Down regulation of enkephalin (δ) receptors Demonstration in membrane-bound and solubilized receptors

The pentapeptide leucine enkephalin induced down-regulation of enkephalin receptors in neuroblastoma-glioma NG108-15 hybrid cells in a reversible fashion, whereas the stable enkephalin analogue, d-Ala²-Met-enkephalinamide (AMEA), and the potent opiate alkaloid, etorphine, had a prolonged effect. The opiate alkaloid, morphine, which has low affinity to δ-type enkephalin receptors of these cells did not induce down-regulation, whereas AMEA decreased the binding of both opiate agonists and antagonists but had no effect on the binding of the α₂-adrenergic ligand, [³H]yohimbine. From several experiments that were designed to remove the tightly bound AMEA, and from experiments with solubilized receptor we ruled out the possibility that the decreased binding capacity of enkephalin-treated cells reflects only receptor masking. The study suggests that down-regulation of enkephalin receptors that may also occur in vivo can account for some of the abnormal physiological responses of subjects treated chromically with opiates. However, since opiates from the morphine type can induce opiate tolerance in vivo, but not down-regulation of enkephalin receptors in the cultured cells, we suggest that down-regulation of δ-type opiate receptors may not be prerequisite for the development of the physiological tolerance/dependence on these alkaloids.     

Enkephalin and alpha-adrenergic receptors: evidence for both common and differentiable regulatory pathways and down-regulation of the enkephalin receptor

Several clones of neuroblastoma-glioma NG108-15 hybrid cells were used to reveal whether the regulation of opiate receptor density interacts with the regulation of alpha-adrenergic or acetyl-choline receptors. Low density of alpha-adrenergic receptors in 3 selected clones was accompanied with similar reduction in the density of enkephalin receptors but not in muscarinic acetyl-choline receptors. Yet opiate antagonists that increased the number of opiate receptors in the parent NG108-15 cells in a stereospecific manner had no similar effect on the number of alpha-adrenergic receptors. Moreover, the stable enkephalin analogue D-ala-2-methionine enkephalinamide, but not the opiate alkaloid morphine, decreased the binding of 3H-DAMEA to the membranes and induced down-regulation of enkephalin receptors. Yet DAMEA had no effect on the binding of the alpha-adrenergic antagonist 3H-yohimbine. The study suggests that alpha-adrenergic and enkephalin receptors may share some common regulatory pathways but opiate peptides and antagonists selectively decrease or increase the density of enkephalin receptors, respectively, with no effect on alpha-adrenergic receptor density.     

A radiolabeled-ligand-binding technique for the characterization of opioid receptors in the intact mouse vas deferens

The mouse vas deferens has served as a useful bioassay for examining the properties of opiate receptor subtypes. However, recent data indicate that the response of the vas deferens to opiates may be mediated by one or more of the several opiate receptors found in this preparation. Although a number of techniques can be utilized to assess the relative contribution of these receptors to the response of the mouse vas deferens to opiates (e.g., selective tolerance and naloxone antagonism studies), a radiolabeled-binding technique would provide an independent means of more completely characterizing the opiate receptor profiles in this preparation. Up to the present, however, there has been only limited success in developing a binding assay utilizing crude membrane fractions of the mouse vas deferens. To circumvent these problems, we have developed a binding technique utilizing the intact vas deferens. In contrast to results obtained with membrane fractions, we found highly specific (90–95%) and saturable binding of d-[2-³H]alanine, 5-d-leucine enkephalin, a ligand selective for delta opiate receptors, to the intact vas. Scatchard analyses indicated a single class of binding sites with an apparent K_d of 1.5 nm and a B_max of approximately 12 pmol/2 vas. The selectivity of binding was also examined. Naltrexone was 40 times less potent than unlabeled 2-d-alanine, 5-d-leucine enkephalin in displacing binding, whereas morphine and ethylketocyclazocine were 300 and 500 times less effective, respectively. This technique, coupled with the mouse vas deferens bioassay, should provide a more complete characterization of opioid receptor populations than has heretofore been possible.     

Interaction of iodinated human [D-Ala2]beta-endorphin with opitate receptors.

