The accumulation of superoxide radical during the aerobic action of xanthine oxidase A requiem for H2O4−

The action of xanthine oxidase upon acetaldehyde or xanthine at pH 10.2 has been shown to be accompanied by substantial accumulation of O₂^? during the first few minutes of the reaction. H₂O₂ decreases this accumulation of O₂^? presumably because of the Haber-Weiss reaction ($\text{H}{}_2\text{O}{}_2\text{+}\text{O}{}_2{}^{\mathrm{?}}\text{→}\text{OH}{}^{\mathrm{?}}\text{+}\text{OH}\text{+}\text{O}{}_2$) and very small amounts of superoxide dismutase eliminate it. This accumulation of O₂^? was demonstrated in terms of a burst of reduction of cytochrome $\text{c}$, seen when the latter compound was added after aerobic preincubation of xanthine oxidase with its substrate. The kinetic peculiarities of the luminescence seen in the presence of luminol, which previously led to the proposal of H₂O₄^?, can now be satisfactorily explained entirely on the basis of known radical intermediates.     

DNA strand scission by enzymically generated oxygen radicals

Col E1 DNA suffers strand scission when exposed to xanthine oxidase acting aerobically on xanthine. Strand scission was prevented by low levels of superoxide dismutase or of catalase. Mannitol, benzoate, or histidine, which scavenge OH · but which react with neither O₂^? nor H₂O₂, also prevented strand scission. Replacement of 0.1 mm ethylenediaminetetraacetate by 0.1 mm diethylenetriaminepentaacetate prevented strand scission. Three mechanisms for the production of OH ·, or of a comparably powerful oxidant, by metal-catalyzed interaction of O₂^? with H₂O₂, are proposed.     

Hyaluronan-mediated protective effect against cell damage caused by enzymatically produced hydroxyl (OH·) radicals is dependent on hyaluronan molecular mass

Hyaluronan (HA) protected tendon fibroblasts against cell damage mediated by hydroxyl radicals (OH·) as demonstrated by release of ⁵¹Cr from labelled cells. Protection afforded by high molecular mass (M_r) HA (1218 kDa) was much more effective than that provided by lower (176 kDa and 668 kDa) M_r HA. OH· was generated by coupling H₂O₂ produced by glucose oxidase: glucose to [Fe²⁺-EDTA] chelate in a Fenton-type system. The flux of OH· was measured by a spectrofluorimetric assay of salicylate produced by the reaction of benzoate with OH·. Cell damage caused by the OH· generating system was prevented in the presence of catalase, which destroyed H₂O₂. Damage caused in a standard incubation time increased with increased amounts of glucose oxidase. Protection against OH·-mediated cell damage increased with increasing concentration of HA. The presence of HA did not interfere with the enzyme-Fenton system, as monitored by production of gluconate. On the other hand, HA scavenged OH· produced by the enzyme-Fenton system, as shown by competition with benzoate, which produced less salicylate in the spectrofluorimetric assay in the presence of HA. The reaction of OH· with HA was measured directly by a pulse radiolysis technique in which a hydrated electron (e) produced OH· by the reaction with nitrous oxide. Second order rate constants obtained in distilled H₂O or in phosphate buffer showed no dependence on HA M_r. Similarly, fluorimetric assay of the flux of in the enzyme-Fenton system confirmed that HA competed with benzoate, thus lowering salicylate production, and the flux was also independent of the molecular mass of HA. These results demonstrate that part of the HA-mediated protection against enzyme-Fenton produced OH· and other reactive oxygen-derived toxic species was not a consequence of either the primary or secondary structure of HA, but rather depends on higher order HA organization. Some aspects of the formation of the HA meshwork (tertiary structure) are M_r dependent. We therefore propose that cell-anchored HA meshworks excluded relatively large enzyme molecules from the immediate environment of the cell, thus reducing the flux of OH· etc. at the cell surface and diminishing cell damage.     

