectral parameters are discussed in relation to those of the same or similar radicals in other nucleosides (-tides).     

E.s.r. studies of sulphur-substituted pyrimidines. 2-thio-5-carboxyuracil at 77 K.

Single crystals of 2-thio-5-carboxyuracil were irradiated and studied at 77 K with e.s.r. spectroscopy. Five resonances were observed and related to the sulphur atom in the 2 position of the pyrimidine ring. Three of the resonances have been assigned to three conformations of a radical formed by hydrogen abstraction from N1. The principal values for the nitrogen coupling are 9-7, 0-0 and 0-0 gauss. The g tensor principal values are 2-173, 1-997 and 1-990 for the dominant conformation of this radical. Two other radicals could not be identified unambiguously.     

Powder and single-crystal electron paramagnetic resonance studies of yeast cytochrome c peroxidase and its peroxide and its peroxide compound, Compound ES

Electron paramagnetic resonance absorption spectrum of ferric cytochrome c peroxidase exhibited a mixture of high- and low-spin compounds. The principal values and the eigenvectors of the g-tensor for the low-spin species were determined by single-crystal EPR spectroscopy at 77 K. The powder EPR spectra of the peroxide compound, Compound ES, were measured at S-, X-, and Q-band microwave frequencies. Careful examination at 77 K showed a narrow free radical-like signal at g = 2.004 with hyperfine structures accompanied by a broad signal spreading on both low- and high-field sides. Single-crystal EPR analyses of Compound ES clearly demonstrated that there exist at least two different radical species: one is isotropic with hyperfine structure at g = 2.004 and the other exhibits an axially symmetric signal at 5 K and broad signal centered at g = 2.004 at 77 K, respectively. The principal values and the eigenvectors of the g-tensor for the axially symmetric signal were determined: g(parallel) = 2.034 and g(perpendicular) = 2.006, 1.999. The orientation of the unique axis (g(parallel)) was found to be identical to that of the heme normal. A new radical signal with complicated hyperfine structures in the g = 2.004 region was observed upon illumination of Compound ES at both 5 and 77 K. The photoinduced species grew effectively by the illumination light around 500 nm. On warming to -80 degrees C, the photoinduced signal was reversibly brought back to the original radical species of Compound ES via an intermediate species. From these results, we have proposed the possible sites for the free radical centers in Compound ES.     

Reductive damage in directly ionized DNA: saturation of the C5=C6 bond of cytosine in d(CGCG)(2) crystals

Electron paramagnetic resonance (EPR) was used to study an oligodeoxynucleotide duplex of d(CGCG)(2) that is known to crystallize in Z-form. After X irradiation at 4 K, EPR data were collected on single crystals and polycrystalline samples as a function of annealing temperature and dose. A radical produced by the net gain of a hydrogen atom at C6 and a proton at N3, Cyt(C6+H, N3+H(+))(+*), is identified. This radical had not been positively identified in polymeric DNA previously. The Cyt(C6+H, N3+H(+))(+*) makes up about 4% of the total radical population at 4 K, increasing to about 10-15% after the DNA is annealed to 240 K. There appears to be neither an increase nor a decrease in the absolute concentration of Cyt(C6+H, N3+H(+))(+*) upon annealing from 4 K to 240 K. Additionally, the presence of another radical, one due to the net gain of hydrogen at C5 of cytosine, the Cyt(C5+H)(*), is implicated. Together, these two radicals appear to account for 60-80% of the reduced species in DNA that has been irradiated at 4 K and annealed to 240 K.     

Characterization of an allylic analogue of the 5'-deoxyadenosyl radical: an intermediate in the reaction of lysine 2,3-aminomutase.

