Mitochondria as an energy generating cell device are very sensitive to oxidative damage. Our previous findings obtained in hepatocytes demonstrated that Complex I of the respiratory chain is more sensitive to oxidative damage than other respiratory chain complexes. We present additional data on isolated mitochondria showing that palmityl carnitine oxidation is strongly depressed at a low (200 μM) tert-butyl hydroperoxide (tBHP) concentration, while oxidation of the flavoprotein-dependent substrate - succinate is not affected and neither is ATP synthesis inhibited by tBHP. In the presence of tBHP, the respiratory control index for palmityl carnitine oxidation is strongly depressed, but when succinate is oxidized the respiratory control index remains unaffected. Our findings thus indicate that flavoprotein-dependent substrates could be an important nutritional factor for the regeneration process in the necrotic liver damaged by oxidative stress., Z. Červinková, H. Rauchová, P. Křiváková, Z. Drahota., and Obsahuje bibliografii a bibliografické odkazy
By determining the calcium retention capacity (CRC) of rat liver
mitochondria, we confirmed and extended previous observations
describing the activation of mitochondrial swelling by phosphate
and tert-butyl hydroperoxide (t-BHP). Using CRC measurements,
we showed that both phosphate and t-BHP decrease the extent
of calcium accumulation required for the full mitochondrial
permeability transition pore (MPTP) opening to 35 % of control
values and to only 15 % when both phosphate and t-BHP are
present in the medium. When changes in fluorescence were
evaluated at higher resolution, we observed that in the presence
of cyclosporine A fluorescence values return after each
Ca2+ addition to basal values obtained before the Ca2+ addition.
This indicates that the MPTP remains closed. However, in the
absence of cyclosporine A, the basal fluorescence after each
Ca2+ addition continuously increased. This increase was
potentiated both by phosphate and t-BHP until the moment when
the concentration of intramitochondrial calcium required for the
full opening of the MPTP was reached. We conclude that in the
absence of cyclosporine A, the MPTP is slowly opened after each
Ca2+ addition and that this rate of opening can be modified by
various factors such as the composition of the media and the
experimental protocol used.
The concentration-dependence of tert-butyl hydroperoxide (BHP) inhibitory effect on oxygen consumption in isolated rat liver mitochondria was measured in the presence of various respiratory substrates. Strong inhibitory effect at low concentrations of BHP (15-30 μM) was found for oxoglutarate and palmitoyl carnitine oxidation. Pyruvate and glutamate oxidation was inhibited at higher concentrations of BHP (100-200 μM). Succinate oxidation was not affected even at 3.3 mM BHP. Determination of mitochondrial membrane potential has shown that in the presence of NADH-dependent substrates the membrane potential was dissipated by BHP but was completely restored after addition of succinate. Our data thus indicate that beside peroxidative damage of complex I also various mitochondrial NADH-dependent dehydrogenases are inhibited, but to a different extent and with different kinetics. Our data also show that succinate could be an important nutritional substrate protecting hepatocytes during peroxidative damage., R. Endlicher ... [et al.]., and Obsahuje seznam literatury
Sensitivity of various mitochondrial enzymes to oxidative damage was tested on isolated rat liver hepatocytes
permeabilized by digitonin. In permeabilized hepatocytes
normal respiratory control
values were obtained and
mitochondrial membranes remained intact. Respiratory rate
s of NADH-dependent (glutamate+malate, palmitylcarnitine
+ malate) and flavoprotein-dependent (succinate) substrates were determined in hepatocytes exposed for 5 min to
0.5-3 mM
tert
-butyl hydroperoxide before addition of digitonin.
Our data showed that oxidation of NADH-dependent
substrates is much more sensitive to oxidative stress than ox
idation of flavoprotein-dependent ones, evidently due to the
modification of iron-sulfur clusters or SH groups in the NADH dehydrogenase enzyme complex (Complex I).