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Literature DB >> 6280785

Delayed kinetics of squid axon potassium channels do not always superpose after time translation.

Abstract

The activation of potassium ion conductance in squid axons by voltage-clamp depolarization is delayed when the depolarizing step is preceded by a conditioning hyperpolarization of the axonal membrane. Moreover, the control conductance kinetics superpose with the delayed kinetics when they are translated along the time axis by an amount equal to the delay. We have found that the degree of superposition with internally perfused axons depends upon voltage-clamp protocol. The kinetics superpose almost exactly for modest test depolarizations, whereas they clearly fail to superpose completely for more positive levels of membrane depolarization. We have modeled these results by incorporating a time dependence into the rate constant of activation of potassium channel gates in the Hodgkin and Huxley model of potassium ionic conductance.

Entities: Chemical Disease

Mesh：

Substances：
Ion Channels
Potassium

Year: 1982 PMID： 6280785 PMCID： PMC1328854

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

8 in total

13 in total

Delayed kinetics of squid axon potassium channels do not always superpose after time translation.

1. Effect of conditioning potential on potassium current kinetics in the frog node.

2. A quantitative description of membrane current and its application to conduction and excitation in nerve.

3. Conditioning hyperpolarization-induced delays in the potassium channels of myelinated nerve.

4. The Cole-Moore effect in nodal membrane of the frog Rana ridibunda: evidence for fast and slow potassium channels.

5. Potassium ion current in the squid giant axon: dynamic characteristic.

6. Sodium ions as blocking agents and charge carriers in the potassium channel of the squid giant axon.

7. Quantitative description of sodium and potassium currents and computed action potentials in Myxicola giant axons.

8. Negative conductance caused by entry of sodium and cesium ions into the potassium channels of squid axons.

1. Quantitative analysis of sodium and potassium activation delays in fresh axons of the squid: Loligo forbesi.

2. A simple modification of the Hodgkin and Huxley equations explains type 3 excitability in squid giant axons.

3. Conditioning hyperpolarization delays in squid axon potassium channels.

4. Characterization of the pace-maker current kinetics in calf Purkinje fibres.

5. Conditioning prepulses and kinetics of potassium conductance in the frog node.

6. Relationship between membrane excitability and single channel open-close kinetics.

7. Delayed activation of the cardiac pacemaker current and its dependence on conditioning pre-hyperpolarizations.

8. Potassium channel kinetics in squid axons with elevated levels of external potassium concentration.

9. Asymmetric modulation and blockade of the delayed rectifier in squid giant axons by divalent cations.

10. Effects of N-alcohols on potassium conductance in squid giant axons.