ABSTRACT
TRH is a neuropeptide that activates phospholipase C and, when acting on secretory cells, usually induces a biphasic response consisting of a transitory increase in secretion (due to IP(3) mobilization of Ca(2+) from intracellular stores), followed by a sustained plateau phase of stimulated secretion (by protein kinase C-dependent influx of extracellular Ca(2+) through voltage-operated Ca(2+) channels). The melanotrope cell of the amphibian Xenopus laevis displays a unique secretory response to TRH, namely a broad transient but no sustained second phase, consistent with the observation that TRH induces a single Ca(2+) transient rather than the classic biphasic increase in [Ca(2+)](i). The purpose of the present study was to determine the signal transduction mechanism utilized by TRH in generating this Ca(2+) signaling response. Our hypothesis was that the transient reflects the operation of only one of the two signaling arms of the lipase (i.e., either IP(3)-induced mobilization of internal Ca(2+) or PKC-dependent influx of external Ca(2+)). Using video-imaging microscopy it is shown that the TRH-induced Ca(2+) transient is dramatically attenuated under Ca(2+)-free conditions and that thapsigargin has no noticeable effect on the TRH-induced transient. These observations indicate that an IP(3)-dependent mechanism plays no important role in the action of TRH. PKC also does not seem to be involved because an activator of PKC did not induce a Ca(2+) transient and an inhibitor of PKC did not affect the TRH response. Experiments with a bis-oxonol membrane potential probe showed that the TRH response also does not underlie a PKC-independent mechanism that would induce membrane depolarization. We conclude that the action of TRH on the Xenopus melanotrope does not rely on the classical phospholipase C-dependent mechanism.
Subject(s)
Melanocyte-Stimulating Hormones/metabolism , Pituitary Gland/metabolism , Signal Transduction , Thyrotropin-Releasing Hormone/pharmacology , Xenopus laevis/physiology , Animals , Calcium/metabolism , Calcium-Transporting ATPases/antagonists & inhibitors , Egtazic Acid/pharmacology , Enzyme Activation/drug effects , Enzyme Inhibitors/pharmacology , Membrane Potentials/drug effects , Piperidines/pharmacology , Pituitary Gland/drug effects , Pituitary Gland/ultrastructure , Protein Kinase C/antagonists & inhibitors , Protein Kinase C/metabolism , Tetradecanoylphorbol Acetate/pharmacology , Thapsigargin/pharmacologyABSTRACT
It is believed that specific patterns of changes in the cytosolic-free calcium concentration ([Ca2+]i) are used to control cellular processes such as gene transcription, cell proliferation, differentiation, and secretion. We recently showed that the Ca2+ oscillations in the neuroendocrine melanotrope cells of Xenopus laevis are built up by a number of discrete Ca2+ rises, the Ca2+ steps. The origin of the Ca2+ steps and their role in the generation of long-lasting Ca2+ patterns were unclear. By simultaneous, noninvasive measuring of melanotrope plasma membrane electrical activity and the [Ca2+]i, we show that numbers, amplitude, and frequency of Ca2+ steps are variable among individual oscillations and are determined by the firing pattern and shape of the action currents. The general Na+ channel blocker tetrodotoxin had no effect on either action currents or the [Ca2+]i. Under Na+-free conditions, a depolarizing pulse of 20 mM K+ induced repetitive action currents and stepwise increases in the [Ca2+]i. The Ca2+ channel blocker CoCl2 eliminated action currents and stepwise increases in the [Ca2+]i in both the absence and presence of high K+. We furthermore demonstrate that the speed of Ca2+ removal from the cytoplasm depends on the [Ca2+]i, also between Ca2+ steps during the rising phase of an oscillation. It is concluded that Ca2+ channels, and not Na+ channels, are essential for the generation of specific step patterns and, furthermore, that the frequency and shape of Ca2+ action currents in combination with the Ca2+ removal rate determine the oscillatory pattern.
