Mapping Protein Dynamics in Catalytic Intermediates of the Redox-Driven Proton Pump Cytochrome c Oxidase

Redox-driven proton pumps such as cytochrome coxidase (CcO) are fundamental elements of the energy transduction machinery in biological systems. CcO is an integral membrane protein that acts as the terminal electron acceptor in respiratory chains of aerobic organisms, catalyzing the four-electron re...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2006-10, Vol.103 (42), p.15398-15403
Main Authors: Busenlehner, Laura S., Salomonsson, Lina, Brzezinski, Peter, Armstrong, Richard N.
Format: Article
Language:English
Subjects:
Active sites
Amides
Biochemistry
Biological Sciences
Biological Transport - physiology
Catalysis
Deuterium
Deuterium - chemistry
Deuterium - metabolism
Deuterium/chemistry/metabolism
Electron Transport Complex IV - chemistry
Electron Transport Complex IV - genetics
Electron Transport Complex IV - metabolism
Electron Transport Complex IV/chemistry/genetics/metabolism
Electrons
Genomics
Hydrogen - chemistry
Hydrogen - metabolism
Hydrogen/chemistry/metabolism
Kinetics
Mass Spectrometry
Molecular structure
Molecules
Oxidation-Reduction
Protein folding
Protein Structure, Tertiary
Protein Subunits - chemistry
Protein Subunits - genetics
Protein Subunits - metabolism
Protein Subunits/chemistry/genetics/metabolism
Protons
Pumping
Rhodobacter sphaeroides - metabolism
Solvents
Spectrum analysis
Water channels
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Summary:Redox-driven proton pumps such as cytochrome coxidase (CcO) are fundamental elements of the energy transduction machinery in biological systems. CcO is an integral membrane protein that acts as the terminal electron acceptor in respiratory chains of aerobic organisms, catalyzing the four-electron reduction of O₂ to H₂O. This reduction also requires four protons taken from the cytosolic or negative side of the membrane, with an additional uptake of four protons that are pumped across the membrane. Therefore, the proton pump must embody a "gate," which provides alternating access of protons to one or the other side of the membrane but never both sides simultaneously. However, the exact mechanism of proton translocation through CcO remains unknown at the molecular level. Understanding pump function requires knowledge of the nature and location of these structural changes that is often difficult to access with crystallography or NMR spectroscopy. In this paper, we demonstrate, with amide hydrogen/deuterium exchange MS, that transitions between catalytic intermediates in CcO are orchestrated with opening and closing of specific proton pathways, providing an alternating access for protons to the two sides of the membrane. An analysis of these results in the framework of the 3D structure of CcO indicate the spatial location of a gate, which controls the unidirectional proton flux through the enzyme and points to a mechanism by which CcO energetically couples electron transfer to proton translocation.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0601451103