Plasticity of the prolactin (PRL) axis: mechanisms underlying regulation of output in female mice.

The output of prolactin (PRL) is highly dynamic with dramatic changes in its secretion from the anterior pituitary gland depending on prevailing physiological status. In adult female mice, there are three distinct phases of output and each of these is related to the functions of PRL at specific stages of reproduction. Recent studies of the changes in the regulation of PRL during its period of maximum output, lactation, have shown alterations at both the level of the anterior pituitary and hypothalamus. The PRL-secreting cells of the anterior pituitary are organised into a homotypic network in virgin animals, facilitating coordinated bouts of activity between interconnected PRL cells. During lactation, coordinated activity increases due to the changes in structural connectivity, and this drives large elevations in PRL secretion. Surprisingly, these changes in connectivity are maintained after weaning, despite reversion of PRL output to that of virgin animals, and result in an augmented output of hormone during a second lactation. At the level of the hypothalamus, tuberoinfundibular dopamine (TIDA) neurons, the major inhibitors of PRL secretion, have unexpectedly been shown to remain responsive to PRL during lactation. However, there is an uncoupling between TIDA neuron firing and dopamine secretion, with a potential switch to enkephalin release. Such a process may reinforce hormone secretion through dual disinhibition and stimulation of PRL cell activity. Thus, integration of signalling along the hypothalamo-pituitary axis is responsible for increased secretory output of PRL cells during lactation, as well as allowing the system to anticipate future demands.

The application of water soluble, mega-Stokes-shifted BODIPY fluorophores to cell and tissue imaging.

BODIPY (4,4-difluoro-4-bora-3a,4a-diaza-s-indacene) fluorophores are widely used in bioimaging to label proteins, lipids and nucleotides, but in spite of their attractive optical properties they tend to be prone to self-quenching because of their notably small Stokes shift. Herein, we compare two BODIPY compounds from a recently developed family of naphthyridine substituted BODIPY derivatives, one a visible emitting derivative (BODIPY-VIS) and one a near-infrared emitting fluorophore with a Stokes shift of approximately 165 nm as contrast reagents for live mammalian cells and murine brain tissue. The compounds were rendered water soluble by their conjugation to polyethylene glycol (PEG). Both PEGylated compounds exhibited good cell uptake compared with their parent compounds and confocal fluorescence microscopy revealed all dyes explored to be nuclear excluding, localizing predominantly within the lipophilic organelles; the endoplasmic reticulum and mitochondria. Cytotoxicity studies revealed that these BODIPY derivatives are modestly cytotoxic at concentrations exceeding 10 µM where they induce apoptosis and necrosis. Although the quantum yield of emission of the visible emitting fluorophore was over an order of magnitude greater than the Mega-Stokes shifted probe, the latter showed considerably reduced tendency to self quench and less interference from autofluorescence. The near-infrared probe also showed good penetrability and staining in live tissue samples. In the latter case similar tendency to exclude the nucleus and to localize in the mitochondria and endoplasmic reticulum was observed as in live cells. This to our knowledge is the first demonstration of such a Mega-Stokes BODIPY probe applied to cell and tissue imaging.

Anterior pituitary cell networks.

Both endocrine and non-endocrine cells of the pituitary gland are organized into structural and functional networks which are formed during embryonic development but which may be modified throughout life. Structural mapping of the various endocrine cell types has highlighted the existence of distinct network motifs and relationships with the vasculature which may relate to temporal differences in their output. Functional characterization of the network activity of growth hormone and prolactin cells has revealed a role for cell organization in gene regulation, the plasticity of pituitary hormone output and remarkably the ability to memorize altered demand. As such, the description of these endocrine cell networks alters the concept of the pituitary from a gland which simply responds to external regulation to that of an oscillator which may memorize information and constantly adapt its coordinated networks' responses to the flow of hypothalamic inputs.

Cardiovascular responses during hypoventilation at exercise.

