GAMMA AND PULSE RADIOLYSIS STUDIES OF THE REACTION BETWEEN SUPEROXIDE IONS AND OXYHEMOGLOBIN-METHEMOGLOBIN SYSTEM

Abstract— The radiolytic studies of oxyhemoglobin or methemoglobin in neutral aerated aqueous solutions with formate ions, lead to three conclusions:
The oxidation of oxyhemoglobin by O^-₂ is not important. The observed low oxidation yield is probably due to the slow reaction with hydrogen peroxide produced by O^-₂ disproportionation.
The reduction of methemoglobin in γ radiolysis reaches a plateau which could be explained by structural considerations.
The reduction of methemoglobin by O^-₂ ions, if it occurs, is relatively slow: k = 1.4 × 10³ M ^-1 s^-1. But a problem remains concerning the spectral characteristics of the product.     

MECHANISM OF PHOTOSENSITIZATION BY PHEOPHORBIDE a STUDIED BY PHOTOHEMOLYSIS OF ERYTHROCYTES AND ELECTRON spIN RESONANCE SPECTROSCOPY

Abstract Phcophorbide a (PPa), a causal substance of food intoxication, when excited by exposure to light wavelengths of over 600 nm, caused the photohemolysis of goat erythrocytes in proportion to the incubation time of the cells. The addition of N-₃, an effective scavenger of ¹O₂, to the medium markedly inhibited the hemolysis of erythrocytes in a concentration-dependent manner, whereas the addition of superoxide dismutase (SOD) and catalase, inhibitors of O^-₂ and H₂O₂ generation, respectively, to the medium had little effect on it.
Methods for converting ¹O₂ to a nitroxide radical by 2,2,6,6-tetramethyl-4-piperidone (TMPD) and for trapping O^-₂ and OH by 5,5-dimethyl-l-pyrroline-A'-oxide (DMPO) were employed to observe directly these activated oxygens by electron spin resonance (ESR). The methods provided evidence that only ¹O₂, was produced by PPa, which was excited by light wavelengths of over 600 nm. Both the addition of N₃ to the solution and the removal of oxygen from the solution inhibited the generation of ¹O₂.
These results led us to conclude that ¹O₂ was mainly responsible for the hemolysis of erythrocytes by photoexcited PPa.     

PHOTOINACTIVATION OF A Chlamydomonas MUTANT(NL–11) IN THE PRESENCE OF METHIONINE: ROLES OF H2O2 and O-2

Abstract— A mutant of Chlamydomonas reinhardtii (NL–11) isolated from a wild type (137c+) was inactivated in the light in the presence of methionine at concentrations where the wild type was not inactivated. The inactivation was suppressed by either catalase or superoxide dismutase (SOD). Light-induced H₂O₂ formation and nitroblue tetrazolium (NBT) reduction inNL–11 were greater than those in the wild type. Methionine stimulated both the H₂O₂ formation and the NBT reduction inNL–11 as well as the wild type. The light-induced NBT reduction inNL–11 in the presence of methionine was partially suppressed by externally added SOD suggesting the participation of O^-₂. These results suggest that the hypersensitivity ofNL–11 to methionine in the light is due to stimulated formation of H₂O₂ and O^-₂.     

CHEMICAL REACTIONS OF SUPEROXIDE ANION RADICAL IN APROTIC SOLVENTS

Abstract— While superoxide anion radical does not normally react with olefins, it does react with activated double bonds. Thus O^-₂ oxidatively cleaves certain α,β-unsaturated ketones such as chalcones and tetracyclone and electron poor olefins such as 1,1-dicyano and 1,1-dinitro olefins. Similarly O^-₂ can react with substituted nitrobenzenes to yield the corresponding nitrophenols. EPR and oxygen labeling (KO³⁶₂) experiments confirm an electron transfer mechanism.     

