Production of the Carbonate Radical Anion during Xanthine Oxidase Turnover in the Presence of Bicarbonate

Bonini, Marcelo G.; Miyamoto, Sayuri; Mascio, Paolo Di; Augusto, Ohára

doi:10.1074/jbc.m406929200

Cited by 85 publications

(78 citation statements)

References 57 publications

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“…Recent literature has reported several developments that have been important in unraveling the SOD1 peroxidase cycle: first, the demonstration that SOD1 peroxidase activity is greatly stimulated by HCO 3 Ϫ (5, 6) and dependent on CO 2 (8); second, the characterization by Richardson's group (27) . (30,33). This idea has inspired continued investigation (30, 31, 39 -41).…”

Section: Discussionmentioning

confidence: 99%

“…Although this process is well described for the heme-dependent peroxidase cycle, current literature data (9,(27)(28)(29)(30) and the fact that the proposed SOD1-bound hypervalent copper states (Cu(III), Cu(II)ϭO, and Cu(II)/ ⅐ OH) have never been characterized suggested to us that an alternative mechanism may take place, leading to CO 3 . production from HCO 3 Ϫ and H 2 O 2 by the enzyme, a process that does not involve copper oxidation beyond the thermodynamically stable Cu(II) form.…”

mentioning

confidence: 99%

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Direct Magnetic Resonance Evidence for Peroxymonocarbonate Involvement in the Cu,Zn-Superoxide Dismutase Peroxidase Catalytic Cycle

Gabel

Ranguelova²,

Stadler³

et al. 2009

Journal of Biological Chemistry

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Cu,Zn-superoxide dismutase (SOD1) is a copper-and zincdependent enzyme. The main function of SOD1 is believed to be the scavenging and detoxification of superoxide radicals. Nevertheless, the last 30 years have seen a rapid accumulation of evidence indicating that SOD1 may also act as a peroxidase, an alternative function that was implicated in the onset and progression of familial amyotrophic lateral sclerosis. Although SOD1 peroxidase activity and its dependence on carbon dioxide have been well described, the molecular basis of the SOD1 peroxidase cycle remains obscure, because none of the proposed catalytic intermediates have so far been identified. In view of recent observations, we hypothesized that the SOD1 peroxidase cycle relies on two steps: 1) reduction of SOD-Cu(II) by hydrogen peroxide followed by 2) oxidation of SOD-Cu(I) by peroxymonocarbonate, the product of the spontaneous reaction of bicarbonate with hydrogen peroxide, to produce SOD-Cu(II) and carbonate radical anion. This hypothesis has been investigated through electron paramagnetic resonance and nuclear magnetic resonance to provide direct evidence for a peroxycarbonate-driven, SOD1-catalyzed carbonate radical production. The results gathered herein indicate that peroxymonocarbonate (HOOCO 2 ؊ ) is a key intermediate in the SOD1 peroxidase cycle and identify this species as the precursor of carbonate radical anions.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Direct Magnetic Resonance Evidence for Peroxymonocarbonate Involvement in the Cu,Zn-Superoxide Dismutase Peroxidase Catalytic Cycle

Gabel

Ranguelova²,

Stadler³

et al. 2009

Journal of Biological Chemistry

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“…A series of experiments were conducted to establish optimum analytical 4 on the CL intensity was tested further, and the results are shown in Figure 3a. These results revealed the fact that Co 2+ was the limiting reactant.…”

