Ghrelin and GHRP-6 enhance electrical and secretory activity in GC somatotropes

It is well established that pituitary somatotropes fire spontaneous action potentials (SAP) which generate Ca(2+) signals of sufficient amplitude to trigger growth hormone (GH) release. It is also known that ghrelin and synthetic GH-releasing peptides (GHRPs) stimulate GH secretion, though the mechanisms involved remain unclear. In the current report, we show that the chronic (96h) treatment with ghrelin and GHRP-6 increases the firing frequency of SAP in the somatotrope GC cell line. This action is associated with a significant increase in whole-cell inward current density. In addition, long-term application of Na(+) or L-type Ca(2+) current antagonists decreases GHRP-6-induced release of GH, indicating that the ionic currents that give rise to SAP play important roles for hormone secretion in the GC cells. Together, our results suggest that ghrelin and GHPR-6 may increase whole-cell inward current density thereby enhancing SAP firing frequency and facilitating GH secretion from GC somatotropes.     

Dexamethasone stimulates the expression of ghrelin and its receptor in rat hypothalamic 4B cells

Growth hormone (GH)-releasing peptides (GHRPs) are synthetic peptides that strongly induce GH release. GHRPs act via a specific receptor, the GHRP receptor (GHSR), of which ghrelin is a natural ligand. GHRPs also induce adrenocorticotropic hormone (ACTH) release in healthy subjects. GHRPs or ghrelin stimulate ACTH release via corticotropin-releasing factor (CRF) and arginin vasopressin in the hypothalamus. Stress-activated CRF neurons are suppressed by glucocorticoids in the hypothalamic paraventricular nucleus (PVN), while CRF gene is up-regulated by glucocorticoids in the PVN cells without the influence of input neurons. However, little is known about the regulation of ghrelin and GHSR type 1a (GHSR1a) genes by glucocorticoids in PVN cells. To elucidate the regulation of ghrelin and GHSR gene expression by glucocorticoids in PVN cells, here we used a homologous PVN neuronal cell line, hypothalamic 4B, because these cells show characteristics of the parvocellular neurons of the PVN. These cells also express ghrelin and GHSR1a mRNA. Dexamethasone increased ghrelin mRNA levels. A potent glucocorticoid receptor antagonist, RU-486, significantly blocked dexamethasone-induced increases in ghrelin mRNA levels. Dexamethasone also significantly stimulated GHSR1a mRNA and protein levels. Finally, ghrelin increased CRF mRNA levels, as did dexamethasone. Incubation with both dexamethasone and ghrelin had an additive effect on CRF and ghrelin mRNA levels. The ghrelin-GHSR1a system is activated by glucocorticoids in the hypothalamic cells.     

Effects of long-term treatment with growth hormone-releasing peptide-2 in the GHRH knockout mouse

Growth hormone (GH) secretagogues (GHS) stimulate GH secretion in vivo in humans and in animals. They act on the ghrelin receptor, expressed in both the hypothalamus and the pituitary. It is unknown whether GHSs act predominantly by increasing the release of hypothalamic GH-releasing hormone (GHRH) or by acting directly on the somatotroph cells. We studied whether a potent GHS could stimulate growth in the absence of endogenous GHRH. To this end, we used GHRH knockout (GHRH-KO) mice. These animals have proportionate dwarfism due to severe GH deficiency (GHD) and pituitary hypoplasia due to reduced somatotroph cell mass. We treated male GHRH-KO mice for 6 wk (from week 1 to week 7 of age) with GH-releasing peptide-2 (GHRP-2, 10 microg s.c. twice a day). Chronic treatment with GHRP-2 failed to stimulate somatotroph cell proliferation and GH secretion and to promote longitudinal growth. GHRP-2-treated mice showed an increase in total body weight compared with placebo-treated animals, due to worsening of the body composition alterations typical of GHD animals. These data demonstrate that GHRP-2 failed to reverse the severe GHD caused by lack of GHRH.     

