Interaction of opiates with opioid binding sites in the bovine adrenal medulla: II. Interaction with kappa sites

Effects of opioids on phagocytic function, oxidative burst capacity, cytokine production and apoptosis in canine leukocytes

Opioids alter immune and apoptotic pathways in several species. They are commonly used in companion animals affected with infectious and/or inflammatory disease, but the immunomodulatory and apoptotic effects of these drugs in dogs are relatively unknown. The aim of the present study was to evaluate the effects of morphine, buprenorphine and fentanyl on canine phagocyte function, oxidative burst capacity, leukocyte cytokine production, and lymphocyte apoptosis. Blood from six healthy adult dogs was incubated in the presence or absence of morphine (200 ng/mL), buprenorphine (10 ng/mL) or fentanyl (10 ng/mL) for 3 h (phagocytic function; cytokine production) or 8 h (apoptosis). Neutrophil phagocytosis of opsonized Escherichia coli, respiratory burst capacity after stimulation with opsonized E. coli or phorbol 12-myristate 13-acetate (PMA), and Annexin V-FITC staining of apoptotic lymphocytes were evaluated using flow cytometry. Leukocyte production of tumor necrosis factor (TNF)-α, interleukin (IL)-6 and IL-10 was assessed after incubation with lipopolysaccharide (LPS), lipoteichoic acid (LTA) or peptidoglycan. Morphine promoted a more intense respiratory burst. Morphine, buprenorphine and fentanyl all promoted LPS- or LTA-induced TNF-α and IL-10 production. However, the opioids tested did not alter TNF-α:IL-10 ratios. Morphine, buprenorphine and fentanyl all inhibited neutrophil apoptosis, an effect that was not concentration dependent in nature. These data indicate that opioids alter immune and apoptotic pathways in dogs. The possible effects of opioids on immune and cellular responses should be considered when designing studies and interpreting outcomes of studies involving administration of opioids in dogs.

Chronic exposure of neonatal rat adrenomedullary chromaffin cells to opioids in vitro blunts both hypoxia and hypercapnia chemosensitivity

At birth, rat adrenomedullary chromaffin cells (AMCs) respond directly to asphyxial stressors such as hypoxia and hypercapnia by triggering catecholamine secretion, which is critical for proper transition to extrauterine life. These non-neurogenic responses are suppressed postnatally in parallel with the development of splanchnic innervation, and reappear following denervation of the adult adrenal gland. To test whether neural factors released from the splanchnic nerve may regulate AMC chemosensitivity, we previously showed that nicotinic agonists in utero and in vitro suppressed hypoxia, but not hypercapnia, sensitivity. Here, we considered the potential role of opiate peptides which are also released from the splanchnic nerve and act via postsynaptic μ-, δ- and -opioid receptors. Treatment of neonatal rat AMC cultures for ∼1 week with μ- and/or δ- (but not ) opioid agonists (2 μm) led to a marked suppression of both hypoxia and hypercapnia sensitivity, as measured by K(+) current inhibition and membrane depolarization; co-incubation with naloxone prevented the effects of combined opioids. The suppression of hypoxia sensitivity was attributable to upregulation of K(ATP) current density and the K(ATP) channel subunit Kir6.2, and was reversed by the K(ATP) channel blocker, glibenclamide. By contrast, suppression of hypercapnia sensitivity was associated with down-regulation of two key mediators of CO(2) sensing, i.e. carbonic anhydrase I and II. Collectively, these studies point to a novel role for opioid receptor signalling in the developmental regulation of chromaffin cell chemosensitivity, and suggest that prenatal exposure to opioid drugs could lead to impaired arousal responses in the neonate.

Cell responses regulated by early reorganization of actin cytoskeleton

Microfilaments exist in a dynamic equilibrium between monomeric and polymerized actin and the ratio of monomers to polymeric forms is influenced by a variety of extracellular stimuli. The polymerization, depolymerization and redistribution of actin filaments are modulated by several actin-binding proteins, which are regulated by upstream signalling molecules. Actin cytoskeleton is involved in diverse cellular functions including migration, ion channels activity, secretion, apoptosis and cell survival. In this review we have outlined the role of actin dynamics in representative cell functions induced by the early response to extracellular stimuli.

The inhibitory effect of opioids on HepG2 cells is mediated via interaction with somatostatin receptors

Opioids, acting via G-protein coupled membrane receptors, induce analgesia. However their role is not limited to their anti-nociceptive action. They are found in several peripheral tissues acting as negative regulators of cellular processes. Even though that is not fully elucidated, it becomes obvious that opioids exert their effects in close relation to other neuropeptides such as somatostatin. Hepatocellular carcinoma is one tumor, among others, which secrete bioactive peptides while somatostatin analogs exert an inhibitory effect. We have used the human hepatocyte-derived cancer cell line HepG2, in order to examine the effect of opioids on cell growth and their possible mode of action. Our results show that the opioid ethylketocyclazocine (EKC) inhibits cell proliferation and induces apoptosis. This inhibitory effect is not exerted via opioids receptors since it was not reversed by the opioid antagonist diprenorphine and functional opioid receptors were not found on HepG2 cells. On the contrary, we show that EKC binds to somatostatin receptors, and activates a PTP signalling cascade. In this respect, the interaction of opioids with somatostatin receptors on hepatocellular carcinoma cells, and the fact that they are widely used for pain control, may provide some additional clues for the discrepancies during treatment with somatostatin analogues.

Receptorphin: a conserved peptide derived from the sequence of the opioid receptor, with opioid displacement activity and potent antiproliferative actions in tumor cells

BACKGROUND

In addition to endogenous opioids, a number of peptide sequences, derived from endogenous (hemorphins, alphaS1-casomorphin), and exogenous proteins (casomorphins, exorphins) have been reported, possessing opioid activity. In the present work, we report the identification of a new peptide, receptorphin (Tyr-Ile-Phe-Asn-Leu), derived from the sequence of the second transmembrane loop of the opioid receptor. This sequence is unique for the opioid receptor, and conserved in all species and receptor-types.

RESULTS AND DISCUSSION

Receptorphin competes for opioid binding, presenting a kappa-receptor interaction, while it binds equally to delta- and mu- opioid and somatostatin-binding sites, and inhibits the cell proliferation of a number of human cancer cell lines, in a dose-dependent and reversible manner, at the picomolar or the nanomolar range. Receptorphin shows a preferential action on prostate cancer cells.

CONCLUSION

Our work identifies, for the first time a peptide, in a receptor sequence, possessing ligand-agonistic activities. A hypothesis, based on receptorphin liberation after cell death, is presented, which could tentatively explain the time-lag observed during opioid antiproliferative action.

Somatostatin and opioid receptors in mammary tissue. Role in cancer cell growth

Somatostatin and opioid systems, are the two main inhibitory systems in mammals. Both classes of substances have been identified in normal and malignant mammary gland, as well as their cognitive receptors. They have been implied in the inhibition of cell growth of cancer cells and cell lines, in a dose-dependent and reversible manner. Somatostatin acts through homologous receptors (SSTRs), belonging to five distinct classes (SSTR1-5). We, and others have identified SSTR2 and 3 as been the only SSTRs present in the breast. Furthermore, opioids act through the three classes of opioid receptors (mu, delta,kappa). In the breast, kappa opioid receptor subtypes (kappa 1-kappa 3) are the most widely expressed. We further have shown that opioids, in addition to their binding to opioid receptors, compete for binding to SSTRs. This functional interaction, together with other identified modes of opioid action in the breast (modulation of steroid receptors, proteases' secretion, interaction with cytoskeletal elements), will be discussed, taking into consideration also the possible local production of casomorphins (casein-derived opioids), which are very potent antiproliferative agents.