Decreased superoxide anion radical production by rat alveolar macrophages following inhalation of ozone or nitrogen dioxide

$\text{In vivo}$ exposure of rats to ozone or nitrogen dioxide results in a dose-dependent decrease in superoxide anion radical production (O₂^?·) by alveolar macrophages isolated from the exposed animals. When alveolar macrophages from ozone-exposed animals were stimulated with phorbol myristate acetate (PMA, a non-phagocytic stimulus of O₂^?· production) the decrease in O₂^?· production ranged from 85.9% of control at 3.2 ppm-hrs ozone to 7% of control at 10.5 ppm-hrs. In a similar fashion, O₂^?· production by PMA-stimulated macrophages from NO₂-exposed rates ranged from 78% of control at 18.3 ppm-hrs NO₂ down to 14.5% of control at 51 ppm-hrs. Since the viability of the alveolar macrophages obtained from ozone or nitrogen dioxide-exposed animals was 88% or better in all cases as judged by both Trypan blue exclusion and lactate dehydrogenase release, the decreased ability of these cells to produce superoxide anion radical cannot be attributed to a pollutant effect on cell viability. This diminution in superoxide anion radical production by alveolar macrophages from the pollutant-exposed animals might account, in part, for the ability of these 2 air pollutants to potentiate bacterial infections in laboratory animals.     

Photosystem II energy coupling in chloroplasts with H2O2 as electron donor

NH₂OH-treated, non-water-splitting chloroplasts can oxidize H₂O₂ to O₂ through Photosystem II at substantial rates (100–250 μequiv · h^?1 · mg^?1 chlorophyll with 5 mM H₂O₂) using 2,5-dimethyl-p-benzoquinone as an electron acceptor in the presence of the plastoquinone antagonist dibromothymoquinone. This H₂O₂ → Photosystem II → dimethylquinone reaction supports phosphorylation with a $\text{P}\text{e}{}_2$ ratio of 0.25–0.35 and proton uptake with $\text{H}{}^{\mathrm{+}}\text{e}$ values of 0.67 (pH 8)–0.85 (pH 6). These are close to the $\text{P}\text{e}{}_2$ value of 0.3–0.38 and the $\text{H}{}^{\mathrm{+}}\text{e}$ values of 0.7–0.93 found in parallel experiments for the H₂O → Photosystem II → dimethylquinone reaction in untreated chloroplasts. Semi-quantitative data are also presented which show that the donor → Photosystem II → dibromothymoquinone (→O₂) reaction can support phosphorylation when the donor used is a proton-releasing reductant (benzidine, catechol) but not when it is a non-proton carrier (I^?, ferrocyanide).     

Iron(II)-bleomycin. Biochemical and spectral properties in the presence of radical scavengers

Consistent with a recent literature report (Repine, J. E. $\text{et}$$\text{al.}$ (1981) $\text{Proc.}$$\text{Nat.}$$\text{Acad.}$$\text{Sci.}$$\text{USA}$$\text{7}\text{?}$$\text{8}\text{?}$, 1001–1003), the release of [³H]-thymine from PM-2 DNA by Fe(II)-H₂O₂-generated ·OH was suppressed by dimethyl sulfoxide. In contrast, DMSO did not affect [³H]-thymine release mediated by Fe(II)-bleomycin. Under aerobic conditions in the presence of $\text{t}$-butyl phenylnitrone, Fe(II)-BLM produces an epr signal that has been presumed to arise by transfer of ·OH or $\text{O}{}_2{}^{\mathrm{<mtext>?</mtext>}}$ from the “active complex” of bleomycin to the spin trap. Remarkably, high concentrations (80 mM) of PBN had no effect on the ability of Fe(II)-BLM to solubilize [³H]-thymine, although the ability of authentic ·OH to degrade DNA was completely suppressed under these condition. The suproxide dismutase catalyst tetrakis(4-N-methylpyridyl)porphineiron(III) also failed to suppress BLM-mediated DNA degradation. Moreover, the epr signal observed with 1.6 mM Fe(II)-BLM in the presence of 80 mM PBN was found to be much less intense than that produced by 1.6 mM Fe(II) and 290 mM H₂O₂, but equivalent in intensity to that obtained with 45 mM Fe(II) and exoess H₂O₂. We conclude that the fragmentation of DNA produced by Fe(II)-BLM can be due neither to free ·OH nor to $\text{O}{}_2{}^{\mathrm{<mtext>?</mtext>}}$. We suggest that DNA degradation is initiated by an “active complex” consisting of BLM, metal and oxygen that functions by abstracting H· from susceptible sites on DNA.     

