The second stalk composed of the b- and delta-subunits connects F0 to F1 via an alpha-subunit in the Escherichia coli ATP synthase.

The b- and delta-subunits of the Escherichia coli ATP synthase are critical for binding ECF1 to the F0 part, and appear to constitute the stator necessary for holding the alpha3beta3 hexamer as the c-epsilon-gamma domain rotates during catalysis. Previous studies have determined that the b-subunits are dimeric for a large part of their length, and interact with the F1 part through the delta-subunit (Rodgers, A. J. W., Wilkens, S., Aggeler, R., Morris, M. B., Howitt, S. M., and Capaldi, R. A. (1997) J. Biol. Chem. 272, 31058-31064). To further study b-subunit interactions, three mutants were constructed in which Ser-84, Ala-144, and Leu-156, respectively, were replaced by Cys. Treatment of purified ECF1F0 from all three mutants with CuCl2 induced disulfide formation resulting in b-subunit dimer cross-link products. In addition, the mutant bL156C formed a cross-link from a b-subunit to an alpha-subunit via alphaCys90. Neither b-b nor b-alpha cross-linking had significant effect on ATPase activities in any of the mutants. Proton pumping activities were measured in inner membranes from the three mutants. Dimerization of the b-subunit did not effect proton pumping in mutants bS84C or bA144C. In the mutant bL156C, CuCl2 treatment reduced proton pumping markedly, probably because of uncoupling caused by the b-alpha cross-link formation. The results show that the alpha-subunit forms part of the binding site on ECF1 for the b2delta domain and that the b-subunit extends all the way from the membrane to the top of the F1 structure. Some conformational flexibility in the connection between the second stalk and F1 appears to be required for coupled catalysis.