An allylic analogue of the 5'-deoxyadenosyl radical has been characterized at the active site of lysine 2,3-aminomutase (LAM) by electron paramagnetic resonance (EPR) spectroscopy. The anhydroadenosyl radical, 5'-deoxy-3',4'-anhydroadenosine-5'-yl, is a surrogate of the less stable 5'-deoxyadenosyl radical, which has never been observed but has been postulated to be a radical intermediate in the catalytic cycles of a number of enzymes. An earlier communication [Magnusson, O.Th., Reed, G. H., and Frey, P. A. (1999) J. Am. Chem. Soc. 121, 9764-9765] included the initial spectroscopic identification at 77 K of the radical, which is formed upon replacement of S-adenosylmethionine by S-3',4'-anhydroadenosylmethionine as a coenzyme for LAM. The electron paramagnetic resonance spectrum of the radical changes dramatically between 77 and 4.5 K. This unusual temperature dependence is attributed to a spin-spin interaction between the radical and thermally populated, higher spin states of the [4Fe-4S]+2 center, which is diamagnetic at 4.5 K. The EPR spectra of the radical at 4.5 K have been analyzed using isotopic substitutions and simulations. Analysis of the nuclear hyperfine splitting shows that the unpaired spin is distributed equally between C5'- and C3'- as expected for an allylic radical. Hyperfine splitting from the beta-proton at C-2'(H) shows that the dihedral angle to the p(z)-orbital at C-3' is approximately 37 degrees. This conformation is in good agreement with a structural model of the radical. The rate of formation of the allylic radical shows that it is kinetically competent as an intermediate. Measurements of 2H kinetic isotope effects indicate that with lysine as the substrate, the rate-limiting steps follow initial reductive cleavage of the coenzyme analogue.     

E.S.R. of spin-trapped radicals in gamma-irradiated polycrystalline nucleic acid constituents and their halogenated derivatives

Free radicals in gamma-irradiated polycrystalline nucleic acid constituents and their 5-halogenated derivatives have been studied by e.s.r. and spin-trapping. After gamma-irradiation at room temperature, the polycrystalline samples were dissolved in aqueous solutions of t-nitrosobutane (tNB) in the absence or presence of oxygen. For many of the nucleic acid constituents, two types of radicals, -C(5)RH-C(6)H- and -C(5)R-C(6)H2-, formed by H-addition to the double bond [-C(5)R=C(6)H-] of the base, were observed, where R is -CH3 or -H. In addition, radicals formed on the sugar moiety were found for some nucleosides. When oxygen was present in the tNB solution, the relative stability of trapped radicals was changed, and thus the presence of more than one radical species could be established. For halogenated bases, the radical produced by H-abstraction from N(1) was observed, and an additional radical species formed by H-addition to the C(6) position was found for 5-fluorouracil. For halogenated nucleosides, the same spectrum was observed in all compounds except the 5-fluoroderivatives, and was assigned to the radicals produced on the sugar moiety. For 5-fluorodeoxyuridine and 5-fluorouridine, the radical formed by H-addition to the C(6) position of the base was observed. In general, the present results are in good agreement with those of previous single crystal studies, but in the case of halogenated compounds other than the 5-fluoroderivatives, it was not possible to spin-trap the alpha-halo radicals which were the most prominent radicals formed from gamma-irradiation of single crystals at room temperature.     

Free radical formation in X-irradiated anhydrous crystals of inosine studied by EPR and ENDOR spectroscopy.

Single crystals of anhydrous inosine were studied subsequent to exposure to high and low doses of X radiation at 10 K using K-band, EPR, ENDOR, and field-swept-ENDOR (FSE) techniques. Immediately following high radiation doses at 10 K at least eight different radicals, RI-RVIII, were observed. All radicals, except for RVIII, were also observed at low doses, but the relative yields varied with the radiation doses. RI, which decayed with no observable successor at about 65 K, has magnetic characteristics similar to those expected for the hypoxanthine base cation. RII, the dominating radical at low radiation doses, exhibits only one hyperfine coupling amenable for ENDOR analysis. From the nature of this coupling and the EPR and FSE characteristics of the resonance, it is suggested that RII is formed by addition of a neighbor sugar fragment to the C2 position of a hypoxanthine base, forming a C2-O5'-C5' ester bond. RII is unstable and decayed at about 60 K without any detectable successor. RIII and RIV are the C2 and C8 H-addition radicals, respectively. These species are formed in minor amounts after irradiation at low temperatures, and they are the only observable radicals left at room temperature. Two sugar-centered radicals, RV and RVI, are formed by net H-abstraction from the C4' and C5' positions, respectively. These radicals dominate the EPR spectra after high radiation doses at low temperatures. A transformation from RV into RIII, the C2 H-adduct, started at about 80 K. Similarly, a transformation of RVI into RIV started at about 210 K. Several minor species were analyzed. RVII is characterized by an alpha-coupling due to 26% spin density at C8, and RVIII is characterized by 12% pi-spin density at N1. Possible structures for these radicals are discussed.     

