Contribution of Persistent Sodium Currents to Spike-Frequency Adaptation in Rat Hypoglossal Motoneurons

doi:10.1152/jn.00831.2004

Contribution of Persistent Sodium Currents to Spike-Frequency Adaptation in Rat Hypoglossal Motoneurons

Jinsong Zeng, Randall K. Powers, Gregory Newkirk, Marc Yonkers and Marc D. Binder

Department of Physiology and Biophysics, University of Washington, School of Medicine, Seattle, Washington

Submitted 13 August 2004; accepted in final form 7 September 2004

In response to constant current inputs, the firing rates ofmotoneurons typically show a continuous decline over time. Thebiophysical mechanisms underlying this process, called spike-frequencyadaptation, are not well understood. Spike-frequency adaptationnormally exhibits a rapid initial phase, followed by a slow,later phase that continues throughout the duration of firing.One possible mechanism mediating the later phase might be areduction in the persistent sodium current (I_NaP) that has beenshown to diminish the capacity of cortical pyramidal neuronsand spinal motoneurons to sustain repetitive firing. In thisstudy, we used the anticonvulsant phenytoin to reduce the I_NaPof juvenile rat hypoglossal motoneurons recorded in brain stemslices, and we examined the consequences of a reduction in I_NaPon the magnitude and time course of spike-frequency adaptation.Adding phenytoin to the bathing solution ( $≥$ 50 µM) generallyproduced a marked reduction in the persistent inward currents(PICs) recorded at the soma in response to slow, voltage-clamptriangular ramp commands (–70 to 0 mV and back). However,the same concentrations of phenytoin appeared to have no significanteffect on spike-frequency adaptation even though the phenytoinoften augmented the reduction in action potential amplitudethat occurs during repetitive firing. The surprising findingthat the reduction of a source of sustained inward current hadno appreciable effect on the pattern of spike generation suggeststhat several types of membrane channels must act cooperativelyto insure that these motoneurons can generate the sustainedrepetitive firing required for long-lasting motor behaviors.

Address for reprint requests and other correspondence: M. D. Binder, Dept. of Physiology and Biophysics, Univ. of Washington, School of Medicine, Box 357290, Seattle, WA 98195 (E-mail: mdbinder{at}u.washington.edu)

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