This study aimed to determine the cardiovascular responses during a prolonged exercise with voluntary hypoventilation (VH). 7 men performed 3 series of 5-min exercise at 65% of normoxic maximal O (2) uptake under 3 conditions: (1) normal breathing (NB) in normoxia (NB (0.21)), (2) VH in normoxia (VH (0.21)), (3) NB in hypoxia (NB (0.157), inspired oxygen fraction=0.157). In both VH (0.21) and NB (0.157), there was a similar drop in arterial oxygen saturation and arterial O (2) content (CaO (2)) which were lower than in NB (0.21). Heart rate (HR), stroke volume, and cardiac output (-) were higher in VH (0.21) than in NB (0.21) during most parts of exercise whereas there was no difference between NB (0.157) and VH (0.21) or NB (0.21). HR variability analysis suggested an increased sympathetic modulation in VH (0.21) only. O (2) transport and oxygen uptake were generally not different between interventions. Mixed venous O (2) content (C-O (2)) was lower in NB (0.157) than in both VH (0.21) and NB (0.21) and not different between the latter. CaO (2)-C-O (2) was not different between NB (0.157) and NB (0.21) but lower in VH (0.21). This study shows that a prolonged exercise with VH leads to a greater cardiac activity, independent from the hypoxic effect. The greater - in VH compared to normal breathing seems to be the main factor for compensating the drop of arterial oxygen content.

Synaptic communication mediates the assembly of a self-organizing circuit that controls reproduction.

Migration of gonadotropin-releasing hormone (GnRH) neurons from their birthplace in the nasal placode to their hypothalamic destination is critical for vertebrate reproduction and species persistence. While their migration mode as individual GnRH neurons has been extensively studied, the role of GnRH-GnRH cell communication during migration remains largely unexplored. Here, we show in awake zebrafish larvae that migrating GnRH neurons pause at the nasal-forebrain junction and form clusters that act as interhemisphere neuronal ensembles. Within the ensembles, GnRH neurons create an isolated, spontaneously active circuit that is internally wired through monosynaptic glutamatergic synapses into which newborn GnRH neurons integrate before entering the brain. This initial phase of integration drives a phenotypic switch, which is essential for GnRH neurons to properly migrate toward their hypothalamic destination. Together, these experiments reveal a critical step for reproduction, which depends on synaptic communication between migrating GnRH neurons.

Visualization of cyclic AMP-regulated presynaptic activity at cerebellar granule cells.

Adenylyl cyclase (AC) modulation of vesicular cycling was visualized at cultured cerebellar granule cell synapses using the sequential uptake of antibodies directed against the intraluminal domain of synaptotagmin I. Vesicle recycling due to spontaneous transmitter release in the absence of action potentials was increased by the AC/protein kinase A (PKA) activators forskolin and CPT-cAMP. These effects were blocked by the PKA inhibitor Rp-cAMPs. Cyclic AMP elevation also induced new cycling at previously silent sites. Activation of L-AP4-sensitive mGluR reduced the cAMP/PKA enhancement at preexisting synapses downstream of both AC and calcium channels. Modulation of the turnover and the number of vesicular release sites provide one mechanism that may underlie cAMP-dependent cerebellar long-term potentiation.

Combining Cadherin Expression with Molecular Markers Discriminates Invasiveness in Growth Hormone and Prolactin Pituitary Adenomas.

Although growth hormone (GH)- and prolactin (PRL)-secreting pituitary adenomas are considered benign, in many patients, tumour growth and/or invasion constitute a particular challenge. In other tumours, progression relies in part on dysfunction of intercellular adhesion mediated by the large family of cadherins. In the present study, we have explored the contribution of cadherins in GH and PRL adenoma pathogenesis, and evaluated whether this class of adherence molecules was related to tumour invasiveness. We have first established, by quantitative polymerase chain reaction and immunohistochemistry, the expression profile of classical cadherins in the normal human pituitary gland. We show that the cadherin repertoire is restricted and cell-type specific. Somatotrophs and lactotrophs express mainly E-cadherin and cadherin 18, whereas N-cadherin is present in the other endocrine cell types. This repertoire undergoes major differential modification in GH and PRL tumours: E-cadherin is significantly reduced in invasive GH adenomas, and this loss is associated with a cytoplasmic relocalisation of cadherin 18 and catenins. In invasive prolactinomas, E-cadherin distribution is altered and is accompanied by a mislocalisation of cadherin 18, ß-catenin and p120 catenin. Strikingly, de novo expression of N-cadherin is present in a subset of adenomas and cells exhibit a mesenchymal phenotype exclusively in invasive tumours. Binary tree analysis, performed by combining the cadherin repertoire with the expression of a subset of known molecular markers, shows that cadherin/catenin complexes play a significant role in discrimination of tumour invasion.