Free radicals from X-irradiated single crystals of uridine-5'-phosphate disodium salt

X-irradiation of single crystals of uridine-5'-phosphate (disodium salt) between 10 and 300 K as well as storage of irradiated crystals at 300 K produces at least seven different radical species. Between 10 and 77 K, the uracil base anion and a secondary alkoxy radical at the ribose-O3'-site are formed. The latter transforms into a C5'-centred alkylphosphate species between 110 and 130 K which in turn decays between 180 and 220 K under formation of a base 5-yl hydrogen addition radical. Irradiation at 300 K additionally produces the base-located 6-yl radical together with a radical tentatively assigned to the doubly protonated base anion. Storage of crystals for several months results in decay of most of these species leaving a radical possibly located at c5' of the ribose. The spectral parameters of these radicals are given and discussed.     

Free radical formation in single crystals of 2'-deoxyguanosine 5'-monophosphate tetrahydrate disodium salt: an EPR/ENDOR study.

Single crystals of 2'-deoxyguanosine 5'-monophosphate were X-irradiated at 10 K and at 65 K, receiving doses between 4.5 and 200 kGy, and studied using K-band EPR, ENDOR, and field-swept ENDOR (FSE) spectroscopy. Evidence for five base-centered and more than nine sugar-centered radicals was found at 10 K following high radiation doses. The base-centered radicals were the charged anion, the N10-deprotonated cation, the C8 H-addition radical, a C5 H-addition radical, and finally a stable radical so far unidentified but with parameters similar to those expected for the charged cation. The sugar-centered radicals were the H-abstraction radicals centered at C1', C2', C3', and C5', an alkoxy radical centered at O3', a C5'-centered radical in which the C5'-O5' phosphoester bond appears to be ruptured, a radical tentatively assigned to a C4'-centered radical involving a sugar-ring opening, as well as several additional unidentified sugar radicals. Most radicals were formed regardless of radiation doses. All radicals formed following low doses (4.5-9 kGy) were also observed subsequent to high doses (100-200 kGy). The relative amount of some of the radicals was dose dependent, with base radicals dominating at low doses, and a larger relative yield of sugar radicals at high doses. Above 200 K a transformation from a sugar radical into a base radical occurred. Few other radical transformations were observed. In the discussion of primary radicals fromed in DNA, the presence of sugar-centered radicals has been dismissed since they are not apparent in the EPR spectra. The present data illustrate how radicals barely traceable in the EPR spectra may be identified due to strong ENDOR resonances. Also, the observation of a stable radical with parameters similar to those expected for the charge guanine cation is interesting with regard to the nature of the primary radicals stabilized in X-irradiated DNA.     

An EPR study of the lineshape of copper in cytochrome c oxidase.

The EPR spectrum of copper in cytochrome c oxidase (EC 1.9.3.1) has been studied between 5 and 220 degreesK, and the spectral parameters have been determined for both forms of EPR-detectable copper by computer simulation methods. Numerical methods have been developed to separate the spectra of intrinsic copper and inactive copper. Evidence is presented to show that inactive copper is probably formed by denaturation. The EPR parameters for intrinsic copper were determined as gx = 1.99, gy = 2.03, gz = 2.185, / Ax(Cu) / = 0.0020 cm-1, / Ay(Cu) / = 0.0025 cm-1, / Az(Cu) / = 0.0030 cm-1. The principal values of the g tensor and the small value of /Az(Cu) / are interpreted in terms of mixing of 3d, 4s, and 4p metal orbitals. A flattened-tetrahedral stereochemistry about Cu2+ with an additional rhombic distrotion is in best agreement with all of the data. The peak-to-peak linewidth is found to be orientation dependent, and is described by a tensor with principal values deltaHx = 45G, deltaHy = 65 G, deltaHz = 85 G. A weak dipolar interaction with a low-spin ferric species stereochemistry for the copper ion is consistent with the electron transport function of the enzyme. Broad EPR signals with a very short spin-lattice relaxation time has been observed near g = 14 and g = 3 at 5 degrees K in oxidized cytochrome oxidase but not in the reduced or denatured enzyme. The possibility that these are due to the "EPR-undetectable" iron and copper is raised.     

Radical formation in salts of pyrimidines III. Cytosine . H2O cyrstals.

