This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Copyright Permission Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Garnier, M. Articles by Vaudry, H. Search for Related Content PubMed PubMed Citation Articles by Garnier, M. Articles by Vaudry, H.

Pharmacological and Functional Characterization of Muscarinic Receptors in the Frog Pars Intermedia¹

European Institute for Peptide Research (IFRMP 23), Laboratory of Cellular and Molecular Neuroendocrinology, INSERM U-413, Unité Affiliée au Centre National de la Recherche Scientifique, University of Rouen, 76821 Mont-Saint-Aignan, France

Address all correspondence and requests for reprints to: Dr. H. Vaudry, European Institute for Peptide Research (IFRMP 23), Laboratory of Cellular and Molecular Neuroendocrinology, INSERM U-413, Unité Affiliée au Centre National de la Recherche Scientifique, University of Rouen, 76821 Mont-Saint-Aignan, France. E-mail: hubert.vaudry{at}univ-rouen.fr

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
The secretion of MSH from the intermediate lobe of the frog pituitary is regulated by multiple factors, including classical neurotransmitters and neuropeptides. In particular, acetylcholine (ACh), acting via muscarinic receptors, stimulates MSH release from frog neurointermediate lobes (NILs) in vitro. The aim of the present study was to characterize the type of receptor and the transduction pathways involved in the mechanism of action of ACh on frog melanotrope cells. The nonselective muscarinic receptor agonists muscarine and carbachol both stimulated MSH release from perifused frog NILs, whereas the M₁-selective muscarinic agonist McN-A-343 was virtually devoid of effect. Both the M₁>M₃ antagonist pirenzepine and the M₃>M₁ antagonist 4-diphenylacetoxy-N-methylpiperidine methiodide inhibited muscarine-induced MSH release. Administration of a brief pulse of muscarine in the vicinity of cultured melanotrope cells provoked a 4-fold increase in the cytosolic calcium concentration ([Ca²⁺]_i). Suppression of Ca²⁺ in the culture medium or addition of 3 mM Ni²⁺ abrogated the stimulatory effect of muscarine on [Ca²⁺]_i and MSH release. In contrast, -conotoxin GVIA and nifedipine did not significantly reduce the stimulatory effect of muscarine on [Ca²⁺]_i and MSH secretion. Exposure of NILs to muscarine provoked an increase in inositol phosphate formation, and this effect was dependent on extracellular Ca²⁺. The inhibitor of polyphosphoinositide turnover neomycin significantly attenuated the muscarine-evoked MSH release. Similarly, pretreatment of frog NILs with phorbol ester markedly reduced the secretory response to muscarine. In contrast, the stimulatory effect of muscarine on MSH release was not affected by the phospholipase A₂ inhibitor dimethyl eicosadienoic acid or by the tyrosine kinase inhibitors lavendustin A, genistein, and tyrphostin 25. Muscarine at a high concentration (10^-4 M) only produced a 40% increase in cAMP formation. Preincubation of frog NILs with pertussis toxin did not significantly affect the muscarine-induced stimulation of MSH release. These results indicate that frog melanotrope cells express a muscarinic receptor subtype pharmacologically related to the mammalian M₃ receptor. Activation of this receptor causes calcium influx through Ni²⁺-sensitive Ca²⁺ channels and subsequent activation of the phopholipase C/protein kinase C transduction pathway.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
IN AMPHIBIANS, the melanotropic peptide MSH, secreted by melanotrope cells of the pars intermedia, plays a pivotal role in the process of skin color adaptation (1). This camouflage aptitude allows the animals to escape to their predators and thus is essential for the survival of endangered amphibian species. The neuroendocrine mechanisms regulating the activity of melanotrope cells in amphibians has been mainly studied in two representative species, the African clawed toad Xenopus laevis (2, 3) and the European green frog Rana ridibunda (4, 5). Using these animal models, it has been demonstrated that MSH secretion is controlled by multiple factors, including classical neurotransmitters and neuropeptides. In the frog Rana ridibunda, the activity of melanotrope cells is inhibited by dopamine (6), -aminobutyric acid (7, 8), serotonin (9), adenosine (10, 11), -adrenergic agonists (12), and neuropeptide Y (13, 14) and is stimulated by ß-adrenergic agonists (12) and TRH (5, 15, 16, 17).

The intermediate lobe of the mammalian pituitary contains both melanotrope cells and corticotrope cells (18). The pars intermedia of amphibians, which is composed of a homogeneous population of melanotrope cells (19), represents a very appropriate model in which to investigate the transduction pathways involved in the mechanism of action of the neuroendocrine messengers regulating MSH secretion.

Acetylcholine (ACh) is recognized as an important modulator of the activity of various types of pituitary cells (20, 21, 22, 23, 24). In particular, ACh stimulates the activity of melanotrope cells in mammals (25, 26) and amphibians (27, 28, 29). In both toads and frogs, the effect of ACh on MSH secretion is mediated by muscarinic receptors (26, 28). Local synthesis of ACh has been demonstrated in the porcine (30) and toad (29) pars intermedia, indicating that ACh may exert an autocrine control on the activity of melanotrope cells.

The aim of the present study was to characterize the type of muscarinic receptor and the transduction mechanisms mediating the action of ACh in melanotrope cells of the frog pituitary.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Animals
Adult male frogs (Rana ridibunda) of about 30 g body weight were purchased from a commercial supplier (Couétard, St. Hilaire de Riez, France). The animals were maintained under artificial illumination (lights on from 0600–1800 h) in a temperature-controlled room (8 ± 0.5 C). The animals were killed by decapitation, and the neuroin-termediate lobes (NILs) were immediately dissected under a microscope. All animal manipulations were performed according to the recommendations of the French ethical committee and under the supervision of authorized investigators.

