Evidence for a single opioid receptor type on the field stimulated rat vas deferens

A series of opioids have been used to study the heterogeneity of the opioid receptor system in rat vas deferentia. β-Endorphin, etorphune, etonitazine, D-Ala²-Nle⁵ (des-COOH) enkephalin and, sufentanil behave as full agonists in this tissue preparation. Ketobemidone, α(+)-N-allyl normetazocine, morphine and oxymorphone show little or no biological activity. In fact, the latter four drugs were able to inhibit the biological effects of β-endorphin, etorphine and sufentanil in a concentration dependent fashion. These data suggest that there is only one opioid receptor type in the rat vas deferens. These observations are discussed in terms of the binding modes for a series of drugs to an homogeneous receptor system.     

SPECIFIC STIMULATION OF MIGRATION OF HUMAN KERATINOCYTES BY μ -OPIATE RECEPTOR AGONISTS

ABSTRACT

There are several indications that neuropeptides, especially the opiate receptor agonists, modulate the immune response by stimulating the formation of granulation tissue and enhancing the reepithelialization. We observed that the μ-opiate receptor ligand β-endorphin stimulates the migration of cultured human foreskin keratinocytes. After 1?hour exposure to 1?µM β-endorphin, the keratinocytes experienced an increase of cell diameter by cellular elongation and stimulation of migration. Dynorphin had a lesser effect under the same condition. The opiate receptor antagonist naltrexone significantly reduced the effect of β-endorphin on keratinocyte migration. This migratory effect of μ-opiate receptor agonists in vitro indicates that the opioid peptides, released in wounds, could play a key role in the final reepithelialization and tissue regeneration in wound healing. This new knowledge will help us not only to understand the mechanism of wound healing but also to improve the therapeutic strategy in the healing of painful chronic wounds.     

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.     

Agonist-Specific Regulation of δ-Opioid Receptor Trafficking by G Protein-Coupled Receptor Kinase and β-Arrestin

Abstract

Opioid receptors mediate multiple biological functions through their interaction with endogenous opioid peptides as well as opioid alkaloids including morphine and etorphine. Previously we have reported that the ability of distinct opioid agonists to differentially regulate μ-opioid receptor (μOR) responsiveness is related to their ability to promote G protein-coupled receptor kinase (GRK)-dependent phosphorylation of the receptor (1). In the present study, we further examined the role of GRK and β-arrestin in agonist-specific regulation of the δ-opioid receptor (δOR). While both etorphine and morphine effectively activate the δOR, only etorphine triggers robust δOR phosphorylation followed by plasma membrane translocation of β-arrestin and receptor internalization. In contrast, morphine is unable to either elicit δOR phosphorylation or stimulate β-arrestin translocation, correlating with its inability to cause δOR internalization. Unlike for the μOR, overexpression of GRK2 results in neither the enhancement of δOR sequestration nor the rescue of δOR-mediated β-arrestin translocation. Therefore, our findings not only point to the existence of marked differences in the ability of different opioid agonists to promote δOR phosphorylation by GRK and binding to β-arrestin, but also demonstrate differences in the regulation of two opioid receptor subtypes. These observations may have important implications for our understanding of the distinct ability of various opioids in inducing opioid tolerance and addiction.     

Agonist stimulation at human μ opioid receptors in a [35S]GTPγS incorporation assay: observation of “bell-shaped” concentration–response relationships under conditions of strong receptor G protein coupling