Effects of two neuronal antidiuretic molecules, neuroparsin and 5-hydroxytryptamine, on cytosolic free calcium monitored with indo-1 in epithelial and muscular cells of the African locust rectum.

Using the probe indo-1 in a microspectrofluorimetric study, it was demonstrated that the locust antidiuretic neurohormone, neuroparsin, enhanced cytosolic free Ca2+ concentrations, measured as percentages of the ratio F405/F480 (R), in epithelial cells of the African locust rectum. 5-hydroxytryptamine, whose antidiuretic effect was previously established, enhanced R in longitudinal muscular cells, and was able to increase R slightly in epithelial cells. The possibility of reciprocal Ca2+ movements between muscular and epithelial cells is discussed. Both of the neuronal molecules, which act via distinct transduction pathways (phosphoinositide turnover for neuroparsin, and Ca(2+)-dependent adenylate cyclase for 5-hydroxytryptamine), stimulated an increase in R by causing Ca2+ entry through dihydropyridine-sensitive Ca2+ channels. Cyclic nucleotides (cAMP and cGMP) lowered R in epithelial cells, the cGMP effect being interpreted as a feedback control on phosphoinositide turnover and resulting in the ability to re-establish cAMP production to levels incompatible with high PLC activity. In longitudinal muscular cells, the increase in R due to cAMP suggests the involvement of 5-hydroxytryptamine in stimulation of adenylate cyclase activity. Furthermore, results enabled the localization in epithelial cells of the transduction pathways mediating the actions of another antidiuretic factor extracted from the glandular lobes of the locust corpora cardiaca.

Why are endocrine pituitary cells excitable?

Since 1975, endocrine pituitary cells have been known to be excitable neuronlike cells. Using powerful single-cell approaches, in particular the patch clamp electrophysiological recording technique and the monitoring of Ca(2+) with fluorescent probes, solid evidence has been provided in the last 10 years that intracellular Ca(2+) signals are produced by stimulators and inhibitors of secretion via the modulation of action potentials in isolated pituitary cells. As cytosolic Ca(2+) changes are thought to control numerous cellular functions (for example, secretion, protein synthesis, gene expression, and proliferation) over a long time scale-milliseconds to hours-it is now time to address the long-standing question of what functions would be physiologically controlled by electrical excitability in intact pituitary tissue.

Spontaneous and gonadotropin-releasing hormone-stimulated cytosolic calcium rises in individual goldfish gonadotrophs.

The cytosolic free calcium concentration, [Ca2+]i, was monitored in single isolated goldfish gonadotrophs with the fluorescent probe Indo-1. It was found that goldfish gonadotrophs exhibit both spontaneous and secretagogue-induced [Ca2+]i rises. Spontaneous [Ca2+]i transients showed striking kinetic features and a sensitivity to external Ca2+ suggesting that they were the consequence of transient Ca2+ entries. Two kinetically distinct patterns of [Ca2+]i rises were generated in response to the two native forms of gonadotropin-releasing hormone (GnRH), salmon GnRH (sGnRH) and chicken GnRH-II (cGnRH-II). In a part of the gonadotrophs, GnRHs triggered a plateau [Ca2+]i rise whereas in other responsive cells they induced a series of [Ca2+]i bursts, each consisting of grouped [Ca2+]i transients. Both plateau and burst [Ca2+]i response patterns were due to Ca2+ entry through plasma membrane Ca2+ channels, inasmuch as they were suppressed with external Ca2+ removal. No contribution of Ca2+ release from thapsigargin-sensitive stores was observed in either response pattern. While in mammalian gonadotrophs GnRH rises [Ca2+] by mostly acting on internal Ca2+ sequestering stores, our results show that GnRH-stimulated goldfish gonadotrophs rapidly increase Ca2+ entry to enhance their [Ca2+]i levels.

Characterization of Ca2+ signals generated by extracellular nucleotides in supporting cells of the organ of Corti.