Reagents
Carbachol, muscarine, pirenzepine, isoproterenol, genistein, forskolin, isobutylmethylxanthine, pertussis toxin (PTX), nifedipine, -conotoxin GVIA (-CgTx), 7,7'-dimethyl eicosadienoic acid, EGTA, HEPES, Leibovitz culture medium (L15), collagenase type IA, and phorbol 12-myristate 13-acetate (PMA) were purchased from Sigma (St. Louis, MO). 4-Diphenylacetoxy-N-methylpiperidine methiodide (4-DAMP) and McN-A-343 were supplied by Research Biochemicals International (Natick, MA). Indo-1 acetoxymethylester was obtained from Molecular Probes (Eugene, OR). Bio-Gel P-2 and the anion exchange resin AG1-X8 (100–200 mesh; formate form) were obtained from Bio-Rad Laboratories (Hercules, CA). BSA (fraction V) was purchased from Boehringer Mannheim (Paris, France). Myo-[³H]inositol was obtained from Amersham (Aylesbury, UK). Tyrphostin 25 (Tyr-A25, AG 82) was obtained from Calbiochem (San Diego, CA). Lavendustin A was obtained from ICN Pharmaceuticals (Costa Mesa, CA). Kanamycin was purchased from Life Technologies (Grand Island, NY). The antibiotic-antimycotic solution and FBS were obtained from BioWhittaker (Gagny, France). Other chemicals were purchased from Sigma.

Perifusion technique
The perifusion system used in this study has been previously described in detail (15). Briefly, NILs were incubated for 15 min in a Ringer’s solution consisting of 15 mM HEPES, 112 mM NaCl, 2 mM KCl, and 2 mM CaCl₂ supplemented with 2 g/liter glucose and 0.3 g/liter BSA. The solution was gassed with O₂-CO₂, (95:5, vol/vol) before use, and the pH was adjusted to 7.35. Then NILs were layered between two beds of Bio-Gel P2 into a plastic column (id, 0.9 cm) delimited by two Teflon pestles (four NILs per perifusion chamber). The tissues were perifused with the Ringer’s solution at a constant flow rate (0.25 ml/min) and temperature (24 C). The effluent perifusate was collected as 7.5-min fractions during stabilization periods and 2.5-min fractions during infusion of the secretagogues. The fractions were immediately chilled at 4 C, and the concentration of MSH was measured in each fraction on the same day as the perifusion experiment using a double antibody RIA procedure (31). The perifusion profiles are expressed as percentages of the basal secretory level, calculated as the mean of four consecutive fractions collected just before the infusion of the secretagogue.

Cell culture
NILs were collected in Ca²⁺-free Ringer’s solution (15 mM HEPES, 112 mM NaCl, 2 mM KCl, 1 mM EGTA, 2 g/liter glucose, and 0.3 g/liter BSA). The tissues were enzymatically dispersed at 22 C for 20 min with collagenase (1.5 mg/ml) in the same solution. Nondissociated neural lobes were allowed to settle, and the supernatant containing dissociated pars intermedia tissue was sampled and centrifuged (30 x g, 5 min). After three rinses with Ca²⁺-free Ringer’s solution, the cells were dispersed by gentle aspiration through a siliconized Pasteur pipette with a flame-polished tip. The cells were resuspended in L15 culture medium adjusted to frog osmolality (L15/water = 1:0.4) supplemented with 0.2 g/liter glucose, 63 mg/liter CaCl₂, and 1% of the kanamycin and antibiotic-antimycotic solutions (fL15). Finally, cells were plated on 35-mm glass coverslips previously coated with poly-L-lysine (10 µg/ml) at a density of 15,000 cells/coverslip. When the cells had settled, coverslips were covered with 2 ml fL15 medium supplemented with 10% FBS. Cells were cultured in a humid atmosphere incubator at 24 C, and the culture medium was renewed every 48 h. Microfluorometric measurements were performed on 3- to 5-day-old cultured cells.

Intracellular calcium measurements
Cultured melanotrope cells were incubated at room temperature with 5 µM indo-1/acetoxymethylester in fL15 medium for 30 min and washed twice with Ringer’s solution. The cytosolic calcium concentration ([Ca²⁺]_i) was monitored by a dual emission microfluorometric system constructed from a Nikon Diaphot inverted microscope equipped for epifluorescence with an oil immersion objective (x100; CF Fluor series; numerical aperture, 1.3) as previously described (32). The fluorescence emission of indo-1, induced by excitation at 355 nm, was recorded at two wavelengths (405 nm, corresponding to the complexed form, and 480 nm, corresponding to the free form) by separate photometers (P1; Nikon, Melville, NY). The 405/480 ratio (R) was determined using an AS1-type acquisition card (Notocord Systems, Croissy-sur-Seine, France). All three signals (405 nm, 480 nm, and R) were continuously recorded with the JAD-FLUO program (version 1.2; Notocord Systems, Croissy-sur-Seine, France). [Ca²⁺]_i was calculated according to the formula established by Grynkiewicz et al. (33): [Ca²⁺]_i = K_d x ß (R - R_min)/(R_max - R), where R_min represents the minimum fluorescence ratio obtained after incubation of cells in Ringer’s solution containing 10 mM EGTA and 10 µM ionomycin, R_max is the maximum fluorescence ratio obtained after incubation of cells in Ringer’s solution containing 10 mM CaCl₂ and 10 µM ionomycin, and ß is the ratio of fluorescence yield from the Ca²⁺_min/Ca²⁺_max indicator at 480 nm. The values obtained for R_min, R_max, and ß were 0.16, 1.82, and 1.62, respectively. The dissociation constant for indo-1 (K_d = 250 nM) has been previously determined (34).

