Abstract
The gamma subunit of the F1 portion of the chloroplast ATP synthase contains a critically placed dithiol that provides a redox switch converting the enzyme from a latent to an active ATPase. The switch prevents depletion of intracellular ATP pools in the dark when photophosphorylation is inactive. The dithiol is located in a special regulatory segment of about 40 amino acids that is absent from the gamma subunits of the eubacterial and mitochondrial enzymes. Site-directed mutagenesis was used to probe the relationship between the structure of the gamma regulatory segment and its function in ATPase regulation via its interaction with the inhibitory epsilon subunit. Mutations were designed using a homology model of the chloroplast gamma subunit based on the analogous structures of the bacterial and mitochondrial homologues. The mutations included (a) substituting both of the disulfide-forming cysteines (Cys199 and Cys205) for alanines, (b) deleting nine residues containing the dithiol, (c) deleting the region distal to the dithiol (residues 224-240), and (d) deleting the entire segment between residues 196 and 241 with the exception of a small spacer element, and (e) deleting pieces from a small loop segment predicted by the model to interact with the dithiol domain. Deletions within the dithiol domain and within parts of the loop segment resulted in loss of redox control of the ATPase activity of the F1 enzyme. Deleting the distal segment, the whole regulatory domain, or parts of the loop segment had the additional effect of reducing the maximum extent of inhibition obtained upon adding the epsilon subunit but did not abolish epsilon binding. The results suggest a mechanism by which the gamma and epsilon subunits interact with each other to induce the latent state of the enzyme.
Highlights
Is composed of an integral membrane-spanning Hϩ-translocating segment (FO or factor O) and a peripheral membrane segment (F1 or factor 1), which contains the catalytic sites for ATP synthesis and hydrolysis
In this study we have utilized this system to examine mutant ␥ subunits with structural changes within the dithiolcontaining regulatory domain and within an additional loop segment predicted by modeling studies to interact directly with the dithiol domain
The results identify potential structural requirements for dithiol regulation and provide new insight into how the ⑀ subunit simultaneously couples proton movement to ␥ rotation and ATP synthesis while blocking the reverse reaction driven by ATP hydrolysis
Summary
Materials—CF1 and CF1 deficient in the ␦ and ⑀ subunits, CF1(-␦⑀), were prepared from fresh market spinach as described previously [6, 25] and stored as ammonium sulfate precipitates. Production and Assembly of ␥ and ⑀ Subunits—The atpG and atpE genes encoding the full-length ␥ and ⑀ subunits, respectively, were cloned into pET expression vectors as described previously [27,28,29], and the constructs were used to transform Escherichia coli BL21 host cells for overexpression of the ␥ and ⑀ proteins. A fourth mutant with the entire region between residues 196 and 241 deleted (␥⌬197–240) was constructed using the forward primer: 5Ј-pATG ATG TAC TAA TTC GAA CAA GAT (bases ϩ715 to ϩ739 with respect to the atpG coding sequence) and the reverse primer: 5Ј-pTT CGG CGG ATC CTT TTA CTT CTT C (bases ϩ572 to ϩ596 with respect to the atpG coding sequence) In this mutant 114 bp (38 amino acid residues) were deleted relative to the wild-type ␥ template and at the same time ␥Glu197-Ile198-Cys199 and Pro239-Ile240-Leu241 were mutated to Ser197-Ala198-Glu199 and Met239-Ser240-Tyr241, respectively. Gel electrophoresis was performed under reducing conditions on pre-cast NuPage (Invitrogen) gels (4 –20% acrylamide gradient)
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