Abstract
A role in coupling proton transport to catalysis of ATP synthesis has been demonstrated for the Escherichia coli F0F1 ATP synthase gamma subunit. Previously, functional interactions between the terminal regions that were important for coupling were shown by finding several mutations in the carboxyl-terminal region of the gamma subunit (involving residues at positions 242 and 269-280) that restored efficient coupling to the mutation, gamma Met-23-->Lys (Nakamoto, R. K., Maeda, M., and Futai, M. (1993) J. Biol. Chem. 268, 867-872). In this study, we used suppressor mutagenesis to establish that the terminal regions can be separated into three interacting segments. Second-site mutations that cause pseudo reversion of the primary mutations, gamma Gln-269-->Glu or gamma Thr-273-->Val, map to an amino-terminal segment with changes at residues 18, 34, and 35, and to a segment near the carboxyl terminus with changes at residues 236, 238, 242, and 246. Each second-site mutation suppressed the effects of both gamma Gln-269-->Glu and gamma Thr-273-->Val, and restored efficient coupling to enzyme complexes containing either of the primary mutations. Mapping of these residues in the recently reported x-ray crystallographic structure of the F1 complex (Abrahams, J. P., Leslie, A. G., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628), reveals that the second-site mutations do not directly interact with gamma Gln-269 and gamma Thr-273 and that the effect of suppression occurs at a distance. We propose that the three gamma subunit segments defined by suppressor mutagenesis, residues gamma 18-35, gamma 236-246, and gamma 269-280, constitute a domain that is critical for both catalytic function and energy coupling.
Highlights
A role in coupling proton transport to catalysis ofATP synthesis has been demonstrated for the Escherichia coli Fof1 ATP synthase'}' subunit
We propose that the three'}' subunit segments defined by suppressor mutagenesis, residues '}'18-35, '}'236-246, and '}'269-280, constitute a domain that is critical for both catalytic function and energy coupling
In the Fof1 ATP synthase, energy coupling between proton transport and catalysis of ATP synthesis occurs via conformational changes transmitted through a complex made up of at least eight different subunits
Summary
Vol 270, No 23, Issue of June 9, pp. 14042-14046, 1995 Printed in U.S.A. SUPPRESSOR MUTAGENESIS REVEALS THREE HELICAL REGIONS INVOLVED IN ENERGY COUPLING*. Functional interactions between terminal regions were realized by identification of several second-site mutations near the carboxyl terminus that restored efficient coupling to the 'YMet-23 ~ Lys mutant [19]. Two such second-site mutations were the replacements, yGln-269 ~ Arg and yThr-273 ~ Ser, Other replacements of these two conserved residues invariably caused reduced turnover and coupling efficiency [20]; the most severe mutations were yGln-269 ~ GIu and yThr-273 ~ Val. In this paper, we describe the identification of several intragenic second-site mutations that suppress yGln-269 ~ Glu and yThr-273 ~ Val. Taken together, the suppressor mutations reveal three 'Y subunit regions that functionally interact to mediate energy coupling
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