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Literature DB >> 1714303

Diffusion model in ion channel gating. Extension to agonist-activated ion channels.

R E Oswald¹, G L Millhauser, A A Carter.

Abstract

Previously, we described a model which treats ion channel gating as a discrete diffusion problem. In the case of agonist-activated channels at high agonist concentration, the model predicts that the closed lifetime probability density function from single channel recording approximates a power law with an exponent of -3/2 (Millhauser, G. L., E. E. Salpeter, and R. E. Oswald. 1988a. Proc. Natl. Acad. Sci. USA. 85: 1503-1507). This prediction is consistent with distributions derived from a number of ligand-gated channels at high agonist concentration (Millhauser, G. L., E. E. Salpeter, and R. E. Oswald. 1988b. Biophys. J. 54: 1165-1168.) but does not describe the behavior of ion channels at low activator concentrations. We examine here an extension of this model to include an agonist binding step. This extended model is consistent with the closed time distributions generated from the BC3H-1 nicotinic acetylcholine receptor for agonist concentrations varying over three orders of magnitude.

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Year: 1991 PMID： 1714303 PMCID： PMC1281348 DOI： 10.1016/S0006-3495(91)82328-1

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

34 in total

1. Statistical methods for model discrimination. Applications to gating kinetics and permeation of the acetylcholine receptor channel.

Authors: R Horn
Journal: Biophys J Date: 1987-02 Impact factor: 4.033

2. Is there a common design for cell membrane channels?

Authors: N Unwin
Journal: Nature Date: 1986 Sep 4-10 Impact factor: 49.962

3. A reevaluation of the mathematical models for simulating single-channel and whole-cell ionic currents.

Authors: G L Millhauser; R E Oswald
Journal: Synapse Date: 1988 Impact factor: 2.562

Review 4. Structure and function of voltage-sensitive ion channels.

Authors: W A Catterall
Journal: Science Date: 1988-10-07 Impact factor: 47.728

5. Closed-time distribution of ionic channels. Analytical solution to a one-dimensional defect-diffusion model.

Authors: C A Condat; J Jäckle
Journal: Biophys J Date: 1989-05 Impact factor: 4.033

6. Fractal models are inadequate for the kinetics of four different ion channels.

Authors: O B McManus; D S Weiss; C E Spivak; A L Blatz; K L Magleby
Journal: Biophys J Date: 1988-11 Impact factor: 4.033

7. Sampling, log binning, fitting, and plotting durations of open and shut intervals from single channels and the effects of noise.

Authors: O B McManus; A L Blatz; K L Magleby
Journal: Pflugers Arch Date: 1987-11 Impact factor: 3.657

5. Analysis of cyclic and acyclic nicotinic cholinergic agonists using radioligand binding, single channel recording, and nuclear magnetic resonance spectroscopy.

Authors: K A McGroddy; A A Carter; M M Tubbert; R E Oswald
Journal: Biophys J Date: 1993-02 Impact factor: 4.033

5 in total

Diffusion model in ion channel gating. Extension to agonist-activated ion channels.

1. Statistical methods for model discrimination. Applications to gating kinetics and permeation of the acetylcholine receptor channel.

2. Is there a common design for cell membrane channels?

3. A reevaluation of the mathematical models for simulating single-channel and whole-cell ionic currents.

Review 4. Structure and function of voltage-sensitive ion channels.

5. Closed-time distribution of ionic channels. Analytical solution to a one-dimensional defect-diffusion model.

6. Fractal models are inadequate for the kinetics of four different ion channels.

7. Sampling, log binning, fitting, and plotting durations of open and shut intervals from single channels and the effects of noise.

8. Relationships of agonist properties to the single channel kinetics of nicotinic acetylcholine receptors.

9. Fractal analysis of a voltage-dependent potassium channel from cultured mouse hippocampal neurons.

10. Diffusion models of ion-channel gating and the origin of power-law distributions from single-channel recording.

1. Protein dynamics and 1/f noise.

2. Single ion channel models incorporating aggregation and time interval omission.

3. Quantitative analysis of DNA-looping kinetics from tethered particle motion experiments.

4. Gating of maxi channels observed from pseudo-phase portraits.

5. Analysis of cyclic and acyclic nicotinic cholinergic agonists using radioligand binding, single channel recording, and nuclear magnetic resonance spectroscopy.