Location and characterization of opiate receptors regulating pituitary secretion

The site at which opiate agonists and antagonists act to alter secretion of prolactin, growth hormone and luteinizing hormone as well as the pharmacological specificity of the opiate receptors mediating these effects were examined in rats. Injection of β-endorphin but not a 10 fold higher dose of the non opiate peptide β-endorphin, increased release of prolactin and growth hormone in male rats while inhibiting luteinizing hormone release in ovariectomized, estrogen primed female rats. Prior treatment with naltrexone i.p. blocked these responses. Injection of naltrexone into the hypothalamus lowered prolactin release. In rats with a surgically formed hypothalamic island systemic administration of morphine or naltrexone altered prolactin release in the same manner as was observed in intact animals. In contrast no effects of β-endorphin or naltrexone were observed on the spontaneous secretion of prolactin $\text{in}$$\text{vitro}$. In addition β-endorphin did not alter the inhibition of prolactin release produced by apomorphine $\text{in}$$\text{vitro}$. The ED₅₀ for stimulation of prolactin release following intraventricular administration of β-endorphin or the synthetic enkephalin analog FK 33-824 was the same, approximately 0.1 ng/rat. However FK 33-824 at 0.2 ng/rat was able to produce much greater analgesia and catatonia than β-endorphin. The metabolism and distribution of β-endorphin was examined but did not account for these differential effects. These results indicate that opiate agonists and antagonists can act at the hypothalamic but not the anterior pituitary level to alter release of prolactin, growth hormone and luteinizing hormone. In addition the data suggest that the opiate receptors mediating release of prolactin may have a different pharmacological specificity from those involved with analgesia and catatonia.     

Comparison of the behavioral effects of β-endorphin and enkephalin analogs

The behavioral effects of β-endorphin, enkephalin analogs, morphine and etorphine were briefly compared. In the tail-flick test in mice and in the wet shake test in rats, β-endorphin and D-Ala²-D-Leu⁵-enkephalin had equal antinociceptive activity; D-Ala² -Met-enkephalinamide and D-Leu⁵-enkephalin were less active. The order of activity of the enkephalin analogs and opiate alkaloids for stimulating locomotor activity in mice paralleled their analgesic activities; β-endorphin, however, had only minimal stimulatory actions. Morphine sulfate, 50 μg injected into the periaqueductal gray, produced hyperactivity but this effect was not observed with etorphine or opioid peptides. By contrast, “wet dog” shakes was observed with the opioid peptides but not with either opiate alkaloid. These heterogenous behavioral responses, which were all antagonized by naloxone, indicate that multiple types of receptors mediate the effects of opiates in the central nervous system.     

Humoral endorphin: A new endogenous factor with opiate-like activity

Humoral (H) endorphin, a novel endogenous opioid ligand detected in brain, blood and cerebrospinal fluid was tested in a series of opiate sensitive assays. H-endorphin displaced radiolabeled enkephalin from its specific bindings sites and inhibited the electrically evoked contraction of the guinea pig ileum and mouse vas deferens. When injected to unanesthesized animals, humoral endorphin induced analgesia in rats and mydriasis in mice. The activity of H-endorphin both $\text{in}\text{vitro}$ and $\text{in}\text{vivo}$ attests to its opioid nature. However, while its antinociceptive effect was blocked by naloxone, mydriasis induced by H-endorphin was resistant to the effect of the opiate antagonist. Similarly, intermediate concentrations of naloxone inhibited the effect of H-endorphin on the guinea pig ileum while its effect on the mouse vas deferens was completely refractory to naloxone. The physiological function of humoral endorphin in various naturally occuring states that show similar paradoxical interactions with naloxone is discussed.     