Inositol phospholipid turnover
Measurement of membrane phospholipid metabolites was performed as previously described (16). Whole NILs were incubated in fL15 medium with myo-[³H]inositol (100 µCi/ml) for 18 h. The pulse medium was then discarded, and the NILs were washed six times with Ringer’s solution supplemented with 1 mM inositol. The NILs were preincubated for 10 min with 10 mM LiCl and exposed for various durations to muscarine in the presence of 10 mM LiCl. The reaction was stopped by addition of ice-cold 20% trichloroacetic acid. The NILs were homogenized, and the membrane fraction was removed by centrifugation. Inositol phosphates contained in the supernatant were analyzed by anion exchange chromatography on AG1-X8 resin, as previously described (16). Free [³H]inositol was eluted by water, whereas inositol monophosphate (IP), inositol bisphosphate (IP₂), and inositol trisphosphate (IP₃) were sequentially eluted by a step gradient of ammonium formate (0.2, 0.45, and 0.8 M, respectively) in 0.1 M formic acid. For each sample, 38 fractions (4 ml each) were collected, and the radioactivity was determined in a 1217 Rackbeta counter (Wallac, Eury, France).

cAMP measurement
Whole NILs were preincubated for 30 min at room temperature with 0.1 mM isobuthylmethylxanthine. The NILs were then incubated for 20 min with muscarine, isoproterenol, or forskolin. The reaction was stopped by addition of ice-cold 20% trichloroacetic acid. NILs were homogenized and centrifuged (10,000 x g for 10 min). Trichloroacetic acid was eliminated from the supernatant by three successive rinses with 1 ml water-saturated diethyl ether. After evaporation of the ether phase, the supernatant was lyophilized, and the cAMP content in the dried extract was measured by RIA, following the procedure recommended in the cAMP RIA kit (Amersham).

Statistical analysis
Values are expressed as the mean ± SEM. Statistical comparisons between groups were made using ANOVA, followed by Student’s t test. Differences were taken to be statistically significant at P < 0.05.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Pharmacological characterization of muscarinic receptors
Administration of graded concentrations of muscarine to perifused frog NILs induced a dose-related stimulation of MSH release (Fig. 1, A and B). The minimum effective concentration was 3 x 10^-6 M. At a concentration of 10^-4 M, muscarine caused a 3-fold increase in MSH secretion (Fig. 1A). The dose-response curves obtained with various muscarinic agonists are compared in Fig. 1B. The nonselective muscarinic receptor agonists muscarine and carbachol both stimulated MSH release in a concentration-dependent manner, and the ED₅₀ values were, respectively, 1.2 x 10^-5 and 3.2 x 10^-6 M. In contrast, the M₁-selective muscarinic agonist McN-A-343 was virtually devoid of effect on MSH release from perifused frog NILs (Fig. 1B).

View larger version (27K): [in this window] [in a new window]   Figure 1. Effect of muscarinic receptor agonists on MSH secretion from perifused frog NILs. A, Perifusion profiles showing effect of graded concentrations of muscarine (Musc; 10 min) on MSH release. Profiles represent the mean (±SEM) secretion pattern of four to seven independent perifusion experiments. The mean basal level of MSH release (100% basal level) was calculated as the mean MSH concentration in the four consecutive fractions (30 min; ) collected before administration of the muscarinic agonist. B, Semilogarithmic plot showing the effects of increasing concentrations of the nonselective muscarinic receptor agonists muscarine (Musc) and carbachol (Carb) and the M1-selective agonist McN-A-343 (McN) on MSH release from perifused frog NILs. All experimental values were calculated from data similar to those presented in A. Each point represents the mean (±SEM) of three to seven experiments. The mean basal level of MSH release in these experiments was 77 ± 11 pg/min·NIL.

View larger version (21K): [in this window] [in a new window]   Figure 2. Effect of muscarine in the absence or presence of muscarinic receptor antagonists on MSH release from perifused frog NILs. A, Perifusion profiles showing effect of muscarine (Musc; 10-4 M; 10 min) on MSH release in control conditions (left panel) or during prolonged administration of the M3>M1 antagonist 4-DAMP (10-6 M; right panel). The antagonist was administered 45 min before the pulse of muscarine. Profiles represent the mean (±SEM) secretion pattern of four independent perifusion experiments. See Fig. 1 for other designations. B, Semilogarithmic plot showing the effects of increasing concentrations of the M1>M3 antagonist pirenzepine (Pir) and the M3>M1 antagonist 4-DAMP on MSH release induced by muscarine (10-4 M). All experimental values were calculated from data similar to those presented in A. Each point represents the mean (±SEM) of three or four independent experiments. Results are expressed as a percentage of the response induced by muscarine in the absence of antagonist. The mean basal level of MSH release in these experiments was 200 ± 19 pg/min·NIL. **, P < 0.01; ***, P < 0.001.

View larger version (21K): [in this window] [in a new window]   Figure 3. Effect of muscarine (10-4 M; 10 sec) on [Ca2+]i in cultured frog melanotrope cells. A, In the presence of 2 mM Ca2+, muscarine induced an immediate increase in [Ca2+]i. The profile represents the mean (±SEM) response of 26 cells. B, In calcium-free medium containing 3 mM EGTA, muscarine did not modify [Ca2+]i. The profile represents the mean (±SEM) response of 17 cells. The arrow indicates the onset of muscarine administration.

View larger version (15K): [in this window] [in a new window]   Figure 4. Effect of calcium suppression (Ca2+, 0; EGTA, 3 mM; A) or perifusion with NiCl2 (Ca2+, 2 mM; Ni2+, 3 mM; B) on basal and muscarine-induced MSH release. The pulses of muscarine (Musc; 10-4 M; 10 min) were administered 45 min after the onset of perifusion with Ca2+-free or Ni2+-containing medium. Profiles represent the mean (±SEM) secretion pattern of 4 (A) and 5 (B) independent perifusion experiments. The mean basal level of MSH release in these experiments was 69 ± 10 pg/min·NIL. See Fig. 1 for other designations.

View larger version (14K): [in this window] [in a new window]   Figure 5. Effect of muscarine (10-4 M; 10 sec) on [Ca2+]i in cultured frog melanotrope cells in the presence of calcium channel blockers. A, Effect of muscarine on [Ca2+]i in the presence of the L-type calcium channel blocker, nifedipine (10-5 M). B, Effect of muscarine on [Ca2+]i in the presence of the N-type calcium channel blocker, -conotoxin GVIA (10-6 M). Cells were incubated with nifedipine or -conotoxin GVIA for 20–60 min before the administration of the pulse of muscarine. Profiles represent the mean (±SEM) responses of 14 (A) and 15 cells (B). The arrow indicates the onset of muscarine administration.