The interaction of beta-endorphin with opiate receptors was studied by using the radioiodinated, metabolically stable D-Ala2 derivative of human beta-endorphin. This analog binds specifically to rat brain membrane preparations with an apparent Kd of about 2.5 x 10-9 M. The ability of various enkephalin analogs, as well as opiate agonists and antagonists, to inhibit the binding of beta-endorphin clearly demonstrates that this peptide can bind to opiate receptors. However, the effects of various cations on the binding of 125I-[D-Ala2]beta-endorphin are markedly different from those found for enkephalin binding. Sodium ion at physiological concentrations decreases substantially the binding of enkephalins but only slightly decreases endorphin binding, whereas manganese enhances enkephalin binding but has no effect on endorphin binding. Moreover, potassium (100 mM) decreases the binding of beta-endorphin but does not affect enkephalin binding. These results suggest that beta-endorphin and enkephalin bind differently to the same receptor or bind to different receptors with overlapping specificity.     

Regulated endocytosis of opioid receptors: cellular mechanisms and proposed roles in physiological adaptation to opiate drugs

Opiate drugs such as morphine and heroin are among the most effective analgesics known. Prolonged or repeated administration of opiates produces adaptive changes in the nervous system that lead to reduced drug potency or efficacy (tolerance), as well as physiological withdrawal symptoms and behavioral manifestations such as craving when drug use is terminated (dependence). These adaptations limit the therapeutic utility of opiate drugs, particularly in the treatment of chronically painful conditions, and are thought to contribute to the highly addictive nature of opiates. For many years it has been proposed that physiological tolerance to opiate drugs is associated with a modification of the number or functional activity of opioid receptors in specific neurons. We now understand certain mechanisms of opioid receptor desensitization and endocytosis in considerable detail. However, the functional roles that these mechanisms play in the complex physiological adaptation of the intact nervous system to opiates are only beginning to be explored.     

Interaction of iodinated enkephalin analogues with opiate receptors.

Radioiodinated derivatives of the metabolically stable enkephalin analogues, [DAla²,Leu⁵]- and [DAla²,DLeu⁵]-enkephalin, have been prepared. Such derivatives show sterospecific binding to receptors in brain homogenates and some neuroblastoma cell lines such as NG108-15 and N4TG1. The relative effects of levorphanol and dextrorphan and Na⁺ and Mn⁺⁺ ions on enkephalin binding in brain and cells indicate that the iodinated derivatives are interacting with opiate receptors. Levorphanol is considerably more potent in displacing specifically bound enkephalin than dextrorphan. Sodium ions at physiological concentrations decrease enkephalin binding whereas manganese ions enhance it. Unlabelled monoiodo derivatives retain high potency in the guinea-pig ileum, mouse vas deferens and receptor binding assays. Unlabelled diiodo derivatives show far lower potency in these assays. It is concluded that radio-iodinated derivatives containing one iodine per molecule retain high affinity for the opiate receptor but diiodo derivatives do not.     

Ethanol Does Not Modify Opiate-Mediated Inhibition of Striatal Adenylate Cyclase

Ethanol increases the activity of "basal," guanine nucleotide- and dopamine-stimulated adenylate cyclase in mouse striatum. In contrast, ethanol, in vitro, did not modify the inhibition of striatal adenylate cyclase activity by opiates (morphine or [D-Ala2,D-Leu5] enkephalin). Following chronic in vivo ethanol treatment of mice, there was also no change in the character of opiate inhibition of striatal adenylate cyclase activity. Since ethanol, in vitro, does decrease striatal opiate receptor binding, the results suggest that the changes in affinity detected by ligand binding studies are not relevant for receptor-coupled adenylate cyclase activity, or that opiate receptor binding and opiate regulation of adenylate cyclase can be modulated independently. The selective effects of ethanol on systems that modulate adenylate cyclase activity may produce imbalances in neuronal function during in vivo ethanol exposure.     

Evidence for a mu-delta opioid receptor complex in CHO cells co-expressing mu and delta opioid peptide receptors

Based on non-competitive binding interactions we suggested that mu and delta receptors associate as a mu/delta receptor complex in rat brain. We hypothesized that the same non-competitive binding interactions observed in rat brain will be seen in CHO cells that co-express mu and delta receptors, but not in cells that express just mu or delta receptors. We used CHO cells expressing the cloned human mu receptor, cloned human delta receptor, or cloned mouse delta/human mu ("dimer cell"). Cell membranes were prepared from intact cells pretreated with 100nM SUPERFIT. [(3)H][d-Ala(2),d-Leu(5)]enkephalin binding assays followed published procedures. SUPERFIT, a delta-selective irreversible ligand, decreased [(3)H][d-Ala(2),d-Leu(5)]enkephalin binding to delta receptors by approximately 75% and to mu receptors by approximately 50% in dimer cells. SUPERFIT treatment did not decrease [(3)H][d-Ala(2),d-Leu(5)]enkephalin binding to mu cells. The IC(50) values observed in SUPERFIT-treated dimer cells were: [d-Pen(2),d-Pen(5)]enkephalin (1820nM) and morphine (171nM). Saturation binding experiments with SUPERFIT-treated dimer cells showed that [d-Pen(2),d-Pen(5)]enkephalin (5000nM) was a competitive inhibitor. In contrast, morphine (1000nM) lowered the B(max) from 1944fmol/mg to 1276fmol/mg protein (35% decrease). Both [d-Pen(2),d-Pen(5)]enkephalin and morphine competitively inhibited [(3)H][d-Ala(2),d-Leu(5)]enkephalin binding to SUPERFIT-treated mu cells. The results indicate that the mu-delta opioid receptor complex defined on the basis of non-competitive binding interactions in rat brain over 20 years ago likely occurs as a consequence of the formation of mu-delta heterodimers. SUPERFIT-treated dimer cells may provide a useful model to study the properties of mu-delta heterodimers.     

