Superoxide oxidase and reductase activity of cytochrome b559 in photosystem II

This study provides evidence for the superoxide oxidase and the superoxide reductase activity of cytochrome b₅₅₉ (cyt b₅₅₉) in PSII. It is reported that in Tris-treated PSII membranes upon illumination, both the intermediate potential (IP) and the reduced high potential (HP^red) forms of cyt b₅₅₉ exhibit superoxide scavenging activity and interconversion between IP and HP^red form. When Tris-treated PSII membranes were illuminated in the presence of spin trap EMPO, the formation of superoxide anion radical (O₂⁻) was observed, as confirmed by EPR spin-trapping spectroscopy. The observations that the addition of enzymatic (superoxide dismutase) and non-enzymatic (cytochrome c, α-tocopherol and Trolox) O₂⁻ scavengers prevented the light-induced conversion of IP ↔ HP^red cyt b₅₅₉ confirmed that IP and HP^red cyt b₅₅₉ are reduced and oxidized by O₂⁻, respectively. Redox changes in cyt b₅₅₉ by an exogenous source of O₂⁻ reconfirmed the superoxide oxidase and reductase activity of cyt b₅₅₉. Furthermore, the light-induced conversion of IP to HP^red form of cyt b₅₅₉ was completely inhibited at pH > 8 and by chemical modification of the imidazole ring of histidine residues using diethyl pyrocarbonate. We proposed that a change in the environment around the heme iron, induced by the protonation and deprotonation of His²² residue generates a favorable condition for the oxidation and reduction of O₂⁻, respectively.     

H2O2 and (.)NO scavenging by Mycobacterium leprae truncated hemoglobin O

Kinetics of ferric Mycobacterium leprae truncated hemoglobin O (trHbOFe(III)) oxidation by H₂O₂ and of trHbOFe(IV)O reduction by NO and NO₂⁻ are reported. The value of the second-order rate constant for H₂O₂-mediated oxidation of trHbOFe(III) is 2.4 × 10³ M⁻¹ s⁻¹. The value of the second-order rate constant for NO-mediated reduction of trHbOFe(IV)O is 7.8 × 10⁶ M⁻¹ s⁻¹. The value of the first-order rate constant for trHbOFe(III)ONO decay to the resting form trHbOFe(III) is 2.1 × 10¹ s⁻¹. The value of the second-order rate constant for NO₂⁻-mediated reduction of trHbOFe(IV)O is 3.1 × 10³ M⁻¹ s⁻¹. As a whole, trHbOFe(IV)O, generated upon reaction with H₂O₂, catalyzes NO reduction to NO₂⁻. In turn, NO and NO₂⁻ act as antioxidants of trHbOFe(IV)O, which could be responsible for the oxidative damage of the mycobacterium. Therefore, Mycobacterium leprae trHbO could be involved in both H₂O₂ and NO scavenging, protecting from nitrosative and oxidative stress, and sustaining mycobacterial respiration.     

Evidence for a pathway that facilitates nitric oxide diffusion in the brain

Nitric oxide (NO) is a diffusible messenger that conveys information based on its concentration dynamics, which is dictated by the interplay between its synthesis, inactivation and diffusion. Here, we characterized NO diffusion in the rat brain in vivo. By direct sub-second measurement of NO, we determined the diffusion coefficient of NO in the rat brain cortex. The value of 2.2 × 10⁻⁵ cm²/s obtained in vivo was only 14% lower than that obtained in agarose gel (used to evaluate NO free diffusion). These results reinforce the view of NO as a fast diffusing messenger but, noticeably, the data indicates that neither NO diffusion through the brain extracellular space nor homogeneous diffusion in the tissue through brain cells can account for the similarity between NO free diffusion coefficient and that obtained in the brain. Overall, the results support that NO diffusion in brain tissue is heterogeneous, pointing to the existence of a pathway that facilitates NO diffusion, such as cell membranes and other hydrophobic structures.     