Opioid peptide receptor studies. 10. Nor-BNI differentially inhibits kappa receptor agonist-induced G-protein activation in the guinea pig caudate: further evidence of kappa receptor heterogeneity

There is strong evidence supporting the existence of multiple kappa receptors. Previous studies proposed that U69,593 and (+)-tifluadom act on different kappa receptor subtypes, kappa(1) (kappa(1)) and kappa(2) (kappa(2)), respectively. In this study, we investigated the effects of the kappa selective antagonist nor-binaltorphimine (Nor-BNI) on U69,593- and (+)-tifluadom-induced receptor-mediated stimulation of [(35)S]-GTP-gamma-S binding in the guinea pig caudate. The IC(50) value of Nor-BNI in the presence of a stimulating concentration of U69,593 (1 microM) was 0.19+/-0.02; while the IC(50) for Nor-BNI in the presence of (+)-tifluadom (1 microM) was 13.9+/- 1.62 nM. The mu-opioid receptor antagonist CTAP (10,000 nM) significantly reduced (+)-tifluadom-stimulated [(35)S]-GTP-gamma-S binding in rat brain sections and guinea pig brain membranes, indicating that (+)-tifluadom has mu agonist activity. Under conditions in which the mu agonist activity of (+)-tifluadom was blocked by 1000 nM CTAP the Ki value for Nor-BNI for inhibition of U69,593-stimulated [(35)S]-GTP-gamma-S binding was 0.036+/-.004 nM, whereas, its Ki value for the (+)-tifluadom-stimulated [(35)S]-GTP-gamma-S binding was 0.27+/-.015 nM. These results suggest that (+)-tifluadom and U69,593 activate pharmacologically different receptors. This study provides functional evidence in support of kappa receptor heterogeneity.

Opioid agonists modify breast cancer cell proliferation by blocking cells to the G2/M phase of the cycle: involvement of cytoskeletal elements

Opioids decrease cell proliferation in different systems including breast, prostate, lung, kidney, and intestine, through an interaction with opioid as well as other membrane-receptor systems (somatostatin, cholinergic), through an unidentified mechanism. Recently, we have reported an interaction of taxol with opioid membrane sites (BBRC 235, 201-204, 1997), and an involvement of opioids to the modification of actin cytoskeleton in renal OK cells (J Cell Biochem. [19981 70:60-69), indicating a possible action of the opioid effect. In the present work, we have examined the effect of two general opioid agonists (ethylketocyclazocine and etorphine) on the cell cycle, in human breast cancer T47D cells, as well as a possible modification of the cellular cytoskeleton under their action, in order to explain the antiproliferative effect of these agents. These two opioids produce a dose-dependent and reversible decrease of the proliferation of T47D cells, with a maximum attained at 10(-8) M. The addition of 10(-8) M of either opioid produced a significant increase of the number of cells arrested in the G2/M phase. Confocal laser microscopy revealed a modification of the actin and tubulin microfilaments, with a clear redistribution at the periphery of the cell, reversed by the addition of the general opioid antagonist diprenorphine. Furthermore, differences between the two opioids were obvious, attributed to the different receptor affinity of each agent. The observed redistribution of actin and tubulin cytoskeletal elements gives therefore a possible answer of the antiproliferative action of opioids. The modification of the cytoskeleton, directly involved to cell division, might provoke a "mechanical" obstacle, which could be the reason of the antiproliferative effect of these agonists. Furthermore, the observed tubulin-opioid interaction by opioids provides a possible explanation of the arrest at the G2/M phase of T47D cells under opioid treatment. Nevertheless, although the observed interaction of opioids with cytoskeletal elements gives a plausible answer of the antiproliferative effects of the agents, this might not be the only action of these agents in cell proliferation. Other, direct or indirect, genomic actions, which which remains to be elucidated, might be taken into consideration.

Kappa1-opioid binding sites are the dominant opioid binding sites in surgical specimens of human pheochromocytomas and in a human pheochromocytoma (KAT45) cell line

The adrenal medulla produces opioids which exert paracrine effects on adrenal cortical and chromaffin cells and on adrenal splanchnic nerves, via specific binding sites. The opioid binding sites in the adrenals are detectable mainly in the medullary part of it and differ in type between species. Thus, the bovine adrenal medulla contains mostly kappa-opioid binding sites and fewer delta- and mu-opioid binding sites while primate adrenals contain mainly delta sites and few kappa-opioid binding sites. Most chromaffin cell tumors, the pheochromocytomas, produce opioids which suppress catecholamine production by the tumor. The aim of the present work was to identify the types of opioid binding sites in human pheochromocytomas. For this purpose, we characterized the opioid binding sites on crude membrane fractions prepared from 14 surgically excised pheohromocytomas and on whole KAT45 cells, a recently characterized human pheochromocytoma cell line. Our data showed that human pheohromocytomas are heterogeneous, as expected, with regard to the production of catecholamines and the distribution and profile of their opioid binding sites. Indeed, only one out of the 14 pheochromocytomas expressed exclusively delta and mu opioid sites, while in the remaining 13 tumors kappa-type binding sites were dominant. The KAT45 cell line possessed a significant number of kappa1 binding sites, fewer kappa2-opioid binding sites and kappa3-opioid binding sites, and minimal binding capacity for delta- and mu-opioid receptor agonists sites. More specifically, the kappa1 sites/cell were approximately 18,000, the kappa2 4500/cell and the kappa3 sites 2000/cell. Our findings for the surgical specimens and the cell line combined with previously published pharmacological data obtained from KAT45 cells suggest that kappa sites appear to be the most prevalent opioid binding sites in pheochromocytomas. Finally, in normal bovine adrenals the profile of opioid binding sites differs in adrenaline and noradrenaline producing chromaffin cells. To test the hypothesis that the type of catecholamine produced by a pheochromocytoma depends on its cell of origin, we compared our binding data with the catecholamine content of each pheochromocytoma examined. We found no correlation between the type of the predominant catecholamine produced and the opioid binding profile of each tumor suggesting that this hypothesis may not be valid.

Modulation of the estrogen-regulated proteins cathepsin D and pS2 by opioid agonists in hormone-sensitive breast cancer cell lines (MCF7 and T47D): evidence for an interaction between the two systems

In many cancer cell lines, including breast, prostate, lung, brain, head and neck, retina, and the gastrointestinal tract, opioids decrease cell proliferation in a dose-dependent and reversible manner. Opioid and/or other neuropeptide receptors mediate this decrease. We report that only the steroid-hormone-sensitive cell lines MCF7 and T47D respond to opioid growth inhibition in a dose-dependent manner. Therefore, an interaction of the opioid and steroid receptor system might exist, as is the case with insulin. To investigate this interaction, we have assayed two estrogen-inducible proteins (pS2 and the lysosomal enzyme cathepsin D) in MCF7 and T47D cells. When cells were grown in the presence of FBS (in which case a minimal quantity of estrogens and/or opioids is provided by the serum), we observed either no effect of etorphine or ethylketocyclazocine (EKC) or an increase of secretion and/or production of pS2 and cathepsin D. However, when cells were cultured in charcoal-stripped serum and in the absence of phenol red, the effect of the two opioids is different: EKC decreased the production and/or secretion of pS2 and cathepsin D, whereas etorphine increased their synthesis and/or secretion. The differential effect of the two general opioids was attributed to their different receptor selectivity. Furthermore, the variations of the ratio of secreted/produced protein and the use of cycloheximide indicate that opioids selectively modify the regulatory pathway of each protein discretely. In conclusion, through the interaction with opioid and perhaps other membrane-receptor sites, opioid agonists modify in a dose-dependent manner the production and the secretion of two estrogen-regulated proteins. Opioids may therefore disturb hormonal signals mediated by the estrogen receptors. Hence, these chemicals may have potential endocrine disrupting activities.

