Oxidation of added NADH by rat liver mitochondria has been studied. It is found that exogenous NADH, when oxidized by rat liver mitochondria in sucrose hypotonic medium supplemented with Mg 2+ and EGTA, generates a membrane potential (v v8 8) even in the absence of added cytochrome c. ADP and phosphate decrease v v8 8, the effect being reversed by oligomycin. Rotenone and myxothiazol do not inhibit v v8 8 generated by oxidation of exogenous NADH. Added cytochrome c increases the rate of the exogenous NADH oxidation and coupled v v8 8 formation. In sucrose isotonic medium, or in hypotonic medium without Mg 2+ , exogenous NADH fails to stimulate respiration and to form a membrane potential. In the presence of Mg 2+ , exogenous NADH appears to be effective in v v8 8 generation in isotonic sucrose medium if mitochondria were treated with digitonin. In isotonic KCl without Mg 2+ , oxidation of exogenous NADH is coupled to the v v8 8 formation and MgCl P addition before mitochondria prevents this effect. In hypotonic (but not in isotonic) sucrose medium, Mg 2+ makes a portion of the cytochrome c pool reducible by exogenous NADH or ascorbate. It is assumed that (i) hypotonic treatment or digitonin causes disruption of the outer mitochondrial membrane, and, as a consequence, desorption of the membrane-bound cytochrome c in a Mg 2+ -dependent fashion ; (ii) incubation in isotonic KCl without Mg 2+ results in swelling of mitochondrial matrix, disruption of the outer membrane and cytochrome c desorption whereas Mg 2+ lowers the K + permeability of the inner membrane and, hence, prevents swelling; (iii) desorbed cytochrome c is reduced by added NADH via NADH-cytochrome b S reductase and cytochrome b S or by ascorbate and is oxidized by cytochrome oxidase. The role of desorbed cytochrome c in oxidation of superoxide and cytoplasmic NADH as well as possible relations of these events to apoptosis are discussed.z 1998 Federation of European Biochemical Societies.
A cytochrome c mutant lacking apoptogenic function but competent in electron transfer and antioxidant activities has been constructed. To this end, mutant species of horse and yeast cytochromes c with substitutions in the N-terminal α-helix or position 72 were obtained. It was found that yeast cytochrome c was much less effective than the horse protein in activating respiration of rat liver mitoplasts deficient in endogenous cytochrome c as well as in inhibition of H2O2 production by the initial segment of the respiratory chain of intact rat heart mitochondria. The major role in the difference between the horse and yeast proteins was shown to be played by the amino acid residue in position 4 (glutamate in horse, and lysine in yeast; horse protein numbering). A mutant of the yeast cytochrome c containing K4E and some other ‘horse’ modifications in the N-terminal α-helix, proved to be (i) much more active in electron transfer and antioxidant activity than the wild-type yeast cytochrome c and (ii), like the yeast cytochrome c, inactive in caspase stimulation, even if added in 400-fold excess compared with the horse protein. Thus this mutant seems to be a good candidate for knock-in studies of the role of cytochrome c-mediated apoptosis, in contrast with the horse K72R, K72G, K72L and K72A mutant cytochromes that at low concentrations were less active in apoptosis than the wild-type, but were quite active when the concentrations were increased by a factor of 2–12.
