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Literature DB >> 2836858

Coupling of vectorial proton flow to a biochemical reaction by local electric interactions.

Abstract

For a transmembrane redox enzyme and a (passive) protonophore, the complete set of rate equations is given. Turnover causes cyclic variation of their electric polarization. This is responsible not only for effects of the electric field on the rate constants but also for the generation of an electric field felt by neighboring molecules. It is calculated that, when the systems are close together at a fixed distance, cycling of the two systems becomes coupled enabling the protonophore to pump protons against their electrochemical gradient. If the electrochemical gradient for protons approaches the input force of the redox reaction, slip (incomplete coupling between the chemical and proton-transport reactions) results. By using different sets of parameters, both kinetically reversible and kinetically irreversible proton pumps can be simulated.

Mesh：

Substances：
Membrane Proteins
Protons

Year: 1988 PMID： 2836858 PMCID： PMC280305 DOI： 10.1073/pnas.85.11.3792

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

13 in total

Review 5. Conformational coupling in H+-pumps and ATP synthesis--its analysis with anisotropic inhibitors of energy transduction in oxidative phosphorylation.

Authors: T Higuti
Journal: Mol Cell Biochem Date: 1984 Impact factor: 3.396

6. The stoichiometry of proton translocation through H+-ATPase of rat-liver mitochondria.

Authors: K F Sholtz; I A Gorskaya; A V Kotelnikova
Journal: Eur J Biochem Date: 1983-10-17

7. Flow-force relationships for a six-state proton pump model: intrinsic uncoupling, kinetic equivalence of input and output forces, and domain of approximate linearity.

Authors: D Pietrobon; S R Caplan
Journal: Biochemistry Date: 1985-10-08 Impact factor: 3.162

Coupling of vectorial proton flow to a biochemical reaction by local electric interactions.

1. Can free energy be transduced from electric noise?

2. How enzymes can capture and transmit free energy from an oscillating electric field.

3. Variation of efficiency with free-energy dissipation in models of biological energy transduction.

Review 4. The generation of the proton electrochemical potential and its role in energy transduction.

Review 5. Conformational coupling in H+-pumps and ATP synthesis--its analysis with anisotropic inhibitors of energy transduction in oxidative phosphorylation.

6. The stoichiometry of proton translocation through H+-ATPase of rat-liver mitochondria.

7. Flow-force relationships for a six-state proton pump model: intrinsic uncoupling, kinetic equivalence of input and output forces, and domain of approximate linearity.

8. The localized delta muH+ problem. The possible role of the local electric field in ATP synthesis.

9. Effect of funiculosin and antimycin A on the redox-driven H+-pumps in mitochondria: on the nature of "leaks'.

10. Energetics of the calcium-transporting ATPase.

1. How yeast cells synchronize their glycolytic oscillations: a perturbation analytic treatment.

2. Redox interactions in cytochrome c oxidase: from the "neoclassical" toward "modern" models.

3. Stochastically pumped adaptation and directional motion of molecular machines.

4. Mechanochemical coupling of the motion of molecular motors to ATP hydrolysis.