Identification of delayed potassium and calcium currents in the rat sympathetic neurone under voltage clamp.

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Identification of delayed potassium and calcium currents in the rat sympathetic neurone under voltage clamp.

O Belluzzi, O Sacchi and E Wanke

Post-ganglionic neurones of the isolated rat superior cervicalganglion were studied at 37 degrees C under two-electrode voltage-clampconditions. Membrane depolarization beyond -40 mV from holdinglevels between -50 and -100 mV produced a delayed outward currentwhich exhibited no inactivation within this voltage range. Thecurrent is carried primarily by K+ ions and its instantaneousI-V relation is linear. The total outward current could be separatedinto two distinct components on the basis of ion-substitutionexperiments. A voltage-dependent component of the delayed current,termed IK(V), is activated by membrane depolarization beyond-40 mV when Ca2+ fluxes are selectively blocked by Cd2+ or inCa2+-free solution. IK(V) develops following first-order kineticsand rises to a peak with a voltage-dependent delay (239 ms at-30 mV and 23 ms at +10 mV). GK(V) attains a saturating valueof the order of 17 mS/cm2 at about +20 mV and can be describedin terms of a simple Boltzmann distribution for a single gatingparticle with a valency equal to +2.5. A second component ofthe delayed outward current, termed IK(Ca), depends on Ca2+entry for its activation and was isolated as difference currentbefore and after block of Ca2+ movements across the membrane.IK(Ca) is larger and faster than IK(V): it is strictly relatedto Ca2+ influx and also depends on membrane potential depolarization.A distinct Ca2+ current, ICa, was recorded from the neuroneexposed to Na+-free or tetrodotoxin solution. ICa was activatedby membrane depolarization beyond -30 mV and reached a maximumvalue near 0 mV. Its activation agrees with fourth-order kineticsand becomes faster with increasing depolarization. The Ca2+current developed with a voltage-dependent time to peak of 2.9-1.8ms and thereafter completely inactivated. The relationship betweenICa and IK(Ca) is discussed. The Ca2+-k+ repolarizing systemis expected to be mainly associated with action potentials arisingfrom a depolarized neurone, whereas the IA current (Belluzzi,Sacchi & Wanke, 1985) dominates the repolarization mechanismat the normal membrane potential. The effect of muscarine wasexamined. Muscarine (10-50 microM) produced a fall in conductancewith a voltage dependence similar to that exhibited by GK(Ca)and was ineffective when removing extracellular Ca2+ or addingCd2+. A partial suppression of ICa by muscarine is demonstrated.It is suggested that the decrease of the outward current magnitudein the presence of muscarine may be accounted for qualitativelyby the reduction in ICa.

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