Involvement Of ATP-sensitive Potassium Channels Research Articles

Possible involvement of K(ATP) channels in the control of 5-HT neurons

The possible involvement of ATP-sensitive potassium channels in the control of the electrical activity of central serotoninergic neurons was investigated by recording their firing rate in the dorsal raphe nucleus of rat brain stem slices exposed to various blockers and openers of these channels. Whereas the channel openers lemakalim and aprikalim produced no change in the firing rate of these neurons, the channel blockers glibenclamide and gliquidone were strongly inhibitory. As expected from an effect through ATP-sensitive potassium channels, the inhibition by glibenclamide could be prevented in a competitive manner by lemakalim and aprikalim. In contrast, the inactive isomer of the latter drug, RP 61499, did not alter the glibenclamide effect. In addition to the channel openers, the GABA receptor antagonists, bicuculline and phaclofen, but not the antagonist of somato-dendritic 5-HT 1A autoreceptors, (-)tertatolol, prevented the negative influence of glibenclamide on the firing rate of serotoninergic neurons. This suggests that GABA acting at both GABA A and GABA B receptors (but not serotonin through the possible stimulation of autoreceptors) was responsible for the effect of glibenclamide. Accordingly, the blockade by the latter drug of ATP-sensitive potassium channels on GABAergic interneurons probably triggered the release of GABA, which in turn, inhibited serotoninergic neurons. In agreement with this hypothetical mechanism, autoradiographic studies demonstrated that ATP-sensitive potassium channels are not located on serotoninergic neurons (but probably on GABAergic interneurons) as the extensive lesion of these neurons by 5,7-dihydroxytryptamine did not reduce the specific labelling of the dorsal raphe nucleus by [ 3H]glibenclamide.

Dopamine and somatostatin inhibition of prolactin secretion from MMQ pituitary cells: role of adenosine triphosphate-sensitive potassium channels.

The sulfonylurea glibenclamide, which is known to block ATP-sensitive potassium channels, increases, in a dose-dependent manner, the release of PRL from MMQ pituitary cells. Glibenclamide does not reduce the dopaminergic inhibition of forskolin-stimulated PRL secretion; conversely it almost completely abolishes the inhibitory effect of somatostatin (SRIF) on this parameter. The sulfonylurea dose dependently increases basal [Ca++]i, without affecting the increase in [Ca++]i induced by high concentrations of extracellular potassium. Glibenclamide does not modify dopamine-induced [Ca++]i reduction, whereas it abolishes the inhibitory effect of SRIF on basal [Ca++]i. In the presence of diazoxide, an opener of ATP-sensitive potassium channels, which lowers basal [Ca++]i, dopamine still reduces [Ca++]i whereas SRIF does not induce a further decrease. Glibenclamide induces the depolarization of the cell membrane and prevents the SRIF-evoked hyperpolarization. The hyperpolarization of the cell membrane induced by dopamine is not modified by glibenclamide. Diazoxide induces a cell membrane hyperpolarization that is enhanced by dopamine but not by SRIF. Finally, glibenclamide does not affect basal and stimulated adenylate cyclase activity. In conclusion, our findings show that, in MMQ cells, glibenclamide stimulates PRL release, suggesting an involvement of ATP-sensitive potassium channels in the regulation of PRL secretion. The reversal by glibenclamide of the effects of SRIF on calcium homeostasis, membrane potential, and PRL release suggests that this type of potassium channel participates to the somatostatinergic inhibition of PRL secretion. Conversely, we found that glibenclamide does not modify the dopaminergic inhibition of PRL secretion and second messenger systems, suggesting that ATP-sensitive potassium channels may not be involved in the inhibitory effect of dopamine on PRL release.

Possible involvement of ATP-sensitive potassium channels in regulating cell excitability in hippocampal neurons

Possible involvement of ATP-sensitive potassium channels in regulating cell excitability in hippocampal neurons