vitamin-k-semiquinone-radical and malic-acid

Inside-out subcellular vesicles of Azotobacter vinelandii are found to produce delta pH and delta psi (interior acidic and positive) when oxidising malate or menadiol. These effects are inherent in both Cyd+ Cyo- (lacking the o-type oxidase) and Cyd- Cyo+ (lacking the bd-type oxidase) strains. They appear to be myxothiazol-sensitive in the Cyd- Cyo+ strain but not in the Cyd+ Cyo- strain. The H+/e- ratio for the terminal part of respiratory chain of a bd-type oxidase overproducing strain is established as being close to 1. It is also shown that NADH oxidation by the vesicles from the Cyd- Cyo+ strain is sensitive to low concentrations of myxothiazol and antimycin A whereas that of the Cyd+ Cyo- strain is resistant to these Q-cycle inhibitors. It is concluded that (i) the bd-type oxidase of A. vinelandii is competent in generating a protonic potential but its efficiency is lower than that of the o-type oxidase and (ii) Q-cycle does operate in the o-type cytochrome oxidase terminated branch of the A. vinelandii respiratory chain and does not in the bd-type quinol oxidase terminated branch. These relationships are discussed in the context of the respiratory protection function of the bd-type oxidase in A. vinelandii.

Topics: Anaerobiosis; Azotobacter vinelandii; Carbonyl Cyanide m-Chlorophenyl Hydrazone; Cell Fractionation; Cytochrome b Group; Cytochromes; Electron Transport Chain Complex Proteins; Escherichia coli Proteins; Hydrogen-Ion Concentration; Kinetics; Malates; Methacrylates; Oxidoreductases; Subcellular Fractions; Thiazoles; Valinomycin; Vitamin K

Based on the inhibitor analysis data, it has been assumed that the Q-cycle plays a role in the cyano-resistant malate oxidation induced by menadione (90 microM) in rat liver mitochondria. The extent of involvement of Q-cycle transmitters in the cyano-resistant respiration of mitochondria is determined by the mode of the electron supply into the Q-cycle. In the presence of dicumarol, i.e., under conditions when CoQ and menadione are reduced by NADH-quinone reductase, the bulk of the electrons pass through the o-center of the Q-cycle. Myxothiazole inhibits the respiration by 70-80%, while antimycin--by only 20-30%. In the presence of myxothiazole and antimycin menadione oxidizes cytochrome b. In the presence of rotenone, when menadione is reduced by DT-diaphorase, the rate of cyano-resistant respiration decreases approximately twofold; its sensitivity towards myxothiazole and antimycin drops down to 40%. In the absence of rotenone and dicumarol the Q-cycle does not participate in the cyano-resistant respiration which under these conditions is insensitive either to myxothiazole or to antimycin. It is concluded that the mechanism of cyano-resistant respiration changes with an alteration in the rates of quinones K3 and CoQ reduction. The mechanism of cyano-resistant respiration is also controlled by the medium tonicity. A reduction in the medium tonicity decrease the participation of the Q-cycle and, correspondingly, the sensitivity of the cyano-resistant respiration towards myxothiazole and antimycin.

Topics: Animals; Antimycin A; Cyanides; Electron Transport; Malates; Methacrylates; Mitochondria, Liver; NAD(P)H Dehydrogenase (Quinone); Oxidation-Reduction; Rats; Rotenone; Thiazoles; Ubiquinone; Vitamin K