ATP has been demonstrated to act as a co-transmitter or neuromodulator in various physiological processes. There is recent evidence that ATP receptors, characterized as P2 purinergic receptors, are expressed in the sensory hair cells of the auditory organ. The aim of the present study was to know whether other cell types of the organ of Corti, the supporting cells, were also sensitive to external ATP. In both types of supporting cells considered in this study, Deiters' cells (DCs) and Hensen's cells (HEs), extracellular ATP at sub-micromolar concentrations evoked a transient increase in [Ca2+]i as monitored with fluorescence microscopy using the calcium probe Indo-1. An apparent Kd of 0.5 and 0.9 microM was determined for DCs and HEs, respectively. Furthermore, we demonstrated that ATP stimulated Ca2+ release from internal stores in DCs, but not in HEs. Dynamic calcium imaging by confocal laser scanning microscopy of ATP induced Ca2+ mobilization demonstrated a calcium wave propagation in the cell body of DCs which originated in the phalangeal processes, suggesting a functional organization of Ca2+ sequestering stores in DCs.

Transient but not oscillating component of the calcium mobilizing response to gonadotropin-releasing hormone depends on calcium influx in pituitary gonadotrophs.

Gonadotropin-releasing hormone (GnRH)-stimulated changes in the cytosolic free Ca2+ concentration ([Ca2+]i) were studied in gonadotrophs cultured from 3-week ovariectomized rat pituitaries. One animal was used per cell preparation. [Ca2+]i was monitored in individual gonadotrophs by dual emission microspectrofluorimetry, using Indo-1 as the intracellular fluorescent Ca2+ probe. A short stimulation with GnRH evoked a complex concentration-dependent Ca2+ response in individual gonadotrophs. 0.1-1 nM GnRH triggered a series of sinusoidal-like [Ca2+]i oscillations superimposed upon a modest slow [Ca2+]i rise--the oscillating response mode--while 10-100 nM GnRH caused a biphasic increase in [Ca2+]i consisting of a monophasic transient and oscillations--the transient/oscillating response mode. Despite the consistency of Ca2+ responses, an inter-preparation heterogeneity of [Ca2+]i oscillations frequency was noticed. Moreover, we observed that, within a given cell preparation, the frequency of [Ca2+]i oscillations was independent of GnRH concentration whereas both peak [Ca2+]i and area under the [Ca2+]i versus time curve were concentration-dependent. Thus, in gonadotrophs, the presence of the GnRH signal would lead to [Ca2+]i oscillations, while the amplitude of the [Ca2+]i responses would code for the concentration of agonist. Both transient and oscillating components of GnRH responses depended on releasing activity of Ca(2+)-sequestering pools in as much as GnRH responses were unaffected by brief removal of external Ca2+, but suppressed by chelating intracellular free Ca2+ with BAPTA. However, prolonged exposure to a Ca(2+)-free medium suppressed the transient component while leaving the oscillating component unaffected. We therefore propose that gonadotrophs employ Ca(2+)-sequestering pools, whose maintenance depends on a slow Ca(2+)-entry, to give an amplitude-coded Ca2+ rise in response to a short GnRH stimulation.

Tamoxifen reduces calcium currents in a clonal pituitary cell line.

The effect of the anti-estrogen Tamoxifen (Tx) on membrane electrical properties and the underlying calcium (Ca2+) conductances was examined in the clonal pituitary cell line GH3/B6 which exhibits calcium action potentials at rest. Electrophysiological recordings (109 cells) were made using either high resistance intracellular microelectrodes or the whole-cell recording (WCR) patch-clamp technique. Electrical activities of 39 spontaneously active GH3/B6 cells were recorded with sharp microelectrodes filled with 3 M KCl. The spikes were Ca2+-dependent since they were blocked by Cobalt ions (Co2+, 5 mM). When applied directly to the recorded cell, Tx (10(-7) M) inhibited action potential firing. This blockade was accompanied by a discrete hyperpolarization of the membrane potential (-2.8 +/- 2 m V) from rest (-39.5 +/- 5 m V) and a 10% increase in the input membrane resistance. The effect stopped soon after Tx removal (mean 11.4 +/- 6 sec), and Tx solvent was unable to elicit the response. Current clamp WCR with pipettes containing potassium gluconate (KGlu, 140 mM) confirmed these results (30 cells), but the addition of cell extract to KGlu was necessary to prevent rundown of the response and to obtain reproducible action potential blockade. Short (1-5 min) or long term (48 h) pretreatment with estradiol (10(-7) to 10(-5) M) did not change the response to Tx, thus indicating that its effect was not mediated through estrogen receptors. Voltage clamp WCR study of the effect of Tx (10(-7) M) using pipettes filled with cesium chloride (140 mM) showed that both fast and slow inactivating calcium conductances were inhibited (38 cells). The fast inactivating Ca2+ current was reduced by about 60-80% whereas slow inactivating Ca2+ current was completely inhibited. This action may represent one way by which the antitumoral effect of this antiestrogen is mediated.

