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Literature DB >> 956766

Sodium channel selectivity. Dependence on internal permeant ion concentration.

Abstract

The selectivity of sodium channels in squid axon membranes was investigated with widely varying concentrations of internal ions. The selectivity ratio, PNa/PK, determined from reversal potentials decreases from 12.8 to 5.7 to 3.5 as the concentration of internal potassium is reduced from 530 to 180 to 50 mM, respectively. The internal KF perfusion medium can be diluted by tetramethylammonium (TMA), Tris, or sucrose solutions with the same decrease in PNa/PK. The changes in the selectivity ratio depend upon internal permeant ion concentration rather than ionic strength, membrane potential, or chloride permeability. Lowering the internal concentration of cesium, rubidium, guanidnium, or ammonium also reduces PNa/Pion. The selective sequence of the sodium channel is: Na greater than guanidinium greater than ammonium greater than K greater than Rb greater than Cs.

Entities: Chemical Disease

Mesh：

Substances：
Chlorides
Sodium
Potassium

Year: 1976 PMID： 956766 PMCID： PMC2228421 DOI： 10.1085/jgp.68.2.111

Source DB: PubMed Journal: J Gen Physiol ISSN： 0022-1295 Impact factor: 4.086

17 in total

Sodium channel selectivity. Dependence on internal permeant ion concentration.

1. Kinetics and steady-state properties of the charged system controlling sodium conductance in the squid giant axon.

2. Single file diffusion.

Review 3. Chemicals as tools in the study of excitable membranes.

4. Voltage clamp experiments on internally perfused giant axons.

5. Depolarization and calcium entry in squid giant axons.

6. Ammonium ion currents in the squid giant axon.

7. Ionic selectivity, saturation, and block in sodium channels. A four-barrier model.

8. Charge movement associated with the opening and closing of the activation gates of the Na channels.

9. The permeability of the sodium channel to organic cations in myelinated nerve.

10. Destruction of sodium conductance inactivation in squid axons perfused with pronase.

1. Mechanisms of cation permeation in cardiac sodium channel: description by dynamic pore model.

2. Modeling ion permeation through batrachotoxin-modified Na+ channels from rat skeletal muscle with a multi-ion pore.

3. Mapping the importance of four factors in creating monovalent ion selectivity in biological molecules.

4. A simple model for multi-ion permeation. Single-vacancy conduction in a simple pore model.

5. The conductance and density of sodium channels in the cut-open squid giant axon.

6. Internal cesium and the sodium inactivation gate in Myxicola giant axons.

7. Interactions between quaternary lidocaine, the sodium channel gates, and tetrodotoxin.

8. Permeability, phase-boundary potential and conductance in a cholinergic channel without constant field.

9. Multiple ion binding sites in Ih channels of rod photoreceptors from tiger salamanders.

10. Voltage-dependent calcium block of normal and tetramethrin-modified single sodium channels.