Three potassium channels in rat posterior pituitary nerve terminals.

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Three potassium channels in rat posterior pituitary nerve terminals.

K Bielefeldt, J L Rotter and M B Jackson

Department of Physiology, University of Wisconsin Medical School, Madison 53706.

1. The patch clamp technique was used to investigate the K+channels in the membranes of nerve terminals in thin slicesprepared from the rat posterior pituitary. 2. Depolarizationof the membrane produced a high density of K+ current. Witha holding potential of -80 mV, test pulses to +50 mV activateda K+ current which was inactivated by 65% within 200 ms. Hyperpolarizingprepulses enhanced the transient K+ current, with half-maximalenhancement at -87 mV. Depolarizing prepulses reduced or eliminatedthe transient K+ current. 3. In cell-attached patches formedwith pipettes containing 130 mM KCl, three types of K+ channelcould be distinguished on the basis of single-channel properties.One channel had a conductance of 33 pS and was inactivated witha time constant of 18 ms. A second channel had a conductanceof 134 pS and was inactivated with a time constant of 71 ms.A third channel had a conductance of 27 pS, was activated relativelyslowly with a time constant of 65 ms, and was not inactivatedduring test pulses of up to one second in duration. 4. Inactivationof the whole-cell K+ current was a biphasic process with twoexponential components. The fast component had a time constantof 22 ms (at +50 mV), corresponding well with the time constantof decay of average current in cell-attached patches containingonly the rapidly inactivating K+ channel. The slow componentof inactivation had a time constant of 104 ms (at +50 mV), whichwas similar to but slightly slower than the time constant ofdecay of the average current in cell-attached patches containingonly the slowly inactivating K+ channel. Inactivation of theslow transient K+ current became more rapid with increasingdepolarization. 5. The low-conductance rapidly inactivatingK+ channel had a lower voltage threshold for activation thanthe other two K+ channels. 6. Both inactivating K+ channelswere enhanced in a similar manner by prior hyperpolarization.There was no difference with regard to voltage mid-point orsteepness. 7. The large-conductance slowly inactivating K+ channelwas activated by Ca2+ at the inner membrane surface. The restingintracellular Ca2+ was sufficiently high to produce significantactivation of this channel without depolarization-induced Ca2+entry. 8. Removal of Ca2+ from the bathing solution produceda -10 mV shift in the voltage dependence of enhancement of bothtransient K+ currents by prior hyperpolarization. This couldbe explained as a surface charge effect.(ABSTRACT TRUNCATEDAT 400 WORDS)

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