The role of monocytes in the effects of β-endorphin and selective agonists of μ-and δ-opiate receptors on the proliferative activity of peripheral blood lymphocytes

The effects of β-endorphin under the conditions of naloxone hydrochloride blockade of opiate receptors, as well as the effects of the selective agonists of μ-and δ-receptors DAGO and DADLE and the effects of melanocyte-potentiating factor (MPF), on the in vitro proliferative response of lymphocytes were studied. The dose-effect dependence indicated stimulating effects of β-endorphin, DAGO, and DADLE on the proliferative response in the presence of phytohemagglutinin (PHA). The tetrapeptide MPF, which is the C-terminal sequence of β-endorphin, had almost no effect on the proliferative activity of lymphocytes. β-Endorphin, naloxone, and the μ-and δ-receptor selective agonists enhanced the proliferative response of lymphocytes in an unfractionated cell culture, whereas β-endorphin, naloxone, and DAGO suppressed the proliferative activity of lymphocytes in the mononuclear fraction purified of monocytes. In both cases, the naloxone blockade of opiate receptors enhanced rather than eliminated the β-endorphin effect.     

Effect of the opiate antagonist naloxone on the electrical activity of identified neurons in the edible snail

The opiate antagonist naloxone modifies the electric activity of some identified neurons of the Helix lucorum which have not been preliminary exposed to the effect of exogenous opioids. Some neurons are excited while others are inhibited by naloxone, and in both cases the reaction may have both a short and long latent period. The reactions depend on naloxone dose and become less expressed or are blocked when naloxone is administered together with the agonists of opiate receptor (morphine, D-Ala2, D-Leu5-enkephalin, bremazocine and beta-endorphin). Opioids alone do not produce any effect on neurons. The effect of naloxone on neurons is assumed to be a result of the elimination by the opiate antagonist of the tonic effect of endogenous opioids by their replacing on opiate receptors which are constantly stimulated by endogenous ligands.     

Central, stereoselective receptors mediate the acute effects of opiate antagonists on luteinizing hormone secretion

Although a central site of acute opiate action in regulating luteinizing hormone (LH) secretion has been suggested by the ability of centrally implanted opiate antagonists to increase LH levels, opiate antagonists are lipophilic and could influence the pituitary in situ. Also, the physiological significance of opiate receptor blockade with antagonists rests on the assumed, but untested, stereoselectivity of these receptors. Therefore, a lipophobic quaternized derivative of naltrexone (MRZ 2663-Naltrexone methobromide) and dextro- (+) and levo- (-) stereoisomers of naloxone were used to study the site- and stereoselectivity of gonadotropin responses to opiate antagonists in vivo. Male rats were injected intracerebroventricularly (icv) or intravenously (iv) with the quaternary or tertiary congeners of naltrexone and subcutaneously (sc) with (-) or (+)-naloxone. Rats injected icv with 20 ug of quaternary naltrexone displayed significant increases in serum luteinizing hormone (LH). The onset of the response was rapid with serum LH levels being significantly elevated 15 minutes after the injection and returning to basal levels 30 minutes later. Rats injected iv with 10 mg/kg of quaternary naltrexone failed to show significant LH responses. Rats injected either centrally or periphally with equivalent doses of tertiary naltrexone showed LH responses that were similar to those found in animals injected icv with quaternary naltrexone. As little as 0.5 mg/kg of (-)-naloxone resulted in significant elevations in serum LH that were higher than those elicited by up to 10 mg/kg of (+)-naloxone, indicating that this effect of naloxone is stereoselective. These data support the argument that opioids can acutely modulate LH secretion through actions at stereoselective opioid receptors in the central nervous system.     

An investigation of the activity of opiate drug receptors located on frog skeletal muscle fibre membrane.

Extracellular and intracellular microelectrode studies were conducted to test the actions and interactions of opiate agonists, antagonists, and procaine on action potentials in frog sartorius muscles. Extracellular studies showed that morphine, methadone, propoxyphene, and procaine all depressed action potential production. Low concentrations of naloxone or naltrexone antagonized the excitability depression produced by the three opiate agonists but not the depression produced by procaine. Intracellular studies revealed that certain concentrations of the opiate agonists produced a biphasic decline in the stimulus-induced increase in sodium conductance (gNa). Naloxone or naltrexone antagonized only the second phase of this decline. These results show that part of the excitability depression produced by opiate agonists is due to an action on opiate drug receptors.     

