Mechanisms underlying the early phase of spike frequency adaptation in mouse spinal motoneurones

doi:10.1113/jphysiol.2005.086033

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Mechanisms underlying the early phase of spike frequency adaptation in mouse spinal motoneurones

G. B Miles¹, Y Dai² and R. M Brownstone^1,3

Departments of
¹ Anatomy & Neurobiology
³ Surgery (Neurosurgery), Dalhousie University, Halifax, NS, Canada
² Department of Physiology, University of Manitoba, Winnipeg, MB, Canada

Spike frequency adaptation (SFA) is a fundamental property ofrepetitive firing in motoneurones (MNs). Early SFA (occurringover several hundred milliseconds) is thought to be importantin the initiation of muscular contraction. To date the mechanismsunderlying SFA in spinal MNs remain unclear. In the presentstudy, we used both whole-cell patch-clamp recordings of MNsin lumbar spinal cord slices prepared from motor functionallymature mice and computer modelling of spinal MNs to investigatethe mechanisms underlying SFA. Pharmacological blocking agentsapplied during whole-cell recordings in current-clamp mode demonstratedthat the medium AHP conductance (apamin), BK-type Ca²⁺-dependentK⁺ channels (iberiotoxin), voltage-activated Ca²⁺ channels (CdCl₂),M-current (linopirdine) and persistent Na⁺ currents (riluzole)are all unnecessary for SFA. Measurements of Na⁺ channel availabilityincluding action potential amplitude, action potential thresholdand maximum depolarization rate of the action potential werefound to correlate with instantaneous firing frequency suggestingthat the availability of fast, inactivating Na⁺ channels isinvolved in SFA. Characterization of this Na⁺ conductance involtage-clamp mode demonstrated that it undergoes slow inactivationwith a time course similar to that of SFA. When experimentallymeasured parameters for the fast, inactivating Na⁺ conductance(including slow inactivation) were incorporated into a MN model,SFA could be faithfully reproduced. The removal of slow inactivationfrom this model was sufficient to remove SFA. These data indicatethat slow inactivation of the fast, inactivating Na⁺ conductanceis likely to be the key mechanism underlying early SFA in spinalMNs.

(Received 8 March 2005; accepted after revision 28 April 2005; first published online 5 May 2005)
Corresponding author R. M. Brownstone: Department of Anatomy and Neurobiology, Faculty of Medicine, Sir Charles Tupper Medical Building, 14A-5850 College St., Halifax, NS, Canada, B3H 1X5. Email: rob.brownstone{at}dal.ca

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				P. J. Harvey, X. Li, Y. Li, and D. J. Bennett Endogenous Monoamine Receptor Activation Is Essential for Enabling Persistent Sodium Currents and Repetitive Firing in Rat Spinal Motoneurons J Neurophysiol, September 1, 2006; 96(3): 1171 - 1186. [Abstract] [Full Text] [PDF]

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