ATP synthesis by ATPase proteoliposomes from the thermophilic cyanobacterium Synechococcus 6716 by ionophore-induced electric potentials and proton gradients

Abstract

ATP synthesis driven by low pre-established electric potentials and pH gradients is studied in large ATPase proteoliposomes, prepared from the ATPase complex and native lipids from the thermophilic cyanobacterium Synechococcus 6716. Electric potentials and pH gradients were achieved by valinomycin and nigericin, respectively, in the presence of a K + gradient across the membrane. External base-pulses were also applied. In this system ATP synthesis driven by valinomycin-induced K + influx, nigericin-induced internal acidification and by external base-pulses is demonstrated. Electric potentials and pH gradients of equivalent size lead to roughly similar ATP synthesis activities. ATP synthesis is optimal at 80–100 nM valinomycin and at 0.75−1 μM nigericin at the proper pre-set ion gradients. Uncoupler and DCCD inhibit ATP synthesis. Prior activation of the complex by thiol agents or trypsin was not required for synthesis activity. The ATP synthesis rate increases with the size of electric potential or pH gradient. The threshold value of the electrochemical gradient for significant ATP synthesis is about 30 mV. ATP production proceeds for more than 60 min. The generation of ionophore-induced electric potentials and pH gradients have been followed by oxonol VI and intraliposomal Neutral red, respectively. The extent of the absorbance changes of both probes is proportional to the size of electric potential or pH gradient. Ionophore-induced oxonol VI and Neutral red responses are stable for at least 30 min. The results are discussed in terms of membrane permeability and vesicle size.