Subject(s)
Calcium/metabolism , Pituitary Gland/physiology , Action Potentials/physiology , Animals , Calcium Channel Blockers/pharmacology , Cells, Cultured , Electrophysiology , Female , Fura-2/metabolism , Kinetics , Male , Microscopy, Fluorescence , Patch-Clamp Techniques , Potassium/pharmacology , Sodium/pharmacology , Tetrodotoxin/pharmacology , Xenopus laevisSubject(s)
Pituitary Gland, Anterior/metabolism , Xenopus laevis/physiology , alpha-MSH/metabolism , Animals , Neuropeptide Y/physiology , Pituitary Gland, Anterior/cytology , Receptors, Dopamine D2/physiology , Receptors, GABA-A/physiology , Receptors, GABA-B/physiology , Secretory Rate , Xenopus laevis/anatomy & histologyABSTRACT
Intracellular Ca2+ oscillations play an important role in the induction of alpha-MSH release from pituitary melanotrope cells of Xenopus laevis. Oscillatory, secretory and adenylyl cyclase activities are all inhibited by dopamine, neuropeptide Y (NPY) and baclofen (a GABAB receptor agonist) and stimulated by sauvagine. In this study, we test the hypothesis that these neural messengers regulate the Ca2+ oscillations via a cAMP/protein kinase A (PKA)-dependent mechanism. To this end, video-imaging microscopy was applied to single Xenopus melanotropes loaded with the Ca2+ indicator Fura-2. The cAMP-dependent PKA inhibitor H89 blocked Ca2+ oscillations as well as the stimulatory actions of 8-Br-cAMP and sauvagine. Treatment of cells inhibited by baclofen with either 8-Br-cAMP or sauvagine led to a reappearance of Ca2+ oscillations. A similar result was found for cells inhibited by NPY. Neither 8-Br-cAMP nor sauvagine induced Ca2+ oscillations in cells inhibited by dopamine. Depolarizing dopamine-inhibited cells with high potassium also failed to induce oscillations, but combining 8-Br-cAMP with membrane depolarization induced oscillations. It is concluded that sauvagine, baclofen and NPY work primarily through a cAMP/PKA-pathway while dopamine inhibits Ca2+ oscillations in a dual fashion, namely via both a cAMP-dependent and a cAMP-independent mechanism, the latter probably involving membrane hyperpolarization.
Subject(s)
Calcium/metabolism , Cyclic AMP/physiology , Periodicity , Pituitary Gland/cytology , Sulfonamides , 8-Bromo Cyclic Adenosine Monophosphate/pharmacology , Amphibian Proteins , Animals , Baclofen/pharmacology , Cyclic AMP-Dependent Protein Kinases/pharmacology , Dopamine/pharmacology , Drug Interactions , Enzyme Inhibitors/pharmacology , Female , Fluorescent Dyes , Fura-2 , GABA Agonists/pharmacology , Isoquinolines/pharmacology , Male , Microscopy, Video , Neuropeptide Y/pharmacology , Peptide Hormones , Peptides/pharmacology , Pituitary Gland/drug effects , Pituitary Gland/enzymology , Vasodilator Agents/pharmacology , Xenopus laevisABSTRACT
The melanotrope cells in the pituitary gland of Xenopus laevis are innervated by neurons containing neuropeptide Y (NPY). In the present study, the mechanism of action of NPY on the melanotropes has been investigated. NPY inhibited in vitro secretion from melanotropes in intact neurointermediate lobes as well as from isolated, single melanotropes. Inhibition of secretion from neurointermediate lobes was mimicked by the NPY analogues PYY and [Leu31,Pro34]NPY, whereas NPY(13-36) was inactive. Secretion from isolated melanotropes was inhibited by [Leu31,Pro34]NPY and NPY(13-36), but NPY(13-36) was 10-fold less potent than [Leu31,Pro34]NPY. Studies on isolated cells revealed that NPY and its analogues inhibited the occurrence of intracellular Ca2+ oscillations with the same potency as they inhibited secretion from isolated cells. In addition to inhibiting basal secretion and spontaneous Ca2+ oscillations, NPY inhibited the basal production of cyclic AMP. On the basis of these results it is proposed that NPY inhibits secretion from Xenopus melanotropes by inhibiting cyclic AMP-dependent spontaneous Ca2+ oscillations through a Y1-like receptor.