The formation of peroxynitrite in the applied physiology of mitochondrial nitric oxide

Mitochondria require nitric oxide (NO) to exert a delicate control of metabolic rate as well as to regulate life functions, cell cycle activation and arrest, and apoptosis. All activities depend on the matrical NO steady state concentration as provided by mitochondrial (mtNOS) and cytosolic sources (eNOS) and reduced by forming superoxide anion and H₂O₂ and a low peroxynirite (ONOO⁻) yield. We review herein the biochemical pathways involved in the control of NO mitochondrial level and its biological and physiological significance in hormone effects and aging. At high NO, the cost of this physiological regulation is that ONOO⁻ excess will lead to nitrosation/nitration and oxidization of mitochondrial and cell proteins and lipids. The disruption of NO modulation of mitochondrial respiration supports then, a platform for prevalent neurodegenerative and metabolic diseases.     

NO, NO, NO! Nitrosyl siblings from [IrCl5(NO)]

Pentachloronitrosyliridate(III) ([IrCl₅(NO)]⁻), the most electrophilic NO⁺ known to date, can be reduced chemically and/or electrochemically by one or two electrons to produce the NO and HNO/NO⁻ forms. The nitroxyl complex can be formed either by hydride attack to the NO⁺ in organic solvent, or by decomposition of iridium-coordinated nitrosothiols in aqueous solutions, while NO is produced electrochemically or by reduction of [IrCl₅(NO)]⁻ with H₂O₂. Both NO and HNO/NO⁻ complexes are stable under certain conditions but tend to labilize the trans chloride and even the cis ones after long periods of time. As expected, the NO⁺ is practically linear, although the IrNO moiety is affected by the counterions due to dramatic changes in the solid state arrangement. The other two nitrosyl redox states comprise bent structures.     

Upstream reactive oxidative species (ROS) signals in exogenous oxidative stress-induced mitochondrial dysfunction

Exogenous oxidative stress induces cell death, but the upstream molecular mechanisms involved of the process remain relatively unknown. We determined the instant dynamic reactions of intracellular reactive oxygen species (ROS, including hydrogen peroxide (H₂O₂), superoxide radical (O₂⁻), and nitric oxide (NO)) in cells exposed to exogenous oxidative stress by using a confocal laser scanning microscope. Stimulation with extracellular H₂O₂ significantly increased the production of intracellular H₂O₂, O₂⁻, and NO (P < 0.01) through certain mechanisms. Increased levels of intracellular ROS resulted in mitochondrial dysfunction, involving the impairment of mitochondrial activity and the depolarization of mitochondrial membrane potential. Mitochondrial dysfunction significantly inhibited the proliferation of human hepatoblastoma G2 (HepG2) cells and resulted in mitochondrial cytochrome c (cyt c) release. The results indicate that upstream ROS signals play a potential role in exogenous oxidative stress-induced cell death through mitochondrial dysfunction and cyt c release.     

Dark production of reactive oxygen species in photosystem II membrane particles at elevated temperature: EPR spin-trapping study

In our study, EPR spin-trapping technique was employed to study dark production of two reactive oxygen species, hydroxyl radicals (OH) and singlet oxygen (¹O₂), in spinach photosystem II (PSII) membrane particles exposed to elevated temperature (47 °C). Production of OH, evaluated as EMPO-OH adduct EPR signal, was suppressed by the enzymatic removal of hydrogen peroxide and by the addition of iron chelator desferal, whereas externally added hydrogen peroxide enhanced OH production. These observations reveal that OH is presumably produced by metal-mediated reduction of hydrogen peroxide in a Fenton-type reaction. Increase in pH above physiological values significantly stimulated the formation of OH, whereas the presence of chloride and calcium ions had the opposite effect. Based on our results it is proposed that the formation of OH is linked to the thermal disassembly of water-splitting manganese complex on PSII donor side. Singlet oxygen production, followed as the formation of nitroxyl radical TEMPO, was not affected by OH scavengers. This finding indicates that the production of these two species was independent and that the production of ¹O₂ is not closely linked to PSII donor side.     

