Ionic conductances contributing to spike repolarization and after-potentials in rat medial vestibular nucleus neurones.

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Ionic conductances contributing to spike repolarization and after-potentials in rat medial vestibular nucleus neurones.

A R Johnston, N K MacLeod and M B Dutia

Department of Physiology, Medical School, Edinburgh, UK.

1. Intracellular recordings were made from 123 tonically activemedial vestibular nucleus (MVN) neurones in a horizontal slicepreparation of the dorsal brainstem of the rat. On the basisof their averaged action potential shapes, the cells were classifiedas either type A, having a single deep after-hyperpolarization(AHP; 40/123 cells, 33%), or type B, having an early fast AHPand a delayed slow AHP (83/123 cells, 67%). The two cell typeswere distributed throughout the rostrocaudal extent of the MVN.2. In type A cells TEA reduced the single deep AHP and decreasedthe rate of spike repolarization. Depolarizing current pulsesfrom a hyperpolarized membrane potential elicited spikes withshort plateau potentials in TEA. These persisted in Ca(2+)-freemedium but were abolished along with the spontaneous activityin TTX. Ca(2+)-free medium did not affect the initial rate ofrepolarization but reduced the deep AHP. Apamin and carbacholhad little effect. 4-Aminopyridine (4-AP) slowed spike repolarizationand the AHP amplitude by a small amount. Thus, in type A cellsspike repolarization and AHP appear to be mediated largely bya TEA-sensitive potassium current (presumably IK) and an apamin-insensitiveCa(2+)-activated potassium current (presumably IC). 3. The earlyfast AHP in type B cells was readily abolished in TEA. In sevenof ten type B cells tested, the spontaneous spikes developedplateau potentials of 100-120 ms duration in 10 mM TEA, whichthen became 7-9 s long in Ca(2+)-free medium. In the remainingthree cells, the spontaneous plateaux were 1.75-2 s long inTEA, and were reduced to 30-100 ms in Ca(2+)-free medium. TTXabolished the spontaneous spikes and plateaux. The delayed AHPwas abolished by apamin, which induced irregular firing. 4-APslowed spike repolarization and abolished the fast AHP, butdid not induce plateaux. Thus, in type B cells spike repolarizationinvolves a TEA-sensitive current (presumably IK) as well asIC and the 4-AP-sensitive potassium current IA, while the apamin-sensitivepotassium current IAHP is responsible for the delayed AHP. 4.The tonic activity in type B cells appears to be regulated mainlyby interactions between a persistent Na+ current, which in mostcells is large enough to generate plateaux when repolarizationis impeded in TEA, and the hyperpolarization mediated by IAHP.About 30% of type B cells have an additional inward Ca2+ current.(ABSTRACTTRUNCATED AT 400 WORDS)

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