The relative effectiveness of .OH,H2O2,O2−, and reducing free radicals in causing damage to biomembranes: A study of radiation damage to erythrocyte ghosts using selective free radical scavengers

The relative effectiveness of oxidizing (^.OH, H₂O₂), ambivalent (O₂^?) and reducing free radicals (e^? and CO₂^?) in causing damage to membranes and membrane-bound glyceraldehyde-3-phosphate dehydrogenase of resealed erythrocyte ghosts has been determined. The rates of damage to membranebound glyceraldehyde-3-phosphate dehydrogenase ($\text{R}$(enz)) were measured and the rates of damage to membranes ($\text{R}$(mb)) were assessed by measuring changes in permeability of the resealed ghosts to the relatively low molecular weight substrates of glyceraldehyde-3-phosphate dehydrogenase. Each radical was selectively isolated from the mixture produced during gamma-irradiation, using appropriate mixtures of scavengers such as catalase, superoxide dismutase and formate. ^.OH, O₂^? and H₂ O₂ were approximately equally effective in inactivating membrane-bound glyceraldehyde-3-phosphate dehydrogenase, while e^? and CO₂^? were the least effective. $\text{R}$(enz) values of O₂^? and H₂O₂ were 10-times and of ^.OH 15-times that of e^?. $\text{R}$(mb) values were quite similar for e^? and H₂O₂ (about twice that of O₂^?), while that of ^.OH was 3-times that of O₂^?. Hence, with respect to $\text{R}$(mb): ${}^{\mathrm{.}}\text{OH}\text{>}\text{e}{}^{\mathrm{?}}\text{=}\text{H}{}_2\text{O}{}_2\text{>}\text{O}{}_2{}^{\mathrm{?}}$ , and with respect to $\text{R}$(enz): ${}^{\mathrm{.}}\text{OH}\text{>}\text{O}{}_2{}^{\mathrm{?}}\text{=}\text{H}{}_2\text{O}{}_2\text{>}\text{e}{}^{\mathrm{?}}$. The difference between the effectiveness of the most damaging and the least damaging free radicals was more than 10-fold greater in damage to the enzyme than to the membranes. Comparison between H₂O₂ added as a chemical reagent and H₂O₂ formed by irradiation showed that membranes and membrane-bound glyceraldehyde-3-phosphate dehydrogenase were relatively inert to reagent H₂O₂ but markedly susceptible to the latter.     

Photobiochemistry in the dark: photohemolysis of red cells sensitized by chlorpromazine-bioenergized triplet acetone system

Chlorpromazine is decomposed when it is treated with bioenergized triplet acetone from the 2-methylpropanal/red cells/O₂ system, forming chlorpromazine-5-oxide, with a concomitant strong hemolytic effect observed by a spectrophotometric method. Experiments with external superoxide dismutase, catalase, benzoate and bicarbonate indicate the absence of $\text{O}{}_2{}^{\mathrm{<mtext>?</mtext>}}$, H₂O₂ and OH· species as the precursor of the hemolytic effect.Comparison between the 2-methylpropanal/peroxidase/O₂ system and the 2-methylpropanal/red cells/O₂ system in the presence of chlorpromazine, indicate that essentially the same type of mechanism occurs in both cases.These results could explain the $\text{in}$$\text{vivo}$ hemolytic and toxic effect of chlorpromazine in the dark.     