The radicals produced by X-irradiation at 77 K and at 300 K in cytosine monohydrate crystals have been analysed by electron-spin-resonance (e.s.r.) spectroscopy. Three radicals have been identified at 77 K: the anion radical and the cation radical of the cytosine molecule, together with the radical resutling from H-abstraction from the nitrogen N1. Irradiation at 300 K produces radicals resulting from H-adition at three different positions of the cytosine molecule. These are the C5-addition radical, the C6-addition radical, and the O2-addition radical. The results are compared with those found previously by other authors.     

Electron spin resonance study of DNA irradiated with an argon-ion beam: evidence for formation of sugar phosphate backbone radicals

In this study, the effects of high-LET radiation on DNA were investigated and compared with the effects of gamma radiation. Hydrated DNA samples at 77 K were irradiated with argon-ion beams ((36)Ar or (40)Ar beam at energies between 60 and 100 MeV/nucleon). The individual free radicals formed were identified and their yields were investigated by electron spin resonance spectroscopy. Argon-ion irradiation resulted in lower yields of base ion radicals and higher yields of neutral radicals than gamma irradiation. A hitherto unknown species was assigned to the radical formed by C-O bond rupture at the deoxyribose C3', resulting in a sugar carbon-centered radical. A previously characterized phosphorus-centered radical was also found. The formation of each of these species was accompanied by an immediate strand break. G values, k values, and analyses for the individual yields of neutral radicals and ion radical composition for argon-ion-irradiated hydrated DNA are reported and compared to those found previously for gamma-irradiated DNA. The lower G values and k values for ion radicals and the higher fraction of neutral radicals found for argon-ion-irradiated DNA are attributed to differences in track structure inherent in the two radiations.     

C5'- and C3'-sugar radicals produced via photo-excitation of one-electron oxidized adenine in 2'-deoxyadenosine and its derivatives

We report that photo-excitation of one-electron-oxidized adenine [A(-H)•] in dAdo and its 2′-deoxyribonucleotides leads to formation of deoxyribose sugar radicals in remarkably high yields. Illumination of A(-H)• in dAdo, 3′-dAMP and 5′-dAMP in aqueous glasses at 143 K leads to 80-100% conversion to sugar radicals at C5′ and C3′. The position of the phosphate in 5′- and 3′-dAMP is observed to deactivate radical formation at the site of substitution. In addition, the pH has a crucial influence on the site of sugar radical formation; e.g. at pH ~5, photo-excitation of A(-H)• in dAdo at 143 K produces mainly C5′• whereas only C3′• is observed at high pH ~12. ¹³C substitution at C5′ in dAdo yields ¹³C anisotropic couplings of (28, 28, 84) G whose isotropic component 46.7 G identifies formation of the near planar C5′•. A β-¹³C 16 G isotropic coupling from C3′• is also found. These results are found to be in accord with theoretically calculated ¹³C couplings at C5′ [DFT, B3LYP, 6-31(G) level] for C5′• and C3′•. Calculations using time-dependent density functional theory [TD-DFT B3LYP, 6-31G(d)] confirm that transitions in the near UV and visible induce hole transfer from the base radical to the sugar group leading to sugar radical formation.     

Phosphate ester cleavage in ribose-5-phosphate induced by OH radicals in deoxygenated aqueous solution. The effect of Fe(II) and Fe(III) ions.

The reaction of OH radicals and H atoms with ribose-5-phosphate (10(-2) M) in deoxygenated aqueous solution at room temperature (dose-rate 2-1 X 10(17) eV/ml-min, dose 5 X 10(18)-15 X 10(18) eV/ml) leads to the following dephosphorylation products (G-values): ribo-pentodialdose 1 (0-2), 2-hydroxy-4-oxoglutaraldehyde 2 (0-06), 5-deoxy-erythro-pentos-4-ulose 3 (0-1) and 3-oxoglutaraldehyde 4 (0-06). In addition, some minor phosphate free products (total G=0-09) are formed. G(inorganic phosphate) =1-3 and G(H2O2)=0-3. On the addition of 10(-3) M (Fe(III) ions, G (1) and G (3) increase to 0-6 and 0-4 respectively. In the presence of 10(-3) M Fe(II), G(1) and G(3) change to 0-4 and 0-8, respectively. The other dephosphorylation products are suppressed by the iron ions. G(1) also increases on the addition of increasing amounts of H2O2. Each product can be assigned a precursor radical formed by hydrogen abstraction from C-5, C-4 or C-3 of the ribose-5-phosphate molecule. Products 1 and 2 are formed by oxydative dephosphorylation of an alpha-phospho radical with preceeding H2O elimination for product 2. Elimination of H3PO4 from a beta-phospho radical leads to product 3; product 4 is formed by elimination of two molecules of H2O from its precursor radical and hydrolytic cleavage of an enol phosphate bond. Deuterium-labelling experiments and the effects of the iron ions and of H2O2 support the mechanisms proposed. The importance of the dephosphorylation mechanisms for the formation of strand breaks in DNA is discussed with special reference to the effects of the radiosensitizers.     

