Transduction of enzyme-ligand binding energy into catalytic driving force

We propose a testable general mechanism by which ligand binding energy can be used to drive a catalytic step in an enzyme catalyzed reaction or to do other forms of work involving protein molecules. This energy transduction theory is based on our finding of the widespread occurrence of ligand bindin...

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Bibliographic Details
Published in:FEBS letters 1991-12, Vol.294 (1), p.1-5
Main Authors: Fisher, Harvey F., Singh, Narinder
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
Calorimetry
Catalysis
Energy transduction
Enzymatic catalysis
Enzymes - metabolism
Fundamental and applied biological sciences. Psychology
Glutamate Dehydrogenase - metabolism
Interaction parameter
Kinetics
Ligands
Liver - enzymology
Mechanisms. Catalysis. Electron transfer. Models
Models, Theoretical
Molecular biophysics
Molecular machine
Physical chemistry in biology
Protein Binding
Thermodynamics
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Summary:We propose a testable general mechanism by which ligand binding energy can be used to drive a catalytic step in an enzyme catalyzed reaction or to do other forms of work involving protein molecules. This energy transduction theory is based on our finding of the widespread occurrence of ligand binding-induced protein macrostate interconversions each having a large invariant Δ H° accompanied by a small but highly variable Δ G°. This phenomenon, which can be recognized by the large Δ Cp°'s it generates, can provide the necessary energy input step but is not in itself sufficient to constitute a workable transduction mechanism. A viable mechanism requires the additional presence of an ‘energy transmission step’ which is terminated to trigger the ‘power’ stroke at a precise location on the reaction coordinate, followed by an energetically inexpensive ‘return’ step to restore the machine to its initial conditions. In the model we propose here, these additional steps are provided by the existence of ligand inducible 2-state transitions in the free enzyme and in each of the enzyme complexes that occur along the reaction coordinate, and by the selective blocking of certain of these interconversions by high energetic barriers. We provide direct experimental evidence supporting the facts that these additional mechanistic components do exist and that the liver glutamate dehydrogenase reaction is indeed driven by just such machinery. We describe some aspects of the chemical nature of these transitions, and evidence for their occurrence in other systems.
ISSN:0014-5793
1873-3468
DOI:10.1016/0014-5793(91)81329-7