Inactivation of the human CuZn superoxide dismutase during exposure to O-2 and H2O2

Human copper-zinc superoxide dismutase undergoes inactivation when exposed to O₂^? and H₂O₂ generated during the oxidation of acetaldehyde by xanthine oxidase at pH 7.4 and 37° C. In contrast, human manganese superoxide dismutase is not inactivated under the same conditions. Catalase and Mn-superoxide dismutase protect CuZn superoxide dismutase from inactivation. Similar protection is observed with hydroxyl radical (OH.) scavengers, such as formate and mannitol. In contrast, other OH. scavengers such as ethanol and tert-butyl alcohol, have no protective action. The latter results indicate that “free OH.” is not responsible for the inactivation. Furthermore, H₂O₂ generated during the oxidation of glucose by glucose oxidase, i.e., without production of O₂^?, does not induce CuZn superoxide dismutase inactivation. A mechanism accounting for this $\text{O}{}_2{}^{\mathrm{?}}\text{H}{}_2\text{O}{}_2$-dependent inactivation of CuZn superoxide dismutase is proposed.     

The hemoglobin of the crossopterygian fish, Latimeria chalumnae (Smith). Subunit structure and oxygen equilibria

There are five oxidation-reduction states of horseradish peroxidase which are interconvertible. These states are ferrous, ferric, Compound II (ferryl), Compound I (primary compound of peroxidase and H₂O₂), and Compound III (oxy-ferrous). The presence of heme-linked ionization groups was confirmed in the ferrous enzyme by spectrophotometric and pH stat titration experiments. The values of pK were 5.87 for isoenzyme A and 7.17 for isoenzymes (B + C). The proton was released when the ferrous enzyme was oxidized to the ferric enzyme while the uptake of the proton occurred when the ferrous enzyme reacted with oxygen to form Compound III. The results could be explained by assuming that the heme-linked ionization group is in the vicinity of the sixth ligand and forms a stable hydrogen bond with the ligand.The measurements of uptake and release of protons in various reactions also yielded the following stoichiometries: Ferric peroxidase + H₂O₂ → Compound I, Compound I + e^? + H⁺ → Compound II, Compound II + e^? + H⁺ → ferric peroxidase, Compound II + H₂O₂ → Compound III, Compound III + 3e^? + 3H⁺ → ferric peroxidase.Based on the above stoichiometries and assuming the interaction between the sixth ligand and heme-linked ionization group of the protein, it was possible to picture simple models showing structural relations between five oxidation-reduction states of peroxidase. Tentative formulae are as follows: [Pr·Po·Fe-(II) $\text{\$}\text{?}$PrH⁺·Po·Fe(II)] is for the ferrous enzyme, Pr·Po·Fe(III)OH₂ for the ferric one, Pr·Po·Fe(IV)OH^? for Compound II, Pr(OH^?)·Po⁺·Fe(IV)OH^? for Compound I, and PrH⁺·Po·Fe(III)O₂^? for Compound III, in which Pr stands for protein and Po for porphyrin. And by Fe(IV)OH^?, for instance, is meant that OH^? is coordinated at the sixth position of the heme iron and the formal oxidation state of the iron is four.     

Nitric oxide donor-induced hyperpermeability of cultured intestinal epithelial monolayers: role of superoxide radical,hydroxyl radical,and peroxynitrite

Many of the cytopathic effects of nitric oxide (NO^·) are mediated by peroxynitrite (PN), a product of the reaction between NO^· and superoxide radical (O^·?₂). In the present study, we investigated the role of PN, O^·?₂ and hydroxyl radical (OH^·) as mediators of epithelial hyperpermeability induced by the NO^· donor, S-nitroso-N-acetylpenicillamine (SNAP), and the PN generator, 3-morpholinosydnonimine (SIN-1). Caco-2_BBe enterocytic monolayers were grown on permeable supports in bicameral chambers. Epithelial permeability, measured as the apical-to-basolateral flux of fluorescein disulfonic acid, increased after 24 h of incubation with 5.0 mM SNAP or SIN-1. Addition of 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide, an NO^· scavenger, or Tiron, an O^·?₂ scavenger, reduced the increase in permeability induced by both donor compounds. The SNAP-induced increase in permeability was prevented by allopurinol, an inhibitor of xanthine oxidase (a source of endogenous O^·?₂). Diethyldithiocarbamate, a superoxide dismutase inhibitor, and pyrogallol, an O^·?₂ generator, potentiated the increase in permeability induced by SNAP. Addition of the PN scavengers deferoxamine, urate, or glutathione, or the OH^· scavenger mannitol, attenuated the increase in permeability induced by both SNAP and SIN-1. Both donor compounds decreased intracellular levels of glutathione and protein-bound sulfhydryl groups, suggesting the generation of a potent oxidant. These results support a role for PN, and possibly OH^·, in the pathogenesis of NO^· donor-induced intestinal epithelial hyperpermeability.     