The effects of opiate agonists on growth hormone and prolactin release in rats

Various opioid receptor agonists, including Met5-enkephalin amide, Leu5-enkephalin amide, [D-Ala]2-Met5-enkephalin amide, [D-Ala]2-Leu5-enkephalin amide, morphine sulfate, d-methadone hydrochloride, and l-methadone hydrochloride were administered to adult male rats by subcutaneous injection. All opioid receptor agonists except Leu5-enkephalin amide significantly stimulated growth hormone and prolactin release. Naloxone and naltrexone blocked the hormone stimulatory effects of the opioids and both naloxone and naltrexone, when administered alone, significantly reduced serum growth hormone and prolactin concentrations. The dopaminergic agonist apomorphine, but not the alpha-adrenergic agonist clonidine, blocked opiate stimulation of prolactin. Morphine sulfate caused growth hormone release in rats pretreated with alpha-methyl-p-tryosine, a catecholamine synthesis inhibitor. Cholinergic agonists, physostigmine and pilocarpine, antagonized the growth hormone and prolactin release induced by morphine sulfate. The data suggest that the opiates stimulate prolactin via an interaction with catecholaminergic neurons controlling prolactin release and stimulate growth hormone via a mechanism independent of alpha-adrenergic or general catecholaminergic influence. The mechanism through which cholinergic agonists act to inhibit opiate agonist stimulation of growth hormone is presently unknown.     

Morphine stimulates prolactin release in normal but not in castrated male rats

Morphine (200 micrograms/rat) was injected intraventricularly (i.v.t.) into normal and into long-term castrated (4 weeks) adult male rats. Animals were killed 10, 20, 40 and 60 min after treatment. In normal animals, the treatment with morphine resulted in a significant increase of serum prolactin concentrations at all time intervals considered. However, the i.v.t. injection of 200 micrograms morphine/rat into castrated rats did not exert any significant effect on prolactin release at any time interval considered. When morphine (200 micrograms/rat) was administered i.v.t. together with the specific opioid receptor blocker naloxone (7.5 or 15 micrograms/rat) the stimulatory effect of morphine on prolactin release was diminished at 10 min, and totally blocked at 20 min. Naloxone given alone did not influence serum prolactin concentrations. The results suggest that the presence of endogenous androgens is essential to permit the stimulatory effect of morphine on prolactin release.     

The effects of partial opiate agonists on plasma prolactin and growth hormone levels in the rat.

Opiate agonists, partial agonists, and antagonists differed in their effects on release of prolactin and growth hormone. Agonists (morphine, methadone or meperidine) elevated plasma levels of both hormones. An antagonist (naloxone) lowered levels of prolactin but not growth hormone. All partial agonists studied raised growth hormone levels; among these, levallorphan, nalorphine, and ciramadol lowered prolactin levels while pentazocine and meptazinol did not. Naloxone blocked morphine-induced release of prolactin and growth hormone. The partial agonists suppressed morphine-induced prolactin release, and several suppressed the elevated growth hormone levels as well. Data from the opiate radioreceptor assay (displacement of ³H-naloxone) in the presence and absence of sodium agrees with the above placement of agents into three classes. These results suggest that classification of opioid compounds into agonists, partial agonists and antagonists may be made by their effects on prolactin and growth hormone release.     

Pharmacological Characterization of an Opioid Receptor in the Ciliate Tetrahymena

A pharmacological characterization has been performed of the opioid receptor involved in modulation of phagocytosis in the protozoan ciliate Tetrahymena. Studies on inhibition of phagocytosis by mammalian prototypic opioid agonists revealed that morphine and β-endorphin have the highest intrinsic activity, whereas all the other opioids tested can only be considered partial agonists. However, morphine (a mu-receptor agonist) is twice as potent as β-endorphin (a delta-receptor agonist). Furthermore, the sensitivity for the opioid antagonist naloxone, determined in the presence of morphine and β-endorphin, is very similar to the sensitivity exhibited by mammalian tissues rich in mu-opioid receptors. We suggest that the opioid receptor coupled to phagocytosis in Tetrahymena is mulike in some of its pharmacological characteristics and may serve as a model system for studies on opioid receptor function and evolution.     

