Differential responses of corticotropin-releasing factor and urocortin 1 to acute pain stress in the rat brain.

It has been hypothesized that corticotropin-releasing factor (CRF) and its related neuropeptide urocortin 1 (Ucn1) play different roles in the initiation and adaptive phases of the stress response, which implies different temporal dynamics of these neuropeptides in response to stressors. We have tested the hypothesis that acute pain stress (APS) differentially changes the dynamics of CRF expression in the paraventricular nucleus of the hypothalamus (PVN), oval subdivision of the bed nucleus of the stria terminalis (BSTov) and central amygdala (CeA), and the dynamics of Ucn1 expression in the midbrain non-preganglionic Edinger-Westphal nucleus (npEW). Thirty minutes after APS, induced by a formalin injection into the left hind paw, PVN, BSTov, CeA and npEW all showed a peak in cFos mRNA expression that was followed by a robust increase in cFos protein-immunoreactivity, indicating a rapid increase in (immediate early) gene expression in all four brain nuclei. CRF-dynamics, however, were affected by APS in a brain nucleus-specific way: in the PVN, CRF-immunoreactivity was minimal at 60 min after APS and concomitant with a marked increase in plasma corticosterone, whereas in the BSTov not CRF peptide but CRF mRNA peaked at 60 min, and in the CeA a surge of CRF peptide occurred as late as 240 min. The npEW differed from the other centers, as Ucn1 mRNA and Ucn1 peptide peaked at 120 min. These results support our hypothesis that each of the four brain centers responds to APS with CRF/Ucn1 dynamics that are specific as to nature and timing. In particular, we propose that CRF in the PVN plays a major role in the initiation phase, whereas Ucn1 in the npEW may act in the later, termination phase of the adaptation response to APS.

Extracellular-signal regulated kinase regulates production of pro-opiomelanocortin in pituitary melanotroph cells.

The extracellular signal-regulated kinase (ERK) pathway is important in the regulation of neuronal plasticity, although a role for the kinase in regulating plasticity of neuroendocrine systems has not been examined. The melanotroph cells in the pars intermedia of pituitary gland of the amphibian Xenopus laevis are highly plastic, undergoing very strong growth to support the high biosynthetic and secretory activity involving α-melanophore-stimulating hormone (α-MSH), a peptide that causes pigment dispersion in dermal melanophores during the adaptation of the animal to a dark background. In the present study, we tested our hypothesis that ERK-signalling is involved in the regulation of melanotroph cell function during black-background adaptation, namely in the production of pro-opiomelanocortin (POMC), the precursor of α-MSH. Using western blot analyses, we found elevated levels of the activated (phosphorylated) form of ERK in melanotrophs of black- versus white-adapted animals. Treatment of melanotrophs in vitro with the mitogen-activated protein kinase kinase inhibitor U0126 markedly reduced ERK phosphorylation and lowered the transcription as well as the translation of POMC. This same treatment also reduced the expression of BDNF transcript IV and of the immediate early genes c-Fos and Nur77. We conclude that ERK-mediated signalling is important for the maintenance of the melanotroph cells in an active state.

Using transgenic animal models in neuroendocrine research: lessons from Xenopus laevis.

Transgenic animals are commonly employed to explore the function of individual proteins. Transgenic animal models include the mouse, the zebrafish, and the South African clawed toad Xenopus laevis. In contrast to mice and zebrafish, with Xenopus transgenesis DNA integration is mostly achieved in the one-cell stage. Moreover, Xenopus (as well as zebrafish) eggs are relatively large, the embryos are transparent, a large offspring is generated, and maintenance of the offspring is easy. In our transgenic studies in Xenopus, we focus on the well-characterized neuroendocrine melanotrope cells of the pituitary pars intermedia that are regulated during the process of adaptation of Xenopus to a changing environment. When the animal is placed on a black background, the melanotrope cells produce and process large amounts of the prohormone proopiomelanocortin (POMC). We apply stable melanotrope-specific transgenesis that is achieved by mixing a Xenopus POMC-promoter/transgene construct with sperm nuclei and injecting this mixture into unfertilized eggs. Since in the melanotrope cells the POMC promoter is much more active in black-adapted animals, the level of transgene expression can be manipulated by placing the animal on either a black or a white background. In this paper we review the possibilities of the Xenopus melanotrope-specific transgenic approach. Following a brief overview of the functioning of Xenopus melanotrope cells, stable melanotrope-specific transgenesis is discussed and our transgenic studies on brain-derived neurotrophic factor and secretory pathway components are described as examples of the transgenic approach in a physiological context and close to the in vivo situation.

Calcium influx through voltage-operated calcium channels is required for proopiomelanocortin protein expression in Xenopus melanotropes.

