Inactivation of the Sodium Current in Myxicola Giant Axons: Evidence for coupling to the activation process

doi:10.1085/jgp.59.6.659

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Inactivation of the Sodium Current in Myxicola Giant Axons

Evidence for coupling to the activation process

L. Goldman ¹ and C. L. Schauf ¹

¹ From the Department of Physiology, School of Medicine, University of Maryland, Baltimore, Maryland 21201

Experiments were conducted on Myxicola giant axons to determineif the sodium activation and inactivation processes are coupledor independent. The main experimental approach was to examinethe effects of changing test pulses on steady-state inactivationcurves. Arguments were presented to show that in the presenceof a residual uncompensated series resistance the interpretationof the results depends critically on the manner of conductingthe experiment. Analytical and numerical calculations were presentedto show that as long as test pulses are confined to an approximatelylinear negative conductance region of the sodium current-voltagecharacteristic, unambiguous interpretations can be made. Whenexamined in the manner of Hodgkin and Huxley, inactivation inMyxicola is quantitatively similar to that described by theh variable in squid axons. However, when test pulses were increasedalong the linear negative region of the sodium current-voltagecharacteristic, steady-state inactivation curves translate tothe right along the voltage axis. The shift in the inactivationcurve is a linear function of the ratio of the sodium, conductanceof the test pulses, showing a 5.8 mv shift for a twofold increasein conductance. An independent line of evidence indicated thatthe early rate of development of inactivation is a functionof the rise of the sodium conductance.

Submitted on November 19, 1971

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