Rhythmic bursts of calcium transients in acute anterior pituitary slices.

Endocrine cells isolated from the anterior pituitary fire intracellular Ca2+ ([Ca2+]i) transients due to voltage-gated Ca2+ entry. However, the patterns of [Ca2+]i transients within the glandular parenchyma of the anterior pituitary are unknown. Here we describe, using real-time confocal laser microscopy, several spontaneous patterns of calcium signaling in acute pituitary slices prepared from male as well as cycling and lactating female rats. Forty percent of the cells demonstrated a spontaneous bursting mode, consisting of an active period of [Ca2+]i transients firing at a constant frequency, followed by a rest period during which cells were either silent or randomly active. The remaining recordings from endocrine cells either demonstrated random [Ca2+]i transients or were silent. These rhythmic bursts of [Ca2+]i transients, which required extracellular calcium, were detected in lactotrophs, somatotrophs, and corticotrophs within the acute slices. Of significance was the finding that the bursting mode could be adjusted by hypothalamic factors. In slices prepared from lactating rats, TRH recruited more bursting cells and finely adjusted the average duty cycle of [Ca2+]i bursts such that cells fired patterned bursts for approximately 70% of the recording period. Eighty-six percent of these cells were lactotrophs. Thus, the rhythmic [Ca2+]i bursts and their tuning by secretagogues may provide timing information that could encode for one or more cellular functions (e.g. exocytosis and/or gene expression) critical for the release of hormones by endocrine cells in the intact gland.

Somatostatin blocks Ca2+ action potential activity in prolactin-secreting pituitary tumor cells through coordinate actions on K+ and Ca2+ conductances.

The hypothalamic peptide somatostatin (SRIF) suppresses secretory activity in phenotypically distinct pituitary endocrine cells. We have used tight-seal whole-cell recording techniques to study the peptide's effects on the electrical properties of tumor pituitary cells derived from rat (GH3/B6) and human adenomas that secrete human PRL in a SRIF-sensitive manner. Both cell types exhibited qualitatively similar electrophysiological properties and electrical responses to SRIF. Under the experimental conditions employed the majority of cells spontaneously generated Ca2+-dependent actions potentials. The actions of the peptide on cellular excitability were markedly affected by the presence of horse and fetal calf sera. Without these additives the electrical responses faded and could not be studied in detail. Therefore, recordings were conducted in media containing sera. In the presence of sera almost all cells spontaneously generated Ca2+ action potentials, and peptide-induced changes in excitability were well preserved. SRIF depressed spontaneous and evoked action potential activity in a dose-dependent manner at concentrations that reduced intracellular free calcium ([Ca2+]i) and suppressed basal PRL release. Current and voltage clamp experiments revealed coordinate actions of the peptide on excitable membrane properties. SRIF (1 nM) enhanced a depolarization-activated, rapidly inactivating outward K+ current, thereby effectively reducing the rate at which action potentials occurred. Over the 10-1000 nM range SRIF slowly activated a virtually noninactivating K+ conductance over a wide range of membrane potential. This effectively hyperpolarized cells away from the threshold for triggering Ca2+-dependent action potentials and shunted the membrane. The peptide induced K+ conductance activated at the level of the resting potential was progressively lost during the intracellular dialysis of whole-cell recording. Dilute aqueous lysates of cells included in the patch pipette prevented much of the rundown of this SRIF-induced electrical response while inclusion of an ATP-regenerating system preserved some of the peptide action. Over the 10-100 nM concentration range SRIF also reduced voltage-dependent Ca2+ current. Furthermore, pretreatment of cells with pertussis toxin abolished SRIF action on cellular excitability, suggesting that SRIF can regulate the function of ionic channels through GTP-binding proteins (G proteins). The results demonstrate that SRIF acts coordinately on the primary conductances expressed in tumor PRL cells to attenuate or block Ca2+ action potential generation and thus Ga2+ entry from extracellular sources.(ABSTRACT TRUNCATED AT 400 WORDS)

Spontaneous and corticotropin-releasing factor-induced cytosolic calcium transients in corticotrophs.