Do copper ions influence the reduction of ferricytochrome C by O−2?

Recently, it was suggested that the measured rate of reduction of ferricyto chrome $\text{C}$ by O^?₂ below pH 8, was too high in the presence of high concentrations of formate (Koppenol, W.H., Van Buuren, K.J.H., Butler J. and Braams, R. (1976) Biochim. Biophys. Acta 449, 157–168).The high values were attributed to the presence of impurities of copper, which compete for O^?₂. This assumption is consistent with either a decrease in the reduction yield of ferricytochrome $\text{C}$ in the presence of copper, or with a very fast reaction of Cu(I) with ferricytochrome $\text{C}$.It was previously shown by us and by others that the reduction yield of ferricytochrome $\text{C}$ by O^?₂ is 100%. We measured the rate of reduction of ferricytochrome $\text{C}$ by Cu(I), and found that this reaction is slow: $\text{k = (1.5±0.5) · 10}{}^3\text{M}{}^{\mathrm{?1}}\text{) ·}\text{s}{}^{\mathrm{?1}}$.Therefore, our results rule out the possibility that below pH 8 copper impurities affect the measured rate constant of the reduction of ferricytochrome $\text{C}$ by O^?₂.     

A reaction of the superoxide radical with tetrapyrroles

Bilirubin and biliverdin were bleached during exposure to the aerobic xanthine oxidase reaction. Enzymic scavenging of O₂^?, by Superoxide dismutase, inhibited, whereas enzymic scavenging of H₂O₂, by catalase, did not. Increasing the rate of production of O₂^? without increasing the turnover rate of xanthine oxidase, by increasing pO₂, accelerated the bleaching of the biliverdin. Moreover, a scavenger of OH·, such as benzoate, or an inactivating chelating agent for iron, such as diethylenetriamine pentaacetate or desferrioxamine mesylate, did not inhibit. It follows that O₂^? can directly attack these tetrapyrroles. Kinetic competition between Superoxide dismutase and bilirubin yielded a value for k_{bilirubin, O2^?} = 2.3 × 10⁴ M^?1s^?1 at pH 8.3 and at 23 °C. A similar experiment for biliverdin yielded a value for k_{bilirubin, O2^?} = 7 × 10⁴ M^?1s^?1.     

The one-electron transfer redox potentials of free radicals. I. The oxygen/superoxide system

The method of determination of Redox potentials of radicals, using the pulse radiolysis technique, is outlined. The method is based on the determination of equilibrium constants of electron transfer reactions between the radicals and appropriate acceptors. The limitations of this technique are discussed.The redox potentials of several quinones-semiquinones are calculated, as well as the standard redox potential of the peroxy radical. and the redox oxidation properties of the peroxy radical in various systems and pH are discussed. The value determined for the redox potentials of $\text{O}{}_2\text{O}{}_2{}^{\mathrm{?}}$ is higher by more than 0.2 V than earlier estimates, which has important implications on the possible role of O₂^? in biological processes of O₂ fixation.     