Purification, characterization and redox properties of hydrogenase from Methanosarcina barkeri (DSM 800)

A soluble hydrogenase from the methanogenic bacterium, Methanosarcina barkeri (DSM 800) has been purified to apparent electrophoretic homogeneity, with an overall 550-fold purification, a 45% yield and a final specific activity of 270 mumol H2 evolved min-1 (mg protein)-1. The hydrogenase has a high molecular mass of approximately equal to 800 kDa and subunits with molecular masses of approximately equal to 60 kDa. The enzyme is stable to heating at 65 degrees C and to exposure to air at 4 degrees C in the oxidized state for periods up to a week. The overall stability of this enzyme is compared with other hydrogenase isolated from strict anaerobic sulfate-reducing bacteria. Ms. barkeri hydrogenase shows an absorption spectrum typical of a non-heme iron protein with maxima at 275 nm, 380 nm and 405 nm. A flavin component, identified as FMN or riboflavin was extracted under acidic conditions and quantified to approximately one flavin molecule per subunit. In addition to this component, 8-10 iron atoms and 0.6-0.8 nickel atom were also detected per subunit. The electron paramagnetic resonance (EPR) spectrum of the native enzyme shows a rhombic signal with g values at 2.24, 2.20 and approximately equal to 2.0. probably due to nickel which is optimally measured at 40 K but still detectable at 77 K. In the reduced state, using dithionite or molecular hydrogen as reductants, at least two types of g = 1.94 EPR signals, due to iron-sulfur centers, could be detected and differentiated on the basis of power and temperature dependence. Center I has g values at 2.04, 1.90 and 1.86, while center II has g values at 2.08, 1.93 and 1.85. When the hydrogenase is reduced by hydrogen or dithionite the rhombic EPR species disappears and is replaced by other EPR-active species with g values at 2.33, 2.23, 2.12, 2.09, 2.04 and 2.00. These complex signals may represent different nickel species and are only observable at temperatures higher than 20 K. In the native preparation, at high temperatures (T greater than 35 K) or in partially reduced samples, a free radical due to the flavin moiety is observed. The EPR spectrum of reduced hydrogenase in 80% Me2SO presents an axial type of spectrum only detectable below 30 K.     

Formation of split electron paramagnetic resonance signals in photosystem II suggests that tyrosine(Z) can be photooxidized at 5 K in the S0 and S1 states of the oxygen-evolving complex

The effect of illumination at 5 K of photosystem II in different S-states was investigated with EPR spectroscopy. Two split radical EPR signals around g approximately 2.0 were observed from samples given 0 and 3 flashes, respectively. The signal from the 0-flash sample was narrow, with a width of approximately 80 G, in which the low-field peak can be distinguished. This signal oscillated with the S(1) state in the sample. The signal from the 3-flash sample was broad, with a symmetric shape of approximately 160 G width from peak to trough. This signal varied with the concentration of the S(0) state in the sample. Both signals are assigned to arise from the donor side of PSII. Both signals relaxed fast, were formed within 10 ms after a flash, and decayed with half-times at 5 K of 3-4 min. The signal in the S(0) state closely resembles split radical signals, originating from magnetic interaction between Y(Z)(*) and the S(2) state, that were first observed in Ca(2+)-depleted photosystem II samples. Therefore, we assign this signal to Y(Z)(*) in magnetic interaction with the S(0) state, Y(Z)(*)S(0). The other signal is assigned to the magnetic interaction between Y(Z)(*) and the S(1) state, Y(Z)(*)S(1). An important implication is that Y(Z) can be oxidized at 5 K in the S(0) and S(1) states. Oxidation of Y(Z) involves deprotonation of the tyrosine. This is restricted at 5 K, and we therefore suggest that the phenolic proton of Y(Z) is involved in a low-barrier hydrogen bond. This is an unusually short hydrogen bond in which proton movement at very low temperatures can occur.     

