Difference between revisions of "Mitchell 1967 Nature"
(Created page with "{{Publication |title=Mitchell P (1967) Proton current flow in mitochondrial systems. Nature 214:1327β8. |info=https://www.nature.com/articles/2141327a0 |authors=Mitchell P |...") Β |
|||
| Line 12: | Line 12: | ||
|preparations=Isolated mitochondria | |preparations=Isolated mitochondria | ||
|topics=pH | |topics=pH | ||
|additional=BEC 2020.2 | |||
}} | }} | ||
Revision as of 01:18, 2 January 2021
| Mitchell P (1967) Proton current flow in mitochondrial systems. Nature 214:1327β8. |
Β» https://www.nature.com/articles/2141327a0
Mitchell P (1967) Nature
Abstract: Following recent publications in Nature on hydrogen ion concentrations and flows in mitochondria [1β5], Baum [6] (see preceding communication) has aptly drawn attention to the fact that the chemiosmotic hypothesis does not require a significant pH-difference across the mitochondrial membrane system [7]. In the original outline of the hypothesis [8] it was shown that the major component of the protonmotive force (p.m.f.) should be a membrane potential. Admitting therefore that the experimental facts may be consistent with the driving of adenosine triphosphate (ATP) synthesis by a proton current that flows through the reversible ATPase system in the cristae membrane under a mainly electrical p.m.f., Baum [6] has asked how the very small number of free protons in the inner aqueous phase of a mitochondrion or sub-mitochondrial particle can permit the flow of an effective proton current, and whether there may not be special energetic obstacles to proton translocation in such small systems.
β’ Bioblast editor: Gnaiger E
Labels: MiParea: Respiration
Preparation: Isolated mitochondria
Regulation: pH
BEC 2020.2