View larger version (25K): [in this window] [in a new window]   Figure 6. Effect of muscarine in the absence or presence of calcium channel blockers on MSH release from perifused frog NILs. A single pulse of muscarine (Musc; 10-4 M; 10 min) was administered under control conditions (A) or during prolonged infusion of 1 µM -CgTx (B), 10 µM nifedipine (C), or 100 µM nifedipine (D). Profiles represent the mean (±SEM) secretion pattern of three to six independent perifusion experiments. The mean basal level of MSH release in these experiments was 126 ± 22 pg/min·NIL. See Fig. 1 for other designations.

View larger version (12K): [in this window] [in a new window]   Figure 7. Effects of muscarine on IP3, IP2, and IP1 formation in myo-[3H]inositol-prelabeled frog NILs. After a 10-min preincubation with 10 mM LiCl, NILs were incubated in the presence of 10-4 M muscarine for the times indicated. Results are expressed as a percentage of the muscarine-induced inositol phosphate (IPx) level in the control. Each value represents the mean (±SEM) of 5–14 independent experiments. Mean inositol phosphate levels in controls were 292 ± 26, 1,160 ± 104, and 16,332 ± 1,490 cpm/NIL, respectively. *, P < 0.05; **, P < 0.01; ***, P < 0.001.

View larger version (24K): [in this window] [in a new window]   Figure 8. Effect of EGTA on muscarine-induced inositol phosphate (IPx) formation. Myo-[3H]inositol-labeled NILs were preincubated for 20 min in HEPES buffer in the absence or presence of 6 mM EGTA. NILs were then incubated for 20 min in the same medium in the absence or presence of muscarine (10-4 M). Results are expressed as a percentage of the IPx level in the absence of EGTA and muscarine. Data are the mean (±SEM) values from five independent experiments. *, P < 0.05; **, P < 0.01.

View larger version (19K): [in this window] [in a new window]   Figure 9. Effect of muscarine in the absence or presence of the phosphatidylinositol turnover blocker neomycin on MSH release from perifused frog NILs. A single pulse of muscarine (Musc; 10-4 M; 10 min) was administered in control conditions (left panel) or during prolonged infusion of neomycin (3 mM; 110 min; right panel). Profiles represent the mean (±SEM) secretion pattern of six independent perifusion experiments. The mean basal level of MSH release in these experiments was 119 ± 7 pg/min·NIL. See Fig. 1 for other designations.

View larger version (15K): [in this window] [in a new window]   Figure 10. Effect of long term treatment with PMA on muscarine-induced MSH release from perifused frog NILs. Intact NILs were incubated for 24 h in fL15 alone (left panel) or in fL15 supplemented with PMA (10-6 M; right panel). Then, a single pulse of muscarine (Musc; 10-4 M) was administered for 10 min. Profiles represent the mean (±SEM) secretion pattern of four independent perifusion experiments. The mean basal level of MSH release in these experiments was 98 ± 12 pg/min·NIL. See Fig. 1 for other designations.

View larger version (34K): [in this window] [in a new window]   Figure 11. Effects of muscarine, isoproterenol, and forskolin on cAMP content in frog NILs. Intact NILs were incubated in HEPES buffer alone (C, control) or supplemented with 100 µM muscarine (Musc), 10 µM isoproterenol (Iso), or 50 µM forskolin (FK). Data are the mean (±SEM) values from 5–14 independent experiments. **, P < 0.01; ***, P < 0.001 (vs. control).

Effect of PTX on muscarine-induced MSH secretion

View larger version (22K): [in this window] [in a new window]   Figure 12. Effect of PTX pretreatment on muscarine-induced MSH release from perifused frog NILs. Intact NILs were incubated for 18 h in fL15 alone (left panel) or in fL15 supplemented with PTX (1 µg/ml; right panel). Then, a single pulse of muscarine (Musc; 10-4 M) was administered for 10 min. Profiles represent the mean (±SEM) secretion pattern of four independent perifusion experiments. The mean basal level of MSH release in these experiments was 90 ± 6 pg/min·NIL. See Fig. 1 for other designations.

Effect of tyrosine kinase inhibitors on muscarine-induced MSH secretion

View larger version (24K): [in this window] [in a new window]   Figure 13. Effect of tyrosine kinase inhibitors on muscarine-induced MSH release from perifused frog NILs. A single pulse of muscarine (Musc; 10-4 M; 10 min) was administered under control conditions (A) or during prolonged infusion of 0.1 µM lavendustin A (B), 10 µM genistein (C), or 100 µM tyrphostin 25 (C). Profiles represent the mean (±SEM) secretion pattern of three to six independent perifusion experiments. The mean basal level of MSH in these experiments was 104 ± 14 pg/min·NIL. See Fig. 1 for other designations.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

However, five subtypes of muscarinic receptors have now been identified (35), allowing a more rigorous pharmacological characterization of the receptor subtypes. In particular, it was found that pirenzepine does not clearly discriminate between the M₁ and M₃ receptor subtypes (36).

The present study has shown that the nonspecific muscarinic agonists muscarine and carbachol both induced a dose-dependent stimulation of MSH release, whereas the selective M₁-receptor agonist McN-A-343 did not affect the secretory activity of frog NILs, indicating that M₁ receptors are not involved in the stimulatory effect of ACh on MSH secretion. The fact that the M₃>M₁ antagonist 4-DAMP was 5 times more potent than the M₁>M₃ antagonist pirenzepine in inhibiting the muscarine-evoked stimulation of MSH secretion suggests that the effect of ACh on frog NIL is mediated by M₃, rather than M₁, receptors. Consistent with this observation, it has been reported that M₃ receptors are expressed in various types of endocrine cells (37, 38, 39).

