论文信息 - The use of dwell time cross-correlation functions to study single-ion channel gating kinetics.

The use of dwell time cross-correlation functions to study single-ion channel gating kinetics.

The derivation of cross-correlation functions from single-channel dwell (open and closed) times is described. Simulation of single-channel data for simple gating models, alongside theoretical treatment, is used to demonstrate the relationship of cross-correlation functions to underlying gating mechanisms. It is shown that time irreversibility of gating kinetics may be revealed in cross-correlation functions. Application of cross-correlation function analysis to data derived from the locust muscle glutamate receptor-channel provides evidence for multiple gateway states and time reversibility of gating. A model for the gating of this channel is used to show the effect of omission of brief channel events on cross-correlation functions.

F G Ball | M S Sansom | C J Kerry | R L Ramsey | P N Usherwood

[1] P. Usherwood,et al. Single channel kinetics of a glutamate receptor. , 1986, Biophysical journal.

[2] P. Usherwood,et al. Single glutamate-activated channels in locust muscle , 1979, Nature.

[3] Edward Moczydlowski,et al. Single-Channel Enzymology , 1986 .

[4] F G Ball,et al. Single-channel autocorrelation functions: the effects of time interval omission. , 1988, Biophysical journal.

[5] M S Sansom,et al. Glutamate receptor channel kinetics: the effect of glutamate concentration. , 1988, Biophysical journal.

[6] M Montal,et al. Kinetic analysis of channel gating. Application to the cholinergic receptor channel and the chloride channel from Torpedo californica. , 1985, Biophysical journal.

[7] Richard Bellman,et al. Introduction to Matrix Analysis , 1972 .

[8] Frank Ball,et al. Aggregated Markov processes incorporating time interval omission , 1988, Advances in Applied Probability.

[9] I. Z. Steinberg,et al. Relationship between statistical properties of single ionic channel recordings and the thermodynamic state of the channels. , 1987, Journal of theoretical biology.