Neuropeptide Y depresses GABA-mediated calcium transients in developing suprachiasmatic nucleus neurons: a novel form of calcium long-term depression.

In contrast to its inhibitory role in mature neurons, GABA can exert excitatory actions in developing neurons, including mediation of increases in cytosolic Ca2+. Modulation of this excitatory activity has not been studied previously. We used Ca2+ digital imaging with Fura-2 to test the hypothesis that neuropeptide Y (NPY) would depress GABA-mediated Ca2+ rises in neurons cultured from the developing suprachiasmatic nucleus (SCN). SCN neurons were chosen as a model system for this study because SCN neurons are primarily GABAergic, they express high levels of NPY and GABA receptors, and functionally, NPY causes profound phase-shifts in SCN-generated circadian rhythms. Vigorous GABA-mediated Ca2+ activity was found in young SCN neurons that were maintained in vitro for 4-14 d. NPY showed a dose-dependent rapid depression of the amplitude of Ca2+ rises generated by GABA released from presynaptic SCN axons. NPY exerted a long-term depression of cytosolic CA2+ in the majority of neurons tested, which lasted more than 1 hr after NPY washout. The magnitude of the NPY depression was dose-dependent. NPY did not affect Ca2+ levels when GABAA receptor activity was blocked by bicuculline; however, when bicuculline and NPY were withdrawn from the perfusion solution, the subsequent CA2+ rise was either significantly reduced or completely absent, suggesting that the NPY receptor was activated in the absence of elevated intracellular Ca2+ and GABAA receptor activity, and that the latent effect of NPY was revealed only after depolarizing GABA stimulation was renewed. Pretreating neurons with pertussis toxin greatly reduced the ability of NPY to depress GABAergic Ca2+ rises, suggesting that the NPY modulation of the GABA activity was based largely on a mechanism involving pertussis toxin-sensitive Gi/Go proteins. NPY receptor stimulation depressed (< 30%) postsynaptic Ca2+ rises evoked by GABA (20 microM) application in the presence of tetrodotoxin (TTX). The effects of NPY were mimicked by the NPY Y1 receptor agonist [Pro34,Leu31] NPY and the Y2 receptor agonist NPY 13-36 and by peptide YY (PYY). Together, our data suggest that the Y1 and Y2 type NPY receptors act both presynaptically and postsynaptically to depress GABA-mediated Ca2+ rises. If related mechanisms exist in peptide modulation of inhibitory GABA activity in mature neurons, this could underlie long-term changes in the behavior of neurons of the SCN necessary for phase-shifting the circadian clock by NPY, NPY also modulated GABA responses in neuroendocrine neurons from the hypothalamic arcuate nucleus. NPY thus can play an important role in evoking long-term depression of GABA-mediated Ca2+ activity in these developing neurons, allowing NPY-secreting cells to modulate the effects of GABA on neurite outgrowth, gene expression, and physiological stimulation. This is the first example of such a cellular memory: that is, long-term Ca2+ depression based on modulation of depolarizing GABA activity.