Effects of the opiate antagonists diprenorphine and naloxone and of selected opiate agonists on feeding behavior in guinea pigs

Opiate-sensitive feeding behavior has now been demonstrated in a number of species. We sought information on which opioid receptors might be involved in the observed feeding behaviors. Guinea pigs are known to have higher concentrations of the opioid kappa receptor than any other laboratory animal, so we compared the feeding suppressive potency of the general opiate antagonist, diprenorphine to that of the relatively more mu-specific antagonist, naloxone in that species. We found that diprenorphine was over twenty times more effective than naloxone in suppressing feeding in guinea pigs, suggesting the importance of receptors other than mu in feeding initiation in the guinea pig. Confirmatory evidence for the role of kappa receptors was sought, but not found, in comparisons of the effectiveness of different types of opiate agonists in promoting feeding in these animals. These agonists suppressed, rather than stimulated feeding. We conclude that no feeding stimulatory effects of opiates can be demonstrated in guinea pigs. This observation may indicate that opioids play little role in the natural regulation of feeding in this species or that opioids result in prolonged sedation during which the animals fail to eat. The greater feeding suppressive potency of diprenorphine, a general opiate antagonist, versus naloxone, a mu-preferential antagonist, indicates that to whatever extent opiates are involved in guinea pig feeding, the opiate effect is probably not a mu receptor effect.     

Opioid receptor agonists and Ca2+ modulation in human B cell lines.

Opiates and opioid peptides have been shown to modulate lymphocyte functions; however, little attention has been given to the type of receptors or receptor signaling mechanisms that are involved. Receptor-mediated signaling via ionized free Ca2+ is an event thought to be important in the triggering of lymphocyte activities. We report use of the calcium indicator dye, indo-1, and flow cytometry to identify B lymphocyte calcium responses to physiologic concentrations of opioid peptides. The human B cell lines Nalm 6 and JY responded to the naturally occurring opioid pentapeptide methionine-enkephalin or other opiate receptor agonists with a rapid, dose-dependent rise in free cytoplasmic Ca2+. This opioid peptide effect on Ca2+ modulation was inhibited by the opiate receptor antagonist naloxone. The synthetic enkephalin analogue DAMGO with specificity for mu-type opiate receptors and the synthetic opiate receptor agonists U50,488H and U69,593 with selectivity for kappa-type sites also stimulated calcium responses when applied to the B cell lines. These studies provide evidence that human B cell lines express functional opiate receptors of the mu- and kappa-types and suggest that such receptors, coupled with Ca2+ modulation, are instrumental in the B cell response to opiates and endogenous opioid neuropeptides.     

Actions of opiate agonists, naloxone, and paraben preservatives in the rat lung circulation

Previous studies have documented direct vascular effects of opiate substances in the systemic circulation. Because opiate receptors have been identified in the lung, we wondered whether opiate substances might affect vasoreactivity in the lung circulation. We studied the pulmonary vascular effects of three opiate agonists: morphine, leucine-enkephalin, and dynorphin, as well as the opiate receptor antagonist naloxone, in isolated rat lungs perfused with a cell- and plasma-free salt solution. Because of previous reports of the smooth muscle effects of the methyl- and propylparaben preservatives in the naloxone preparation, we also studied the pulmonary vascular effects of these preservatives in the rat lung circulation. We found that morphine, a mu-receptor agonist, leucine-enkephalin, a delta-receptor agonist, and dynorphin, a kappa-receptor agonist, caused no immediate vascular effect when injected into the pulmonary artery. In addition, morphine did not affect the pulmonary vasoconstrictions induced by hypoxia, angiotensin II, or potassium chloride. The commercial preparation of naloxone, Narcan, caused a marked vasodilation during hypoxic pulmonary vasoconstriction. However, this effect was entirely attributable to the preservatives methyl- and propylparaben, as pure naloxone had no effect on either the baseline pulmonary vascular tone or the vasoconstrictive response to hypoxia. We conclude that opiate receptor agonists and antagonists do not affect vasoreactivity in the rat lung circulation and that the methyl- and propylparaben preservatives in Narcan are pulmonary vasodilators.     