Peripheral estrogen receptor-alpha selectively modulates the waveform of GH secretory bursts in healthy women

Estradiol (E(2)) drives growth hormone (GH) secretion via estrogen receptors (ER) located in the hypothalamus and pituitary gland. ERalpha is expressed in GH releasing hormone (GHRH) neurons and GH-secreting cells (somatotropes). Moreover, estrogen regulates receptors for somatostatin, GHR peptide (GHRP, ghrelin), and GH itself, while potentiating signaling by IGF-I. Given this complex network, one cannot a priori predict the selective roles of hypothalamic compared with pituitary ER pathways. To make such a distinction, we introduce an investigative model comprising 1) specific ERalpha blockade with a pure antiestrogen, fulvestrant, that does not penetrate the blood-brain barrier; 2) graded transdermal E(2) administration, which doubles GH concentrations in postmenopausal women; 3) stimulation of fasting GH secretion by pairs of GHRH, GHRP-2 (a ghrelin analog), and l-arginine (to putatively limit somatostatin outflow); and 4) implementation of a flexible waveform deconvolution model to estimate the shape of secretory bursts independently of their size. The combined strategy unveiled that 1) E(2) prolongs GH secretory bursts via fulvestrant-antagonizable mechanisms; 2) fulvestrant extends GHRH/GHRP-2-stimulated secretory bursts; 3) l-arginine/GHRP-2 stimulation lengthens GH secretory bursts whether or not E(2) is present; 4) E(2) limits the capability of l-arginine/GHRP-2 to expand GH secretory bursts, and fulvestrant does not inhibit this effect; and 5) E(2) and/or fulvestrant do not alter the time evolution of l-arginine/GHRH-induced GH secretory bursts. The collective data indicate that peripheral ERalpha-dependent mechanisms determine the shape (waveform) of in vivo GH secretory bursts and that such mechanisms operate with secretagogue selectivity.     

The effects of ACTH 1-17 on GH secretion in vitro

Recently we demonstrated that ACTH 1-17 infusion in normal subjects is able to stimulate growth hormone (GH) secretion. In order to study the mechanism by which ACTH 1-17 induces this hormonal secretory pattern, we examined the effects of ACTH 1-17 addition to primary cultures of rat anterior pituitary cells and of two human pituitary adenomas (a mixed GH- and PRL-secreting adenoma and a prolactinoma) on GH and PRL secretion. Normal rat pituitary cells responded to rGRF with a dose-dependent increase of rGH: ACTH 1-17 induced a slight not significant increase of rGH secretion even at micromolar concentrations. Furthermore no additive effect of ACTH 1-17 on rGRF-stimulated GH release was observed. No significant stimulatory effect was also documented in the human tumors studied. These results suggest that the GH releasing activity of ACTH 1-17 observed in vivo is mediated via a direct action on CNS.     

Robust growth hormone (GH) secretion in aged female rats co-administered GH-releasing hexapeptide (GHRP-6) and GH-releasing hormone (GHRH)

Aging is associated with a blunted growth hormone (GH) secretory response to GH-releasing hormone (GHRH), in vivo. The objective of the present study was to assess the effects of aging on the GH secretory response to GH-releasing hexapeptide (GHRP-6), a synthetic GH secretagogue. GHRP-6 (30 micrograms/kg) was administered alone or in combination with GHRH (2 micrograms/kg) to anesthetized female Fischer 344 rats, 3 or 19 months of age. The peptides were co-administered to determine the effect of aging upon the potentiating effect of GHRP-6 on GHRH activity. The increase in plasma GH as a function of time following administration of GHRP-6 was lower (p less than 0.001) in old rats than in young rats; whereas the increase in plasma GH secretion as a function of time following co-administration of GHRP-6 and GHRH was higher (p less than 0.001) in old rats than in young rats (mean Cmax = 8539 +/- 790.6 micrograms/l vs. 2970 +/- 866 micrograms/l, respectively; p less than 0.01). Since pituitary GH concentrations in old rats were lower than in young rats (257.0 +/- 59.8 micrograms/mg wet wt. vs. 639.7 +/- 149.2 micrograms/mg wet wt., respectively; p less than 0.03), the results suggested that GH functional reserve in old female rats was not linked to pituitary GH concentration. The differential responses of old rats to individually administered and co-administered GHRP-6 are important because they demonstrate that robust and immediate GH secretion can occur in old rats that are appropriately stimulated. The data further suggest that the cellular processes subserving GH secretion are intact in old rats, and that age-related decrements in GH secretion result from inadequate stimulation, rather than to maladaptive changes in the mechanism of GH release.     