Neutron-induced free radicals in oriented DNA

Samples of oriented DNA containing 30 per cent water were irradiated with neutrons at 77 K. The electron spin resonance (e.s.r.) spectra obtained from these irradiated DNA samples show that the formation of radicals is different when the incident neutrons are parallel or perpendicular to the DNA helix. When the incident neutrons are perpendicular to the DNA helix the e.s.r. spectra of thymine and guanine ionic radicals (T-., G+.) are observed. An additional e.s.r. spectrum corresponding to the hydrogen addition radical on thymine (TH.) is observed when the incident neutrons are parallel to DNA helix. The TH. radical appears to be formed by protonation of T-. .     

Electron trapping and reactions in rhamnose by ESR and ENDOR.

The main objective for a reinvestigation of rhamnose was to devise a mechanistic link between the trapped electron detected previously and the secondary radicals observed at 77 K and at room temperature. Single crystals of rhamnose were X-irradiated at temperatures between 15 and 300 K and examined using ESR, ENDOR, and field-swept ENDOR techniques. After low-temperature irradiation a C3 H-abstraction radical is formed following the visible light-induced decay of the trapped electron. This species was previously assigned erroneously to a C2 H-abstraction species. At temperatures above 120 K, this radical deprotonates at the C3 hydroxy group. Furthermore, a C2 H-abstraction radical is formed following the thermally induced decay of the trapped electron. The C2 and C3 H-abstraction radicals did not convert into each other. A third radical species formed at low temperatures is a C5 H-abstraction radical. It is unstable above 250 K and decays without any apparent successor. The C2 and C3 H-abstraction radicals are formed thermally and photochemically from the parent trapped electron. The conversions are mediated by hydrogen atoms formed intermediately or by elimination of hydride ions. The thermal decomposition pathway requires further studies, in particular with respect to the possible role of water. Recently, Box et al. analyzed the site of the trapped electron in rhamnose crystals. The present results support the results obtained by these authors (Radiat. Res. 121, 262 (1990)). In particular, trapped electron vs proton distances closely match the conversion mechanisms suggested.     

The Horseradish Peroxidase Catalysed Oxidation of Deoxyribose Sugars

The ability of horseradish peroxidase (E.C. 1.11.1.7. Donor: H₂O₂ oxidoreductase) to catalytically oxidize 2-deoxyribose sugars to a free radical species was investigated. The ESR spin-trapping technique was used to denionstrate that free radical species were formed. Results with the spin trap 3.5-dibronio-4-nitrosoben-zene sulphonic acid showed that horseradish peroxidase can catalyse the oxidation of 2-deoxyribose to produce an ESR spectrum characteristic of a nitroxide radical spectrum. This spectrum was shown to be a composite of spin adducts resulting from two carbon-centered species, one spin adduct being characterized by the hyperfine coupling constants a^N = 13.6Ganda^H_β = 11.0G, and the other by a^N = 13.4G and a^H = 5.8 G. When 2-deoxyribose-5-phosphate was used as the substrate, the spectrum produced was found to be primarily one species characterized by the hyperfine coupling constants a^N = 13.4G and a^H= 5.2. All the radical species produced were carbon-centered spin adducts with a β hydrogen, suggesting that oxidation occurred at the C(2) or C(5) moiety of the sugar. Interestingly, it was found that under the same experimental conditions, horseradish peroxidase apparently did not catalyze the oxidation of either 3-deoxyribose or D-ribose to a free radical since no spin adducts were found in these cases.

It can be readily seen that 2-deoxyribose and 2-deoxyribose-5-phosphate can be oxidized by HRP/H₂O₂ to form a free radical species that can be detected with the ESR spin-trapping technique. There are two probable sites for the formation of a CH type radical on the 2-deoxyribose sugar, these being the C(2) and the C(5) carbons. The fact that there is a species produced from 2-deoxy-ribose, but not 2-deoxy-ribose-5-phosphate, suggests that there is an involvement of the C(5) carbon in the species with the 1 1.0G β hydrogen. In the spectra formed from 2-deoxy-ribose, there is a big difference in the hyperfine splitting of the β hydrogens, suggesting that the radicals are formed at different carbon centers, while the addition of a phosphate group to the C(5) carbon seems to inhibit radical formation at one site. In related work, the chemiluminescence of monosaccharides in the presence of horseradish peroxidase was proposed to be the consequence of carbon-centered free radical formation (10).