Involvement of the hypothalamus in opiate-stimulated prolactin secretion

Administration of opiate agonists to rats is known to elevate plasma prolactin, an effect which is antagonised by the opiate antagonist naloxone. However, this appears not to be a result of a direct action at the pituitary gland. We report here that opiate agonists stimulate prolactin secretion from isolated adenohypophysial cells when they are coincubated with hypothalamic fragments. Both morphine and Met-enkephalin stimulated prolactin secretion by 1.84 fold and 1.50 fold respectively, and this was antagonised by naloxone. These findings support the hypothesis that one site of action of opioid compounds on pituitary hormone secretion is at the level of hypothalamus.     

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-like activity of the enkephalin analog Tyr-D-Ala-Gly-Phe-NH2

The analgetic activity of the tetrapeptide enkephalin analog, its influence on the interneuronal transmission of excitation in various areas of the central nervous system and on opiate receptors of vas deferens were studied. The tetrapeptide was found to have a marked analgetic effect during intravenous injection to mice but to be less active than morphine. The tetrapeptide as well as morphine inhibited the impulse summation in rabbits and both spontaneous and bradykinin-induced neuronal activity in the rat sensory motor cortex. The tetrapeptide inhibited the contractions of isolated vas deferens in mice. The opiate antagonist naloxone eliminated both analgetic effect of the tetrapeptide and its inhibitory effect on the impulse summation, neuronal activity and contractions of vas deferens.     

Opiate-Inhibited Adenylate Cyclase in Rat Brain Membranes Depleted of Gs-Stimulated Adenylate Cyclase

Opiate agonists inhibit adenylate cyclase in brain membranes, but under normal conditions the maximal inhibition is small (10-15%). When rat brain membranes were preincubated at pH 4.5, washed, and then assayed for adenylate cyclase at pH 7.4, stimulation of activity by agents (fluoride, guanylyl-5'-imidodiphosphate, cholera toxin) that act through the stimulatory GTP-binding coupling protein (Gs) protein was lost. At the same time, inhibition of basal adenylate cyclase by opiate agonists was increased to a maximum of 30-40%. Opiate inhibition was maximal at low magnesium concentrations (less than 5 mM), required guanine nucleotides, and decreased the Vmax, not Km, of the enzyme. Incubation of membranes with pertussis toxin lowered the apparent affinity for agonists in inhibiting activity. The delta opioid agonists were more potent than mu agonists, and the Ke values for naloxone in blocking agonist inhibition were similar for both mu and delta agonists (50-90 nM). These results suggest that inhibition of adenylate cyclase in brain is not mediated by mu opiate receptors, but whether classic high-affinity delta and kappa receptors are involved with this enzyme cannot be confirmed by these experiments.     

Microsomal Opiate Receptors: Characterization of Smooth Microsomal and Synaptic Membrane Opiate Receptors

In continuing studies on smooth microsomal and synaptic membranes from rat forebrain, we compared the binding properties of opiate receptors in these two discrete subcellular populations. Receptors in both preparations were saturable and stereospecific. Scatchard and Hill plots of [3H]naloxone binding to microsomes and synaptic membranes were similar to plots for crude membranes. Both synaptic membranes and smooth microsomes contained similar enrichments of low- and high-affinity [3H]naloxone binding sites. No change in the affinity of the receptors was observed. When [3H]D-ala2-D-leu5-enkephalin was used as ligand, microsomes possessed 60% fewer high-affinity sites than did synaptic membranes, and a large number of low-affinity sites. In competition binding experiments microsomal opiate receptors lacked the sensitivity to (guanyl-5'-yl)imidodiphosphate [Gpp(NH)p] shown by synaptic and crude membrane preparations. In this respect microsomal opiate receptors resembled membranes that were experimentally guanosine triphosphate (GTP)-uncoupled with N-ethylmaleimide (NEM). Agonist binding to microsomal and synaptic membrane opiate receptors was decreased by 100 mM NaCl. Like NEM-treated crude membranes, microsomal receptors were capable of differentiating agonist and antagonists in the presence of 100 mM NaCl. MnCl2 (50-100 microM) reversed the effects of 100 mM NaCl and 50 microM GTP on binding of the mu-specific agonist [3H]dihydromorphine in both membrane populations. Since microsomal receptors are unable to distinguish agonists from antagonists in the presence of Gpp(NH)p, they are a convenient source of guanine nucleotide-uncoupled opiate receptors.     

