4. ATP-synthesis rotatory catalysis by F-ATPase: Real-time recording of intersubunit rotation
Autor(en): | Junge, W. Sabbert, D. Engeibrecht, S. |
Stichwörter: | Biophysical chemistry; Catalysis; Diffusion; Molecular structure; Protein dynamics (molecular dynamics) | Erscheinungsdatum: | 1996 | Journal: | Berichte der Bunsengesellschaft/Physical Chemistry Chemical Physics | Volumen: | 100 | Ausgabe: | 12 | Startseite: | 2014 | Seitenende: | 2019 | Zusammenfassung: | ATP synthase (F-ATPase) is an ubiquitous enzyme in photosynthesis and respiration of prokaryotic and eukaryotic organisms. It couples proton translocation through its membrane portion, F0, to the synthesis of the "energy carrier molecule" ATP at the peripheral portion, F, [1]. Three cooperative reaction sites are distributed with trigonal symmetry over the hexagonal array of (αβ)3 in F1 [2, 3]. It has been proposed that the endergonic release of spontaneously formed ATP [4, 5] might involve mechanical energy transduction [6, 7] through the proton driven rotation of subunit γ within (αβ)3 [2, 8, 9]. We recorded the putative intersubunit rotation in real time [10]. Applying polarized absorption relaxation after photobleaching (PARAP) to immobilized F, with eosinlabeled γ, we observed the rotational motion of γ relative to immobilized (γ β)3 in the lime range of 100 ms, compatible with the rate of ATP hydrolysis by immobilized F,. Its angular domain of at least 200 degrees favours a rotatory tri-site mechanism of catalysis with γ acting as a crankshaft in the center of (αβ)3. © VCH yerlagsgeseHschaft mbH, 1996. |
ISSN: | 0940483X | Externe URL: | https://www.scopus.com/inward/record.uri?eid=2-s2.0-0000651633&partnerID=40&md5=d4fbfa69597415fd7c2746048010c269 |
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