Enkephalins and Opiate Antagonists Control Calmodulin Distribution in Neuroblastoma-Glioma Cells

The calcium binding protein calmodulin and the opiate receptor binding sites are unevenly distributed in various subcellular fractions of neuroblastoma-glioma NG108-15 cells. The crude mitochondrial-membrane fraction of these cells contains two membrane fractions that are separable by sucrose gradient centrifugation. These two differ in the content of both calmodulin and opiate receptors. Leucine enkephalin and D-Ala2-methionine enkephalinamide decrease the amount of membrane-bound calmodulin in the NC108-15 cells in a time- and dose-dependent manner, whereas the opiate antagonists naloxone and levallorphan have an opposite effect. Naloxone blocks the effect of leucine enkephalin and dextrallorphan has no significant effect. The opiate alkaloids entorphine and phenazocine induce changes similar to that of the enkephalins whereas morphine is inactive even at high concentrations. The alteration in the amount of membrane-bound calmodulin after a short incubation (15 min) with the enkephalins or with naloxone is reflected as an opposite change in the amount of calmodulin in the cell cytosol. Naloxone and levallorphan also increase the number of opiate receptors in NG108-15 cells but dextrallorphan has no such effect. Modulation of the intracellular distribution of calmodulin by opioid peptides and alkaloids may control the activity of various membrane-bound and cytosolic systems that are calmodulin- and/or calcium-dependent.     

Upregulation of the opioid receptor complex by the chronic administration of morphine: a biochemical marker related to the development of tolerance and dependence.

Studies conducted after the development of the rapid filtration assay for opiate receptors, and before the recognition of multiple opioid receptors, failed to detect changes in opioid receptors induced by chronic morphine. Recent experiments conducted in our laboratories were designed to examine the hypothesis that only one of several opioid receptor types might be altered by chronic morphine. Using binding surface analysis and irreversible ligands to increase the "resolving power" of the ligand binding assay, the results indicated that chronic morphine increased both the Bmax and Kd of the opioid receptor complex, labeled with either [3H][D-Ala2,D-Leu5]enkephalin, [3H][D-Ala2-MePhe4,Gly-ol5]enkephalin or [3H]6-desoxy-6 beta-fluoronaltreone. In the present study rats were pretreated with drugs known to attenuate the development of tolerance and dependence [the irreversible mu-receptor antagonist, beta-funaltrexamine (beta-FNA), and the inhibitor of tryptophan hydroxylase, para-chlorophenylalanine], prior to subcutaneous implantation of morphine pellets. The results demonstrated that 1) unlike chronic naltrexone, beta-FNA failed to upregulate opioid receptors and 2) both beta-funaltrexamine and PCPA pretreatment attenuated the chronic morphine-induced increase in the Bmax, but not the Kd, of the opioid receptor complex. These results provide evidence that naltrex-one-induced upregulation of the opioid receptor complex might occur indirectly as a consequence of interactions at beta-funaltrexamine-insensitive opioid receptors and that morphine-induced upregulation (increased Bmax) of the opioid receptor complex is a relevant in vitro marker related to the development of tolerance and dependence. These data collectively support the hypothesis that endogenous antiopiate peptides play an important role in the development of tolerance and dependence to morphine.     

Some thoughts on the significance of enkephalin,the endogenous ligand

Enkephalin is compared to morphine and its congeners with particular regard to physico-chemical properties, biological stability and sensitivity to narcotic antagonists. Possible sites of action are considered. Interactions between endogenous enkephalin and exogenous opiate at the opiate receptor are discussed as a possible basis of tolerance and dependence caused by chronic administration of opiates.     