A cytochrome c mutant lacking apoptogenic function but competent in electron transfer and antioxidant activities has been constructed. To this end, mutant species of horse and yeast cytochromes c with substitutions in the N-terminal alpha-helix or position 72 were obtained. It was found that yeast cytochrome c was much less effective than the horse protein in activating respiration of rat liver mitoplasts deficient in endogenous cytochrome c as well as in inhibition of H(2)O(2) production by the initial segment of the respiratory chain of intact rat heart mitochondria. The major role in the difference between the horse and yeast proteins was shown to be played by the amino acid residue in position 4 (glutamate in horse, and lysine in yeast; horse protein numbering). A mutant of the yeast cytochrome c containing K4E and some other "horse" modifications in the N-terminal alpha-helix, proved to be (i) much more active in electron transfer and antioxidant activity than the wild-type yeast cytochrome c and (ii), like the yeast cytochrome c, inactive in caspase stimulation, even if added in 400-fold excess compared with the horse protein. Thus this mutant seems to be a good candidate for knock-in studies of the role of cytochrome c-mediated apoptosis, in contrast with the horse K72R, K72G, K72L and K72A mutant cytochromes that at low concentrations were less active in apoptosis than the wild-type, but were quite active when the concentrations were increased by a factor of 2-12.
At low Ca2+ concentrations the pore of the inner mitochondrial membrane can open in substates with lower permeability (Hunter, D. R., and Haworth, R. A. (1979) Arch. Biochem. Biophys., 195, 468-477). Recently, we showed that Ca2+ loading of mitochondria augments the cyclosporin A-dependent decrease in transmembrane potential (DeltaPsi) across the inner mitochondrial membrane caused by 10 micro M myristic acid but does not affect the stimulation of respiration by this fatty acid. We have proposed that in our experiments the pore opened in a substate with lower permeability rather than in the "classic" state (Bodrova, M. E., et al. (2000) IUBMB Life, 50, 189-194). Here we show that under conditions lowering the probability of "classic pore" opening in Ca2+-loaded mitochondria myristic acid induces the cyclosporin A-sensitive DeltaPsi decrease and mitochondrial swelling more effectively than uncoupler SF6847 does, though their protonophoric activities are equal. In the absence of P(i) and presence of succinate and rotenone (with or without glutamate) cyclosporin A either reversed or only stopped DeltaPsi decrease induced by 5 micro M myristic acid and 5 micro M Ca2+. In the last case nigericin, when added after cyclosporin A, reversed the DeltaPsi decrease, and the following addition of EGTA produced only a weak (if any) DeltaPsi increase. In P(i)-containing medium (in the presence of glutamate and malate) cyclosporin A reversed the DeltaPsi decrease. These data show that the cyclosporin A-sensitive decrease in DeltaPsi by low concentrations of fatty acids and Ca2+ cannot be explained by specific uncoupling effect of fatty acid. We propose that: 1) low concentrations of Ca2+ and fatty acid induce the pore opening in a substate with a selective cation permeability, and the cyclosporin A-sensitive DeltaPsi decrease results from a conversion of DeltaPsi to pH gradient due to the electrogenic cation transport in mitochondria; 2) the ADP/ATP-antiporter is involved in this process; 3) higher efficiency of fatty acid compared to SF6847 in the Ca2+-dependent pore opening seems to be due to its interaction with the nucleotide-binding site of the ADP/ATP-antiporter and higher affinity of fatty acids to cations.
We show that Ca2+ loading of mitochondria substantially augments the myristate-induced decrease in the transmembrane electric potential difference (deltapsi). Such a Ca2+ action is without effect on the respiration rate and is not accompanied by the high-amplitude swelling when low concentrations of Ca2+ and myristate are used. The myristate-induced deltapsi decrease is prevented and reversed by cyclosporin A (CsA); the decrease is prevented and transiently reversed by nigericin. To explain these effects, we suggest that myristate induces opening of the mitochondrial permeability transition pore at a low-conductance state. Addition of carboxyatractylate (CAtr) after myristate induces the CsA-sensitive uncoupling, but when added after myristate and CsA, CAtr produces a decrease in deltapsi, if the interval between myristate and CsA addition is sufficiently long. The CAtr effect is completely reversed by EGTA and transiently reversed by nigericin. This suggests that the ADP/ATP-antiporter participates in the CsA-sensitive uncoupling when present as a pore complex constituent. ADP/ATP-antiporter that does not take part in the pore complex formation is involved in the CsA-insensitive uncoupling.
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