Three potassium channels in rat posterior pituitary nerve terminals.

1. The patch clamp technique was used to investigate the K+ channels in the membranes of nerve terminals in thin slices prepared from the rat posterior pituitary. 2. Depolarization of the membrane produced a high density of K+ current. With a holding potential of ‐80 mV, test pulses to +50 mV activated a K+ current which was inactivated by 65% within 200 ms. Hyperpolarizing prepulses enhanced the transient K+ current, with half‐maximal enhancement at ‐87 mV. Depolarizing prepulses reduced or eliminated the transient K+ current. 3. In cell‐attached patches formed with pipettes containing 130 mM KCl, three types of K+ channel could be distinguished on the basis of single‐channel properties. One channel had a conductance of 33 pS and was inactivated with a time constant of 18 ms. A second channel had a conductance of 134 pS and was inactivated with a time constant of 71 ms. A third channel had a conductance of 27 pS, was activated relatively slowly with a time constant of 65 ms, and was not inactivated during test pulses of up to one second in duration. 4. Inactivation of the whole‐cell K+ current was a biphasic process with two exponential components. The fast component had a time constant of 22 ms (at +50 mV), corresponding well with the time constant of decay of average current in cell‐attached patches containing only the rapidly inactivating K+ channel. The slow component of inactivation had a time constant of 104 ms (at +50 mV), which was similar to but slightly slower than the time constant of decay of the average current in cell‐attached patches containing only the slowly inactivating K+ channel. Inactivation of the slow transient K+ current became more rapid with increasing depolarization. 5. The low‐conductance rapidly inactivating K+ channel had a lower voltage threshold for activation than the other two K+ channels. 6. Both inactivating K+ channels were enhanced in a similar manner by prior hyperpolarization. There was no difference with regard to voltage mid‐point or steepness. 7. The large‐conductance slowly inactivating K+ channel was activated by Ca2+ at the inner membrane surface. The resting intracellular Ca2+ was sufficiently high to produce significant activation of this channel without depolarization‐induced Ca2+ entry. 8. Removal of Ca2+ from the bathing solution produced a ‐10 mV shift in the voltage dependence of enhancement of both transient K+ currents by prior hyperpolarization. This could be explained as a surface charge effect.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  M. Jackson,et al.  Passive current flow and morphology in the terminal arborizations of the posterior pituitary. , 1993, Journal of neurophysiology.

[2]  M B Jackson,et al.  Cable analysis with the whole-cell patch clamp. Theory and experiment. , 1992, Biophysical journal.

[3]  M B Jackson,et al.  Action potential broadening and frequency-dependent facilitation of calcium signals in pituitary nerve terminals. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[4]  G. Augustine,et al.  Regulation of transmitter release at the squid giant synapse by presynaptic delayed rectifier potassium current. , 1990, The Journal of physiology.

[5]  M. Nowycky,et al.  Direct measurement of exocytosis and calcium currents in single vertebrate nerve terminals , 1990, Nature.

[6]  C. Bourque Intraterminal recordings from the rat neurohypophysis in vitro. , 1990, The Journal of physiology.

[7]  R. Aldrich,et al.  Voltage-dependent gating of Shaker A-type potassium channels in Drosophila muscle , 1990, The Journal of general physiology.

[8]  J W Moore,et al.  Identification of ionic currents at presynaptic nerve endings of the lizard. , 1989, The Journal of physiology.

[9]  Jose R. Lemos,et al.  Two types of calcium channels coexist in peptide-releasing vertebrate nerve terminals , 1989, Neuron.

[10]  P. Legendre,et al.  Characterization of three types of potassium current in cultured neurones of rat supraoptic nucleus area. , 1989, The Journal of physiology.

[11]  G. Oxford,et al.  The inactivating K+ current in GH3 pituitary cells and its modification by chemical reagents. , 1989, The Journal of physiology.

[12]  B M Salzberg,et al.  Optical studies of the secretory event at vertebrate nerve terminals. , 1988, The Journal of experimental biology.

[13]  D. Faber,et al.  Synaptic transmission mediated by single club endings on the goldfish Mauthner cell. II. Plasticity of excitatory postsynaptic potentials , 1988, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[14]  K. Racké,et al.  Effects of tetraethylammonium ions on frequency‐dependent vasopressin release from the rat neurohypophysis. , 1988, The Journal of physiology.

[15]  C. Bourque Transient calcium‐dependent potassium current in magnocellular neurosecretory cells of the rat supraoptic nucleus. , 1988, The Journal of physiology.