Neither intravenous nor intracerebroventricular administration of obestatin affects the secretion of GH, PRL, TSH and ACTH in rats

To examine the effect of obestatin, a recently identified peptide derived from preproghrelin, on pituitary hormone secretion, obestatin was administered in anesthetized male rats. Intravenous administration of obestatin did not show any effect on plasma GH, PRL, ACTH and TSH levels. Since obestatin has been reported to have opposite effects of ghrelin in regulating food intake, gastric emptying and intestinal contractility, GH suppressive effect, which is opposite effect of ghrelin, was tested. Intravenous administration of GHRH or GHRP-2, a ghrelin receptor ligand, resulted in a marked plasma GH elevation. However obestatin did not show any effect on GHRH- or GHRP-2-induced GH rise. Furthermore intracerebroventricular administration of obestatin also did not influence plasma GH, PRL, ACTH and TSH levels. These findings suggest that obestatin has no effect on pituitary hormone secretions despite the presence of GPR39, a receptor for obestatin, in the pituitary.     

Diverse intracellular signalling systems used by growth hormone-releasing hormone in regulating voltage-gated Ca2+ or K channels in pituitary somatotropes

Influx of Ca2+ via Ca2+ channels is the major step triggering exocytosis of pituitary somatotropes to release growth hormone (GH). Voltage-gated Ca2+ and K+ channels, the primary determinants of the influx of Ca2+, are regulated by GH-releasing hormone (GHRH) through G-protein-coupled intracellular signalling systems. Using whole-cell patch-clamp techniques, the changes of the Ca2+ and K+ currents in primary cultured ovine and human somatotropes were recorded. Growth hormone-releasing hormone (10 nmol/L) increased both L- and T-type voltage-gated Ca2+ currents. Inhibition of the cAMP/protein kinase A (PKA) pathway by either Rp-cAMP or H89 blocked this increase in both L- and T-type Ca2+ currents. Growth hormone-releasing hormone also decreased voltage-gated transient (IA) and delayed rectified (IK) K+ currents. Protein kinase C (PKC) inhibitors, such as calphostin C, chelerythrine or downregulation of PKC, blocked the effect of GHRH on K+ currents, whereas an acute activation of PKC by phorbol 12, 13-dibutyrate (1 micromol/L) mimicked the effect of GHRH. Intracellular dialysis of a specific PKC inhibitor (PKC19-36) also prevented the reduction in K+ currents by GHRH. It is therefore concluded that GHRH increases voltage-gated Ca2+ currents via cAMP/PKA, but decreases voltage-gated K+ currents via the PKC signalling system. The GHRH-induced alteration of Ca2+ and K+ currents augments the influx of Ca2+, leading to an increase in [Ca2+]i and the GH secretion.     

Mechanism involved in synergistic adrenocorticotropin response to activating protein kinase-A and -C in rat anterior pituitary cells

Activation of protein kinase C (PKC) stimulates adrenocorticotropin (ACTH) release synergistically in the presence of corticotropin releasing factor (CRF). We examined the effect of a cyclic nucleotide-specific phosphodiesterase inhibitor, 1-isoamyl-3-isobutylxanthine (IIX), on arginine vasopressin (AVP)-induced ACTH release and intracellular cAMP accumulation in normal rat anterior pituitary cells. IIX alone elevated intracellular cAMP accumulation. IIX potentiated AVP-induced ACTH release synergistically without further increase in cAMP accumulation, suggesting that synergistic ACTH release has an alternative mechanism other than the synergistic elevation of intracellular cAMP accumulation which has been reported. Phorbol 12-myristate-13-acetate (PMA) also induced synergistic ACTH release when incubated with IIX. IIX had no additional effect on ACTH response when incubated with maximal dose of CRF, forskolin or 8-bromoadenosine 3',5'-cyclic monophosphate (8-Br-cAMP). Moreover, the combination of PMA and 8-Br-cAMP produced synergistic ACTH response. In conclusion, the synergistic ACTH release from rat pituitary corticotrophs occurs at least in the presence of directly activating events of PKC and PKA as well as PKC-induced inhibition of phosphodiesterase activity.     

Relation of endogenous opioid peptides and morphine to neuroendocrine functions.