Desensitization and coupled receptors: a model of drug dependence

It is assumed that certain drug receptors are so coupled with certain physiological receptors that stimulation of either receptor increases the sensitivity of the other. If the drug receptor suffers tolerance (i.e. slow desensitization) and if insensitivity of the drug receptor also makes the physiological receptor insensitive, then tolerance must be responsible for a physiological deficiency. This may be remedied by increased drug administration which will raise the sensitivity of the remaining physiological receptors so that a normal or near-normal physiological situation is achieved. Thus the organism is not only tolerant to the drug but also dependent on it. If such theoretical considerations apply to opiate receptors (as drug receptors) and to catecholamine receptors (as physiological receptors), then the theory predicts that acute morphine administration increases the sensitivity of dopamine receptors, that sympathetic stimulation decreases pain sensitivity, that opioid tolerance provokes increased catecholamine activity, that alpha-receptor stimulants attenuate and alpha-receptor antagonists exacerbate morphine abstinence, and that catecholaminergic inhibition results in increased morphine toxicity. All of these predictions have been verified experimentally.     

Differential sorting of human delta-opioid receptors after internalization by peptide and alkaloid agonists

Desensitization and internalization of G protein-coupled receptors observed after agonist activation are considered two important regulatory processes of receptor transduction. Endogenous human delta-opioid receptors (hDOR) are differentially regulated in terms of desensitization by peptide ([d-Pen2,5]enkephalin (DPDPE) and Deltorphin I) and alkaloid (etorphine) agonists in the neuroblastoma cell line SK-N-BE (Allouche, S., Roussel, M., Marie, N., and Jauzac, P. (1999) Eur. J. Pharmacol. 371, 235-240). In the present study, we examined the role of hDOR internalization and down-regulation in this differential desensitization. Sustained activation by peptides for 30 min caused a marked decrease of both [3H]diprenorphine binding sites and hDOR immunoreactivity, observed in a Western blot, whereas a moderate reduction by 30% was observed after a 30- and 60-min etorphine exposure in binding experiments without opioid receptor degradation. Using fluorescence microscopy, we visualized hDOR internalization promoted by different agonists in SK-N-BE cells expressing FLAG-tagged hDOR. Agonist withdrawal results in a greater recycling process correlated with a stronger hDOR resensitization after etorphine treatment compared with DPDPE or Deltorphin I, as shown in binding, immunocytochemical, and functional experiments. This suggests a distinct sorting of opioid receptors after their internalization. We demonstrated a lysosomal hDOR targeting upon peptides by using chloroquine in binding, Western blot, and immunocytochemical experiments and by colocalization of this receptor with a late endosome marker. In contrast, when the recycling endosome blocker monensin was used, acceleration of desensitization associated with a strong intracellular immunostaining was observed upon etorphine treatment. The possibility of separate endocytic pathways responsible for the differential sorting of hDOR upon peptide and alkaloid ligand exposure was ruled out by binding and immunocytochemical experiments using sucrose hypertonic solution. First, these results showed complex relationships between hDOR internalization/down-regulation and desensitization. Second, we demonstrated for the first time that the same receptor could undergo a distinct sorting after internalization by peptide and alkaloid agonists.     

3H-diprenorphine is selective for mu opiate receptors in vivo

The displacement of 3H-diprenorphine from opiate receptors by mu-selective opiates was measured in the mouse striatum and thalamus in vivo. In addition, the regional distribution of opiate receptor binding using 3H-diprenorphine, 3H-naloxone and 3H-lofentanil was measured. The displacement of 3H-diprenorphine by naloxone and carfentanil in vivo showed no differences in the striatum and thalamus suggesting that 3H-diprenorphine binds only to one opiate receptor subtype in vivo. This finding is substantiated by the observation that the mu selective ligands 3H-naloxone and 3H-lofentanil have the same in vivo distribution of receptor binding as 3H-diprenorphine. The implication of these findings for PET imaging of opiate receptor subtypes is discussed.     

Activation of protein kinase C down-regulates IFN-gamma receptors

Treatment of mouse EL-4 cells with intracellular activators of protein kinase C, namely 4-phorbol 12-myristate 13-acetate (PMA) and diacylglycerol, resulted in 90% reduction in cell surface interferon-gamma (IFN-gamma) receptors as judged by iodinated-IFN-gamma binding. This did not seem to be due to a decreased in the receptor affinity, since that of the remaining surface receptors appeared to be significantly increased as shown in Scatchard plot analysis. Kinetics experiments revealed that a PMA treatment as short as 15 min was sufficient to induce a decrease of 30% of IFN-gamma receptors, whereas the highest levels of down-regulation were observed after 60-90 min. Treatment of EL-4 cells with calcium ionophore, A23187, although ineffective by itself, dramatically increased the ability of suboptimal PMA concentrations to mediate IFN-gamma receptor down-regulation. Finally, specificity studies revealed that PMA is particularly effective in decreasing the binding of IFN-gamma to T-lymphocytes. Altogether these results suggest a possible involvement of protein kinase C in the regulation of IFN-gamma receptor expression.     

