Journal
BIOCHEMICAL JOURNAL
Volume 430, Issue -, Pages 171-177Publisher
PORTLAND PRESS LTD
DOI: 10.1042/BJ20100621
Keywords
ATPase; F0F1-ATP synthase; ion transport; proton channel; proton permeation
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Funding
- Ministry of Education, Culture, Sports, Science, and Technology of Japan [18107004, 19042006, 19770103]
- Grants-in-Aid for Scientific Research [19770103, 19042006, 18107004] Funding Source: KAKEN
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In F0F1 (F0F1-ATP synthase), proton translocation through F drives rotation of the oligomer ring of F-0-c subunits (c-ring) relative to F-0-a. Previous reports have indicated that a conserved arginine residue in F-0-a plays a critical role in the proton transfer at the F-0-a/c-ring interface. Indeed, we show in the present study that thermophilic F(0)F(1)s with substitution of this arginine (aR169) to other residues cannot catalyse protoncoupled reactions. However, mutants with substitution of this arginine residue by a small (glycine, alanine, valine) or acidic (glutamate) residue mediate the passive proton translocation. This translocation requires an essential carboxy group of F-0-c (cE56) since the second mutation (cE56Q) blocks the translocation. Rotation of the c-ring is not necessary because the same arginine mutants of the 'rotation-impossible' (c(10)-a)F0F1, in which the c-ring and F-0-a are fused to a single polypeptide, also exhibits the passive proton translocation. The mutant (aR169G/Q217R), in which the arginine residue is transferred to putatively the same topological position in the F-0-a structure, can block the passive proton translocation. Thus the conserved arginine residue in F-0-a ensures proton-coupled c-ring rotation by preventing a futile proton shortcut.
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