Context: The appearance of “bell”- (or “inverted U”-) shaped agonist concentration–response curves (CRCs) in in vitro pharmacological experiments is a frequently observed but poorly communicated phenomenon. In the context of G protein coupled receptor research, it is commonly attributed to the recruitment of secondary targets or to desensitization or feedback processes, but the concrete background of these observations often remains intriguing. Objective: Here, we addressed the subject of bell-shaped agonist CRCs at the µ opioid receptor (µOR) by testing the impact of experimental conditions favoring G protein coupling. Methods: G protein activation by recombinant human µORs heterologously expressed in CHO cells was assessed in [³⁵S]GTPγS binding assays using the opioid ligands DAMGO, morphine, fentanyl and naloxone. Experimental conditions were varied by changing the NaCl (10–300?mM) and the GDP concentration (0.3–30?µM). Results: Both the sodium and the GDP concentration were inversely related to G protein coupling, as evident by an increase in basal [³⁵S]GTPγS incorporation at low sodium and low GDP levels and by the concomitant appearance of the partial agonist activity of the µOR antagonist, naloxone. Bell-shaped CRCs were observed for the efficacious agonists DAMGO, fentanyl and morphine, and this phenomenon was promoted by low sodium as well as by low GDP concentrations. Conclusion: µOR agonist CRCs show a non-monotonic behavior with a decline of maximal stimulation under conditions of strong receptor-G protein coupling, and this behavior is visible at the level of G protein activation itself.     

Comparison of opiate- and opioid-peptide-induced immobility.

Intraventricular administration of the endogenous opioid peptide β-endorphin produces a profound state of immobilization in rats characterized by the absence of spontaneous movement, loss of the righting response and extreme generalized muscular rigidity. The immobility syndrome induced by the opioid peptides β-endorphin and D-Met²-Pro⁵-enkephalinamide was compared with the behavioral profile prodced by subcutaneous and intraventricular administration of the opiates, morphine, methadone and etonitazene. The results indicate a close similarity between the pattern of effects caused by the opiates and opioid peptides. The immobility syndrome could also be produced by injection of β-endorphin into the ventromedial periaqueductal gray, but not into the caudate, globus pallidus, amygdala or dorsolateral periaqueductal gray. The resemblance between the opiate- and β-endorphin-induced profiles suggests that their effects are mediated through common mechanisms.     

β-endorphin proteolysis by guinea-pig ileum myenteric plexus membranes: Increased γ-endorphin turnover after chronic exposure to morphine

The influence of chronic morphine exposure $\text{in vitro}$ on the biotransformation of β-endorphin (βE) was investigated using the myenteric plexus-longitudinal muscle of guinea-pig ileum. A membrane preparation was incubated with βE and the degradation of βE as well as the accumulation of several βE fragments in the incubation medium were followed with time. The levels of peptides were determined by specific radioimmunoassays after separation by high-pressure liquid chromatography. It was found that exposure to morphine did not affect the disappearance of βE, but altered the time course of accumulation of βE fragments. In fact, the accumulation of γ-endorphin, α-endorphin and des-tyrosine¹-α-endorphin was enhanced, while that of des-tyrosine¹-γ-endorphin was not changed. Additionally, the disappearance of γ-endorphin appeared to be stimulated by morphine exposure. These data provide evidence that the fragmentation of βE is changed by chronic morphine exposure in such a way that the turn-over of γ-endorphin is increased.     

Differential signaling properties at the kappa opioid receptor of 12-epi-salvinorin A and its analogues

The kappa opioid receptor (KOPR) has been identified as a potential drug target to prevent or alter the course of mood, anxiety and addictive disorders or reduce response to stress. In a search for highly potent and selective KOPR partial agonists as pharmacological tools, we have modified 12-epi-salvinorin A, a compound which we have previously observed to be a KOPR partial agonist. Five analogues of 12-epi-salvinorin A were synthesized and their effects on G protein activation as well as β-arrestin2 recruitment were evaluated. Only 12-epi-salvinorin A (1) partially activated signaling through G proteins, yet acted as a full agonist in the β-arrestin 2 DiscoveRx assay. Other salvinorin analogues tested in these functional assays were full agonists in both assays of KOPR activation. By comparison, the non-selective opioid ligand nalbuphine, known to be a partial agonist for G-protein activation, was also a partial agonist for the β-arrestin mediated signaling pathway activated through KOPR.     

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.     