Transduction mechanisms associated with activation of muscarinic receptors in frog melanotrope cells
Stimulation of M₁, M₃, and M₅ muscarinic receptors can activate a number of signaling pathways (see Ref. 40 for review). Although these receptor subtypes are generally associated with activation of polyphosphoinositide turnover, the involvement of PLA₂ and phospholipase D, adenylyl cyclase, and tyrosine kinases has also been described. In the present study, we have investigated the transduction mechanisms involved in the muscarine-induced stimulation of MSH release in frog NILs.

Administration of muscarine to cultured frog melanotrope cells provoked a rapid, monophasic elevation of [Ca²⁺]_i. Muscarinic agonists usually induce an immediate transient [Ca²⁺]_i rise due to mobilization of intracellular Ca²⁺ stores, followed by a sustained plateau phase resulting from Ca²⁺ influx (36). When frog melanotrope cells were incubated under Ca²⁺-free conditions, the [Ca²⁺]_i increase evoked by muscarine was totally abolished. Similarly, the stimulatory effect of muscarine on MSH release was abrogated when frog NILs were perifused with Ca²⁺-free or Ni²⁺-supplemented medium. These results indicate that the response of melanotrope cells to muscarine requires calcium influx. However, neither the L-type Ca²⁺ channel blocker nifedipine nor the N-type Ca²⁺ channel blocker -CgTx could prevent the elevation of [Ca²⁺]_i provoked by muscarine. Likewise, the stimulatory effect of muscarine on MSH release was not significantly affected by addition of nifedipine or -CgTx in the perifusion medium. Administration of a high concentration of nifedipine (100 µM), which was supposed to block low voltage activated Ca²⁺ channels (T channels) (41), did not inhibit the stimulatory effect of muscarine on MSH release either. These data suggest that the Ca²⁺ influx involved in the secretory response to muscarine may be accounted for by activation of P- or Q-type channels. Consistent with this hypothesis, the occurrence of P- and Q-type Ca²⁺ channels has been recently described in rat melanotrope cells (42). Alternatively, muscarinic receptors might activate receptor-operated Ca²⁺ channels (43). Electrophysiological studies are clearly required to investigate the type of Ca²⁺ channels implicated in the muscarine-induced Ca²⁺ entry.

The present data have shown that muscarine induces a significant increase in inositol phosphate formation in frog NILs. In addition, neomycin, a drug known to block PI turnover by directly binding to PIP₂ and PIP (44), inhibited the muscarine-evoked stimulation of MSH release. In contrast, pretreatment of NILs with PTX did not affect the secretory response of the tissue to muscarine. These data indicate that the stimulatory effect of muscarine on frog melanotrope cells can be ascribed to activation of a phospholipase C (PLC) through a PTX-insensitive G protein. In agreement with these findings, it has been shown that M₂ and M₄ muscarinic receptors are coupled to PTX-sensitive G proteins, whereas M₁, M₃, and M₅ muscarinic receptors are generally coupled to PTX-insensitive G proteins (36). Although the implication of a PLA₂ in the mechanism of action of ACh has been described in various models (45), including frog adrenocortical cells (46), our data have shown that PLA₂ is not involved in the muscarine-evoked stimulation of MSH release in the frog pars intermedia. Finally, the fact that suppression of extracellular calcium totally abolished the stimulatory effect of muscarine on inositol lipid turnover indicated that the calcium influx provoked by muscarine was necessary for activation of PLC. In agreement with this idea, it has been reported that PLC activity is regulated by physiologically relevant Ca²⁺ concentrations (47, 48, 49).

Administration of a short pulse of PMA to perifused frog NILs induced a significant stimulation of MSH release (data not shown), indicating the importance of PKC in the regulation of MSH secretion. In contrast, prolonged exposure of NILs to PMA, which is known to induce down-regulation of PKC (50), markedly reduced the effect of muscarine on MSH release. These data confirmed that the stimulatory action of ACh on frog melanotrope cells is mediated through the PLC/PKC transduction pathway.

It has been previously shown that M₂ and M₄ muscarinic receptors are negatively coupled to adenylate cyclase, whereas activation of odd-numbered receptors is associated with either a decrease (51) or an increase in the cAMP level. The present study has shown that muscarine causes only a slight increase in cAMP formation in frog NILs. This effect of muscarine could be secondary to the elevation of [Ca²⁺]_i and/or to PKC activation, as described in other models (52, 53, 54). It has also been found that stimulation of muscarinic receptors (43, 55, 56), particularly the M₃ receptor subtype (57, 58, 59), can activate a tyrosine kinase. However, the stimulatory effect of muscarine on MSH release was not affected by three potent tyrosine kinase inhibitors, which have recently been shown to potentiate the inhibitory effect of -aminobutyric acid on frog melanotrope cells (60). These data suggest that tyrosine phosphorylation is not involved in the transduction events promoted by activation of muscarinic receptors in the frog pars intermedia.

Figure 14 summarizes the proposed mechanism of action of ACh on frog melanotrope cells as revealed by the present study. Activation of an M₃-like muscarinic receptor induces Ca²⁺ influx via Ni²⁺-sensitive calcium channels. ACh also activates a phospholipase C whose activity strongly depends on Ca²⁺ influx and causes a modest stimulation of adenylyl cyclase. In addition to Ca²⁺ mobilization, activation of PKC is implicated in the secretory response of frog melanotrope cells to ACh. In contrast, PLA₂ and tyrosine kinases do not appear to play any significant role in the cholinergic stimulation of MSH release.

View larger version (19K): [in this window] [in a new window]   Figure 14. Schematic representation summarizing the intracellular events associated with cholinergic stimulation of frog melanotrope cells. Binding of ACh to a muscarinic receptor pharmacologically related to the mammalian M3 receptor induces Ca2+ entry via Ni2+-sensitive calcium channels. ACh also causes activation of PLC through a PTX-insensitive G protein, generating diacylglycerol (DAG) and IP3. Concurrently, ACh provokes a modest stimulation of adenylyl cyclase (AC). The increase in [Ca2+]i resulting from Ca2+ influx is required for the ACh-induced stimulation of PLC and might be responsible for the activation of adenylyl cyclase (dotted line). The increase in [Ca2+]i and the activation of PKC are both involved in the ACh-induced stimulation of MSH release.