Morphine and the endogenous opioid peptides (EOP) exert similar effects on the neuroendocrine system. When adminstered acutely, they stimulate growth hormone (GH), prolactin (PRL), and adrenocorticotropin (ACTH) release, and inhibit release of luteinizing hormone (LH), follicle stimulating hormone (FSH),and thyrotropin (TSH). Recent studies indicate that the EOP probably have a physiological role in regulating pituitary hormone secretion. Thus injection of naloxone (opiate antagonist) alone in rats resulted in a rapid fall in serum concentrations of GH and PRL, and a rise in serum LH and FSH, suggesting that the EOP help maintain basal secretion of these hormones. Prior administration of naloxone or naltrexon inhibited stress-induced PRL release, and elevated serum LH in castrated male rats to greater than normal castrate levels. Studies on the mechanisms of action of the EOP and morphine on hormone secretion indicate that they have no direct effect on the pituitary, but act via the hypothalamus. There is no evidence that the EOP or morphine alter the action of the hypothalamic hypophysiotropic hormones on pituitary hormone secretion; they probably act via hypothalamic neurotransmitters to influence release of the hypothalamic hormones into the pituitary portal vessels. Preliminary observations indicate that they may increase serotonin and decrease dopamine metabolism in the hypothalamus, which could account for practically all of their effects on pituitary hormone secretion.     

GH-releasing peptides improve cardiac dysfunction and cachexia and suppress stress-related hormones and cardiomyocyte apoptosis in rats with heart failure

Growth hormone (GH)-releasing peptides (GHRP), a class of synthetic peptidyl GH secretagogues, have been reported to exert a cardioprotective effect on cardiac ischemia. However, whether GHRP have a beneficial effect on chronic heart failure (CHF) is unclear, and the present work aims to clarify this issue. At 9 wk after pressure-overload CHF was created by abdominal aortic banding in rats, one of four variants of GHRP (GHRP-1, -2, and -6 and hexarelin, 100 mug/kg) or saline was injected subcutaneously twice a day for 3 wk. Echocardiography and cardiac catheterization were performed to monitor cardiac function and obtain blood samples for hormone assay. GHRP treatment significantly improved left ventricular (LV) function and remodeling in CHF rats, as indicated by increased LV ejection fraction, LV end-systolic pressure, and diastolic posterior wall thickness and decreased LV end-diastolic pressure and LV end-diastolic dimension. GHRP also significantly alleviated development of cardiac cachexia, as shown by increases in body weight and tibial length in CHF rats. Plasma CA, renin, ANG II, aldosterone, endothelin-1, and atrial natriuretic peptide were significantly elevated in CHF rats but were significantly decreased in GHRP-treated CHF rats. GHRP suppressed cardiomyocyte apoptosis and increased cardiac GH secretagogue receptor mRNA expression in CHF rats. GHRP also decreased myocardial creatine kinase release in hypophysectomized rats subjected to acute myocardial ischemia. We conclude that chronic administration of GHRP alleviates LV dysfunction, pathological remodeling, and cardiac cachexia in CHF rats, at least in part by suppressing stress-induced neurohormonal activations and cardiomyocyte apoptosis.     

A cellular basis for functionally releasable pools in somatotropes

In an attempt to define the cellular basis for the phenomenon of releasable pools, we compared the effects of two growth hormone (GH)-releasing peptides which differentially influence the dynamics of GH release. Monodispersed anterior pituitary cells from neonatal male rats were subjected to reverse hemolytic plaque assays for GH in the presence or absence of GH-releasing peptide (GHRP-6, an enkephalin-like hexapeptide) and rat GH-releasing factor (GRF). GRF increased the rate of plaque formation (an index of the rate of hormone release) from almost all somatotropes, whereas GHRP-6 influenced only half of these cells. Analysis of plaque sizes (which provides a relative index of the cumulative amount of hormone released per cell) revealed that GRF produced a bimodal frequency distribution of plaque sizes, demonstrating that some somatotropes released more hormone than others after treatment with a maximal dose of this secretagogue. This pattern contrasted with those of untreated and GHRP-6 treated somatotropes which each produced unimodal frequency distributions that were skewed to the left (toward smaller plaques) and were virtually superimposable at the end of a 4 h incubation. However, GHRP-6 greatly accelerated the rate at which the final size distribution pattern was attained. Taken together, these results suggest that GHRP-6 causes the immediate release of a limited pool of GH which is present only in a discrete subpopulation of somatotropes that respond to GRF. This pool may be identical to that which is released over a more prolonged period under basal conditions. Moreover, GRF appears to access a more substantial pool of hormone which is not released by GHRP-6. This pool is present in a small minority of somatotropes but probably accounts for a larger portion of the GH released by pituitaries stimulated with GRF.     

