Azide inhibition of mitochondrial electron transport I. The aerobic steady state of succinate oxidation

The azide inhibition of the succinate oxidase activity of rat-liver mitochondria is specific for active (State 3) respiration with no observable inhibition of resting (State 4) respiration. In the range of azide concentrations which inhibit State 3 to rates less than those of State 4, a negative control of respiration by ADP and inorganic phosphate is observed. The inhibition is specific for a site between cytochromes a and a₃, causing a crossover between these two cytochromes with cytochrome a becoming reduced and cytochrome a₃ remaining highly oxidized. Trapped steady-state difference spectra at liquid nitrogen temperatures show that the reduced cytochrome a in the azide-inhibited system has an band at 596 mμ, 6 m μ displaced from its usual position at 602 mμ.

The azide inhibition is released by uncouplers of oxidative phosphorylation such that the uncoupled respiration requires up to ten times as much azide as does coupled (State 3) respiration for comparable inhibition. The release of inhibition by uncouplers occurs with no change in the steady-state concentration of reduced cytochrome a₅₉₆ and the increased respiration is attributed to an increased rate of oxidation of the cytochrome a₅₉₆. This cytochrome is postulated to be either an intermediate in electron transport and energy conservation reactions or an azide compound of such an intermediate.