PHOTOSYNTHETIC NITRITE REDUCTION BY DITHIOERYTHRITOL AND THE EFFECT OF NITRITE ON ELECTRON TRANSPORT IN ISOLATED CHLOROPLASTS

Abstract. Photosynthetic reduction of nitrite to ammonia with type C chloroplasts from the heterocont alga Bumilleriopsis filiformis was investigated using 3,6-diaminodurene/ascorbate and 3,6-diaminodurene/dithioerythritol (DAD/DTE) as electron donor couple. Rates approach 6–10 μmol NO^-₂ reduced/mg chlorophyll/h and are steady for up to 30 min. The presence of oxygen or NADP⁺ only slightly diminished the rates of nitrite reduction obtained with DAD/DTE. Illuminated chloroplasts reduce oxygen in the presence of DAD/DTE at 135 μmol/mg chlorophyll/h without acceptor supplied. Photosynthetic oxygen uptake by this system in the presence of ferredoxin and NO^-₂, however, is inhibited to 42% by nitrite reductase with concurrent nitrite reduction. NO^-₃ and NO^-₂ have no effect on photosystem I-mediated NADP⁺ reduction, NO^-₂ (10 m M ) inhibits ferricyanide-mediated oxygen evolution to 72%. Also photosystem II reactions assayed e.g. with silicomolybdate are inhibited significantly by NO^-₂ (1 m M ), but only slightly by NO^-₃. Nitrite reductase is inhibited by p -chloromercuribenzoate ( p CMB), and this inhibition is prevented by DTE. Results suggest that photosynthetic nitrite reduction can cope with low concentrations of either compound, provided relevant thiol groups are protected.     

SUPEROXIDE RADICALS, SUPEROXIDE DISMUTASES AND THE AEROBIC LIFESTYLE

Abstract— The superoxide radical (O^-₂) is a commonplace product of the biological reduction of molecular oxygen and plays an important role in oxygen toxicity. Superoxide dismutases (SOD) catalytically scavenge this radical and are the primary defense against its cytotoxicity. The data which support these statements have been briefly reviewed. Oxygen enhances the lethality of certain antibiotics, such as streptonigrin, and of ionizing radiation as well. The role of O^-₂ in the enhancements is presented and the basis of the radioprotective effects of SOD discussed. Several more recent developments are presented in detail including: (a) The induction of the MnSOD of E. coli upon exposure to very low levels of oxygen, (b) The changes in SOD in E. coli as a function of nutritional state, during culture in a chemostat. (c) A convenient new assay and activity stain for SOD.     

A PULSE RADIOLYSIS STUDY OF THE ONE-ELECTRON OXIDATION AND REDUCTION OF 5, 10-METHENYLTETRAHYDROFOLATE

Abstract— The one-electron reduction and oxidation of 5,10-methenyltetrahydrofolate has been studied in aqueous solution in the acidity range H₀= -1 to pH = 7 using the reducing species CO^-₂ and (CH₃)₂-COH and oxidising species Br^-₂, and H₂SeO+₃. The spectral and other properties of the radicals so formed were found to be indcpendent of the reductant/oxidant used. Two protolytic forms of both the oxidised and reduced radicals were observed with approximate p K , values of 0.5 ± 0.3 being determined. Both the bridged form (5.10-methenyltetrahydrofolate) and the unbridged form (5- formyltetrahydrofolate) were found to be easily oxidised, whereas only the former could be reduced.     