Effect of opiate-active substances on pancreatic polypeptide levels in dogs

The present study examines the effect of orally and intravenously administered opiate-active substances on peripheral vein plasma pancreatic polypeptide (PP) levels in conscious dogs. The intragastric instillation of digested gluten stimulated postprandial PP levels significantly which was reduced by the specific opiate-receptor antagonist naloxone. Naloxone had no effect when added to undigested gluten. Similarly, naloxone reduced significantly the postprandial PP response to a test meal of casopeptone which contains the opiate-active β-casomorphins. The addition of synthetic β-casomorphins to a liver extract/sucrose test meal significantly augmented the rise of postprandial PP levels which was also blocked by naloxone. The intravenous infusion of morphine, leu-enkephalin, D-ala²-D-leu⁵-enkephalin, β-casomorphin-5 and β-casomorphin-4 elicited a dose-dependent and naloxone reversible effect on basal PP levels. During a background infusion of glucose and amino acids the same opiate-active substances had either none or a stimulatory effect on PP release in these dogs. The addition of naloxone abolished the stimulatory effect in response to β-casomorphin-5 and β-casomorphin-4 and resulted in an inhibition of PP levels during the infusion of morphine and leu-enkephalin. This latter inhibitory effect was no longer observed when the dose of naloxone was increased ten- and fifty-fold, respectively. The present data suggest that orally ingested opiate-active substances participate in the stimulation of postprandial PP release in dogs via specific opiate-receptor mediated mechanisms. The effect of intravenously administered opiate-active substances on PP levels depends on the metabolic state with regard to the level of circulating nutrients. It is suggested that PP release is stimulated via μ-opiate receptors and inhibited via δ-opiate receptors. An increase of circulating nutrients would “activate” μ-receptor sites which are masked in the basal state when exogenous opiates are administered. However, with regard to endogenous opiates an increase of circulating nutrients, mainly carbohydrates, activates inhibitory effects of endogenous opiates suggesting that exogenous and endogenous opiates act at different target sites.     

Enkephalin analogues and naloxone modulate the release of growth hormone and prolactin - evidence for regulation by an endogenous opioid peptide in brain

Met⁵-enkephalin amide, D-Ala²-Met⁵-enkephalin amide, D-Ala²-Leu⁵-enkephalin amide, morphine sulfate and naloxone hydrochloride were examined for their effects on growth hormone and prolactin release $\text{in}$$\text{vivo}$ and $\text{in}$$\text{vitro}$. Subcutaneous injection of D-Ala²-Met⁵ enkephalin amide^a, D-Ala²-Leu⁵ enkephalin amide^b and morphine sulfate, but not Met⁵-enkephalin and amide^c, resulted in significant elevations in the serum growth hormone and prolactin of immature female rats. Naloxone blocked the hormone-stimulatory effect of the opioid receptor agonists and when administered alone significantly reduced serum growth hormone and prolactin concentrations. None of the drugs demonstrated a direct action on anterior pituitary tissue growth hormone or prolactin release $\text{in}$$\text{vitro}$.     

Regulation of opioid peptides on the release of arginine vasotocin in the hen

Arginine vasotocin (AVT), an avian neurohypophysial hormone, is released during osmotic stimulation and oviposition. In the present study, the role of opioid peptides on AVT release was studied by examining the effects of an opioid agonist and antagonist on osmotic- and oviposition-induced secretion of AVT. The administration of hypertonic saline (1.5 M NaCl) induced an increase in the plasma levels of AVT. The simultaneous administration of morphine, an opioid receptor agonist, inhibited the osmotically induced increase in plasma levels of AVT in a dose-dependent manner. On the other hand, the co-administration of morphine with naloxone, an opioid receptor antagonist, attenuated the inhibitory effect of morphine. Moreover, injection of naloxone alone enhanced the osmotically induced increase in plasma levels of AVT. However, the administration of morphine did not inhibit the oviposition-induced increase in plasma levels of AVT. These results suggest that osmotic-induced release of AVT may be under opioid regulation, while oviposition-induced release of AVT may be controlled by a different mechanism. J. Exp. Zool. 286:481-486, 2000.     

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.     

Social conflict activates opioid analgesic and ingestive behaviors in male mice

The activation of endogenous opioid mechanisms and their subsequent effects on rodent behavior and physiology has usually been characterized following artificial stress. In this study the more naturalistic stress arising from social conflict between male mice was used to investigate the involvement of opioid systems in post-conflict analgesic and ingestive behaviors. Both the aggressive encounters and the subsequent defeat experience resulted in marked analgesia and the induction of ingestive behaviors. Feeding and drinking responses were analogous to those observed after administrations of either the endogenous opioid peptide, β-endorphin, or the exogenous opioid agonist morphine. The ingestive behaviors following defeat or central opiate administration were blocked by the opiate antagonist naloxone. The present results support the hypothesis of a direct activation of the endogenous opiate system following social conflict.     

