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Literature DB >> 2437974

Why is gramicidin valence selective? A theoretical study.

Abstract

Calculations contrasting the channel solvation energy for cesium ions and chloride ions associated with water in gramicidin-like channels are presented. The energy profile for the cation exhibits a deep well at the channel entrance; within the single file region the solvation energy is roughly constant. The anion exhibits a totally different energy profile. There is an energy barrier at the channel entrance; if the ion could surmount this barrier, it would be quite stable within the channel. At the channel entrance, the calculated solvation energy difference between anion and cation is approximately 15 kcal mol-1. This is completely consistent with the observation that chloride neither permeates nor blocks the channel since the estimated rate of ion entry would be approximately 0.01-10(-5) s-1, far slower than the rate at which the channel dimer dissociates into monomers.

Entities: Chemical

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Year: 1987 PMID： 2437974 PMCID： PMC1329938 DOI： 10.1016/S0006-3495(87)83391-X

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

23 in total

1. Ionic selectivity of Na and K channels of nerve membranes.

Authors: B Hille
Journal: Membranes Date: 1975

2. The gramicidin A transmembrane channel: a proposed pi(L,D) helix.

Authors: D W Urry
Journal: Proc Natl Acad Sci U S A Date: 1971-03 Impact factor: 11.205

3. Ion movements in gramicidin pores. An example of single-file transport.

Authors: B W Urban; S B Hladky; D A Haydon
Journal: Biochim Biophys Acta Date: 1980-11-04

4. Gramicidin A crystals contain two cation binding sites per channel.

Authors: R E Koeppe; J M Berg; K O Hodgson; L Stryer
Journal: Nature Date: 1979-06-21 Impact factor: 49.962

5. Helical channels in crystals of gramicidin A and of a cesium--gramicidin A complex: an x-ray diffraction study.

Authors: R E Koeppe; K O Hodgson; L Stryer
Journal: J Mol Biol Date: 1978-05-05 Impact factor: 5.469

6. Voltage-induced thickness changes of lipid bilayer membranes and the effect of an electrin field on gramicidin A channel formation.

Authors: E Bamberg; R Benz
Journal: Biochim Biophys Acta Date: 1976-03-19

7. Number of water molecules coupled to the transport of sodium, potassium and hydrogen ions via gramicidin, nonactin or valinomycin.

Authors: D G Levitt; S R Elias; J M Hautman
Journal: Biochim Biophys Acta Date: 1978-09-22

8. Influence of membrane thickness and ion concentration on the properties of the gramicidin a channel. Autocorrelation, spectral power density, relaxation and single-channel studies.

Authors: H A Kolb; E Bamberg
Journal: Biochim Biophys Acta Date: 1977-01-04

3. Effective pore radius of the gramicidin channel. Electrostatic energies of ions calculated by a three-dielectric model.

Authors: H Monoi
Journal: Biophys J Date: 1991-04 Impact factor: 4.033

Review 4. Structure and function of channels and channelogs as studied by computational chemistry.

Authors: G Eisenman; O Alvarez
Journal: J Membr Biol Date: 1991-01 Impact factor: 1.843

5. Electrostatic modeling of dipole-ion interactions in gramicidinlike channels.

Authors: M Sancho; G Martínez
Journal: Biophys J Date: 1991-07 Impact factor: 4.033

6. A semi-microscopic Monte Carlo study of permeation energetics in a gramicidin-like channel: the origin of cation selectivity.

Authors: V Dorman; M B Partenskii; P C Jordan
Journal: Biophys J Date: 1996-01 Impact factor: 4.033

Why is gramicidin valence selective? A theoretical study.

1. Ionic selectivity of Na and K channels of nerve membranes.

2. The gramicidin A transmembrane channel: a proposed pi(L,D) helix.

3. Ion movements in gramicidin pores. An example of single-file transport.

4. Gramicidin A crystals contain two cation binding sites per channel.

5. Helical channels in crystals of gramicidin A and of a cesium--gramicidin A complex: an x-ray diffraction study.

6. Voltage-induced thickness changes of lipid bilayer membranes and the effect of an electrin field on gramicidin A channel formation.

7. Number of water molecules coupled to the transport of sodium, potassium and hydrogen ions via gramicidin, nonactin or valinomycin.

8. Influence of membrane thickness and ion concentration on the properties of the gramicidin a channel. Autocorrelation, spectral power density, relaxation and single-channel studies.

9. Interaction of ions and water in gramicidin A channels: streaming potentials across lipid bilayer membranes.

10. Water permeability of gramicidin A-treated lipid bilayer membranes.

1. Continuum electrostatics fails to describe ion permeation in the gramicidin channel.

2. Molecular dynamics computations and solid state nuclear magnetic resonance of the gramicidin cation channel.

3. Effective pore radius of the gramicidin channel. Electrostatic energies of ions calculated by a three-dielectric model.

Review 4. Structure and function of channels and channelogs as studied by computational chemistry.

5. Electrostatic modeling of dipole-ion interactions in gramicidinlike channels.

6. A semi-microscopic Monte Carlo study of permeation energetics in a gramicidin-like channel: the origin of cation selectivity.

7. The normal modes of the gramicidin-A dimer channel.

8. Energetics of ion permeation through membrane channels. Solvation of Na+ by gramicidin A.

9. Theoretical study of the antiparallel double-stranded helical dimer of gramicidin as an ion channel.

10. Valence selectivity of the gramicidin channel: a molecular dynamics free energy perturbation study.