	Acknowledgments

 
The authors thank Miss C. Buquet for technical support during cell culture.

	Footnotes

 
¹ This work was supported by grants from INSERM U-413, the European Union (Human Capital and Mobility Program, Grant ERBCHRXCT920017), and the Conseil Régional de Haute-Normandie.

² Recipient of a fellowship from the Ministère de l’Education Nationale, de l’Enseignement Supérieur, et de la Recherche.

Received February 6, 1998.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Hadley ME, Bagnara JT 1969 Integrated nature of chromatophore responses in the in vitro frog skin bioassay. Endocrinology 84:69–82[Medline]
2. Roubos EW 1997 Background adaptation by Xenopus laevis: a model for studying neuronal information processing in the pituitary pars intermedia. Comp Biochem Physiol 118:533–550[CrossRef]
3. Jenks BG, Leenders HJ, Martens GJM, Roubos EW 1993 Adaptation physiology: the functioning of pituitary melanotrophs cells during background adaptation of the amphibian Xenopus laevis. Zool Sci 10:1–11
4. Tonon MC, Desrues L, Lamacz M, Chartrel N, Jenks BG, Vaudry H 1993 Multihormonal regulation of pituitary melanotrophs. Ann NY Acad Sci 680:175–187[Medline]
5. Gonzalez de Aguilar JL, Malagon MM, Vazquez-Martinez RM, Lihrmann I, Tonon MC, Vaudry H, Gracia-Navarro F 1997 Two frog melanotrope cell subpopulations exhibiting distinct biochemical and physiological patterns in basal conditions and under thyrotropin-releasing hormone stimulation. Endocrinology 138:970–977[Abstract/Free Full Text]
6. Desrues L, Lamacz M, Jenks BG, Vaudry H, Tonon MC 1993 Effect of dopamine on adenylate cyclase activity, polyphosphoinositide and cytosolic calcium concentrations in frog pituitary melanotrophs. J Endocrinol 136:421–429[Abstract/Free Full Text]
7. Louiset E, van de Put FHMM, Tonon MC, Basille C, Jenks BG, Vaudry H, Cazin L 1990 Electrophysiological evidence for the existence of GABA_A receptors in cultured frog melanotrophs. Brain Res 517:151–156[CrossRef][Medline]
8. Desrues L, Vaudry H, Lamacz M, Tonon MC 1995 Mechanism of action of gamma-aminobutyric acid on frog melanotrophs. J Mol Endocrinol 14:1–12[Abstract/Free Full Text]
9. Lamacz M, Tonon MC, Leboulanger F, Héry F, Verhofstad AJ, Pelletier G, Vaudry H 1989 Effect of serotonin on -melanocyte-stimulating hormone (-MSH) secretion from perifused frog neurointermediate lobes. Evidence for the presence of serotonin-containing cells in the frog pars intermedia. J Endocrinol 122:135–146[Abstract/Free Full Text]
10. Chartrel N, Tonon MC, Lamacz M, Vaudry H 1992 Adenosine inhibits -melanocyte-stimulating hormone release from frog pituitary melanotrophs. Evidence for the involvement of A1 adenosine receptors negatively coupled to adenylate-cyclase. J Neuroendocrinol 4:751–757
11. Mei YA, Vaudry H, Cazin L 1994 Inhibitory effect of adenosine on electrical activity of frog melanotrophs mediated through A1 purinergic receptors. J Physiol 481:349–355[Medline]
12. Lamacz M, Garnier M, Héry F, Tonon MC, Vaudry H 1995 Adrenergic control of alpha-melanocyte-stimulating hormone release in frog pituitary is mediated by both beta- and a nonconventional alpha-2 subtype of adrenoreceptors. Neuroendocrinology 61:430–436[Medline]
13. Danger JM, Leboulanger F, Guy J, Tonon MC, Benyamina M, Martel JC, Saint-Pierre S, Pelletier G, Vaudry H 1986 Neuropeptide Y in the intermediate lobe of the frog pituitary acts as an -MSH-release inhibiting factor. Life Sci 39:1183–1192[CrossRef][Medline]
14. Chartrel N, Conlon JM, Danger JM, Fournier A, Tonon MC, Vaudry H 1991 Characterization of melanotropin-release-inhibiting factor (melanostatine) from frog brain: homology with human neuropeptide Y. Proc Natl Acad Sci USA 88:3862–3866[Abstract/Free Full Text]
15. Tonon MC, Leroux P, Stoeckel ME, Jegou S, Pelletier G, Vaudry H 1983 Catecholaminergic control of -melanocyte-stimulating hormone (-MSH) release by frog neurointermediate lobe in vitro: evidence for direct stimulation of -MSH release by thyrotropin-releasing hormone. Endocrinology 112:133–141[Abstract]
16. Desrues L, Tonon MC, Vaudry H 1990 Thyrotropin-releasing hormone stimulates polyphosphoinositide metabolism in the frog neurointermediate lobe. J Mol Endocrinol 5:129–136[Abstract/Free Full Text]
17. Galas L, Lamacz M, Garnier M, Roubos EW, Tonon MC, Vaudry H Involvement of extracellular and intracellular calcium sources in TRH-induced -MSH secretion from frog melanotrope cells. Mol Cell Endocrinol, in Press
18. Stoeckel ME, Schmitt G, Porte A 1981 Fine structure and cytochemistry of the mammalian pars intermedia. Ciba Found Symp 81:101–127[Medline]
19. Benyamina M, Delbende C, Jégou S, Leroux P, Leboulenger F, Tonon MC, Guy J, Pelletier G, Vaudry H 1986 Localization and identification of -melanocyte-stimulating hormone (-MSH) in the frog brain. Brain Res 366:230–237[CrossRef][Medline]
20. Schaeffer JM, Hsueh JW 1980 Acetylcholine receptors in the rat anterior pituitary gland. Endocrinology 106:1377–1381[Medline]
21. Schlegel W, Wuarin F, Zbaren C, Zahnd GR 1985 Lowering of cytosolic free Ca²⁺ by carbachol, a muscarinic cholinergic agonist, in clonal pituitary cells (GH₃ cells). Endocrinology 117:976–981[Abstract]
22. Canonico PL, Jarvis WD, Sortino MA, Scapagnini U, MacLeod RM 1987 Cholinergic stimulation of inositol phosphate production in cultured anterior pituitary cells. Neuroendocrinology 46:306–311[Medline]
23. Carmeliet P, Denef C 1988 Immunocytochemical and pharmacological evidence for an intrinsic cholinomimetic system modulating prolactin and growth hormone release in rat pituitary. Endocrinology 123:1128–1139[Abstract]
24. Pinter I, Makara GB, Acs Zs 1996 Acetylcholine stimulates growth hormone secretion in the neonatal rat pituitary. J Neuroendocrinol 8:935–939[CrossRef][Medline]
25. Zhang ZW, Feltz P 1990 Nicotinic acetylcholine receptors in porcine hypophyseal intermediate lobe cells. J Physiol 422:83–101[Abstract/Free Full Text]
26. Poisbeau P, Trouslard J, Feltz P, Schlichter R 1994 Calcium influx through neuronal-type nicotinic acetylcholine receptors present on the neuroendocrine cells of the porcine pars intermedia. Neuroendocrinology 60:378–388[Medline]
27. Lamacz M, Tonon MC, Louiset E, Cazin L, Strosberg D, Vaudry H 1989 Acetylcholine stimulates -melanocyte-stimulating hormone release from frog pituitay melanotrophs through activation of muscarinic and nicotinic receptors. Endocrinology 125:707–714[Abstract]
28. Louiset E, Cazin L, Duval M, Lamacz M, Tonon MC, Vaudry H 1990 Effect of acetylcholine on the electrical and secretory activities of frog pituitary melanotrophs. Brain Res 533:300–308[CrossRef][Medline]