Early alterations of actin cytoskeleton in OK cells by opioids

Recently we identified and characterized opioid binding sites in OK (opossum kidney) cells and observed decreased proliferation of these cells in response to opioids. In the present study we investigated the effects of opioids on the actin cytoskeleton and explored whether their antiproliferative action may relate to alterations in the distribution or the dynamics of actin microfilaments. Exposure of OK cells to the opioids alphaS1 casomorphin and ethylketocyclazocine resulted in a rapid and substantial actin microfilament reorganization. This was documented by a significant dose-dependent decrease in the amounts of F-actin, determined by measurements of quantitative fluorescence, by immunoblot analysis and by a concomitant increase of the G/total-actin ratio measured by the DNase I inhibition assay. These changes were verified by confocal laser scanning microscopy, which showed marked redistribution of the microfilamentous structures in the presence of the opioids without affecting the organization of microtubules or vimentin intermediate filaments. The effect of opioids on actin polymerization dynamics occurred within 15 min and persisted for at least 2 h, while their restoration to control levels was accomplished 6 h later, indicating a reversible phenomenon. Northern blot analysis showed that the concentration of the actin transcript was unaffected. The addition of diprenorphine, a general opioid antagonist, prevented the effects of opioids on the actin cytoskeleton. The inhibition of OK cell proliferation, induced by ethylketocyclazocine and alphaS1 casomorphin was partially prevented in the presence of phallacidin, which stabilizes microfilaments. Our findings demonstrate that opioids, acting via kappa 1 binding sites, induce rapidly modifications in the dynamics of actin polymerization, and in the organization of microfilaments in OK cells, which may relate to their antiproliferative effect on these cells.

Opioid alkaloids and casomorphin peptides decrease the proliferation of prostatic cancer cell lines (LNCaP, PC3 and DU145) through a partial interaction with opioid receptors

Opioid agonists (ethylketocyclazocine, etorphine, [D-Ala2,D-Leu5]enkephalin (DADLE), [D-Ala2, N-Me-Phe4-Gly-ol]enkephalin (DAGO), [D-Ser2,Leu5]enkephalin-Thr6 (DSLET) and morphine were found to inhibit the proliferation of human prostate cancer cell lines (LNCaP, DU145, and PC3), in a dose-dependent manner. The 50% inhibitory concentrations (IC50) were in the picomolar range. In many cases, this effect was antagonized by the general opioid antagonist, diprenorphine, indicating the existence of specific opioid binding sites. Saturation binding experiments with selective ligands and effectors showed no opioid sites on the LNCaP cell line, kappa1 and mu sites on the PC3 cell line, and kappa1, kappa3 and mu sites on the DU145 cell line. In other cases, the opioid effect was not antagonized by diprenorphine, indicating that the action of opioids might be mediated through other membrane receptors. Furthermore, casomorphin peptides, issued from bovine alpha- (alpha-casein-90-95 and alpha-casein-90-96) and beta-caseins (beta-casomorphin and beta-casomorphin-1-5), and human alphaS1-casein (alphas -casomorphin and alphaS1-casomorphin amide) inhibited cell proliferation of human prostate cell lines, also by a mechanism partly involving opioid receptors. As opioid neurons can be found in the prostate gland, and casomorphin peptides might reach the gland through the general circulation, the above findings indicate a putative role of opioids in prostate cancer cell growth.

Taxol inhibits opioid binding on T47D human breast cancer cells

In the T47D human breast cancer cell line, Taxol was found to compete for ethylketocyclazocine opioid binding (IC50 3.3 pM). In contrast, no interaction of the drug with [3H]diprenorphine binding occurred. Binding was multiphasic, in the absence of colchicine (10[-6] M), but monophasic in its presence, indicating an involvement of the cytoskeleton in this process. Alignment of Taxol binding domains on alpha and beta tubulin with the kappa opioid site revealed homology of these sites with the first extracellular loop of the receptor. These results indicate a possible new action of Taxol, indicating for the first time a membrane action of the agent.

Identification and characterization of opioid and somatostatin binding sites in the opossum kidney (OK) cell line and their effect on growth

Opioids and somatostatin analogs have been implicated in the modulation of renal water handling, but whether their action is accomplished through central and/or peripheral mechanisms remains controversial. In different cell systems, on the other hand, opioids and somatostatin inhibit cell proliferation. In the present study, we have used an established cell line, derived from opossum kidney (OK) proximal tubules, in order to characterize opioid and somatostatin receptors and to investigate the action of opioids and somatostatin on tubular epithelial tissue. Our results show the presence of one class of opioid binding sites with kappa, selectivity (KD 4.6 +/- 0.9 nM, 57,250 sites/cell), whereas delta, mu, or other subtypes of the kappa site were absent. Somatostatin presents also a high affinity site on these cells (KD 24.5 nM, 330,000 sites/cell). No effect of either opioids or somatostatin on the activity of the NA+/Pi cotransporter was observed, indicating that these agents do not affect ion transport mechanisms. However, opioid agonists and somatostatin analogs decrease OK cell proliferation in a dose-dependent manner; in the same nanomolar concentration range, they displayed reversible specific binding for these agents. The addition of diprenorphine, a general opioid antagonist, reversed the effects of opioids, with the exception of morphine. Furthermore, morphine interacts with the somatostatin receptor in this cell line too, as was the case in the breast cancer T47D cell line. Our results indicate that in the proximal tubule opioids and somatostatin do not affect transport, but they might have a role in the modulation of renal cell proliferation either during ontogenesis or in kidney repair.

Identification of a novel opioid peptide (Tyr-Val-Pro-Phe-Pro) derived from human alpha S1 casein (alpha S1-casomorphin, and alpha S1-casomorphin amide)

A new casomorphin pentapeptide (alpha S1-casomorphin) has been isolated from the sequence of human alpha S1-casein [alpha S1-casein-(158-162)], with the sequence Tyr-Val-Pro-Phe-Pro. This peptide was found to bind with high affinity to all three subtypes of the kappa-opioid receptor (kappa 1-kappa 2). When amidated at the C-terminus, alpha S1-casomorphin amide binds to the delta- and kappa 3-opioid sites. Both alpha S1-casomorphin and its amide inhibit in a dose-dependent and reversible manner the proliferation of T47D human breast cancer cells. This anti-proliferative activity was greater for alpha S1-casomorphin, which was the most potent opioid in inhibiting T47D cell proliferation. In T47D breast cancer cells, other casomorphins have been found to bind to somatostatin receptors in addition to opioid sites. In contrast, alpha S1-casomorphin and its amide do not interact with somatostatin receptors in our system.

The antiproliferative effect of opioid receptor agonists on the T47D human breast cancer cell line, is partially mediated through opioid receptors

In the present study, we investigated the action of opioid receptor agonists on the proliferation of cells of the T47D human breast cancer cell line, grown in the absence of exogenously added steroids and growth factors. We found that the opioid receptor agonists ethylketocyclazocine, morphine, [D-Ala2,D-Leu5]enkephalin (DADLE), [D-Ser2,Leu5]enkephalin-Thr6 (DSLET) and etorphine inhibit dose dependently cell proliferation. The opioid receptor antagonist diprenorphine had no significant effect per se, but it was able to reverse the action of all opioid receptor agonists except morphine. In order to investigate the mechanism of action of opioids on T47D cells, we characterised the opioid receptors present on this cell line, by saturation binding, using radiolabelled [D-Ala2,N-Me-Phe4-Gly5-ol]enkephalin (DAGO, mu-opioid receptor agonist), ethylketocyclazocine (kappa 1-, kappa 2-, mu- and delta-opioid receptor agonist), diprenorphine (kappa 2-, kappa 3-, delta- and mu-opioid receptor antagonist), DADLE (delta- and mu-opioid receptor agonist), and effectors. We identified opioid binding sites belonging mainly to the kappa-type (kappa 1, kappa 2 and kappa 3), a few delta-opioid receptor sites, but no mu-opioid receptors. Our results indicate that the inhibitory effect of opioids on T47D cell growth is mediated through kappa- and delta-opioid receptors. The effect of mu-acting morphine might not be mediated through opioid receptors.