Morphine- and opioid peptide-induced inhibition of the release of dopamine from tuberoinfundibular neurons

Dopamine concentrations in pituitary stalk plasma ovariectomized rats and ovariectomized, estrogen-treated rats were measured following the subcutaneous administration of morphine or the intraventricular administration of ß-endorphin or [D-Ala²]-methionine-enkephalinamide, a synthetic enkephalin analog. The administration of morphine or the opioid peptides led to an 85–89% reduction in the concentration of dopamine in pituitary stalk plasma when compared to the mean concentration of dopamine in stalk plasma of vehicle-treated animals. Pretreatment of rats with naloxene, an opiate antagonist, prevented the opioid peptide-induced reduction in the stalk plasma concentration of dopamine. These results are supportive of the hypothesis that endogenous opioid peptides modulate the release of dopamine by tuberoinfundibular neurons into hypophysial portal blood.     

β-endorphin-induced increase in striatal dopamine turnover

Human β-endorphin administered intracisternally in a dose of 15 μg per rat increased striatal concentrations of the dopamine metabolites, 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) as well as producing catalepsy. These effects were inhibited by naloxone. Pargyline-induced decreases in striatal DOPAC and HVA were greater in endorphin-treated than in saline-treated animals, supporting the concept that β-endorphin increases striatal dopamine turnover. β-endorphin increased the rate of decline in striatal dopamine concentration following synthesis inhibition with α-methyltyrosine, further suggesting that endorphin increases striatal dopamine turnover. β-endorphin and probenecid interacted competitively to decrease the effects of each other to increase striatal HVA. Naloxone prevented the effect of endorphin to decrease the HVA response to probenecid. Thus, probenecid cannot be used to assess the effects of endorphin on striatal dopamine turnover. If β-endorphin acts presynaptically to decrease dopamine release in striatum, the increases in striatal DOPAC and HVA probably represent a compensatory attempt to increase dopamine synthesis. Although turnover of dopamine to its metabolites is increased, dopamine release may be suppressed by β-endorphin.     

Modification of the effects of naloxone in morphine-dependent mice

Mice were rendered dependent on morphine by mixing morphine with their food (2 mg/g) for three days. Increasing doses of naloxone precipitated dose-dependent withdrawal reactions such as weight loss and jumping. These withdrawal reactions were antagonized by morphine pretreatment. Effects of morphine, such as increased locomotor activity, inhibition of intestinal transport, and analgesia were antagonized by naloxone in both non-dependent and dependent subjects. The antagonist actions of naloxone were increased in dependent subjects; lower doses of naloxone were sufficient to antagonize effects of morphine. The present results confirm earlier studies indicating that precipitation of withdrawal can be antagonized by morphine pretreatment suggesting that withdrawal reactions are due to actions of naloxone at the same receptor at which opioid agonists act. The increased antagonist potency of naloxone in dependent subjects extends earlier results obtained with analgesic effects to several other agonist effects of morphine and is consistent with the interpretation that exposure to an opioid agonist induces a change in the conformation of opioid receptors.     

Opioid regulation of luteinising hormone and prolactin release in the horse—identical or independent endocrine pathways?

In order to determine if endogenous opioids regulate luteinising hormone (LH) and prolactin secretion via a common, gonadotropin-releasing hormone (GnRH) dependent pathway in the horse, effects of the opioid antagonist naloxone (300 mg) and the GnRH agonist buserelin (20 μg) on prolactin and LH secretion were investigated in stallions (n = 22), long-term castrated geldings (n = 15) and non-lactating mares during the luteal phase of the oestrous cycle (n = 16). Blood samples for determination of LH and prolactin concentrations were withdrawn at 15 min intervals for 120 min. After 60 min of sampling, animals were treated with either naloxone, buserelin or saline. In stallions, naloxone significantly increased LH as well as prolactin release (P < 0.05), indicating an opioid inhibition of both hormones, whereas in mares, naloxone stimulated only LH secretion (P < 0.05). No changes in plasma LH or prolactin concentrations after injection of naloxone were found in geldings. In all animal groups, buserelin induced a significant release of LH (P < 0.05) without affecting prolactin. We conclude that endogenous opioids inhibit LH and prolactin release in the horse but the regulation of these two hormones involves independent opioid pathways. These are activated differentially in stallions, geldings and mares. The opioid regulation of prolactin secretion is not mediated via GnRH.     