Altered levels of β-endorphin fragments after chronic morphine treatment of guinea-pig ileum invitro and invivo

The isolated myenteric plexus-longitudinal muscle of the guinea-pig ilem (GPI) was used as testsystem to study the influence of chronic morphine treatment on the levels of enkephalins, β-endorphin and some of its fragments. The peptides were assayed by means of a combination of high pressure liquid chromatography and radioimmunoassays. It was found that the levels of methionine- and leucine-enkephalin and β-endorphin were not altered by chronic morphine treatment of guinea-pigs $\text{in}$$\text{vivo}$ nor in GPI exposed to morphine $\text{in}$$\text{vitro}$. However, the levels of some β-endorphin fragments i.c. γ-endorphin and des-tyrosine-γ-endorphin were elevated after morphine treatment $\text{in}$$\text{vitro}$ and $\text{in}$$\text{vivo}$ respectively. It is suggested that β-endorphin and its fragments are involved in homeostatic processes during development of opiate tolerance.     

Enhanced response to apomorphine in rats treated with multiple injections of human beta endorphin and its blockade by Pro-Leu-Gly-NH2 and cyclo (Leu-Gly)

Repeated intraventricular injections of human β-endorphin to rats every eight hours for three days resulted in the development of super-sensitivity of brain dopamine receptors as evidenced by an enhanced locomotor activity response to apomorphine, a dopamine receptor agonist. Daily subcutaneous injections of Pro-Leu-Gly-NH₂ or its cyclic analog, cyclo (Leu-Gly) blocked the enhanced apomorphine-induced stimulation of locomotor activity in β-endorphin treated rats. Thus, the development of brain dopamine receptor supersensitivity induced by chronic β-endorphin administration may be regulated by the hypothalamic peptides.     

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.     

Chronic ethanol consumption in rats produces opioid antinociceptive tolerance through inhibition of mu opioid receptor endocytosis

It is well known that the mu-opioid receptor (MOR) plays an important role in the rewarding properties of ethanol. However, it is less clear how chronic ethanol consumption affects MOR signaling. Here, we demonstrate that rats with prolonged voluntary ethanol consumption develop antinociceptive tolerance to opioids. Signaling through the MOR is controlled at many levels, including via the process of endocytosis. Importantly, agonists at the MOR that promote receptor endocytosis, such as the endogenous peptides enkephalin and β-endorphin, show a reduced propensity to promote antinociceptive tolerance than do agonists, like morphine, which do not promote receptor endocytosis. These observations led us to examine whether chronic ethanol consumption produced opioid tolerance by interfering with MOR endocytosis. Indeed, here we show that chronic ethanol consumption inhibits the endocytosis of MOR in response to opioid peptide. This loss of endocytosis was accompanied by a dramatic decrease in G protein coupled receptor kinase 2 (GRK2) protein levels after chronic drinking, suggesting that loss of this component of the trafficking machinery could be a mechanism by which endocytosis is lost. We also found that MOR coupling to G-protein was decreased in ethanol-drinking rats, providing a functional explanation for loss of opioid antinociception. Together, these results suggest that chronic ethanol drinking alters the ability of MOR to endocytose in response to opioid peptides, and consequently, promotes tolerance to the effects of opioids.     

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.     

Human small cell lung cancer cells express high affinity naloxone-insensitive [125I]β-endorphin binding sites

Previous reports have demonstrated that β-endorphin stimulates the clonal growth of human small cell lung carcinoma (SCLC) cell lines. In this study, the human SCLC lines, NCI-H69, NCI-H345, and NCI-N417, were observed to be highly-enriched in saturable, high-affinity binding sites which are labeled by [¹²⁵I]β-endorphin. In contrast to conventional opioid receptors, [¹²⁵I]β-endorphin SCLC binding was insensitive to naloxone and other mu, delta, or kappa opioid ligands. Further analysis of the NCI-H69 cells demonstrated that specific (naloxone-insensitive) binding was dependent on receptor concentration, reversible, sensitive to sodium ion, but insensitive to the GTP analogue, Gpp(NH)p. These results suggest a role for naloxone-insensitive β-endorphin in modulating SCLC metabolism.     

