Clathrin light chains' role in selective endocytosis influences antibody isotype switching.

Clathrin, a cytosolic protein composed of heavy and light chain subunits, assembles into a vesicle coat, controlling receptor-mediated endocytosis. To establish clathrin light chain (CLC) function in vivo, we engineered mice lacking CLCa, the major CLC isoform in B lymphocytes, generating animals with CLC-deficient B cells. In CLCa-null mice, the germinal centers have fewer B cells, and they are enriched for IgA-producing cells. This enhanced switch to IgA production in the absence of CLCa was attributable to increased transforming growth factor ß receptor 2 (TGFßR2) signaling resulting from defective endocytosis. Internalization of C-X-C chemokine receptor 4 (CXCR4), but not CXCR5, was affected in CLCa-null B cells, and CLC depletion from cell lines affected endocytosis of the δ-opioid receptor, but not the ß2-adrenergic receptor, defining a role for CLCs in the uptake of a subset of signaling receptors. This instance of clathrin subunit deletion in vertebrates demonstrates that CLCs contribute to clathrin's role in vivo by influencing cargo selectivity, a function previously assigned exclusively to adaptor molecules.

Opiate antagonist prevents µ- and δ-opiate receptor dimerization to facilitate ability of agonist to control ethanol-altered natural killer cell functions and mammary tumor growth.

In the natural killer (NK) cells, δ-opiate receptor (DOR) and µ-opioid receptor (MOR) interact in a feedback manner to regulate cytolytic function with an unknown mechanism. Using RNK16 cells, a rat NK cell line, we show that MOR and DOR monomer and dimer proteins existed in these cells and that chronic treatment with a receptor antagonist reduced protein levels of the targeted receptor but increased levels of opposing receptor monomer and homodimer. The opposing receptor-enhancing effects of MOR and DOR antagonists were abolished following receptor gene knockdown by siRNA. Ethanol treatment increased MOR and DOR heterodimers while it decreased the cellular levels of MOR and DOR monomers and homodimers. The opioid receptor homodimerization was associated with an increased receptor binding, and heterodimerization was associated with a decreased receptor binding and the production of cytotoxic factors. Similarly, in vivo, opioid receptor dimerization, ligand binding of receptors, and cell function in immune cells were promoted by chronic treatment with an opiate antagonist but suppressed by chronic ethanol feeding. Additionally, a combined treatment of an MOR antagonist and a DOR agonist was able to reverse the immune suppressive effect of ethanol and reduce the growth and progression of mammary tumors in rats. These data identify a role of receptor dimerization in the mechanism of DOR and MOR feedback interaction in NK cells, and they further elucidate the potential for the use of a combined opioid antagonist and agonist therapy for the treatment of immune incompetence and cancer and alcohol-related diseases.

Dopaminergic amacrine cells express opioid receptors in the mouse retina.

The presence of opioid receptors has been confirmed by a variety of techniques in vertebrate retinas including those of mammals; however, in most reports, the location of these receptors has been limited to retinal regions rather than specific cell types. Concurrently, our knowledge of the physiological functions of opioid signaling in the retina is based on only a handful of studies. To date, the best-documented opioid effect is the modulation of retinal dopamine release, which has been shown in a variety of vertebrate species. Nonetheless, it is not known if opioids can affect dopaminergic amacrine cells (DACs) directly, via opioid receptors expressed by DACs. This study, using immunohistochemical methods, sought to determine whether (1) µ- and δ-opioid receptors (MORs and DORs, respectively) are present in the mouse retina, and if present, (2) are they expressed by DACs. We found that MOR and DOR immunolabeling were associated with multiple cell types in the inner retina, suggesting that opioids might influence visual information processing at multiple sites within the mammalian retinal circuitry. Specifically, colabeling studies with the DAC molecular marker anti-tyrosine hydroxylase antibody showed that both MOR and DOR immunolabeling localize to DACs. These findings predict that opioids can affect DACs in the mouse retina directly, via MOR and DOR signaling, and might modulate dopamine release as reported in other mammalian and nonmammalian retinas.

[Role of dopamine D1- and D2-receptors in the delta1-opioidergic immunostimulation].

