Revisiting Kadenbach: Electron flux rate through cytochrome c‐oxidase determines the ATP‐inhibitory effect and subsequent production of ROS

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Abstract

Mitochondrial respiration is the predominant source of ATP. Excessive rates of electron transport cause a higher production of harmful reactive oxygen species (ROS). There are two regulatory mechanisms known. The first, according to Mitchel, is dependent on the mitochondrial membrane potential that drives ATP synthase for ATP production, and the second, the Kadenbach mechanism, is focussed on the binding of ATP to Cytochrome c Oxidase (CytOx) at high ATP/ADP ratios, which results in an allosteric conformational change to CytOx, causing inhibition. In times of stress, ATP‐dependent inhibition is switched off and the activity of CytOx is exclusively determined by the membrane potential, leading to an increase in ROS production. The second mechanism for respiratory control depends on the quantity of electron transfer to the Heme aa3 of CytOx. When ATP is bound to CytOx the enzyme is inhibited, and ROS formation is decreased, although the mitochondrial membrane potential is increased.

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High protonic potential actuates a mechanism of production of reactive oxygen species in mitochondria.

S Korshunov, V. Skulachev, A A Starkov (1997)

Formation of H2O2 has been studied in rat heart mitochondria, pretreated with H2O2 and aminotriazole to lower their antioxidant capacity. It is shown that the rate of H2O2 formation by mitochondria oxidizing 6 mM succinate is inhibited by a protonophorous uncoupler, ADP and phosphate, malonate, rotenone and myxothiazol, and is stimulated by antimycin A. The effect of ADP is abolished by carboxyatractylate and oligomycin. Addition of uncoupler after rotenone induces further inhibition of H2O2 production. Inhibition of H2O2 formation by uncoupler, malonate and ADP+Pi is shown to be proportional to the delta psi decrease by these compounds. A threshold delta psi value is found, above which a very strong increase in H2O2 production takes place. This threshold slightly exceeds the state 3 delta psi level. The data obtained are in line with the concept [Skulachev, V.P., Q. Rev. Biophys. 29 (1996), 169-2021 that a high proton motive force in state 4 is potentially dangerous for the cell due to an increase in the probability of superoxide formation.

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The whole structure of the 13-subunit oxidized cytochrome c oxidase at 2.8 A.

T Tsukihara, H Aoyama, E Yamashita … (1996)

The crystal structure of bovine heart cytochrome c oxidase at 2.8 A resolution with an R value of 19.9 percent reveals 13 subunits, each different from the other, five phosphatidyl ethanolamines, three phosphatidyl glycerols and two cholates, two hemes A, and three copper, one magnesium, and one zinc. Of 3606 amino acid residues in the dimer, 3560 have been converged to a reasonable structure by refinement. A hydrogen-bonded system, including a propionate of a heme A (heme a), part of peptide backbone, and an imidazole ligand of CuA, could provide an electron transfer pathway between CuA and heme a. Two possible proton pathways for pumping, each spanning from the matrix to the cytosolic surfaces, were identified, including hydrogen bonds, internal cavities likely to contain water molecules, and structures that could form hydrogen bonds with small possible conformational change of amino acid side chains. Possible channels for chemical protons to produce H2O, for removing the produced water, and for O2, respectively, were identified.

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Mitochondrial dysfunction in cardiac disease: ischemia--reperfusion, aging, and heart failure.

Edward Lesnefsky, Shadi Moghaddas, Bernard Tandler … (2001)

Mitochondria contribute to cardiac dysfunction and myocyte injury via a loss of metabolic capacity and by the production and release of toxic products. This article discusses aspects of mitochondrial structure and metabolism that are pertinent to the role of mitochondria in cardiac disease. Generalized mechanisms of mitochondrial-derived myocyte injury are also discussed, as are the strengths and weaknesses of experimental models used to study the contribution of mitochondria to cardiac injury. Finally, the involvement of mitochondria in the pathogenesis of specific cardiac disease states (ischemia, reperfusion, aging, ischemic preconditioning, and cardiomyopathy) is addressed. Copyright 2001 Academic Press.

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Journal ID (nlm-ta): Bioessays

Journal ID (iso-abbrev): Bioessays

Journal ID (doi): 10.1002/(ISSN)1521-1878

Journal ID (publisher-id): BIES

Title: Bioessays

Publisher: John Wiley and Sons Inc. (Hoboken )

ISSN (Print): 0265-9247

ISSN (Electronic): 1521-1878

Publication date (Electronic): 12 May 2016

Publication date (Print): June 2016

Volume: 38

Issue: 6 ( doiID: 10.1002/bies.v38.6 )

Pages: 556-567

Affiliations

[ ¹ ] Cardiovascular Research Lab, Biochemical Pharmacological Research CenterPhilipps‐University Marburg MarburgGermany

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[*] [* ] Corresponding author:

Sebastian Vogt

E‐mail: vogts@ 123456med-uni.marburg.de

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Publisher ID: BIES201600043

DOI: 10.1002/bies.201600043

PMC ID: 5084804

PubMed ID: 27171124

SO-VID: f598b401-c61f-4c2e-a64e-247ec4b64ba6

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This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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source-schema-version-number 2.0

component-id bies201600043

cover-date June 2016

details-of-publishers-convertor Converter:WILEY_ML3GV2_TO_NLMPMC version:4.9.6 mode:remove_FC converted:28.10.2016

ScienceOpen disciplines: Cell biology

Keywords: allosteric inhibition,cytochrome c oxidase,enzyme kinetics,ischaemic preconditioning,phosphodiesterase inhibitors,reactive oxygen species

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ScienceOpen disciplines: Cell biology

Keywords: allosteric inhibition, cytochrome c oxidase, enzyme kinetics, ischaemic preconditioning, phosphodiesterase inhibitors, reactive oxygen species

Revisiting Kadenbach: Electron flux rate through cytochrome c‐oxidase determines the ATP‐inhibitory effect and subsequent production of ROS

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Most cited references 111

High protonic potential actuates a mechanism of production of reactive oxygen species in mitochondria.

The whole structure of the 13-subunit oxidized cytochrome c oxidase at 2.8 A.

Mitochondrial dysfunction in cardiac disease: ischemia--reperfusion, aging, and heart failure.

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