Kappa opioids exert a strong antiproliferative effect on PC12 rat pheochromocytoma cells

Pheochromocytomas synthesize several types of opioids and their receptors. Opioids affect the proliferation rate of normal and tumoral cells. We have previously shown that the PC12 rat pheochromocytoma cells synthesize multiple opioids. The aim of the present work was to study the effect of opioids on the proliferation of these pheochromocytoma cells. Thus, the effect of several opioid agonists and antagonists was examined on basal and EGF-induced PC12 cell proliferation. The kappa opioid agonists dynorphin A, U-69593, and U-50488 suppressed basal proliferation in a dose-dependent manner. The effect of kappa opioids was blocked by the general opioid antagonist naloxone and the selective kappa antagonist nor-binaltorphimine. Furthermore, both opioid antagonists given alone had a strong stimulatory effect, a findings suggesting that the proliferation of PC12 cells is under tonic inhibition by locally produced kappa opioids. Finally, the mu-opioid agonist DAGO and the delta and mu agonists DADLE and DSLET were ineffective.

Opioids inhibit dopamine secretion from PC12 rat pheochromocytoma cells in a naloxone-reversible manner

Opioids inhibit the release of catecholamines in the nervous system. Normal adrenal chromaffin cells produce delta opioids and they respond to them by suppressing the release of their catecholamines. Chromaffin cell tumors, the pheochromocytomas, produce mainly kappa opioids. The aim of this work was: (a) to test if pheochromocytomas retain the response of normal chromaffin cell catecholamines to delta opioids and to naloxone (a general opioid antagonist), and (b) to test if kappa opioids exert any specific effect on catecholamine release from these tumors. Since we have previously shown that, in common with human pheochromocytomas, the PC12 rat pheochromocytoma cells express the prodynorphin gene and secret its kappa opioid products, we used these cells to examine the effect of several opioid agonists and of naloxone on basal, nicotine-, and KCl-induced dopamine release. Dopamine is the main PC12 catecholamine. We have found that the specific kappa opioid agonist U-69593 inhibited the release of dopamine in a dose-dependent manner (IC50=0.5 x 10(-8)M). Under basal conditions the mean concentration of dopamine in the culture media was 11.25 +/- 0.57 ng/mg of total cellular protein (n=13). A 30 min exposure to U-69593 at 10(-6) M suppressed basal dopamine release to 58 +/- 2% (n=7) of controls. A 12 hr pre-incubation with U-69593 caused the same degree of suppression. The effect of the synthetic kappa opioid agonist dynorphin A was indistinguishable from that of U-69593. DADLE (a mu and delta synthetic opioid agonist) was significantly less effective in suppressing dopamine release (IC50=10(-7)M). The concentration of dopamine following exposure to 10-6 M of DADLE for 30 min was 74 +/- 5% of the controls (n=4). The mu opioid agonist DAGO was ineffective. The suppressive effect of all opioid agonists was blocked by naloxone suggesting that conventional opioid receptors were involved.

Stress-induced behavioral responses and multiple opioid systems in the brain

Various stressor produce a wide range of behavioral responses such as analgesia, catalepsy and motor suppression, which are sensitive to opioid receptor antagonists. These behavioral responses in stress are accompanied by changes in the contents of opioid peptides, the mRNAs encoding their precursors and opioid receptor binding in the brain. In the present article, experimental data concerning stress-induced analgesia and motor suppression is reviewed and discussed in relation to a possible involvement of different opioid systems in the various observed behavioral responses in stress. Pharmacological studies with subtype-selective antagonists have demonstrated that not only mu- but also delta- and/or kappa-opioid receptors are involved in opioid-mediated stress-induced analgesia. There are two types of stress-induced analgesia referred to as opioid-mediated and non-opioid mediated forms. It has been proposed that the intensity and temporal pattern of stressor may be a critical factor determining the nature of stress-induced analgesia. Accumulated evidence demonstrate that these two forms of pain inhibitory systems interact each other according to a collateral inhibition model. Recent studies show that parallel activation of multiple opioid receptors mediates non-opioid froms of stress-induced analgesia. Dynorphins, by acting at kappa-opioid receptors, may play a pivotal role in the expression of stress-induced motor suppression, whereas enkephalins may act to attenuate this response.

Opioid peptide receptor studies. 3. Interaction of opioid peptides and other drugs with four subtypes of the kappa 2 receptor in guinea pig brain

Using guinea pig, rat, and human brain membranes depleted of mu and delta receptors by pretreatment with the site-directed acylating agents BIT (mu selective) and FIT (delta selective), previous studies from our laboratory resolved two subtypes of the kappa 2 binding site, termed kappa 2a and kappa 2b. In more recent studies, we used 6 beta-[125Iodo]-3,14-dihydroxy-17-cyclopropylmethyl-4,5 alpha-epoxymorphinan ([125I]IOXY) to characterize multiple kappa 2 binding sites in rat brain. The results indicated that [125I]IOXY, like [3H]bremazocine, selectively labels kappa 2 binding sites in rat brain membranes pretreated with BIT and FIT. In the rat brain, using 100 nM [D-Ala2-MePhe4,Gly-ol5]enkephalin to block [125I]IOXY binding to the kappa 2b site, we resolved two subtypes of the kappa 2a binding site. In the present study we examined the binding of [125I]IOXY to the kappa 2 receptors of guinea pig brain. As observed in rat brain, [125I]IOXY, under appropriate assay conditions, selectively labels kappa 2 binding sites. Quantitative binding studies readily demonstrated the presence of kappa 2a and kappa 2b binding sites. The kappa 2a binding sites were selectively assayed using 5 microM [Leu5]enkephalin to block [125I]IOXY binding to the kappa 2b sites, and kappa 2b sites were selectively assayed using 5 microM (-)-(1S,2S)-U50,488 to block [125I]IOXY binding to the kappa 2a sites. Under these conditions, two subtypes of the kappa 2a site were resolved with high (kappa 2a-1) and low (kappa 2a-2) affinity for nor-BNI (Ki values = 0.88 and 476 nM) and CI977 (Ki values = 17.5 and 95,098 nM). Similarly, two subtypes of the kappa 2b site were observed with high (kappa 2b-1) and low (kappa 2b-2) affinity for [D-Ala2-MePhe4,Gly-ol5]enkephalin (DAMGO) (Ki values = 97 and 12,321 nM) and alpha-neoendorphin (Ki values = 33 and 5308 nM). Two-site models were also resolved in the presence of 100 microM 5'-guanylyimidodiphosphate (GppNHp). We carried out detailed ligand selectivity analysis of the multiple kappa 2 binding sites. Most test agents were either nonselective or selective for the kappa 2a-1 site. Nalbuphine was moderately selective for the kappa 2a-2 site. Similarly, although most test agents were either nonselective or selective for the kappa 2b-1 site, butorphanol, and the delta antagonists naltrindole, naltriben, and 7-benzylidene-7-dehydronaltrexone were moderately selective for the kappa 2b-2 site.(ABSTRACT TRUNCATED AT 400 WORDS)

Presence in neuroblastoma cells of a mu 3 receptor with selectivity for opiate alkaloids but without affinity for opioid peptides