Melanotrope cells of Xenopus laevis generate transitory increases in intracellular Ca(2+), known as Ca(2+) oscillations. These oscillations arise from the influx of Ca(2+) through voltage-operated Ca(2+) channels (VOCCs). Such oscillations are the driving force for secretion of a-melanophore-stimulating hormone (alpha-MSH) from the cell. The influx of Ca(2+) through VOCCs initiates the mobilization of intracellular Ca(2+) to generate a Ca(2+) wave. The function of the Ca(2+) wave in the melanotrope is unknown, but its presence in the nucleus suggests a role in the regulation of gene expression, perhaps that of proopiomelanocortin (POMC), the precursor protein for alpha-MSH. To determine the possible function of Ca(2+) waves in Xenopus melanotropes, we addressed whether functional VOCCs, which are an established requirement for both secretion and Ca(2+) wave initiation, are also required to maintain POMC gene expression.

Melanotrope cells of Xenopus laevis express multiple types of high-voltage-activated Ca2+ channels.

Pituitary melanotrope cells are neuroendocrine signal transducing cells that translate physiological stimuli into adaptive hormonal responses. In this translation process, Ca2+ channels play essential roles. We have characterised which types of Ca2+ current are present in melanotropes of the amphibian Xenopus laevis, using whole-cell, voltage-clamp, patch-clamp experiments and specific blockers of the various current types. Running an activation current-voltage relationship protocol from a holding potential (HP) of -80 mV/or -110 mV, shows that Xenopus melanotropes possess only high-voltage activated (HVA) Ca2+ currents. Steady-state inactivation protocols reveal that no inactivation occurs at -80 mV, whereas 30% of the current is inactivated at -30 mV. We determined the contribution of individual channel types to the total HVA Ca2+ current, examining the effect of each channel blocker at an HP of -80 mV and -30 mV. At -80 mV, omega-conotoxin GVIA, omega-agatoxin IVA, nifedipine and SNX-482 inhibit Ca2+ currents by 21.8 +/- 4.1%, 26.1 +/- 3.1%, 24.2 +/- 2.4% and 17.9 +/- 4.7%, respectively. At -30 mV, omega-conotoxin GVIA, nifedipine and omega-agatoxin IVA inhibit Ca2+ currents by 33.8 +/- 3.0, 24.2 +/- 2.6 and 16.0 +/- 2.8%, respectively, demonstrating that these blockers substantially inhibit part of the Ca2+ current, independently from the HP. We have previously demonstrated that omega-conotoxin GVIA can block Ca2+ oscillations and steps. We now show that nifedipine and omega-agatoxin IVA do not affect the intracellular Ca2+ dynamics, whereas SNX-482 reduces the Ca2+ step amplitude. We conclude that Xenopus melanotrope cells express all four major types of HVA Ca2+ channel, as well as the resulting currents, but no low-voltage activated channels. The results provide the basis for future studies on the complex regulation of channel-mediated Ca2+ influxes into this neuroendocrine cell type as a function of its role in the animal's adaptation to external challenges.

Differential expression of high voltage-activated Ca2+ channel types in the rostral reticular thalamic nucleus of the absence epileptic WAG/Rij rat.

In the WAG/Rij rat, a model for human absence epilepsy, spike-wave discharges (SWD) and absence epileptic behavior develop after the age of 3 months. The rostral part of the reticular thalamic nucleus (rRTN) is involved in SWD. Ca(2+) channels play a central role in the initiation and maintenance of burst firing activity of thalamic cells. We hypothesize that a changed expression of alpha(1)-subunits of one or more high voltage-activated Ca(2+) channel types in the rRTN underlies the development of SWD. To test this hypothesis we compared 3- and 6-month-old WAG/Rij rats with nonepileptic, age-matched control rats. By immunocytochemistry, the expressions of alpha(1)1.3-, alpha(1)2.1-, alpha(1)2.2-, and alpha(1)2.3-subunits were shown in both strains, demonstrating the presence of Ca(v)1.3, Ca(v)2.1, Ca(v)2.2, and Ca(v)2.3 channels, respectively. Quantification of channel expression indicates that the development of SWD in WAG/Rij rats is concomitant with an increased expression of Ca(v)2.1 channels in the rRTN. These channels are mainly presynaptic, as revealed by double immunofluorescence involving the presynapse marker syntaxin. The mechanism by which this increase could be related to the occurrence of SWD has been discussed.

Expression and characterization of the extracellular Ca(2+)-sensing receptor in melanotrope cells of Xenopus laevis.