Acute and chronic regulation of pituitary receptors for vasopressin and corticotropin releasing hormone

At least two hypothalamic peptides, corticotropin releasing hormone (CRH) and vasopressin (VP), are important in regulating adrenocorticotropin (ACTH) release from the anterior pituitary. Both are secreted in a pulsatile manner and stimulate ACTH secretion by interacting with G protein-coupled receptors (GPCRs), namely the type 1 CRH receptor and V1b receptor, respectively. Repeated or prolonged stimulation with either peptide can cause reduced ACTH responsiveness or desensitisation, both in vivo and in vitro. Desensitisation of perifused sheep anterior pituitary cells to VP was found to be rapid and occurred following treatment with 5 nM VP for 5 min. This is within the range of concentrations and durations of VP pulses seen in sheep portal blood during acute stress. In contrast, significant desensitisation of the ACTH response to CRH required pre-treatment for longer than 25 min with a CRH concentration of 1 nM, suggesting that endogenous pulses may not elicit desensitisation. Although rapid GPCR desensitisation involves uncoupling of receptors from their G proteins, commonly mediated by receptor phosphorylation, and internalisation of receptors, desensitisation of neither the CRH nor VP receptor was mediated by PKA or PKC, respectively. Desensitisation of the response to VP was found to be dependent upon receptor internalisation, and resensitisation could be delayed by treatment with a protein phosphatase 2B inhibitor. The rapid kinetics of desensitisation of the ACTH response to VP suggest that this process is important in regulating the response to acute rather than chronic stress. If, as has been suggested, CRH acts in a permissive way to set corticotrope gain, desensitisation to CRH could also be important in long term regulation of ACTH secretion.     

Estimation of the size and shape of GH secretory bursts in healthy women using a physiological estradiol clamp and variable-waveform deconvolution model

Because estrogen production and age are strong covariates, distinguishing their individual impact on hypothalamo-pituitary regulation of growth hormone (GH) output is difficult. In addition, at fixed elimination kinetics, systemic GH concentration patterns are controlled by three major signal types [GH-releasing hormone (GHRH), GH-releasing peptide (GHRP, ghrelin), and somatostatin (SS)] and by four dynamic mechanisms [the number, mass (size), and shape (waveform) of secretory bursts and basal (time invariant) GH secretion]. The present study introduces an investigative strategy comprising 1) imposition of an experimental estradiol clamp in pre- (PRE) and postmenopausal (POST) women; 2) stimulation of fasting GH secretion by each of GHRH, GHRP-2 (a ghrelin analog), and l-arginine (to putatively limit SSergic restraint); and 3) implementation of a flexible-waveform deconvolution model to estimate basal GH secretion simultaneously with the size and shape of secretory bursts, conditional on pulse number. The combined approach unveiled the following salient percent POST/PRE contrasts: 1) only 27% as much GH secreted in bursts during fasting (P < 0.001); 2) markedly attenuated burstlike GH secretion in response to bolus GHRP-2 (29%), bolus GHRH (30%), l-arginine (37%), constant GHRP-2 (38%), and constant GHRH (42%) (age contrasts, 0.0016 相似文献   

Secretin, glucagon, gastric inhibitory polypeptide, parathyroid hormone, and related peptides in the regulation of the hypothalamus- pituitary-adrenal axis

Secretin, glucagon, gastric inhibitory polypeptide (GIP), and parathyroid hormone (PTH) belong, together with vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase (AC)-activating polypeptide, to a family of peptides (the VIP-secretin-glucagon family), which also includes growth hormone-releasing hormone and exendins. All the members of this peptide family possess a remarkable amino-acid sequence homology, and bind to G-protein-coupled receptors, whose signaling mechanism primarily involves AC/protein kinase A and phospholipase C/protein kinase C cascades. VIP and pituitary AC-activating polypeptide play a role in the regulation of the hypothalamus-pituitary-adrenal (HPA) axis, and in this review we survey findings that also other members of the VIP-secretin-glucagon family may have the same function. Secretin and secretin receptors are expressed in the hypothalamus and pituitary gland, and secretin inhibits adrenocorticotropic hormone (ACTH) release. No evidence is available for the presence of secretin receptors in adrenal glands, but secretin selectively depresses the glucocorticoid response to ACTH of dispersed zona fasciculata-reticularis (ZF/R) cells. Glucagon and glucagon-like peptide-1 are contained in the hypothalamus, and all the components of the HPA axis are provided with glucagon and glucagons-like-1 receptors. These peptides exert a short-term inhibitory effect on stress-induced pituitary ACTH release and depress the ZF/R cell response to ACTH by inhibiting the AC/protein kinase A cascade; they also stimulate hypothalamic arginine-vasopressin release. GIP receptors are present in the ZF/R of the normal adrenals, and are particularly abundant in some types of adrenocortical adenomas and hyperplasias. GIP, through the activation of the AC/protein kinase A cascade, evokes a sizeable glucocorticoid secretagogue effect, leading to the identification of a food/GIP-dependent Cushing's syndrome. PTH and PTH-related protein are expressed in the hypothalamus and pituitary gland, and PTH and PTH-related protein receptors in all the components of the HPA axis. Both peptides enhance ACTH and arginine-vasopressin release, as well as stimulate aldosterone and glucocorticoid secretion of dispersed zona glomerulosa and ZF/R cells, respectively. The involvement of growth hormone-releasing hormone and exendins in the functional regulation of the HPA axis has not yet been extensively investigated.     