Radicals associated with the catalytic intermediates of bovine cytochrome c oxidase

Two radicals have been detected previously by electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectroscopies in bovine cytochrome oxidase after reaction with hydrogen peroxide, but no correlation could be made with predicted levels of optically detectable intermediates (P_M, F and F) that are formed. This work has been extended by optical quantitation of intermediates in the EPR/ENDOR sample tubes, and by comparison with an analysis of intermediates formed by reaction with carbon monoxide in the presence of oxygen. The narrow radical, attributed previously to a porphyrin cation, is detectable at low levels even in untreated oxidase and increases with hydrogen peroxide treatments generally. It is presumed to arise from a side-reaction unrelated to the catalytic intermediates. The broad radical, attributed previously to a tryptophan radical, is observed only in samples with a significant level of F but when F is generated with hydrogen peroxide, is always accompanied by the narrow radical. When P_M is produced at high pH with CO/O₂, no EPR-detectable radicals are formed. Conversion of the CO/O₂-generated P_M into F when pH is lowered is accompanied by the appearance of a broad radical whose ENDOR spectrum corresponds to a tryptophan cation. Quantitation of its EPR intensity indicates that it is around 3% of the level of F determined optically. It is concluded that low pH causes a change of protonation pattern in P_M which induces partial electron redistribution and tryptophan cation radical formation in F. These protonation changes may mimic a key step of the proton translocation process.     

EPR properties of a g=2 broad signal trapped in an S1 state in Ca-depleted Photosystem II

We investigated a new EPR signal that gives a broad line shape around g=2 in Ca²⁺-depleted Photosystem (PS) II. The signal was trapped by illumination at 243 K in parallel with the formation of Y_Z. The ratio of the intensities between the g=2 broad signal and the Y_Z signal was 1:3, assuming a Gaussian line shape for the former. The g=2 broad signal and the Y_Z signal decayed together in parallel with the appearance of the S₂ state multiline at 243 K. The g=2 broad signal was assigned to be an intermediate S₁X state in the transition from the S₁ to the S₂ state, where X represents an amino acid radical nearby manganese cluster, such as D1-His337. The signal is in thermal equilibrium with Y_Z. Possible reactions in the S state transitions in Ca²⁺-depleted PS II were discussed.     

Extracellular superoxide production associated with secondary root growth following desiccation of Pisum sativum seedlings

The seedling stage is arguably the most vulnerable phase in the plant life cycle, where the young establishing plant is extremely sensitive to environmental stresses such as drought. Here, the production of superoxide (O₂⁻), a molecule involved in stress signaling, was measured in response to desiccation of Pisum sativum L. seedlings. Following desiccation that was sufficient to kill the radicle meristem, viability could be retained by seedlings that grew secondary roots. Upon rehydration, secondary roots formed in a region that had displayed intense extracellular O₂⁻production on desiccation. Treating partially desiccated seedlings with hydrogen peroxide (H₂O₂) prevented viability loss. In summary, reactive oxygen species (ROS) appear to participate in the signaling required for secondary root formation following desiccation stress of P. sativum seedlings.     

Reaction of N-hydroxyguanidine with the ferrous-oxy state of a heme peroxidase cavity mutant: A model for the reactions of nitric oxide synthase

Yeast cytochrome c peroxidase was used to construct a model for the reactions catalyzed by the second cycle of nitric oxide synthase. The R48A/W191F mutant introduced a binding site for N-hydroxyguanidine near the distal heme face and removed the redox active Trp-191 radical site. Both the R48A and R48A/W191F mutants catalyzed the H₂O₂ dependent conversion of N-hydroxyguanidine to N-nitrosoguanidine. It is proposed that these reactions proceed by direct one-electron oxidation of NHG by the Fe⁺⁴O center of either Compound I (Fe⁺⁴O, porph⁺) or Compound ES (Fe⁺⁴O, Trp⁺). R48A/W191F formed a Fe⁺²O₂ complex upon photolysis of Fe⁺²CO in the presence of O₂, and N-hydroxyguanidine was observed to react with this species to produce products, distinct from N-nitrosoguanidine, that gave a positive Griess reaction for nitrate + nitrite, a positive Berthelot reaction for urea, and no evidence for formation of NO. It is proposed that HNO and urea are produced in analogy with reactions of nitric oxide synthase in the pterin-free state.     