Spontaneous and CRF-stimulated changes in the cytosolic free calcium concentration ([Ca2+]i) were studied in two types of corticotrophs: 1) cultured human ACTH-secreting pituitary adenoma cells (hACTH cells), and 2) identified small ovoid corticotrophs cultured from normal rat pituitaries. [Ca2+]i was monitored in individual corticotrophs by dual emission microspectrofluorimetry using indo-1 as the intracellular fluorescent Ca2+ probe. In hACTH cells, [Ca2+]i measurements were carried out in combination with electrophysiological recordings obtained using whole cell patch-clamp techniques. It was shown that a single spontaneous Ca(2+)-dependent action potential led to a marked transient increase in [Ca2+]i in human tumoral corticotrophs. Spontaneous fluctuations in [Ca2+]i were also observed in unpatched corticotrophs whether derived from human pituitary tumors or normal rat tissue. Based on their striking kinetic features and their sensitivity to external Ca2+, we suggest that these spontaneous [Ca2+]i transients were the consequence of action potential firing. Under separate voltage-clamp (patch-clamp) conditions, tumor corticotrophs showed two Ca2+ current components: a low threshold, rapidly inactivating (T-type) current, and a higher threshold, slowly inactivating (L-type) current. The dihydropyridine Ca2+ channel blocker PN 200-110 (100 nM) abolished the L-type current without affecting the T-type current, while the inorganic Ca2+ channel blocker Cd2+ (200 microM) suppressed both Ca2+ currents. The Na+ channel blocker tetrodotoxin (5 microM) did not affect inward currents in tumor corticotrophs. Both L- and T-type voltage-gated Ca2+ channels were involved in controlling [Ca2+]i transients in both tumor and normal corticotrophs, inasmuch as Cd2+ (200 microM) abolished [Ca2+]i) transients, while PN 200-110 (100 nM) greatly diminished, but did not completely abolish, [Ca2+]i transients. The latter did not appear to depend on a voltage-dependent Na+ influx, since they were unaffected by tetrodotoxin (5 microM). Corticotrophs generate [Ca2+]i transients in response to the hypothalamic secretagogue CRF by acting on their membrane excitability. Indeed, we demonstrated in combined fluorescent and electrophysiological experiments that CRF (100 nM) had a coordinate action on human tumoral corticotrophs comprised of a modest depolarization and an increase in the frequency of both action potentials and subsequent [Ca2+]i transients. A coincident increase in the peak amplitude of the [Ca2+]i transient and after hyperpolarization was also observed in some CRF-stimulated cells. CRF (100 nM) evoked qualitatively similar [Ca2+]i patterns in human tumoral and normal rat corticotrophs not subjected to patch-clamping.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrical properties of cultured human adrenocorticotropin-secreting adenoma cells: effects of high K+, corticotropin-releasing factor, and angiotensin II.

ACTH-secreting pituitary adenoma cells were cultured from specimens obtained by transphenoidal hypophysectomy in five patients with Cushing's disease. The majority of adenoma cells (90%) stained specifically with antiserum against human ACTH. The electrophysiological properties and response to hormones of these cells were studied with intracellular recording techniques under current clamp and voltage clamp conditions. Most (80%) of the cells fired action potentials that were Ca2+-dependent inasmuch as they were blocked by Co2+ (5 mM) and by removal of Ca2+ from the medium, but were unaffected by tetrodotoxin (0.3 mM) and by Na+ removal. The cells responded to factors known to stimulate ACTH release, including high K+, CRF, and angiotensin II (AII). High K+ (50 mM) induced a membrane depolarization in association with an increase in conductance. CRF (100 nM) produced a depolarization, a decrease in conductance, an increase in spike firing, and an increase in spike duration. Although AII was inactive in ordinary recordings, in cells loaded with lithium (Li+) to promote the phospholipid-dependent second messenger system, the peptide produced an increase in spike firing and spike duration with no change in membrane potential. The combination of CRF and AII (CRF + AII; 100 nM each) in Li+-loaded cells caused a greater excitatory effect than either peptide alone. Under voltage clamp, the response either to CRF or to CRF + AII could be attributed, at least in part, to the inhibition of a slow, voltage-dependent K+ current that is persistently active at resting potential. These results indicate that modulation of action potential firing may be an early step in the regulation of ACTH release from pituitary cells by known secretagogues. Since action potentials in these cells are associated with Ca2+ entry, the resulting changes in intracellular Ca2+ levels could mediate the effects of the hormones on secretion.

