Oxidative phosphorylation and respiratory control phenomenon in Paracoccus denitrificans plasma membrane.

Changes in respiratory activity, transmembrane electric potential, and ATP synthesis as induced by additions of limited amounts of ADP and P(i) to tightly coupled inverted (inside-out) Paracoccus denitrificans plasma membrane vesicles were traced. The pattern of the changes was qualitatively the same as those observed for coupled mitochondria during the classical State 4-State 3-State 4 transition. Bacterial vesicles devoid of energy-dependent permeability barriers for the substrates of oxidation and phosphorylation were used as a simple experimental model to investigate two possible mechanisms of respiratory control: (i) in State 4 phosphoryl transfer potential (ATP/ADP × P(i)) is equilibrated with proton-motive force by reversibly operating F(1)·F(o)-ATPase (thermodynamic control); (ii) in State 4 apparent "equilibrium" is reached by unidirectional operation of proton motive force-activated F(1)·F(o)-ATP synthase. The data support the kinetic mechanism of the respiratory control phenomenon.