29. Van Strien FJC, Roubos E, Vaudry H, Jenks BG 1996 Acetylcholine autoexcites the release of proopiomelanocortin-derived peptides from melanotrope cells of Xenopus laevis via an M₁ muscarinic receptor. Endocrinology 137:4298–4307[Abstract]
30. Tandon A, Collier B, Zhang ZW, Feltz P 1991 Acetylcholine synthesis in a primary culture of porcine intermediate lobe cells. J Neuroendocrinol 3:274–277
31. Vaudry H, Tonon MC, Delarue C, Vaillant R, Kraicer J 1978 Biological and radioimmunological evidence for melanocyte-stimulating hormone (MSH) of extrapituitary origin in the rat brain. Neuroendocrinology 27:9–24[Medline]
32. Larcher A, Lamacz M, Delarue C, Vaudry H 1992 Effect of vasotocin on cytosolic free calcium concentrations in frog adrenocortical cells in primary culture. Endocrinology 131:1087–1093[Abstract]
33. Grynkiewicz G, Poenie M, Tsien RY 1985 A new generation of Ca²⁺ indicators with greatly improved fluorescence properties. J Biol Chem 260:3440–3450[Abstract/Free Full Text]
34. Mollard P, Guérineau N, Audin J, Dufy B 1989 Measurement of Ca²⁺ transients using simultaneous dual-emission microspectrofluorimetry and electrophysiology in individual pituitary cells. Biochem Biophys Res Commun 164:1045–1052[CrossRef][Medline]
35. Bonner TI, Buckley NJ, Young AC, Brann MR 1987 Identification of a family of muscarinic acetylcholine receptor genes. Science 237:527–532[Abstract/Free Full Text]
36. Caulfield MP 1993 Muscarinic receptors-characterization, coupling and function. In: Watson SP (ed) Pharmacology and Therapeutics. Pergamon Press, New York, vol 58:319–379
37. Verspohl EJ, Tacke R, Mutschler E, Lambrecht G 1990 Muscarinic receptor subtypes in rat pancreatic islets: binding and functional studies. Eur J Pharmacol 178:303–311[Medline]
38. Walker SW, Strachan MW, Lightly ER, Williams BC, Bird IM 1990 Acetylcholine stimulates cortisol secretion through the M₃ muscarinic receptor linked to a polyphosphoinositide-specific phospholipase C in bovine adrenal fasciculata/reticularis cells. Mol Cell Endocrinol 72:227–238[CrossRef][Medline]
39. Abello J, Ye F, Bosshard A, Bernard C, Cuber JC, Chayvialle JA 1994 Stimulation of glucagon-like peptide-1 secretion by muscarinic agonist in a murine intestinal endocrine cell line. Endocrinology 134:2011–2017[Abstract]
40. Felder CC 1995 Muscarinic acetylcholine receptors: signal transduction through multiple effectors. FASEB J 9:619–625[Abstract]
41. Rossier MF, Burnay MM, Valloton MB, Capponi AM 1996 Distinct functions of T- and L-type calcium channels during activation of bovine adrenal glomerulosa cells. Endocrinology 137:4817–4826[Abstract]
42. Ciranna L, Feltz P, Schlichter R 1996 Selective inhibition of high voltage-activated L-type and Q-type Ca²⁺ currents by serotonin in rat melanotrophs. J Physiol 490:595–609[Medline]
43. Felder CC, MacArthur L, Ma AL, Gusovsky F, Kohn EC 1993 Tumor-suppression function of muscarinic acetylcholine receptors is associated with activation of receptor-operated calcium influx. Proc Natl Acad Sci USA 90:1706–1710[Abstract/Free Full Text]
44. Carney DH, Scott DL, Gordon EA, LaBelle EF 1985 Phosphoinositides in mitogenesis: neomycin inhibits thrombin-stimulated phosphoinositide turnover and initiation of cell proliferation. Cell 42:479–488[CrossRef][Medline]
45. Conklin BR, Brann MR, Buckley NJ, Ma AL, Bonner TI, Axelrod J 1988 Stimulation of arachidonic acid release and inhibition of mitogenesis by cloned genes for muscarinic receptor subtypes stably expressed in A9 L cells. Proc Natl Acad Sci USA 85:8698–8702[Abstract/Free Full Text]
46. Delarue C, Leboulenger F, Homo-Delarche F, Benyamina M, Lihrmann I, Perroteau I, Vaudry H 1986 Involvement of prostaglandins in the response of frog adrenocortical cells to muscarinic receptor activation. Prostaglandins 32:87–91[CrossRef][Medline]
47. Honda K, Takano Y, Kamiya H 1996 Involvement of protein kinase C in muscarinic agonist-induced contractions of guinea pig ileal longitudinal muscle. Gen Pharmacol 27:957–961[Medline]
48. Rhee SG, Choi KD 1992 Regulation of inositol phospholipid-specific phospholipase C isozymes. J Biol Chem 267:12393–12396[Free Full Text]
49. Yang CM, Chou SP, Wang YY, Hsieh JT, Ong R 1993 Muscarinic regulation of cytosolic free calcium in canine tracheal smooth muscle cells: Ca²⁺ requirement for phospholipase C activation. Br J Pharmacol 110:1239–1247[Medline]
50. Cheng K, Chan WW, Arias R, Barreto A Jr, Butler B 1992 PMA-sensitive protein kinase C is not necessary in TRH-stimulated prolactin release from female rat pituitary cells. Life Sci 51:1957–1967[CrossRef][Medline]
51. Stein R, Pinkas-Kramarski R, Sokolovsky M 1988 Cloned M1 muscarinic receptors mediate both adenylate cyclase inhibition and phosphoinositide turnover. EMBO J 7:3031–3035[Medline]
52. Choi EJ, Wong ST, Hinds TR, Storm DR 1992 Calcium and muscarinic agonist stimulation of type I adenylylcyclase in whole cells. J Biol Chem 267:12440–12442[Abstract/Free Full Text]
53. Baumgold J, Fishman PH 1988 Muscarinic receptor-mediated increase in cAMP levels in SK-N-SH human neuroblastoma cells. Biochem Biophys Res Commun 154:1137–1143[CrossRef][Medline]
54. Felder C.C, Kanterman, RY, Ma AL, Axelrod J 1989 A transfected m1 muscarinic receptor stimulates adenylate cyclase via phosphatidylinositol hydrolysis. J Biol Chem 264:20356–20362[Abstract/Free Full Text]
55. Gusovsky F, Lueders JE, Kohn EC, Felder CC 1993 Muscarinic receptor-mediated tyrosine phosphorylation of phospholipase C-. J Biol Chem 268:7768–7772[Abstract/Free Full Text]
56. Wan Y, Kurosaki T, Huang XY 1996 Tyrosine kinases in activation of the MAP kinase cascade by G-protein-coupled receptors. Nature 380:541–544[CrossRef][Medline]
57. Schmidt M, Hüwe SM, Fasselt B, Homann D, Rümenapp U, Sandmann J, Jakobs KH 1994 Mechanisms of phospholipase D stimulation by m3 muscarinic acetylcholine receptors. Evidence for involvement of tyrosine phosphorylation. Eur J Biochem 225:667–675[Medline]
58. Slack BE, Breu J, Petryniak MA, Srivastava K, Wurtman RJ 1995 Tyrosine phosphorylation-dependent stimulation of amyloid precursor protein secretion by the m3 muscarinic acetylcholine receptor. J Biol Chem 270:8337–8344[Abstract/Free Full Text]
59. Soltoff SP, Toker A 1995 Carbachol, substance P, and phorbol ester promote the tyrosine phosphorylation of protein kinase C in salivary gland epithelial cells. J Biol Chem 270:13490–13495[Abstract/Free Full Text]
60. Castel H, Louiset E, Vaudry H, Cazin L 1998 A protein tyrosine kinase modulates GABA_A receptor in frog pituitary melanotrope cells. Ann NY Acad Sci 839:74–79[CrossRef][Medline]