Hydroxyl radical production from hydrogen peroxide and enzymatically generated paraquat radicals: Catalytic requirements and oxygen dependence

The ability of paraquat radicals (PQ^+.) generated by xanthine oxidase and glutathione reductase to give H₂O₂-dependent hydroxyl radical production was investigated. Under anaerobic conditions, paraquat radicals from each source caused chain oxidation of formate to CO₂, and oxidation of deoxyribose to thiobarbituric acid-reactive products that was inhibited by hydroxyl radical scavengers. This is in accordance with the following mechanism derived for radicals generated by γ-irradiation [H. C. Sutton and C. C. Winterbourn (1984) Arch. Biochem. Biophys.235, 106–115] PQ^+. + Fe³⁺ (chelate) → Fe²⁺ (chelate) + PQ⁺⁺ H₂O₂ + Fe²⁺ (chelate) → Fe³⁺ (chelate) + OH^? + OH.. Iron-(EDTA) and iron-(diethylenetriaminepentaacetic acid) (DTPA) were good catalysts of the reaction; iron complexed with desferrioxamine or transferrin was not. Extremely low concentrations of iron (0.03 μm) gave near-maximum yields of hydroxyl radicals. In the absence of added chelator, no formate oxidation occurred. Paraquat radicals generated from xanthine oxidase (but not by the other methods) caused H₂O₂-dependent deoxyribose oxidation. However, inhibition by scavengers was much less than expected for a reaction of hydroxyl radicals, and this deoxyribose oxidation with xanthine oxidase does not appear to be mediated by free hydroxyl radicals. With O₂ present, no hydroxyl radical production from H₂O₂ and paraquat radicals generated by radiation was detected. However, with paraquat radicals continuously generated by either enzyme, oxidation of both formate and deoxyribose was measured. Product yields decreased with increasing O₂ concentration and increased with increasing iron(DTPA). These results imply a major difference in reactivity between free and enzymatically generated paraquat radicals, and suggest that the latter could react as an enzyme-paraquat radical complex, for which the relative rate of reaction with Fe³⁺ (chelate) compared with O₂ is greater than is the case with free paraquat radicals.     

Complete stoichiometry of free NADPH oxidation in liver microsomes

The stoichiometry of free NADPH oxidation in phenobarbital induced rabbit liver microsomes was measured by means of registering the rates of NADPH, H⁺ and O₂ consumption and $\text{O}{}_2{}^{\mathrm{<mtext>?</mtext>}}$ and H₂O₂ production. $\text{ΔO}{}_2{}^{\mathrm{<mtext>?</mtext>}}\text{:ΔH}{}_2\text{O}{}_2$ ratio is approximately I indicating that about half H₂O₂ results from $\text{O}{}_2{}^{\mathrm{<mtext>?</mtext>}}$ dismutation, the second half being formed directly. ΔNADPH:ΔH₂O₂ and ΔO₂:ΔH₂O₂ ratios exceed I and therefore another product of the reaction is water. The fact that the ratio (ΔNADPH-ΔH₂O₂):(ΔO₂-ΔH₂O₂) is 2 allows one to consider direct 4-electron O₂ reduction as the major way of water formation rather than endogenous substrate hydroxylation.     

Modeling the scavenging activity of ellagic acid and its methyl derivatives towards hydroxyl, methoxy, and nitrogen dioxide radicals

The reaction mechanisms involved in the scavenging of hydroxyl (OH^·), methoxy (OCH₃ ^·), and nitrogen dioxide (NO₂ ^·) radicals by ellagic acid and its monomethyl and dimethyl derivatives were investigated using the transition state theory and density functional theory. The calculated Gibbs barrier energies associated with the abstraction of hydrogen from the hydroxyl groups of ellagic acid and its monomethyl and dimethyl derivatives by an OH· radical in aqueous media were all found to be negative. When NO₂ ^· was the radical involved in hydrogen abstraction, the Gibbs barrier energies were much larger than those calculated when the OH^· radical was involved. When OCH₃ ^· was the hydrogen-abstracting radical, the Gibbs barrier energies lay between those obtained with OH^· and NO₂ ^· radicals. Therefore, the scavenging efficiencies of ellagic acid and its monomethyl and dimethyl derivatives towards the three radicals decrease in the order OH^· >> OCH₃ ^· > NO₂ ^·. Our calculated rate constants are broadly in agreement with those obtained experimentally for hydrogen abstraction reactions of ellagic acid with OH· and NO₂· radicals.