In vitro and in vivo ACTH-releasing activity of ovine CRF,sauvagine and urotensin I

The ability of three homologous peptides, ovine corticotropin-releasing factor (CRF), sauvagine and urotensin I, to release ACTH was examined in vitro and in vivo. All three peptides exhibit statistically equivalent potencies to stimulate ACTH secretion both by cultured pituitary cells and in pharmacology blocked rats. These results suggest that all three peptides evolved from a common mammalian precursor that possessed high hypophysiotropic potency.     

Endocrine actions of opioids

The widespread occurrence of opioid peptides and their receptors in brain and periphery correlates with a variety of actions elicited by opioid agonists and antagonists on hormone secretion. Opioid actions on pituitary and pancreatic peptides are summarized in Table 1. In rats opioids stimulate ACTH and corticosterone secretion while an inhibition of ACTH and cortisol levels was observed in man. In both species, naloxone, an opiate antagonist, stimulates the release of ACTH suggesting a tonic suppression by endogenous opioids. In rats, a different stimulatory pathway must be assumed through which opiates can stimulate secretion of ACTH. Both types of action are probably mediated within the hypothalamus. LH is decreased by opioid agonists in many adult species while opiate antagonists elicit stimulatory effects, both apparently by modulating LHRH release. A tonic, and in females, a cyclic opioid control appears to participate in the regulation of gonadotropin secretion. Exogenous opiates potently stimulate PRL and GH secretion in many species. Opiate antagonists did not affect PRL or GH levels indicating absence of opioid control under basal conditions, while a decrease of both hormones by antagonists was seen after stimulation in particular situations. In rats, opiate antagonists decreased basal and stress-induced secretion of PRL. Data regarding TSH are quite contradictory. Both inhibitory and stimulatory effects have been described. Oxytocin and vasopressin release were inhibited by opioids at the posterior pituitary level. There is good evidence for an opioid inhibition of suckling-induced oxytocin release. Opioids also seem to play a role in the regulation of vasopressin under some conditions of water balance. The pancreatic hormones insulin and glucagon are elevated by opioids apparently by an action at the islet cells. Somatostatin, on the contrary, was inhibited. An effect of naloxone on pancreatic hormone release was observed after meals which contain opiate active substance. Whether opioids play a physiologic role in glucose homeostasis remains to be elucidated.     

Involvement of protein kinase C and protein kinase A in the muscarinic receptor signalling pathways mediating phospholipase C activation, arachidonic acid release and calcium mobilisation.

The involvement of protein kinase C (PKC) and protein kinase A (PKA) in cholinergic signalling in CHO cells expressing the M3 subtype of the muscarinic acetylcholine receptor was examined. Muscarinic signalling was assessed by measuring carbachol-induced activation of phospholipase C (PLC), arachidonic acid release, and calcium mobilisation. Carbachol activation of PLC was not altered by inhibition of PKC with chelerythrine chloride, bisindolylmaleimide or chronic treatment with phorbol myristate acetate (PMA). Activation of PKC by acute treatment with PMA was similarly without effect. In contrast, inhibition of PKC blocked carbachol stimulation of arachidonic acid release. Likewise, PKC inhibition resulted in a decreased ability of carbachol to mobilise calcium, whereas PKC activation potentiated calcium mobilisation. Inhibition of PKA with H89 or Rp-cAMP did not alter the ability of carbachol to activate PLC. Similarly, PKA activation with Sp-cAMP or forskolin had no effect on PLC stimulation by carbachol. Carbachol-mediated release of arachidonic acid was decreased by H89 but only slightly increased by forskolin. Forskolin also increased calcium mobilisation by carbachol. These results suggest a function for PKC and PKA in M3 stimulation of arachidonic acid release and calcium mobilisation but not in PLC activation.