Evidence is presented for the occurrence of a unique opiate alkaloid-selective, opioid peptide-insensitive binding site in N18TG2 mouse neuroblastoma cells and in late passage hybrid F-11 cells, derived from N18TG2 neuroblastoma cells and rat dorsal root ganglion cells. Those cells lacked classical opioid peptide-sensitive receptor subtypes, but contained [3H]morphine and [3H]diprenorphine binding sites with affinity for certain opiate alkaloids but not for any endogenously occurring opioid peptide or peptide analog tested, including D-ala2-D-leu5-enkephalin (DADLE), D-Ala2,N-Me-Phe4,Gly5-ol (DAGO) and dynorphin A(1-17). The binding site differed from hitherto described mu, delta and kappa neuronal opioid receptors not only on the basis of peptide insensitivity, but also on the basis of selectivity and affinities of alkaloids. Saturation experiments with [3H]morphine indicated the presence of a single site with Kd = 49 nM and Bmax = 1510 fmol/mg protein. This novel binding site was not present in F-11 hybrid cells at early passage. Instead the hybrid cells contained conventional opioid receptors (predominantly delta and also mu) capable of binding DADLE and other peptides as well as opiate alkaloids. With additional passage (cell divisions) of the hybrid cells, during which a limited change occurred in mouse chromosome number, the peptide-insensitive binding appeared and the opioid peptide-binding (delta and mu) receptors were lost reciprocally. Thus, expression of the peptide-insensitive binding normally may be repressed when conventional opioid receptors are expressed. The peptide-insensitive opiate binding site described here appears to correspond to the mu 3 receptor subtype, recently identified pharmacologically and functionally in several cell types of the immune system.(ABSTRACT TRUNCATED AT 250 WORDS)

Dihydrocodeinone-hydrazone, dihydrocodeinone-oxime, naloxone-3-OMe-oxime, and clocinnamox fail to irreversibly inhibit opioid kappa receptor binding

Previous work from our lab identified two subtypes of the opioid kappa receptor. Whereas the kappa1 receptor can be labeled by [3H]U69,593 (5 alpha,7 alpha,8 beta-(-)- N-methyl-N-[7-(1-pyrrolidinyl)-1-oxaspiro(4,5)dec-8-yl]-phenyl- benzeneacetamide), the kappa2 receptor can be labeled by [125I]OXY (6 beta-125iodo-3,14-dihydroxy-17-cyclopropylmethyl-4,5 alpha-epoxymorphinan). Other data demonstrate that [125I]IOXY, like [3H]bremazocine, labels two populations of kappa2 receptors in guinea pig brain: kappa2a and kappa2b binding sites. In the present study, we tested the hypothesis that certain dihydrocodeinone and oxicodone derivatives, which have been shown to irreversibly block low affinity [3H]naloxone binding sites, would also bind irreversibly to opioid kappa receptor subtypes. We also tested the novel irreversible mu receptor antagonist, clocinnamox (14 beta-(p-chlorocinnamoylamino)-7,8-dihydro-N-cyclopropylmethylno rmorphinone mesylate). Wash-resistant inhibition (WRI) assays were conducted to detect apparent irreversible inhibition. The proportion of WRI attributable to inhibition of receptor binding, termed receptor inhibition (RI), was calculated by the equation: RI = WRI (wash-resistant inhibition) - SI (supernatant inhibition or inhibition attributable to residual drug.) Dihydrocodeinone-hydrazone, dihydrocodeinone-oxime and naloxone-3-OMe-oxime failed to produce any wash-resistant inhibition of kappa receptor binding. In contrast, preincubating guinea pig membranes with 1 microM clocinnamox produced a substantial degree of wash-resistant inhibition (greater than 90%) at kappa1 and kappa2 binding sites. However, as indicated by supernatant inhibition values of 70% to 90%, there was a large amount of residual clocinnamox which remained despite the use of an extensive washing procedure.(ABSTRACT TRUNCATED AT 250 WORDS)

The functional role of opioid receptors in acetylcholine release in the rat adrenal medulla

The functional role of opioid receptors in acetylcholine release from splanchnic nerve terminals in the adrenal medulla was investigated in halothane-anesthetized rats. The extracellular acetylcholine level was measured by a newly developed in vivo adrenal microdialysis method. The potassium (K+)-evoked acetylcholine release from the splanchnic nerve terminals was inhibited by morphine (10 microM), a mu-opioid receptor agonist, and [D-Pen2,D-Pen5]enkephalin (DPDPE, 1 and 10 microM), a delta-opioid receptor agonist. These inhibitory effects of morphine and DPDPE were significantly abolished by naltrexone (9 mg/kg i.p.), a mu-opioid receptor antagonist, and naltrindole (9 mg/kg i.p.), a delta-opioid receptor antagonist, respectively. 5 alpha,7 alpha-beta-(-)- N-methyl-N-[7-(1-pyrrolidinyl)-1-oxaspiro(4,5)dec-8-yl]benzene acetamide (U69593, 10 microM), a kappa-opioid receptor agonist, had no influence on the K(+)-evoked acetylcholine release. The findings suggest that both mu- and delta-opioid receptors might have a functional role in acetylcholine release from splanchnic nerve terminals in the adrenal medulla of the rat. The present study indicates that adrenal microdialysis is a useful method for studying the control mechanism of adrenomedullary function in the rat in vivo.

Morphine receptors in immunocytes and neurons

Receptor interactions of morphine are reviewed, with particular attention given to a recently discovered opiate receptor, designated mu 3, with unique selectivity for morphine and certain other opiate alkaloids. Morphine, other opiate alkaloids and related analogs are known to bind to the classical delta, mu and kappa opioid receptor subtypes. Each of these subtypes also binds one or more of the endogenous opioid peptides with high affinity. Immunocytes have recently been found to contain a unique receptor for morphine, capable of binding morphine and certain other opiate alkaloids, but with essentially no or exceedingly low affinity for the naturally occurring endogenous opioid peptides or peptide analogs. This putative mu 3 (morphine/opiate alkaloid) receptor is present in invertebrate immunocytes as well as in human peripheral blood monocytes (macrophages). More recently this same receptor has been found in certain established macrophage cell lines and in human peripheral blood granulocytes. Finally, the same or closely related opiate alkaloid-selective (mu 3) receptor has been found to be present in a neuroblastoma and in a hybrid neural cell line. Studies indicate that in the immunocytes the receptor mediates inhibitory effects of morphine on cellular chemotaxis. While the functional coupling of this receptor in neurons is not known, it is postulated that the receptor may mediate effects of opiates on neuronal differentiation and cell division as well as neuronal transmission. Both for the immune system and the nervous system, the mu 3 receptor may constitute a major site of action for putative endogenous morphine or morphine-like substances. This receptor system also provides an additional pharmacological site of action for exogenously administered opiate alkaloid drugs. The mu 3 receptor is proposed to be an important neuro-immune link. This system is likely to play a significant role in a variety of responses involving the immune system, including the response of the organism to stress, infection and malignant transformation.

Selective labeling of kappa 2 opioid receptors in rat brain by [125I]IOXY: interaction of opioid peptides and other drugs with multiple kappa 2a binding sites

Recent studies from our laboratory resolved two subtypes of the kappa 2 binding site, termed kappa 2a and kappa 2b, using guinea pig, rat, and human brain membranes depleted of mu and delta receptors by pretreatment with the site-directed acylating agents BIT (mu-selective) and FIT (delta-selective). 6 beta-Iodo-3,14-dihydroxy-17-cyclopropylmethyl-4,5 alpha-epoxymorphinan (IOXY), an opioid antagonist that has high affinity for kappa 2 sites, was radioiodinated to maximum specific activity (2200 Ci/mmol) and purified by high pressure liquid chromatography and used to characterize multiple kappa 2 binding sites. The results indicated that [125I]IOXY, like [3H]bremazocine, selectively labels kappa 2 binding sites in rat brain membranes pretreated with BIT and FIT. Using 100 nM [D-Ala2-MePhe4,Gly-ol5]enkephalin to block [125I]IOXY binding to the kappa 2b site, two subtypes of the kappa 2a binding site were resolved, both in the absence and presence of 50 microM 5'-guanylyimidodiphosphate. Viewed collectively, these results provide further evidence for heterogeneity of the kappa opioid receptor, which may provide new targets for drug design, synthesis, and therapeutics.

