Review
doi: 10.1016/j.bpj.2014.03.039.
Permeation redux: thermodynamics and kinetics of ion movement through potassium channels
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- PMID: 24806917
- PMCID: PMC4017269
- DOI: 10.1016/j.bpj.2014.03.039
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Review
Permeation redux: thermodynamics and kinetics of ion movement through potassium channels
Biophys J.
.
Abstract
The fundamental biophysics underlying the selective movement of ions through ion channels was launched by George Eisenman in the 1960s, using glass electrodes. This minireview examines the insights from these early studies and the explosive progress made since then.
Copyright © 2014 Biophysical Society. Published by Elsevier Inc. All rights reserved.
Figures
Structural models used in theoretical studies of ion selectivity. (A) Simple model used to introduce the concept of field strength leading to 11 cationic selectivity sequences (2,5,6). Ions, water, and ligands are represented by simple hard-spheres with embedded point charges. Selectivity arises from the difference in the interaction energy of the cation with a water molecule (top) and an anionic coordinating ligand (bottom). (B) Ion-selective transfer process is depicted with atomic models incorporating all molecular details in the case of solvation in liquid water (top) and binding to the K+-selective ionophore valinomycin (bottom). Such atomic models were used to carry out some of the earliest MD free energy simulations on ion binding selectivity (12,13,15).
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References
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- Eisenman, G., and S. Krasne. 1973. Further considerations on the ion selectivity of carrier molecules and membranes. In IV International Biophysics Congress Symposium on Membrane Structure and Function, Moscow, Russia.
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