XRCC1 and base excision repair balance in response to nitric oxide

Inflammation associated reactive oxygen and nitrogen species (RONs), including peroxynitrite (ONOO⁻) and nitric oxide (NO), create base lesions that potentially play a role in the toxicity and large genomic rearrangements associated with many malignancies. Little is known about the role of base excision repair (BER) in removing these endogenous DNA lesions. Here, we explore the role of X-ray repair cross-complementing group 1 (XRCC1) in attenuating RONs-induced genotoxicity. XRCC1 is a scaffold protein critical for BER for which polymorphisms modulate the risk of cancer. We exploited CHO and human glioblastoma cell lines engineered to express varied levels of BER proteins to study XRCC1. Cytotoxicity and the levels of DNA repair intermediates (single-strand breaks; SSB) were evaluated following exposure of the cells to the ONOO⁻ donor, SIN-1, and to gaseous NO. XRCC1 null cells were slightly more sensitive to SIN-1 than wild-type cells. We used small-scale bioreactors to expose cells to NO and found that XRCC1-deficient CHO cells were not sensitive. However, using a molecular beacon assay to test lesion removal in vitro, we found that XRCC1 facilitates AAG-initiated excision of two key NO-induced DNA lesions: 1,N⁶-ethenoadenine and hypoxanthine. Furthermore, overexpression of AAG rendered XRCC1-deficient cells sensitive to NO-induced DNA damage. These results show that AAG is a key glycosylase for BER of NO-induced DNA damage and that XRCC1's role in modulating sensitivity to RONs is dependent upon the cellular level of AAG. This demonstrates the importance of considering the expression of other components of the BER pathway when evaluating the impact of XRCC1 polymorphisms on cancer risk.     

Oxidative decarboxylation of tris-(p-carboxyltetrathiaaryl)methyl radical EPR probes by peroxidases and related hemeproteins: Intermediate formation and characterization of the corresponding cations

Tris(p-carboxyltetrathiaaryl)methyl radicals (TAM) are good EPR probes for measurement of dioxygen concentration in biological systems and for EPR imaging. It has been previously reported that these radicals are efficiently oxidized by superoxide, O₂⁻, or alkylperoxyl radicals, ROO, and by liver microsomes via an oxidative decarboxylation mechanism leading to the corresponding quinone-methides (QM). This article shows that peroxidases, such as horseradish peroxidase (HRP), lactoperoxidase (LPO) and prostaglandin synthase (PGHS), and other hemeproteins, such as methemoglobin (metHb), metmyoglobin (metMb) and catalase, also efficiently catalyze the oxidation of TAM radicals to QM by H₂O₂ or alkylhydroperoxides. These reactions involve the intermediate formation of the corresponding cations TAM⁺ that have also been cleanly generated by K₂Ir(IV)Cl₆ and characterized by UV-Visible spectroscopy and mass spectrometry, and through their reactions with ascorbate or H₂O₂. Labelling experiments on HRP-catalyzed oxidation of TAM to QM using H₂¹⁸O or ¹⁸O₂ in the presence of glucose and glucose oxidase (GOX) showed that the oxygen atom incorporated into QM came both from O₂ and from H₂O. Mechanisms for these reactions in agreement with those data were proposed. Oxidative decarboxylation of TAM to QM is a new reaction catalyzed by peroxidases. Such reactions should be considered when using TAM as EPR oximetry probes invivo or in vitro in complex biological media.