Circadian Rhythm of the Pupillary Response to Morphine and to Naloxone

Mice respond to morphine with characteristic mydriasis which is antagonized by naloxone. The present study presents data on the diurnal variation of these responses. The mydriatic response is at its highest level at 0800 and has a nadir at 2400. This effect is not influenced by ambient light conditions. The miotic response to naloxone in the morphine-dilated pupil is maximal between 1200 and 1600 and minimal at 0400. The curves of the responses to the two drugs, therefore, differ as do their acrophases. Pharmacokinetic factors are probably not responsible for the observed variations. It is speculated that these diurnal changes may reflect cyclic alteration in the affinity of the opiate receptors to agonists and antagonists, respectively, or in the number of available receptors.     

Butorphanol tartrate induces feeding in rats

Peripheral administration of butorphanol tartrate markedly enhanced feeding from 0800 to 1400 hours when compared with vehicle controls. Butorphanol tartrate feeding was not antagonized by doses of naloxone as high as 10 mg/kg. These data support the concept that the kappa or sigma opiate receptors are involved in feeding behavior.It is well recognized that the endogenous opiates play a role in the central regulation of appetite (1, 2, 3, 4). Numerous studies have shown that The endogenous opioid peptides and morphine can initiate feeding under various conditions (5–12) whereas the opiate antagonist, naloxine can reduce food consumption (13–20). Recently, the endogenous opiod peptide, dynorphin, has been reported to enhance food intake (12–25).Much evidence has been accumulated indicating that a number of opiate receptors are present in the brain, each one having a high affinity for a specific endogenous opioid peptide (26, 27). Both the cyclazocine related compounds (28) and the feeding enhancer, dynorphin (29–32), have been reported to be specific kappa receptor agonists. In the present study, we report on the effect of the morphinan congener, butorphanol tartrate (33), on ingestive behaviour.     

On the specificity of naloxone as an opiate antagonist.

Since the discovery of endogenous opioid peptides in brain (68,69,97,113, 128) and the pituitary gland (26,81,105,125) there has been considerable interest in their possible roles in a variety of physiological and pharmacological processes. Many studies have used antagonism by naloxone as a criterion for implicating endogenous opiates in a process, assuming that naloxene has no pharmacological actions other than those related to blockade of opiate receptors. The doses of naloxene used are often higher than those required to antagonize the analgesic and other effects of morphine. However, multiple forms of opiate receptors are present in nervous tissue and higher concentrations of naloxene are required to antagonize effects mediated by some of these receptors (83). Although the earlier literature supports the assumption that the effects of naloxene are due to the blockade of opiate receptors (87), there are an increasing number of reports which indicate that naloxene may have pharmacological actions unrelated to opiate receptor blockade. The subsequent review serves to emphasize that antagonism by naloxene is a necessary but not sufficient criterion for invoking the mediation of a response by an endogenous opiate (61). Additional lines of evidence which serve to strengthen the conclusion that endogenous opiates mediate a process will be considered.     

Lack of antagonism by naloxone of the analgesic and locomotor stimulant actions of ketamine

Ketamine hydrochloride caused dose-related analgesia and ataxia in rats. In mice, ketamine caused dose-related analgesia and stimulation of locomotor activity. None of these actions of ketamine were appreciably altered by the narcotic antagonist naloxone. Thus, these actions of ketamine do not appear to be mediated by opiate receptors.     