In vitro effects of beta-endorphin on testicular release of androgens in the lizard podarcis sicula raf

The effects of the proopiomelanocortin-derived opioid peptide, beta-endorphin (β-EP), and of the opioid antagonist, naloxone (NAL), on both basal and pituitary-stimulated androgen secretion from superfused quiescent and active testes were assessed in the adult lizard, Podarcis sicula. In the absence of the homologous pituitary, in vitro treatment with β-EP and/or NAL did not affect basal secretion of androgens from quiescent and active testes. Conversely, in the presence of the homologous pituitary, treatment with β-EP brought about a decrease in androgen secretion in active testes, but no effect on quiescent ones Naloxone counteracted the inhibitory effect of β-EP in active testes, and enhanced maximal pituitary-stimulated secretion of androgens in quiescent but not in active testes. The effects produces by β-endorphin and naloxone were reversible. These results suggest that, in this lizard, opioids might be involved in the control of androgen release. The lack of effect of β-EP and naloxone when added directly to the testes seems to suggest that the opioid agonist and antagonist act on androgen release by modulating pituitary gonadotrophin output. © 1996 Wiley-Liss, Inc.     

The met-enkephalin analog FK 33-824 directly inhibits ACTH release by the rat pituitary gland in vitro

Systematic administration of the enkephalin analog FK 33-824 was previously shown to stimulate PRL secretion and to inhibit ACTH secretion in man. Naloxone prevented the effect on PRL release, but not on ACTH release. In this study, the direct action of this analog on hormone release by rat anterior pituitary lobes $\text{in}$$\text{vitro}$ were investigated. 1 uM FK 33-824 inhibited basal ACTH secretion by anterior pituitary glands in vitro, while 0.1 uM and 1 uM attenuated the lysine vasopressin stimulated ACTH release. Naloxone did not reverse the inhibitory action of the analog on ACTH release. β-Endorphin (0.01 - 1 uM) did not directly affect ACTH release. Basal and dopamine-induced inhibition of PRL release by anterior pituitary glands was neither influenced by FK 33-824 (0.1 and 1 uM), nor by β-endorphin (0.1 and 1 uM) with or without bacitracin. This study shows that the long-acting met-enkephalin analog FK 33-824 differentially affects PRL and ACTH secretion by the pituitary gland. It seems to stimulate PRL release at a suprapituitary site and this action probably involves u opiate receptors, because naloxone prevents these stimulatory effects. The inhibitory effect of FK 33-824 on ACTH release, however, is mediated via a direct effect at the pituitary level, which does not involve u receptors, as naloxone did not prevent this effect. In this respect, its action differs from that of β-endorphin, which does not directly affect ACTH release by the anterior pituitary gland.     

Suppression of serum prolactin by naloxone but not anti-β-endorphin antiserum in stressed and unstressed rats

The role of endogenous opioids in the regulation of tonic and stress-induced prolactin secretion was studied in male rats. Animals with chronically indwelling intra-atrial catheters were used and served as their own controls. Intravenous injection of a potent rabbit anti-β-endorphin antiserum produced no change in either baseline serum prolactin or in the rise induced by swimming for 15 minutes at 20 C. Naloxone, 0.5 mg/kg intravenously, produced a small but statistically significant lowering of baseline serum prolactin levels, as well as a mild blunting of the stress-induced serum prolactin rise. The failure of anti- - endorphin antiserum to affect serum prolactin may be explained either by failure of the antiserum to gain access to hypothalamic prolactin regulating loci, or to lack of involvement of β-endorphin in the control of serum prolactin. The suppression of prolactin secretion seen with naloxone indicates that endogeneous opioids are involved in prolactin regulation, though the relatively small magnitude of the changes observed suggests that their role under physiological conditions may be a minor one.     

Endorphins and the central inhibition of urinary bladder motility

The involvement of endogenous opioid mechanisms in the central neurogenic control of urinary bladder function has been examined in anesthetized rats. Intracerebroventricular (ICV) microinjection of β-endorphin (0.5–2.0 μg) produced powerful inhibition of rhythmic bladder contractions initiated by central reflex activity. The peptide fragments γ-endorphin and α-endorphin (4–16 μg), formed by the processing of β-endorphin by membrane homogenates of brain, were less active than the parent compound. The inhibitory effects of β-endorphin was reversed by ICV naloxone (1–2 μg) but higher doses were required to reverse γ- or α-endorphin effects. ICV naloxone administered alone increased intravesicular pressure and bladder contraction frequency. These observations support the hypothesis that the endorphins have a physiological role in the central regulation of urinary bladder activity.