THE CHROMOPHORES AS ENDOGENOUS SENSITIZERS INVOLVED IN THE PHOTOGENERATION OF SINGLET OXYGEN IN SPINACH THYLAKOIDS

Abstract— The photogeneration of singlet oxygen (¹O₂) from thylakoids and the chromophores involved as endogenous sensitizers were investigated using chloroplasts and thylakoids isolated from spinach. The blue light-induced inhibition kinetics of photosynthetic electron transport and that of CTvCF, ATPase were also studied. The spectral dependence of the generation of ¹O₂ from thylakoid membranes, measured by the imidazole plus RNO method, clearly demonstrated that the Fe-S centers play an important role in ¹O₂ generation, acting as sensitizers in thylakoids. The photoinhibition of the electron transport in isolated chloroplasts was strikingly depressed by a lipid-soluble '0₂ quencher and enhanced by deuterium oxide substitution, indicating that the inhibition processes are mainly mediated by ¹O₂ which is produced via photodynamic activation. The involvement of chloroplast cytochromes in the production of ¹O₂ was deduced from the action spectrum for the photodynamic inhibition of the electron carrier chain. The results obtained from the kinetic studies appear consistent with the involvement of some components such as the Fe-S centers and cytochrome chromophores of the carrier chain in the generation of ¹O₂.     

CONCENTRATION-DEPENDENT LIFETIMES OF Cu(NN)+2 SYSTEMS: EXCIPLEX QUENCHING FROM THE ION PAIR STATE

Abstract— The concentration dependence of the lifetimes of the charge transfer excited states of Cu(dmp)⁺₂ and Cu(dpp) ⁺₂ has been investigated in CH₂C1₂ solution at 20^°C. (dmp denotes 2,9-dimethyf-1,10-phenanthroline, and dpp denotes 2,9-diphenyl-l,10-phenanthroline.) In dilute solution (< 30 μM) the lifetime of Cu(dmp)⁺₂, is 95 ± 5 ns, independent of the anion. At higher concentrations the lifetime decreases, in most cases, to a limiting value that depends upon the counterion. The measured limiting lifetimes range from 38 ± 3 ns for CIO^-₄ to 78 ± 5 ns for PF^-₆. The anion-induced quenching is attributed to exciplex quenching which is mediated by an ion pair which exists in the ground state. The results imply that the quenching ability of the anions follows the order BPh-₄ < PF -₆, < BF-₄ < CIO -₄ < NO-₃ which is consistent with previous estimates of donor strength. The lifetime of Cu(dpp)⁺₂ is also concentration dependent, but the effect is much smaller because the phenyl substituents impede attack by the anion.     

SPECTRAL CHARACTERIZATION OF LIGHT-REDUCIBLE CYTOCHROME IN A PLASMA MEMBRANE-ENRICHED FRACTION AND IN OTHER MEMBRANES FROM CAULIFLOWER INFLORESCENCES

Abstract— Low temperature spectroscopy has been used to characterize microsomal fractions obtained from cauliflower inflorescences ( Brasska oleracea L.) by differential centrifugation and partition in an aqueous polymer two-phase system. The plasma membrane-enriched fraction (U₃) was found to contain one dominant b -cytochrome, which could be reduced both by blue light and by dithionite. An action spectrum of the blue light-induced absorbance change [LIAC, Δ(A₄₃₀—A₄₁₀)] associated with the reversible reduction of this b -type cytochrome indicated that the primary light-receptor was a flavin-like compound. Another microsomal fraction (L₃) containing membranes from mitochondria, endoplasmic reticulum and other organelles also contained light-reducible cytochrome. One of these could be identified as cytochrome c oxidase, and another may be identical to cytochrome b ₅ of the endoplasmic reticulum.     