[16]  H. Gainer,et al.  Effects of stimulus frequency and potassium channel blockade on the secretion of vasopressin and oxytocin from the neurohypophysis. , 1987, Neuroendocrinology.

[17]  E. Stuenkel,et al.  Electrical properties of axons and neurohypophysial nerve terminals and their relationship to secretion in the rat. , 1986, The Journal of physiology.

[18]  E R Kandel,et al.  Action-potential duration and the modulation of transmitter release from the sensory neurons of Aplysia in presynaptic facilitation and behavioral sensitization. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[19]  R. Dyball,et al.  Single ion channel activity in peptidergic nerve terminals of the isolated rat neurohypophysis related to stimulation of neural stalk axons , 1986, Brain Research.

[20]  M. Kameyama,et al.  Single transient K channels in mammalian sensory neurons. , 1986, Biophysical journal.

[21]  Michael A. Rogawski,et al.  The A-current: how ubiquitous a feature of excitable cells is it? , 1985, Trends in Neurosciences.

[22]  G. Dayanithi,et al.  The role of patterned burst and interburst interval on the excitation‐coupling mechanism in the isolated rat neural lobe. , 1985, The Journal of physiology.

[23]  A. Mallart A calcium‐activated potassium current in motor nerve terminals of the mouse. , 1985, The Journal of physiology.

[24]  E. Neher,et al.  Potassium channels in cultured bovine adrenal chromaffin cells. , 1985, The Journal of physiology.

[25]  R. Dyball,et al.  Facilitation of vasopressin release from the neurohypophysis by application of electrical stimuli in bursts. Relevant stimulation parameters. , 1984, Neuroendocrinology.

[26]  G. Leng,et al.  Reversible fatigue of stimulus‐secretion coupling in the rat neurohypophysis. , 1984, The Journal of physiology.

[27]  D. Senseman,et al.  Optical recording of action potentials from vertebrate nerve terminals using potentiometric probes provides evidence for sodium and calcium components , 1983, Nature.

[28]  E. Kandel,et al.  Molecular biology of learning: modulation of transmitter release. , 1982, Science.

[29]  J. Dubois Evidence for the existence of three types of potassium channels in the frog Ranvier node membrane. , 1981, The Journal of physiology.

[30]  A. Marty,et al.  Ca-dependent K channels with large unitary conductance in chromaffin cell membranes , 1981, Nature.

[31]  R. Dyball,et al.  Phasic firing enhances vasopressin release from the rat neurohypophysis , 1979, The Journal of physiology.

[32]  Y. Jan,et al.  Two Mutations of synaptic transmission in Drosophila , 1977, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[33]  K. B. Ruf,et al.  Action potentials and release of neurohypophysial hormones in vitro , 1971, The Journal of physiology.

[34]  E. Neher Two Fast Transient Current Components during Voltage Clamp on Snail Neurons , 1971, The Journal of general physiology.

[35]  C. Stevens,et al.  Voltage clamp studies of a transient outward membrane current in gastropod neural somata , 1971, The Journal of physiology.

[36]  J. Mambrini,et al.  Modification of transmitter release by ions which prolong the presynaptic action potential , 1970, The Journal of physiology.

[37]  W. Douglas,et al.  Stimulus—secretion coupling in a neurosecretory organ: the role of calcium in the release of vasopressin from the neurohypophysis , 1964, The Journal of physiology.

[38]  S. Hagiwara,et al.  Membrane changes of Onchidium nerve cell in potassium‐rich media , 1961, The Journal of physiology.

[39]  P. Thorn,et al.  A fast, transient K+ current in neurohypophysial nerve terminals of the rat. , 1991, The Journal of physiology.

[40]  B. Salzberg,et al.  Calcium Channels that Are Required for Secretion from Intact Nerve Terminals of Vertebrates Are Sensitive to ~0-Conotoxin and Relatively Insensitive to Dihydropyridines , 1989 .

[41]  B M Salzberg,et al.  Action potentials and frequency-dependent secretion in the mouse neurohypophysis. , 1986, Neuroendocrinology.

[42]  M. Blaustein,et al.  Calcium-Activated Potassium Channels in Presynaptic Nerve Terminals , 1986 .

[43]  I. Cooke,et al.  Single channels and ionic currents in peptidergic nerve terminals , 1986, Nature.

[44]  Alain Marty,et al.  Tight-Seal Whole-Cell Recording , 1983 .

[45]  J. Nordmann Stimulus-secretion coupling. , 1983, Progress in brain research.