Opiate activity of a bone marrow humoral factor which stimulates antibody production

The radioceptor method was used to demonstrate that humoral factor of the bone marrow, a stimulant of antibody production (SAP), contains substances that competitively remove 3H-morphine and 3H-met-enkephalin from opiate receptors of the rat brain, and 3H-met-enkephalin from specific binding sites on human lymphocytes. Comparison of the magnitudes EC50 SAP obtained during the removal of labeled opiates allows a suggestion to be made that opiates contained by the preparation under study have a greater capability to interact with delta-type opiate receptors rather than with those of the mu-type.     

Interaction of [3H](–)-SKF-10,047 with Brain σ Receptors: Characterization and Autoradiographic Visualization

The sigma opiates differ from other opiates in their stimulatory and psychotomimetic actions. The sigma opiate [3H](-)-SKF-10,047 has been used to characterize sigma receptors in rat nervous tissue. Binding of [3H](-)-SKF-10,047 to rat brain membranes was of high affinity, saturable, and reversible. Scatchard analysis revealed the apparent interaction of this drug with two distinct binding sites characterized by affinities of 0.03 and 75 nM (5 mM Tris-HCl buffer, pH 7.4, at 4 degrees C). Competition analyses involving rank order determinations for a series of opiates and other drugs indicate that the high-affinity binding site is the mu opiate receptor. The lower-affinity site (revealed after suppression of mu and delta receptor binding) has been identified as the sigma opiate/phencyclidine receptor. In vitro autoradiography has been used to visualize neuroanatomical patterns of receptors labeled using [3H](-)-SKF-10,047 in the presence of normorphine and [D-Ala2,D-Leu5]enkephalin to block mu and delta interactions, respectively. Labeling patterns differ markedly from those for mu, delta, or kappa receptors. The highest densities (determined by quantitative autoradiography) are found in the medial portion of the nucleus accumbens, amygdaloid nucleus, hippocampal formation, central gray, locus coeruleus, and the parabrachial nuclei. Receptors in these structures could account for the stimulatory, mood-altering, and analgesic properties of the sigma opiates. Although not the most selective sigma opiate ligand, [3H](-)-SKF-10,047 binds to sigma opiate receptors in brain, and this interaction can be readily distinguished from its interactions with other classes of brain opiate receptors.     

Functional dissociation of mu opioid receptor signaling and endocytosis: implications for the biology of opiate tolerance and addiction.

Opiate analgesia, tolerance, and addiction are mediated by drug-induced activation of the mu opioid receptor. A fundamental question in addiction biology is why exogenous opiate drugs have a high liability for inducing tolerance and addiction while native ligands do not. Studies indicate that highly addictive opiate drugs such as morphine are deficient in their ability to induce the desensitization and endocytosis of receptors. Here, we demonstrate that this regulatory mechanism reveals an independent functional property of opiate drugs that can be distinguished from previously established agonist properties. Moreover, this property correlates with agonist propensity to promote physiological tolerance, suggesting a fundamental revision of our understanding of the role of receptor endocytosis in the biology of opiate drug action and addiction.     

Multiple opiate receptors: emerging concepts

Increasing biochemical evidence indicates that the wide spectrum of opiate pharmacological actions are mediated via heterogeneous classes of receptors. μ receptors have been identified as the high affinity sites where morphine-like opiates exert their analgesic effects. δ receptors have a somewhat different CNS distribution and have been identified as sites relatively selective for the naturally occuring enkephalins. Recent biochemical studies provide evidence for two additional classes of opiate receptor sites which were originally proposed on the basis of physiological studies. Ketocyclazocine-like opiates produce their unique ataxic and sedative effects via interaction with K receptors, and SKF-10,047 (N-allylnorcyclazocine) and related opiates produce stimulant and psychotomimetic effects via interactions with σ receptors.Many opiate drugs interact at multiple receptor sites. Thus, the constellation of neuropharmacological actions of a particular opioid ligand may reflect its various potencies at a combination of μ, δ, K, and σ receptors.     

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.