Dynorphin 1-17 delays the vasopressin induced mobilization of intracellular calcium in cultured astrocytes from the rat neural lobe

Opioid peptides are present in nerve terminals in the rat neural lobe where they partially coexist with vasopressin. Morphological findings suggest that these neuropeptides are released onto pituicytes, which is in agreement with a possible role for the pituicyte in oxytocin and vasopressin release from the neural lobe. Pituicytes in culture respond to vasopressin with a mobilization of calcium from intracellular stores. In the present study this vasopressin induced increase in intracellular free calcium levels was both delayed and decreased by pre-exposure to dynorphin 1-17, while dynorphin 1-17 by itself did not affect basal calcium levels. All effects of dynorphin 1-17 could be blocked with naloxone. The present results suggest that opioid receptors are present on pituicytes and are coupled to a second messenger pathway by which opioid peptides may inhibit inositol phosphate dependent calcium mobilization by other neuropeptides, such as vasopressin.

Functional evidence for multiple receptor activation by kappa-ligands in the inhibition of spinal nociceptive reflexes in the rat

1. The evidence for kappa-receptor heterogeneity is equivocal. We have now investigated this question by comparing the effects of five putatively selective kappa-agonists. The parameters examined were: the relative potencies in depressing hindlimb flexor muscle reflexes to noxious pinch stimuli in both spinalized and sham-spinalized rats; the reversibility of these effects by naloxone; and the effects on blood pressure. 2. Two types of drug effect was discriminated. One drug group, represented by U-50,488, U-69,593 and PD-117,302, had a potency ratio between sham and spinalized rats approximately 10 fold lower than the other group, which comprised GR103545 and CI-977. 3. Under sham-spinalized conditions, CI-977 and GR103545 at high doses caused only sub-maximal reductions of spinal reflexes. U-50,488 was still active when superimposed on these high doses of GR103545. 4. Naloxone reversed all effects, but different doses were required between compounds, with GR103545 taking some 20 times higher doses of naloxone to cause reversal than did U-50,488. 5. The effects on mean arterial pressure were opposite between groups. 6. The results imply that more than one type of naloxone-sensitive non-mu opioid receptor must be involved in mediating these complex actions of ligands that have been claimed to be selective for kappa-receptors.

Morphine tolerance and inhibition of oxytocin secretion by kappa-opioids acting on the rat neurohypophysis

1. The present study investigated the mechanisms by which endogenous opioids regulate oxytocin secretion at the level of the posterior pituitary gland. Effects of the selective kappa-agonist U50,488 on oxytocin secretion were studied in urethane-anaesthetized lactating rats. Oxytocin secretion in response to electrical stimulation (0.5 mA, matched biphasic 1 ms pulses, 50 Hz, 60-180 pulses) of the neurohypophysial stalk was bioassayed on-line by measuring increases in intramammary pressure, calibrated with exogenous oxytocin. Intravenous (I.V.) U50,488 inhibited electrically stimulated oxytocin secretion, without affecting mammary gland sensitivity to oxytocin. The inhibition was dose related, with an ID50 of 441 (+194, -136) micrograms/kg and was naloxone reversible. Antagonism of endogenous beta-adrenoceptor activation by propranolol (1 mg/kg) reduced the potency of U50,488. The selective mu-agonist morphine (up to 5 mg/kg), had no effect on electrically stimulated oxytocin secretion, but depressed the mammary response to oxytocin. 2. In lactating rats given intracerebroventricular (I.C.V.) morphine infusion for 5 days to induce tolerance and dependence, I.V. U50,488 still inhibited electrically stimulated oxytocin secretion, but the ID50 was reduced to 170 (+78, -54) micrograms/kg; thus at the posterior pituitary the sensitivity of kappa-receptors is enhanced rather than reduced in morphine-tolerant rats, indicating the absence of cross-tolerance. In these rats, naloxone produced a large, sustained, fluctuating increase in intramammary pressure indicating morphine-withdrawal excitation of oxytocin secretion; I.V. U50,488 diminished this response, confirmed by radioimmunoassay, demonstrating the independence of mu- and kappa-receptors regulating oxytocin secretion. 3. In pregnant rats, I.C.V. infusion of morphine from day 17-18 of pregnancy delayed the start of parturition by 4 h, but did not significantly affect the progress of parturition once established, indicating tolerance to the inhibitory actions of morphine on oxytocin secretion in parturition, and lack of cross-tolerance to endogenous opioids restraining oxytocin in parturition. 4. Neurointermediate lobes from control and I.C.V. morphine-infused virgin rats were impaled on electrodes and perifused in vitro. Vasopressin and oxytocin release from the glands was measured by radioimmunoassay. Each gland was exposed to two periods of electrical stimulation (13 Hz, for 3 min). Naloxone (5 x 10(-6) M) was added before the second stimulation; half the lobes from each I.C.V. treatment were exposed to 5 x 10(-5) M morphine throughout.(ABSTRACT TRUNCATED AT 400 WORDS)

Comparative thermodynamics of opioid receptor ligand interaction in the bovine adrenal medulla membranes--evidence of opioid site heterogeneity

1. A marked dependence on temperature of agonist binding delta, mu and kappa 1-3 opioid sites in the bovine adrenal medulla was observed, at the range of 0 to 37 degrees C. These changes concern kinetic (k1) and equilibrium constants (Kd), but not binding capacities (Bmax). 2. These dependences are different for each ligand and each opioid receptor, suggesting their molecular heterogeneity. 3. The comparative thermodynamics indicates that the interaction of opioid agonists with their receptor is exergonic (delta G degree < 0) and entropy driven (delta S degree > 0). 4. The comparison of Van't Hoff and Arrhenius plots indicates a discrete mechanism in the binding of each opioid receptor.

Endogenous opioid regulation of oxytocin secretion through pregnancy in the rat

We have investigated the influence of endogenous opioids on oxytocin secretion during pregnancy. In blood-sampled conscious rats on days 18 and 21 of pregnancy plasma oxytocin concentration, measured by radioimmunoassay, was significantly increased compared to non-pregnant or post-partum rats. On days 15, 18 and 21 of pregnancy but not in non-pregnant, early pregnant or post-partum rats, the opioid antagonist naloxone caused a significant increase in plasma oxytocin compared to vehicle injection, indicating activation of an endogenous opioid restraint over oxytocin secretion. Electrically stimulated neural lobes isolated from 16- and 21-day pregnant rats released more oxytocin than those from non-pregnant rats. However, naloxone (10(-5) M) was less effective at potentiating, and the kappa-opioid agonist U50,488 (10(-5)M) was less effective at inhibiting, stimulated release at the end of pregnancy than in non-pregnant rats suggesting desensitization of oxytocin nerve terminals to actions of endogenous opioids. Neural lobes from male rats drinking 2% saline for 4 days also showed desensitization of oxytocin nerve endings to naloxone. Neither neural lobe content of dynorphin A(1-8), an endogenous kappa-opioid, nor prodynorphin mRNA expression, measured by in situ hybridization histochemistry in the supraoptic nucleus altered during pregnancy. However, neural lobe content of Met5-enkephalin significantly decreased by day 21 of gestation suggesting enhanced release.(ABSTRACT TRUNCATED AT 250 WORDS)

Opioid binding sites in jerboa (Jaculus orientalis) brain: a biochemical comparative study in the awake-active and induced hibernating states

1. Using tritiated ligands [3H]DADLE, [3H]DAGO, [3H]EKC and [3H]Bremazocine, we have demonstrated the presence of delta, mu and kappa sites in brain membranes from jerboa (Jaculus orientalis), a desert rodent and a true hibernator. 2. A comparative study was realized in the case of the induced hibernating state, indicating a reduction of binding capacities during the hibernation state. 3. Using radioimmunoassay, the endogenous pentapeptide methionine-enkephalin (Met-enk) was evaluated in different areas of jerboa brain in comparison with the effect of induced hibernation on the level of Met-enk. 4. A thermodynamic analysis of the effect of temperature on the binding of opioids, indicates that the hibernating and the active state are energetically different. delta G degrees, delta H degrees and delta S degrees were calculated. A break of the Van't Hoff plot was observed in the active state at 15 degrees C, indicating a possible transition state of membranous phospholipids and/or proteins. 5. The role of phospholipids was studied, using the effect of phospholipase A2 and membrane reconstitution. Phospholipids play a key role in the opioid binding.