The extracellular Ca(2+)-sensing receptor (CaR) is expressed in many different organs in various species, ranging from mammals to fish. In some of these organs, this G protein-coupled receptor is involved in the control of systemic Ca(2+) homeostasis, whereas in other organs its role is unclear (e.g. in the pituitary gland). We have characterized the CaR in the neuroendocrine melanotrope cell of the intermediate pituitary lobe of the South African clawed toad Xenopus laevis. First, the presence of CaR mRNA was demonstrated by RT-PCR and in situ hybridization. Then it was shown that activation of the CaR by an elevated extracellular Ca(2+) concentration and different CaR-activators, including L-phenylalanine and spermine, stimulates both Ca(2+) oscillations and secretion from the melanotrope. Furthermore, it was revealed that activation of the receptor stimulates Ca(2+) oscillations through opening of voltage-operated Ca(2+) channels in the plasma membrane of the melanotropes. Finally, it was shown that the CaR activator L-phenylalanine could induce the biosynthesis of proopiomelanocortin in the intermediate lobe. Thus, in this study it is demonstrated that the CaR is present and functional in a defined cell type of the pituitary gland, the amphibian melanotrope cell.

Sauvagine regulates Ca2+ oscillations and electrical membrane activity of melanotrope cells of Xenopus laevis.

Ca2+ oscillations regulate secretion of the hormone alpha-melanphore-stimulating hormone (alpha-MSH) by the neuroendocrine pituitary melanotrope cells of the amphibian Xenopus laevis. These Ca2+ oscillations are built up by discrete increments in the intracellular Ca2+ concentration, the Ca2+ steps, which are generated by electrical membrane bursting firing activity. It has been demonstrated that the patterns of Ca2+ oscillations and kinetics of the Ca2+ steps can be modulated by changing the degree of intracellular Ca2+ buffering. We hypothesized that neurotransmitters known to regulate alpha-MSH secretion also modulate the pattern of Ca2+ oscillations and related electrical membrane activity. In this study, we tested this hypothesis for the secretagogue sauvagine. Using high temporal-resolution Ca2+ imaging, we show that sauvagine modulated the pattern of Ca2+ signalling by increasing the frequency of Ca2+ oscillations and inducing a broadening of the oscillations through its effect on various Ca2+ step parameters. Second, we demonstrate that sauvagine caused a small but significant decrease in K+ currents measured in the whole-cell voltage-clamp, whereas Ca2+ currents remained unchanged. Third, in the cell-attached patch-clamp mode, a stimulatory effect of sauvagine on action current firing was observed. Moreover, sauvagine changed the shape of individual action currents. These results support the hypothesis that the secretagogue sauvagine stimulates the frequency of Ca2+ oscillations in Xenopus melanotropes by altering Ca2+ step parameters, an action that likely is evoked by an inhibition of K+ currents.

TRH signal transduction in melanotrope cells of Xenopus laevis.

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.

New aspects of signal transduction in the Xenopus laevis melanotrope cell.

Light and temperature stimuli act via various brain centers and neurochemical messengers on the pituitary melanotrope cells of Xenopus laevis to control distinct subcellular activities such as the biosynthesis, processing, and release of alpha-melanophore-stimulating hormone (alphaMSH). The melanotrope signal transduction involves the action of a large repertoire of neurotransmitter and neuropeptide receptors and the second messengers cAMP and Ca(2+). Here we briefly review this signaling mechanism and then present new data on two aspects of this process, viz. the presence of a stimulatory beta-adrenergic receptor acting via cAMP and the egress of cAMP from the melanotrope upon a change of alphaMSH release activity.

Multiple control and dynamic response of the Xenopus melanotrope cell.

Some amphibian brain-melanotrope cell systems are used to study how neuronal and (neuro)endocrine mechanisms convert environmental signals into physiological responses. Pituitary melanotropes release alpha-melanophore-stimulating hormone (alpha-MSH), which controls skin color in response to background light stimuli. Xenopus laevis suprachiasmatic neurons receive optic input and inhibit melanotrope activity by releasing neuropeptide Y (NPY), dopamine (DA) and gamma-aminobutyric acid (GABA) when animals are placed on a light background. Under this condition, they strengthen their synaptic contacts with the melanotropes and enhance their secretory machinery by upregulating exocytosis-related proteins (e.g. SNAP-25). The inhibitory transmitters converge on the adenylyl cyclase system, regulating Ca(2+) channel activity. Other messengers like thyrotropin-releasing hormone (TRH) and corticotropin-releasing hormone (CRH, from the magnocellular nucleus), noradrenalin (from the locus coeruleus), serotonin (from the raphe nucleus) and acetylcholine (from the melanotropes themselves) stimulate melanotrope activity. Ca(2+) enters the cell and the resulting Ca(2+) oscillations trigger alpha-MSH secretion. These intracellular Ca(2+) dynamics can be described by a mathematical model. The oscillations travel as a wave through the cytoplasm and enter the nucleus where they may induce the expression of genes involved in biosynthesis and processing (7B2, PC2) of pro-opiomelanocortin (POMC) and release (SNAP-25, munc18) of its end-products. We propose that various environmental factors (e.g. light and temperature) act via distinct brain centers in order to release various neuronal messengers that act on the melanotrope to control distinct subcellular events (e.g. hormone biosynthesis, processing and release) by specifically shaping the pattern of melanotrope Ca(2+) oscillations.