This article has been cited by other articles:

				A. Belmeguenai, L. Desrues, J. Leprince, H. Vaudry, M.-C. Tonon, and E. Louiset Neurotensin Stimulates Both Calcium Mobilization from Inositol Trisphosphate-Sensitive Intracellular Stores and Calcium Influx through Membrane Channels in Frog Pituitary Melanotrophs Endocrinology, December 1, 2003; 144(12): 5556 - 5567. [Abstract] [Full Text] [PDF]

				H. Tostivint, D. Vieau, N. Chartrel, I. Boutelet, L. Galas, A. Fournier, I. Lihrmann, and H. Vaudry Expression and Processing of the [Pro2,Met13]Somatostatin-14 Precursor in the Intermediate Lobe of the Frog Pituitary Endocrinology, September 1, 2002; 143(9): 3472 - 3481. [Abstract] [Full Text] [PDF]

				L. Galas, M.-C. Tonon, D. Beaujean, R. Fredriksson, D. Larhammar, I. Lihrmann, S. Jegou, A. Fournier, N. Chartrel, and H. Vaudry Neuropeptide Y Inhibits Spontaneous {alpha}-Melanocyte-Stimulating Hormone ({alpha}-MSH) Release via a Y5 Receptor and Suppresses Thyrotropin-Releasing Hormone-Induced {alpha}-MSH Secretion via a Y1 Receptor in Frog Melanotrope Cells Endocrinology, May 1, 2002; 143(5): 1686 - 1694. [Abstract] [Full Text] [PDF]

				R. N. Faradji, E. Havari, Q. Chen, J. Gray, K. Tornheim, B. E. Corkey, R. C. Mulligan, and M. A. Lipes Glucose-induced Toxicity in Insulin-producing Pituitary Cells That Coexpress GLUT2 and Glucokinase. IMPLICATIONS FOR METABOLIC ENGINEERING J. Biol. Chem., September 21, 2001; 276(39): 36695 - 36702. [Abstract] [Full Text] [PDF]

This Article Abstract