Section: Effects Of the Concentrations Of Chemicalsmentioning

confidence: 99%

Experimental Studies on the Chemiluminescence Reaction Mechanism of Carbonate/Bicarbonate and Hydrogen Peroxide in the Presence of Cobalt(II)

et al. 2008

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Chemiluminescence (CL) phenomena of carbonates or bicarbonates of potassium, sodium, or ammonium with hydrogen peroxide in the presence of cobalt sulfate were reported. After cobalt(II) solution was injected into the mixture of carbonate/bicarbonate and hydrogen peroxide, a CL signal was given out briefly. The CL conditions of these systems were optimized. The CL reaction mechanisms were studied experimentally by examining the spectrum emitted by the CL system and the effect of various free radical scavengers on CL emission intensity. The results showed that the maximal emission wavelengths of the CO 3 2--H 2 O 2 -Co 2+ and HCO 3 --H 2 O 2 -Co 2+ systems were 440 and 490 nm, respectively. As a result, a radical scavenger of ascorbic acid, thiourea, and superoxide dismutase exhibited different effects on these CL systems. The different CL mechanisms involving the carbon dioxide dimer and the oxygen dimer were revealed, respectively.

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“…То есть конечные продукты реакции автоокисления адреналина, кроме адренохрома, могут быть не только супероксид анионы, но и радикалы карбонат/бикарбонатного буфера и диоксида углерода, растворённого в буфере. Такое наше предположение основывается на данных современной литературы, где активно обсуждается существование и роль карбонатных радикалов и радикалов диоксида углерода [30][31][32][33][34][35][36][37][38]42].…”

Section: рисунокunclassified

“…В известной ферментативной модельной системе ксантин/ксантиноксидаза также генерируются не только супероксид анион радикалы, пероксид водорода и пероксинитрит, но и продуцируются карбонатные анион радикалы, которые, как предполагается, могут быть важными медиаторами в патофизиологических эффектах ксантиноксидазы [36]. В литературе демонстрируются и обсуждаются возможные пути образования при различных условиях пероксимонокарбоната и карбонатных радикалов как патогенетических оксидантов из вездесущего физиологического буфера карбонат/бикарбонат/диоксид углерода [33,37].…”

Section: рисунокunclassified

Involvement of carbonate/bicarbonate ions in the superoxide-generating reaction of adrenaline autoxidation

Sirota

2015

BIOMED KHIM

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An important role of carbonate/bicarbonate ions has been recognized in the superoxide generating reaction of adrenaline autooxidation in an alkaline buffer (a model of quinoid adrenaline oxidation in the body). It is suggested that these ions are directly involved not only in formation of superoxide anion radical (О2 -·) but also other radicals derived from the carbonate/bicarbonate buffer. Using various buffers it was shown that the rate of accumulation of adrenochrome, the end product of adrenaline oxidation, and the rate of О2 -· formation depend on concentration of carbonate/bicarbonate ions in the buffer and that these ions significantly accelerate adrenaline autooxidation thus demonstrating prooxidant properties. The detectable amount of diformazan, the product of nitro blue tetrazolium (NBT) reduction, was significantly higher than the amount of adrenochrome formed; taking into consideration the literature data on О2 -· detection by NBT it is suggested that adrenaline autooxidation is accompanied by one-electron reduction not only of oxygen dissolved in the buffer and responsible for superoxide formation but possible carbon dioxide also dissolved in the buffer as well as carbonate/bicarbonate buffer components leading to formation of corresponding radicals. The plots of the dependence of the inhibition of adrenochrome and diformazan formation on the superoxide dismutase concentration have shown that not only superoxide radicals are formed during adrenaline autooxidation. Since carbonate/bicarbonate ions are known to be universally present in the living nature, their involvement in free radical processes proceeding in the organism is discussed.

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Production of the Carbonate Radical Anion during Xanthine Oxidase Turnover in the Presence of Bicarbonate

Cited by 85 publications

References 57 publications

Direct Magnetic Resonance Evidence for Peroxymonocarbonate Involvement in the Cu,Zn-Superoxide Dismutase Peroxidase Catalytic Cycle

Direct Magnetic Resonance Evidence for Peroxymonocarbonate Involvement in the Cu,Zn-Superoxide Dismutase Peroxidase Catalytic Cycle

Experimental Studies on the Chemiluminescence Reaction Mechanism of Carbonate/Bicarbonate and Hydrogen Peroxide in the Presence of Cobalt(II)

Involvement of carbonate/bicarbonate ions in the superoxide-generating reaction of adrenaline autoxidation

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