Subunit specific antisera to the Escherichia coli ATP synthase: effects on ATPase activity, energy transduction, and enzyme assembly

We obtained antisera to each of the five subunits (α, β, γ, δ, and ?) of the F₁ portion of the proton-translocating ATPase from Escherichia coli (ECF₁). No cross-reaction between the antiserum to a given subunit and any of the other four subunits was observed by Ouchterlony immunodiffusion. The α antiserum reacted only with the denatured α chain. Antibodies to either subunit β or subunit γ inhibited the ATPase activity of the enzyme. The ATPase activity of the holoenzyme in the everted membrane vesicles was just as sensitive as purified ECF₁ to inhibition by the anti-β or anti-γ serum. A prolonged digestion of ECF₁ with trypsin removed intact γ from ECF₁, but did not alter the sensitivity of the ATPase to inhibition by the anti-γ serum. Proteolytic fragments were isolated from the trypsinized enzyme. They gave an immunoprecipitation band with the anti-γ serum, but none of the other subunit antisera. The antiδ serum detached ECF₁ from everted membrane vesicles and completely blocked both the ATP- and respiration-dependent pyridine nucleotide transhydrogenase, an energylinked membrane function. The δ antiserum had no effect on the ATPase activity of the ECF₁. The e antiserum stimulated the ATPase activity of purified ECF₁ as shown previously (P. P. Laget and J. B. Smith, Arch. Biochem. Biophys.197, 83, 1979), but strongly inhibited the holoenzyme in membrane vesicles. The α antiserum completely blocked the ATP-driven transhydrogenase. The same antiserum maximally inhibited the respiratory chain-driven reaction by only 35%. These observations indicate that the antiserum selectively affected energy transduction mediated by the ATPase. The protonmotive force generated by substrate oxidation was probably not dissipated by the ? antiserum. Adsorbing the δ or ? antiserum with everted membrane vesicles selectively removed those antibodies that reacted with membrane-bound ATPase. The adsorbed sera still reacted strongly with purified ECF₁, and prevented it from restoring ATP-dependent proton translocation in ECF₁-depleted vesicles. Therefore, it appears that more of the δ and the ? subunit is exposed in the purified ECF₁ molecule than in the membrane-bound enzyme.