The kappa-opioid receptor: evidence for the different subtypes

Classification of drugs acting on the kappa-opioid receptors seems to be difficult, since some of these ligands are also sigma agonists and/or display non-opioid actions as well. Furthermore, certain benzomorphans having kappa-agonistic character, are shown to be mu-antagonists too. Therefore the classification of the kappa-opioid receptor has to be presently restricted to two subclasses that also have physiological meaning. Dynorphin and Met-enkephalin-Arg6-Phe7 are proposed as endogenous peptide ligands for kappa-receptors. Nonpeptide agonists are benzeneacetamides interacting with the kappa1 receptor. Benzomorphans bind to both subtypes of kappa-receptors. No selective nonpeptide ligand for the kappa2 receptor exists as yet. Nor-binaltorphimine, a specific kappa-antagonist also inhibits both kappa-subtypes. Further research for kappa2 selective drugs is necessary for clear distinction between the two kappa-opioid binding sites. Molecular cloning of opioid receptors including their subtypes are expected to provide direct proof of their existence.

Phenylpiperidine opioid antagonists that promote weight loss in rats have high affinity for the kappa 2B (enkephalin-sensitive) binding site

Certain opioid antagonists of the phenylpiperidine series (PPAs), such as LY255582, seem uniquely efficacious at producing weight loss in lean and meal-fed obese Zucker rats. Comparison of the pharmacological and receptor binding profile of PPAs that promote marked weight loss with those that do not has failed to find any obvious differences between these two groups of narcotic antagonists, which might explain the differences in their biological activities. The potent stimulatory effect of dynorphin, and other kappa agonists, on feeding behavior suggests that the antagonists that promote weight loss might have high affinity for kappa receptors. The recent demonstration by several laboratories of kappa receptor heterogeneity prompted us to test the hypothesis that the antagonists that promote weight loss might have high affinity for a subtype of kappa binding sites. In the present study, therefore, we determined the Ki values of five PPAs, naloxone, and naltrexone at mu, delta, kappa 1, kappa 2a, and kappa 2b binding sites. The data indicate that antagonists have subnanomolar Ki values and high selectivity for the kappa 2b binding site (relative to the kappa 2a binding site) are efficacious at promoting weight loss.

Interaction of opioid peptides and other drugs with multiple kappa receptors in rat and human brain. Evidence for species differences

Previous experiments resolved four kappa binding sites in guinea pig brain termed kappa 1a, kappa 1b, and kappa 2b. The present study was undertaken to examine the occurrence of kappa receptor subtypes in rat and human brain. [3H]U69,593 and [3H]bremazocine were used to label kappa 1 and kappa 2 binding sites, respectively, present in brain membranes depleted of mu and delta binding sites by pretreatment with the irreversible ligands, BIT and FIT. Low levels of [3H]U69,593 binding precluded a detailed quantitative study of kappa 1 binding sites in these species. Quantitative examination of [3H]bremazocine binding resolved two kappa 2 binding sites in both rat and human brain whose ligand selectivity patterns differed from that of the guinea pig. These observations suggest that there may be considerable variation in the ligand recognition site of kappa receptor subtypes among mammalian species.

Differential effects of Mg2+ and other divalent cations on the binding of tritiated opioid ligands

The effects of MgCl2 on the binding of tritiated ligands to opioid binding sites in homogenates of guinea-pig brain in HEPES buffer have been studied. The binding of tritiated mu-, delta-, and kappa-opioid agonists was promoted in a concentration-dependent manner over a range of MgCl2 concentrations from 0.1 mM to 10 mM, as was binding of the nonselective antagonists [3H]diprenorphine and [3H]naloxone. At concentrations of MgCl2 above 10 mM reversal of this effect was observed. The effects of MgCl2 on binding parameters differed at each site. The promoting effects of MgCl2 were mimicked by MnCl2, CaCl2, and MgSO4, but CoCl2 and ZnCl2 were inhibitory. Following treatment of guinea-pig brain synaptosomes at pH 11.5 to eliminate G proteins, the binding of the mu-opioid agonist [3H][D-Ala2, MePhe4, Gly-ol5]enkephalin and [3H]naloxone was much reduced but binding of [3H]diprenorphine was unaffected. Under these conditions MgCl2 still promoted binding of [3H]diprenorphine. The results suggest that Mg2+ ions promote binding by an action at the opioid receptor, even in the absence of G protein, and that opioid antagonists may differ in their recognition of opioid receptor binding sites.

Interaction of opioid peptide-containing terminals with dopaminergic perikarya in the rat hypothalamus

Both direct pituitary and indirect CNS mechanisms have been postulated for the influence of opiate agonists on prolactin secretion. By examining the interactions between terminals of neurons containing opioid peptides and hypothalamic TH-positive cell bodies, this paper addressed the anatomical basis for the latter mechanism. Initial electron microscopic studies directly demonstrated contact between opioid peptide terminals and dopaminergic cell bodies and provided some visual criteria for assessing opioid-dopamine interactions at the light microscopic level. Using these guidelines, we examined the rates of contact on both A12 and A14 neurons of each of the three opioid peptide families: pro-enkephalin, pro-dynorphin, and pro-opiomelanocortin (POMC). For A14 neurons, many of which project to the posterior pituitary, contact rates were estimated at 15, 20, and 5% for dynorphin, Met-enkephalin, and ACTH (a POMC derivative), respectively. In contrast, the A12 dopamine neurons, which regulate prolactin secretion by inhibition, showed a roughly 70% contact rate with dynorphin axons (P less than 0.001) with Met-enkephalin and ACTH contact rates remaining low at 20 and 5% respectively. Contact frequency varied significantly during the estrus cycle only with dynorphin contacts on A12 neurons. Proestrus and diestrus (less so) showed a small but significant (P less than 0.05) elevation in contact rates versus estrus, male, lactating and pregnant groups. No other significant difference emerged among these groups. On the basis of these observations, we conclude that dynorphin represents a significant and specific factor in the innervation of A12 dopamine neurons. This relationship may account for some if not most of the influence of opiate agonists and antagonists on prolactin secretion.

After chronic opioid exposure sensory neurons become supersensitive to the excitatory effects of opioid agonists and antagonists as occurs after acute elevation of GM1 ganglioside

Mouse sensory dorsal-root ganglion (DRG) neurons chronically exposed to 1 microM D-Ala2-D-Leu5-enkephalin (DADLE) for greater than 1 week in culture become tolerant to opioid inhibitory effects, i.e. shortening of the duration of the calcium-dependent component of the action potential (APD). Acute application of higher concentrations of DADLE (ca. 10 microM) to these treated neurons not only fails to shorten the APD but, instead, generally elicits excitatory effects, i.e. prolongation of the APD. The present study shows that chronic DADLE- or morphine-treated DRG neurons also become supersensitive to the excitatory effects of opioids. Whereas nM concentrations of dynorphin(1-13) are generally required to prolong the APD of naive DRG neurons, fM levels become effective after chronic opioid treatment. Whereas 1-30 nM naloxone or diprenorphine do not alter the APD of naive DRG neurons, both opioid antagonists unexpectedly prolong the APD of most of the treated cells. Similar supersensitivity to the excitatory effects of opioid agonists and antagonists was previously observed after acute treatment of naive DRG neurons with GM1 ganglioside. Our results suggest that both chronic opioid and acute GM1 treatments of DRG neurons greatly enhance the efficacy of opioid excitatory receptor functions so that even the extremely weak agonist properties of naloxone and diprenorphine become effective in prolonging the APD of these treated cells when tested at low concentrations, whereas their antagonist properties at inhibitory opioid receptors do not appear to be altered. Furthermore, whereas cholera toxin-B subunit (CTX-B; 1-10 nM) blocks opioid-induced APD prolongation in naive DRG neurons (presumably by interfering with endogenous GM1 modulation of excitatory opioid receptors functions), even much higher concentrations of CTX-B were ineffective in chronic opioid-treated as well as acute GM1-elevated neurons. These and related data suggest that opioid excitatory supersensitivity in chronic opioid-treated DRG neurons may be due to a cyclic AMP-dependent increase in GM1 ganglioside levels. Our results may clarify mechanisms of opioid dependence and the paradoxical supersensitivity to naloxone which triggers withdrawal symptoms after opiate addiction.