SINGLET OXYGEN: A MAJOR REACTIVE SPECIES IN THE FUROCOUMARIN PHOTOSENSITIZED INACTIVATION OF E. COLI RIBOSOMES

Abstract— The skin photosensitizing furocoumarins, 8-methoxypsoralen (MOP) and 4,5',8-trimethylpsoralen (TMP), inactivate E. coli ribosomes in vitro , on UV irradiation at 313 nm. Purging the solutions with N₂ protects the ribosomes considerably against photoinactivation (75% with MOP and 80% with TMP). In air, the ribosome photoinactivation is mainly due to singlet oxygen (¹O₂), since the presence of NaN₃ and other ¹O₂ quenchers protects the system and the inactivation is enhanced in D₂O. Although ¹O₂ dominates as the inactivating species, the possibility of additional (∼15%) minor mechanisms involving free radicals exists. However, O^-₂ does not appear to be the damaging species, since superoxide dismutase does not provide any protection.
Photosensitization of the partially purified enzyme, phe-tRNA-synthetase with MOP or TMP shows inactivation and protection curves similar to those seen with the ribosomes. On the other hand, unfrac-tionated tRNA^phc is not photosensitized under similar conditions, although it shows self-photosensitization. It is likely that in the furocoumarin-sensitized ribosomes, the primary events of photoinactivation are associated with the proteins.     

PULSE RADIOLYSIS STUDIES IN MODEL LIPID SYSTEMS: FORMATION AND BEHAVIOR OF PEROXY RADICALS IN FATTY ACIDS

Abstract— Radiolytic formation and peroxidation of fatty acid radicals have been investigated by pulse radiolysis techniques in oleate, linoleate, linolenate and arachidonate systems. A strong absorption band at 280 nm associated with conjugated radicals, R_conj, formed in polyunsaturated fatty acid moieties has been used as a probe for kinetic processes occurring at doubly allylic sites in the hydrocarbon chain. Formation of R_conj by O^- has been found to be more efficient than the less selective OH radical. Peroxidation of R_conj is shown to be somewhat slower, ( k _R+ O₂˜ 3 × 10⁸ M ^-1 s^-1), than O₂ reactions with radicals in oleate ( k _R+ O₂= 1 × 10⁹ M ^-1 s^-1). Peroxy radicals generated in these reactions disappear slowly by essentially second order processes (2 k RO₁˜ 10⁷ M ^-1 s^-1). The superoxide radical, O^-₂, shows little if any reactivity towards 0.01 M linolenate or arachidonate over periods of 20 s.     

LASER PHOTOLYSIS OF 3-METHYLLUMIFLAVIN

Abstract— Using high-intensity actinic light, the chlorophyll a fluorescence transient from HCO^-₃-depleted chloroplasts shows a rapid initial rise (O → I) followed by a slow phase (I → P). In the presence of HCO^-₃, the O → I rise is delayed but the I → P phase is much more rapid. Using low-intensity actinic light, the chlorophyll a fluorescence transient from 3-(3,4-dichlorophenyl)-1,1 dimethylurea (DCMU)-treated chloroplasts is delayed in the presence of HCO^-₃. Bicarbonate increases the amount of delayed light emission from chloroplasts given 10 s illumination with weak blue light (0·4 W/m²). DCMU greatly increases the amount of delayed light seen in the presence of HCO^-₃ under these conditions but decreases the amount seen in the absence of HCO^-₃. It is suggested that HCO^-₃ may somehow form or stabilize, in the dark, a number of reaction centers corresponding to the S₁ state in the model of B. Forbush, B. Kok and M. McGloin ( Photochem. Photobiol. 14, 307–321, 1971).     

INTERACTIONS AMONG PHOTOSYNTHETIC ANTENNA EXCITED STATES

Abstract. The data of Kung and DeVault (1978) showing high-order fluorescence from chromatophores of photosynthetic bacteria are analyzed in relation to other data on first-order fluorescence of photosynthetic systems, particularly that of Monger and Parson (1977). The wavelengths of emission observed (down to 445 nm) require energy equivalent to two lowest singlet-excited states. The dependence on excitation intensity is best explained by any of the following third-order processes: (a) 3 S ₁→3 S ₀; (b) 2 S ₁+ T , → 2 S ₀+ T ₁; (c) S ₁+ 2 T ₁→ 3 S ₀. However, (c) is ruled out because it predicts heavy T ₁-destruction which is not observed. Contribution from the second order process: 2 S ₁→ S ₀ is probable, but even the data of Monger and Parson show that it is insufficient by itself. Two-photon absorption: S ₀+ hv ₁→ S ₁; S ₁+ hv ₁→ S _n; S _n S ₀+ hv ₂ could also account for the high-order fluorescence and its dependence on excitation intensity. [ S ₀, S ₁ S _n are ground, first excited and a higher excited singlet states, respectively, of antenna bacteriochlorophyll, T _t is the lowest triplet state, c/v , is the exciting wavelength (694 or 868 nm) and c/v ₂ the wavelength of the high-order fluorescence (445, 535. or 600 nm), where c = velocity of light.] Maximum values are estimated for some of the rate constants.     