Comparative study on the effect of morphine and the opioid-like peptides in the vas deferens of rodents: species and strain differences, evidence for multiple opiate receptors

The effect of an opiate alkaloid and an opioid-like peptide was studied on the electrically evoked twitching of the vas deferens of 3 common laboratory rodents. Normorphine and the synthetic opioid peptide D-Alanine₂ methionine enkephalinamide (D-Ala₂) produced dose dependent inhibitions of the twitching response in the mouse vas deferens. In the rat vas, while β-endorphin (β-EP) caused an inhibitory effect in three strains of rats to a similar degree, morphine produced a dose related enhancement of the twitching. In the guinea pig, both morphine and β-EP caused an increased in the muscular twitch. The results are interpreted in terms of an heterogenous mixture of opiate receptors present in the vas deferens from these rodents. The mouse appears to contain mainly δ receptors while the rat has mostly ε receptors characterized by their specificity and sensitivity to the action of β-EP. The guinea pig vas deferens has apparently lost the sensitivity to the inhibitory influence of the opioids, suggesting the absence of μ or δ opiate receptors in this tissue.     

Impedance-based analysis of mu opioid receptor signaling and underlying mechanisms

The mu opioid receptor is a G-protein coupled receptor able to signal through the Gα_i/o class of G-protein and β-arrestin pathways, stimulating down-stream effector pathways. Signaling bias occurs when different receptor agonists lead to different signaling outcomes. Traditionally these have been studied using end-point assays. Real-time cellular analysis platforms allow for the analysis of the holistic effects of receptor activation as an integrated output. While this allows for different ligands to be compared rapidly, the cellular mechanisms underlying the signal are not well described. Using an impedance based system, the impedance responses for two opioid ligands, morphine and DAMGO were examined.The impedance responses for these two agonists, while showing similar features, were distinct from each other. Some of the mechanisms underlying the mu opioid receptor coupled impedance changes were investigated. It was found that the response is a result of discrete cellular processes, including G-protein signaling and protein kinase phosphorylation.     

Codeine and 6-Acetylcodeine Analgesia in Mice

Summary 1. Acetylation of morphine at the 6-position changes its pharmacology. To see if similar changes are seen with codeine, we examined the analgesic actions of codeine and 6-acetylcodeine.2. Like codeine, 6-acetylcodeine is an effective analgesic systemically, supraspinally and spinally, with a potency approximately a third that of codeine.3. The sensitivity of 6-acetylcodeine analgesia to the mu-selective antagonists β-FNA and naloxonazine confirmed its classification as a mu opioid. However, it differed from the other mu analgesics in other paradigms.4. Antisense mapping revealed the sensitivity of 6-acetylcodeine to probes targeting exons 1 and 2 of the mu opioid receptor gene (Oprm), a profile distinct from either codeine or morphine. Although heroin analgesia also is sensitive to antisense targeting exons 1 and 2, heroin analgesia also is sensitive to the antagonist 3-O-methylnaltrexone, while 6-acetylcodeine analgesia is not.5. Thus, 6-acetylcodeine is an effective mu opioid analgesic with a distinct pharmacological profile.     

Binding of β-endorphin and its fragments to the nonopiod receptor of murine peritoneal macrophages

The tritium-labeled selective agonist of the nonopioid β-endorphin receptor the decapeptide immunorphin ([³H]SLTCLVKGFY) with a specific activity of 24 Ci/mmol was prepared. It was shown that [³H]immunorphin binds with a high affinity to the non-opioid β-endorphin receptor of mouse peritoneal macrophages (K _d 2.4 ± 0.1 nM). The specific binding of [³H]immunorphin to macrophages was inhibited by unlabeled β-endorphin (K _i of the [³H]immunorphin-receptor complex 2.9 ± 0.2 nM) and was not inhibited by unlabeled naloxone, α-endorphin, γ-endorphin, and [Met⁵]enkephalin (K _i > 10 μM). Thirty fragments of β-endorphin were synthesized, and their ability to inhibit the specific binding of [³H]immunorphin to macrophages was studied. It was found that the shortest peptide having practically the same inhibitory activity as β-endorphin is its fragment 12–19 (K _i 3.1 ± 0.3 nM).