Naloxone potentiates the release of oxytocin induced by systemic administration of cholecystokinin without enhancing the electrical activity of supraoptic oxytocin neurones

Studies performed in conscious female rats confirmed that iv injection of cholecystokinin octapeptide (CCK; 20 mu/kg) increased the circulating concentration of oxytocin but not that of vasopressin, and confirmed that the stimulation of oxytocin release was markedly facilitated after iv administration of naloxone (1 mg/kg), indicating attenuation of oxytocin release by endogenous opioids. To investigate the site of action of the endogenous opioids, the electrical activity of putative oxytocin neurones in the supraoptic nucleus was recorded in urethane-anaesthetised female rats. Oxytocin neurones responded to CCK injection with an increase in firing rate lasting 5-15 min, but this response was not facilitated by prior injection of naloxone. The results suggest that the opioid influence upon CCK-induced oxytocin release operates at the level of the neurosecretory terminals in the neurohypophysis rather than centrally. Since CCK does not elevate vasopressin release, it appears unlikely that dynorphin, the opioid peptide co-existing with vasopressin, is responsible in these circumstances for the cross-inhibition of oxytocin release. It is suggested that products of proenkephalin A, the met-enkephalin precursor present in the supraoptic nucleus and in the neurohypophysis itself, may be active in the regulation of oxytocin release.

Adenosine release in morphine-induced hypotension in rats

1. Following intravenous administration of morphine.HCl a reduction in mean arterial blood pressure (MABP) was produced, quaternary morphine analogue was ineffective. 2. Theophylline and 8-phenyltheophylline administration reduced morphine-induced hypotension. 3. A2 adenosine receptor agonist caused an hypotension while A1 adenosine receptor agonist was ineffective. 4. L-NG-Mono-methylarginine administration reduced the hypotensive effect of exogenous A2 agonist while it was ineffective on morphine-induced hypotension. 5. Morphine-induced hypotension was increased by pretreatment with dipyridamole, whereas tetrabenazine abolished it. 6. The present study is consistent with previous reports on the central hypotensive action of morphine and propose a role for adenosine release in morphine-induced hypotension.

Visualization of mu opiate receptor downregulation following morphine treatment in neonatal rat brain

In order to visualize neuroanatomical alterations in specific brain regions, light microscopy autoradiography was carried out on neonatal brain sections from controls and neonates chronically treated with morphine. In the case of brains exposed to morphine from postnatal day (PD) 1-4, mu receptor density on PD 5 was non-existent in the patches of the striatum. There were also decreases in mu opiate receptor density in the surrounding matrix area, and in the nucleus accumbens and amygdala. Longer durations of morphine treatment (PD 1-8) did not show these alterations in mu opiate receptor density. These data demonstrate the unique plasticity seen in the immature opioid system. It is suggested that the differences observed in neonatal vs adult central nervous system may be due to interactions with and the differential development of the G-protein/cyclic adenosine 3',5'-monophosphate (cAMP) system.

Neuroanatomical localization of kappa 1 and kappa 2 opioid receptors in rat and guinea pig brain

The neuroanatomical localization of kappa opioid receptors in rat and guinea pig brain was determined by quantitative in vitro receptor autoradiography. Our study shows striking differences in kappa 1 and kappa 2 receptor distributions both between species and within each species. In the rat brain, kappa 1 sites (labeled by [3H]U-69,593) are of low density and confined to a small number of structures. These include the claustrum, endopiriform nucleus, caudate putamen, nucleus accumbens, midline nuclear group of the thalamus, superficial grey layer of the superior colliculus, and central grey. kappa 2 sites (labeled by [3H]ethylketocyclazocine or [3H]bremazocine under conditions in which mu, delta, and kappa 1 binding was suppressed) are more widely distributed throughout all levels of rat brain. kappa 2 sites occur at high density in the caudate putamen, nucleus accumbens, amygdala, thalamus, and interpeduncular nuclei. In guinea pig brain, kappa 1 sites predominate and are of high density in layers I and VI of the neocortex, claustrum, endopiriform nucleus, caudate putamen, nucleus accumbens, and molecular layer of the cerebellum. As in rat brain, kappa 2 sites in guinea pig are more uniformly and widely distributed throughout the brain than are kappa 1 sites. The highest density of kappa 2 sites is in the dorsal parabrachial nucleus, interpeduncular nuclei, mammillary nuclei, and posterior thalamic nuclei. Results from this study demonstrate important interspecies differences in the distribution of kappa 1 and kappa 2 opioid receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Localisation and pharmacological characterisation of [3H]bremazocine binding in the bovine adrenal medulla

[3H]Bremazocine (5 nM), in the presence of excess unlabelled mu and delta opioid ligands labelled two anatomically distinct populations of binding sites in the bovine adrenal medulla; a high density over the peripheral adrenaline-containing region of the medulla and a lower density over the central noradrenaline-containing region. This non-mu, non-delta opioid binding was specific (diprenorphine sensitive) but did not appear to involve classical kappa (kappa 1), sigma or PCP binding sites being insensitive to high concentrations of dynorphin (1-13), 3-PPP or MK-801. A significant proportion of the binding at both locations was however sensitive to competition by U50,488H or metorphamide. These data provide further evidence to support the existence of multiple opioid binding sites in the bovine adrenal medulla.

Opioid inhibition of nicotine-induced 45Ca2(+)-uptake into cultured bovine adrenal medullary cells

The ability of a number of opioid agonists and antagonists to affect nicotine-induced 45Ca2(+)-uptake into cultured bovine adrenal medullary cells has been investigated. High (10 microM) concentrations of the opioid agonist bremazocine produced a significant inhibition of nicotine-induced 45Ca2(+)-uptake throughout the 15 min time course examined. The opioid subtype-selectivity of this inhibition was investigated; mu and delta selective agonists produced only minor effects whereas the kappa selective agonist U50-488H and the endogenous opioid peptides dynorphin(1-13) and metorphamide almost abolished nicotine-induced 45Ca2(+)-uptake. The U50-488H inhibition was significant at 10 nM concentrations with an IC50 of approximately 1 microM. U50-488H inhibition could not be reversed or reduced by the opioid antagonists naxolone, diprenophine or Mr2266. Furthermore, Mr2266 and its optical isomer Mr2267 also produced marked inhibition of 45Ca2(+)-uptake. The inhibition was specific to nicotine-induced 45Ca2(+)-uptake in that a similar level of uptake evoked by potassium depolarization was unaffected by high concentrations of U50-488H. These data indicate that opioid inhibition of nicotine-induced 45Ca2(+)-uptake does not involve classical, stereospecific opioid receptors and suggests the involvement of a pharmacologically distinct opioid recognition site. It is speculated that this may be associated with the nicotine receptor-ionophore complex.