PHOTOREDUCTION OF CYTOCHROME b551 OF PARTIALLY PURIFIED NEUROSPORA NITRATE REDUCTASE VIA ITS INTERNAL FLAVIN

Abstract— Nitrate reductases (NR) from NR-normal Neurospora crassa mutant albino band and from NR-defective mutantsnit–1 andnit–3 were isolated and partially purified in order to test the photo-reducibility of their cytochrome b ₅₅₇ via the NR-internal FAD. Photoreducibility with blue light of the isolated enzyme was observed as absorbance increase at 423, 524 and553–557 nm. It was independent of NADPH-nitrate reductase activity and could be induced if the dissociable FAD was not lost in the isolation procedure. The photoreduction of cytochrome b ₅₅₇ was readily reversible due the high autoxi-dation rate of this cytochrome. Therefore, anaerobic conditions are required for photoreduction with low light intensities. If aerobic conditions are applied, high intensities become necessary to overcome the simultaneous cytochrome h₅₅₇ oxidation.     

PHOTOFRAGMENTATION OF α-OXOCARBOXYLIC ACIDS IN AQUEOUS SOLUTION. AN EPR STUDY. FORMATION OF SEMIDIONE RADICALS BY DECARBOXYLATIVE SUBSTITUTION OF α-OXOCARBOXYLIC ACIDS BY ACYL RADICALS-I: GLYOXYLIC, PYRUVIC, α-OXOBUTYRIC, α-OXOGLUTARIC AND α-OXOISOCAPROlC ACIDS

Abstract— By means of in situ photolysis EPR of aqueous solutions of α-oxocarboxylic acids (RCO-CO₂H) at pH values above 5, semidione radical anions [RC(O^-)=C(O')R] and α-hydroxy-α-carboxy alkyl radicals [RC(OH)CO₂-] were detected. C0₂ was identified as a reaction product. On photolysis of mixtures of α-oxocarboxylic acids (RCOCO₂H and R'COCC₂H), "mixed" semidione radical anions [RC(O^->=C(O)R'] were observed in addition to RC(O^-)=C(O')R, R'C(O^-)=C(O')R', RC(OH)CO₂^- and R'C(OH)CO₂^-. The experimental results are explained in terms of photodecarboxylation (α-clea-vage) of electronically excited RCOCOJ to yield RCO and CO₂. The radicals RC(OH)CO₂^- are formed by reduction of RCOCO₂^- by CO₂^-. The semidione radicals are produced by addition of RCO to RCOCO₂^- followed by decarboxylation of the intermediate adduct. This mechanism was confirmed by generating acyl radicals independently and reacting them with α-oxocarboxylic acids. Selected product studies support the mechanism suggested.     

ELECTRON PARAMAGNETIC RESONANCE OF SOME TRIPHENYLMETHANE DYES IN THE TRIPLET STATE

Abstract— Electron paramagnetic resonance spectra of the triplet states of several triphenylmethane dyes in glassy solutions at 90 K have been measured and their zero-field splitting parameters estimated. Crystal violet and para rosaniline do not possess trigonal symmetry in their triplet states, and the unusually broad absorptions in the Δ M ₈= 1 region of the spectra have been attributed to the presence of different rotational isomers of the dye cations. A number of malachite green derivatives were investigated, but absorption of the triplet states of these dyes was only observed in the low field Δ M ₈= 2 region of the spectrum.     