Energy-coupling mechanisms under aerobic and anaerobic conditions in autotrophically grown Pseudomonas saccharophila

The cell-free preparations from autotrophieally grown Pseudomonas saccharophila catalyzed the process of electron transport from H₂ or various other organic electron donors to either O₂ or NO₃^? with concomitant ATP generation. The respective $\text{P}\text{O}$ ratios with H₂ and NADH were 0.63 and 0.73, the respective $\text{P}\text{NO}{}_3{}^{\mathrm{?}}$ ratios were 0.57 and 0.54. In contrast, the $\text{P}\text{O}$ and $\text{P}\text{NO}{}_3{}^{\mathrm{?}}$ ratios with succinate were 0.18 and 0.11, respectively. ATP formation coupled to the oxidation of ascorbate, in the absence or presence of added N,N,N′,N′-tetramethyl-p-phenylenediamine or cytochrome c, could not be detected. Various uncouplers inhibited phosphorylation with either O₂ or NO₃^? as terminal electron acceptors without affecting the oxidation of H₂ or other substrates. The NADH oxidation at the expense of O₂ or NO₃^? reduction as well as the associated phosphorylation were inhibited by rotenone and amytal. The aerobic and anaerobic H₂ oxidation and coupled ATP synthesis, on the other hand, was unaffected by the flavoprotein inhibitors as well as by the NADH trapping system. The NADH, H₂, and succinate-linked electron transport to O₂ or NO₃^? and the associated phosphorylations were sensitive, however, to antimycin A or 2-n-nonyl-4-hydroxyquino-line-N-oxide, and cyanide or azide. The data indicated that although the phosphorylation sites 1 and II were associated with NADH oxidation by O₂ or NO₃^?, the energy conservation coupled to H₂ oxidation under aerobic or anaerobic conditions appeared to involve site II only.     

Dual action of ionophore A23187 on intact chloroplasts

1. Ionophore A23187 induces uncoupling of potassium ferricyanide-dependent O₂ evolution by envelope-free chloroplasts and oxaloacetate-dependent O₂ evolution by intact chloroplasts. The half maximal concentration ($\text{C}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) for stimulation of oxygen evolution in both cases is approximately 4 μM · 100 μg chlorophyll · ml^?1.2. Ionophore A23187 also induces inhibition of CO₂ and 3-phosphoglycerate-dependent O₂ evolution by intact chloroplasts in the presence of 3 mM MgCl₂. The half maximal concentrations ($\text{C}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) for inhibition of O₂ evolution are 3 μM and 5 μM respectively · 100 μg^?1 chlorophyll · ml^?1.3. A very high concentration of ionophore A23187 (10 μM · 20 μg^?1 chlorophyll · ml^?1) plus 0.1 mM EDTA lowers the fluorescence yield of intact chloroplasts suspended in a cation-free medium in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea, indicating loss of divalent cation from the diffuse double layers of the thylakoid membranes.4. These results are discussed in relation to ionophore A23187-induced divalent cation/proton exchange at both the thylakoid and the envelope membranes of intact chloroplasts.     

Peroxide binding to the type 3 site in Rhus vernicifera laccase depleted of type 2 copper

The interaction between hydrogen peroxide and oxidized $\text{Rhus}\text{vernicifera}$ laccase from which the type 2 copper has been removed, was investigated. For that end, the circular dichroic spectrum of the modified enzyme has been measured in the presence of increasing concentrations of hydrogen peroxide. The characteristic band observed upon binding peroxide to native laccase is also observed for the type 2 copper depleted enzyme. However, there are several quantitative differences in the latter one. First, the intensity is lower and band width is larger. Secondly, from the titrations, it becomes apparent that the affinity for H₂O₂ is markedly lower than that of the native enzyme. While the affinity for the native enzyme is higher than 10⁸ M^?1, it decreases to 1·10⁴ M^?1 for the type 2 depleted enzyme.