Enhancement of opiate-induced depressions in serum luteinizing hormone levels by the prior administration of naloxone in the male rat

The effects of naloxone pretreatment on opiate agonist-induced depressions in serum luteinizing hormone (LH) levels were examined in male rats. Our results demonstrated a pronounced enhancement of morphine's actions 6 hours after the administration of naloxone (0.5 mg/kg). This effect was characterized by a 10 fold reduction in the ED50 (1.26 mg/kg versus 0.13 mg/kg in saline- and naloxone-pretreated rats, respectively) and much greater depressions in serum LH levels at each dose of morphine. The actions of naloxone were not confined to morphine, since similar increased potencies were found for opioid agonists with selectivity for a variety of opioid receptor subtypes. Because naloxone did not alter the uptake of subsequently administered morphine into brain, our results cannot be explained on the basis of an increased availability of the agonist. Rather, it appears that naloxone pretreatment induces a change in the sensitivity of those receptors involved in the effects of opioid agonists on LH.     

MORPHINE INDUCED CALCIUM DEPLETION IN DISCRETE REGIONS OF RAT BRAIN1

The in vivo administration of a single dose of morphine produces a decrease of tissue calcium in the rat brain. This decrease is observed to be linear, dose-dependent, time-dependent and to occur to an equal degree in 8 discrete brain regions. This effect of morphine is blocked by naloxone and exhibits a high degree of sterospecificity. The reserpine induced decrease of brain calcium was not antagonized by naloxone. Differentiation of this response using reserpine and naloxone indicates the possibility of calcium pools in the central nervous system. The results are discussed in terms of a specific effect of opiate drugs and the role of calcium in opiatereceptor interactions.     

CHARACTERISTICS AND REGIONAL DISTRIBUTIONS OF TWO DISTINCT [3H]NALOXONE BINDING SITES IN THE RAT BRAIN

Using [³H]naloxone at a concentration of 4.5 nm , the potent opiate agonist etorphine as well as the potent antagonist diprenorphine displace only about 75% of specific naloxone binding P₂ fractions from rat whole forebrain, without additive effect. Several other opiates and antagonists completely displace specific naloxone binding. This indicates that etorphine and diprenorphine specifically bind to one and the same naloxone binding site (type I) while leaving another naloxone binding site (type II) unaffected. Type I binding sites are much more thermo-labile than type II. [³H]Naloxone binding to type I sites is unaffected by incubation temperature in the range 10 to 25°C. while binding type II sites decreases rapidly with increasing incubation temperature, no specific type II binding being detectable at or above 20°C. The two naloxone receptor types also differ with respect to pH dependence, and affinity for naloxone with types I and II having affinity constants (K_d) of 2 and 16 nm , respectively, at 0°C. The two binding sites have different regional distributions with high relative levels of type II receptors in cerebellum and low relative levels in pons-medulla and striatum. In whole rat brain there are about 4 times as many type II receptors as type I. These results suggest that naloxone and several other opiate agonists and antagonists bind to two distinct receptor types which are probably not agonist/antagonist aspects of the same receptor.     

An investigation of the role of kappa opiate receptor agonists in the initiation of feeding

A large body of evidence has suggested a role for the endogenous opiates and their receptors in the regulation of appetite. In this study we have examined the relative effects of ketocyclazocine (KC), cyclazocine and ethylketocyclazocine, all putative kappa opiate receptor agonists, and morphine, a putative mu receptor agonist, on food consumption. All the kappa agonists induced feeding when administered at 8 AM as did morphine. KC failed to induce feeding during the nocturnal feeding period (2000 and 0200 hours) and morphine suppressed feeding at these times. KC and morphine suppressed starvation induced feeding when food was made available immediately after injection and had no effect when food was presented 2 and 4 hours after injection. High doses of naloxone (5 mg/kg) suppressed KC induced feeding while actually enhancing high dose morphine (25 mg/kg) induced feeding. Repeated injections of KC or morphine for 5 days resulted in enhancement of the feeding response with initiation of feeding occuring earlier. Taken together with the studies showing that the endogenous kappa ligand, dynorphin, enhabces feeding the most parsimonious interpretation of these studies is that kappa agonists are endogenous initiators of feeding and that kappa receptors are maximally saturated at times of food deprivation and during spontaneous feeding. The mu (or one of the other) opiate receptors inhibit feeding due to their sedative effect and antagonism of this effect leads to enhancement of the feeding response. It is postulated that kappa opiate receptors represent an important component of the natural feeding drive.