PHOTOACTIVATION OF NITRATE REDUCTASE FROM NEUROSPORA CRASSA

Abstract— The photoactivation of nitrate reductase from Neurospora crassa was studied in partially purified extracts. The inactive enzyme [inactivated by reduction in the presence of potassium cyanide] could be reactivated by chemical oxidation with ferricyanide or by irradiation with blue light. The enzyme contains a short electron transfer chain consisting of flavin adenine dinucleotide, cytochrome b ₅₅₇ and molybdenum which normally transfers electrons from reduced pyridine nucleotide to nitrate. This overall activity, which was negligible in the inactive enzyme, was restored to approximately 70% of the ferricyanide control by irradiation. However, nitrate reduction using reduced methylviologen as reducing power, which was also negligible in the inactive enzyme, was photoactivated to 100%. The diaphorase activity of the enzyme mediated by the flavin adenine dinucleotide, which was fully active in the inactivated enzyme, was inhibited approximately 30% by the irradiation treatment. The action spectrum for photoactivation showed that a flavin was the photoreceptor chromophore. Photoactivation occurs only in the presence of oxygen.     

ELECTRON TRANSFER FROM THE EXCITED STATE OF TYROSINE TO COMPOUNDS CONTAINING DISULFIDE LINKAGES

Abstract— The flash photolysis of aqueous solutions of tyrosine has been studied in the presence of various concentrations of the cyclic disulfide sodium lipoate (thioctic acid, Na⁺ salt). In addition to the formation of phenoxyl radicals and hydrated electrons (and possibly H atoms) from the photoionization of tyrosine, the characteristic spectrum of the radical anion RSSR^- of lipoate was also observed in neutral as well as in alkaline solutions. From the dependence of these yields upon the concentration of lipoate, it was found that a long–lived triplet excited state of tyrosine, rather than the singlet excited state, is involved in these reactions. The negative radical ions RSSR^- are formed by two distinct pathways: (a) Na⁺–lipoate reacts with the solvated electrons which are ejected from the tyrosine triplets ³Tyr → RO.+ e ^-_aq+ H⁺ followed by e ^-_aq+ RSSR → RSSR^-, and (b) by direct interaction of lipoate with triplet excited tyrosine, resulting in the transfer of a negative charge from tyrosine to the disulfide linkage. At high lipoate concentrations, the singlet excited state of lipoate is quenched, k ₄= 1.6 × 10¹⁰ M ^-1 sec^-1, but this reaction does not lead to the formation of RSSR^- radical ions.     

124-kDa PHYTOCHROME IN MODEL MEMBRANE SYSTEMS: STUDIES OF THE Ii700 INTERMEDIATES WITH THE PROTEIN COVALENTLY BOUND TO PREFORMED LIPOSOMES

Abstract— We have described the covalent binding of 124-kDa oat phytochrome to large unilamellar liposomes composed of either dioleoyl phosphatidylcholine or dipalmkoyl phosphatidylcholine or soybean lecithin, without affecting the photochromic properties of the protein. These phytochrome-liposome systems have now been studied by laser flash photolysis. The liposomes, independent of their membrane rigidity (liquid-crystal vs gel-like phase), do not influence the ratio and reactivity of the two primary photoproducts, Iⁱ₇₀₀- of the red absorbing form of phytochrome, P_l Thus, the lifetimes of the Iⁱ₇₀₀ intermediates and the activation parameters associated with Iⁱ₇₀₀Iⁱ_bl are the same as those measured for nonbound phytochrome in buffer solution. The temperature increase from about 273 K. to 297 K lowers the population of the shorter-lived Iⁱ₇₀₀ intermediate to the same extent both in the liposome-P_l and in nonbound P_l, whereas it does not affect the relative population of the Iⁱ₇₀₀ intermediates from non-bound P_l in the presence of 25% ethylene glycol added to the buffer solution (ionic strength 0.17).