Growth hormone-releasing hormone (GHRH) neurons in GHRH-enhanced green fluorescent protein transgenic mice: a ventral hypothalamic network.

The hypothalamic GHRH neurons secrete pulses of GHRH to generate episodic GH secretion, but little is known about the mechanisms involved. We have made transgenic mice expressing enhanced green fluorescent protein (eGFP) specifically targeted to the secretory vesicles in GHRH neurons. GHRH cells transported eGFP from cell bodies in the arcuate nucleus to extensively arborized varicose fiber terminals in the median eminence. Patch clamp recordings from visually identified GHRH cells in mature animals showed spontaneous action potentials, often firing in short bursts up to 10 Hz. GHRH neurons received frequent synaptic inputs, as demonstrated by the recording of abundant inward postsynaptic currents, but spikes were followed by large after-hyperpolarizations, which limited their firing rate. Because many GHRH neurons lie close to the ventral hypothalamic surface, this was examined by wide-field binocular epifluorescence stereomicroscopy. This approach revealed an extensive horizontal network of GHRH cells at low power and individual fiber projections at higher power in the intact brain. It also showed the dense terminal projections of the GHRH cell population in the intact median eminence. This model will enable us to characterize the properties of individual GHRH neurons and their structural and functional connections with other neurons and to study directly the role of the GHRH neuronal network in generating episodic secretion of GH.

A secreted fluorescent reporter targeted to pituitary growth hormone cells in transgenic mice.

In stable transfection experiments in the GH-producing GC cell line, a construct containing the entire signal peptide and the first 22 residues of human GH linked in frame with enhanced green fluorescent protein (eGFP), produced brightly fluorescent cells with a granular distribution of eGFP. This eGFP reporter was then inserted into a 40-kb cosmid transgene containing the locus control region for the hGH gene and used to generate transgenic mice. Anterior pituitaries from these GH-eGFP transgenic mice showed numerous clusters of strongly fluorescent cells, which were also immunopositive for GH, and which could be isolated and enriched by fluorescence-activated cell sorting. Confocal scanning microscopy of pituitary GH cells from GH-eGFP transgenic mice showed a markedly granular appearance of fluorescence. Immunogold electron microscopy and RIA confirmed that the eGFP product was packaged in the dense cored secretory vesicles of somatotrophs and was secreted in parallel with GH in response to stimulation by GRF. Using eGFP fluorescence, it was possible to identify clusters of GH cells in acute pituitary slices and to observe spontaneous transient rises in their intracellular Ca2+ concentrations after loading with Ca2+ sensitive dyes. This transgenic approach opens the way to direct visualization of spontaneous and secretagogue-induced secretory mechanisms in identified GH cells.

The electrophysiological effects of thyrotropin-releasing hormone are similar in human TSH- and prolactin-secreting pituitary cells.

We studied the electrophysiological properties of individually characterized TSH-secreting cells cultured from pituitary fragments surgically removed from three patients, two who had primary TSH-secreting adenomas and one who had chronic TSH hypersecretion (hyperplasia) secondary to primary hypothyroidism. The TSH-secreting cells were excitable and had calcium-dependent action potentials. More than 80% of the cells cultured from the two patients with TSH-secreting adenomas were spontaneously active, whereas fewer cells (20%) cultured from the hypothyroid patient were spontaneously active. TRH (50 nmol/L) induced a complex pattern of electrical changes. The initial response was transient hyperpolarization (activation of potassium conductance), followed by increased low amplitude voltage fluctuations occasionally leading to action potentials. These TRH-induced electrophysiological changes were similar to those reported in rat and human PRL-secreting adenoma cells. These results suggest that TRH may have an identical mode of action in tumoral PRL and TSH cells. In the cells from the hypothyroid patient, the initial response to TRH cells was similar, but the second phase response was greater. The findings that the cells cultured from these patients behaved differently with regard to their electrophysiological characteristics (action potentials) and responses to TRH may reflect the different clinical conditions from which they were derived.