The study has shown that activation of delta1-opioid receptors by a highly selective peptide agonist DPDPE (100 microg/kg) results in a significant increase of the immune response to antigen (SRBC, 5 x 10(8)) in CBA mice. SCH-23390 (1 mg/kg), a selective antagonist of the postsynaptic dopamine D1-receptors, and selective D2-blocker haloperidol (1 mg/kg) prevented immunostimulating effect of DPDPE. Comparison of effects of the antagonists suggests that delta1-opioidergic immunostimulation has more significant impact due to involvement of dopamine D1-receptors.

δ-Opioid Receptors, microRNAs, and Neuroinflammation in Cerebral Ischemia/Hypoxia.

Hypoxia and ischemia are the main underlying pathogenesis of stroke and other neurological disorders. Cerebral hypoxia and/or ischemia (e.g., stroke) can lead to neuronal injury/death and eventually cause serious neurological disorders or even death in the patients. Despite knowing these serious consequences, there are limited neuroprotective strategies against hypoxic and ischemic insults in clinical settings. Recent studies indicate that microRNAs (miRNAs) are of great importance in regulating cerebral responses to hypoxic/ischemic stress in addition to the neuroprotective effect of the δ-opioid receptor (DOR). Moreover, new discovery shows that DOR can regulate miRNA expression and inhibit inflammatory responses to hypoxia/ischemia. We, therefore, summarize available data in current literature regarding the role of DOR and miRNAs in regulating the neuroinflammatory responses in this article. In particular, we focus on microglia activation, cytokine production, and the relevant signaling pathways triggered by cerebral hypoxia/ischemia. The intent of this review article is to provide a novel clue for developing new strategies against neuroinflammatory injury resulting from cerebral hypoxia/ischemia.

Agonist-induced phosphorylation bar code and differential post-activation signaling of the delta opioid receptor revealed by phosphosite-specific antibodies.

The δ-opioid receptor (DOP) is an attractive pharmacological target due to its potent analgesic, anxiolytic and anti-depressant activity in chronic pain models. However, some but not all selective DOP agonists also produce severe adverse effects such as seizures. Thus, the development of novel agonists requires a profound understanding of their effects on DOP phosphorylation, post-activation signaling and dephosphorylation. Here we show that agonist-induced DOP phosphorylation at threonine 361 (T361) and serine 363 (S363) proceeds with a temporal hierarchy, with S363 as primary site of phosphorylation. This phosphorylation is mediated by G protein-coupled receptor kinases 2 and 3 (GRK2/3) followed by DOP endocytosis and desensitization. DOP dephosphorylation occurs within minutes and is predominantly mediated by protein phosphatases (PP) 1α and 1ß. A comparison of structurally diverse DOP agonists and clinically used opioids demonstrated high correlation between G protein-dependent signaling efficacies and receptor internalization. In vivo, DOP agonists induce receptor phosphorylation in a dose-dependent and agonist-selective manner that could be blocked by naltrexone in DOP-eGFP mice. Together, our studies provide novel tools and insights for ligand-activated DOP signaling in vitro and in vivo and suggest that DOP agonist efficacies may determine receptor post-activation signaling.

Autoantibodies against opioid or glutamate receptors are associated with changes in morphine reward and physical dependence in mice.

BACKGROUND: Possible interactions between nervous and immune systems during opioid addiction remain elusive. Recombinant mu-delta opioid receptors (MDOR) and the glutamate receptor 1 (GluR1) subunit of amino-3-hydroxy-5-methyl-4-isoxazole propionic acid glutamate receptors are involved in acute and chronic effects of morphine. Elevated levels of autoantibodies (aAbs) to these receptors were demonstrated in heroin human addicts and in animal models. This study characterized the role of aAbs to these receptors in behavioral modulations recruited during opioid tolerance and sensitization. METHODS AND FINDINGS: Male CD-1 mice, immunized with either MDOR or GluR1 peptide fragments (80 microg intraperitoneal (i.p.)), were examined for spontaneous behavior and response to morphine (5 mg/kg i.p.). Spontaneous home-cage activity, novelty-induced self-grooming and morphine-induced hyperactivity were higher in GluR1 mice compared to Vehicle subjects, whereas MDOR immunization was associated with an increased morphine-induced conditioned place preference. In response to escalating doses of morphine (from 10 to 60 mg/kg i.p., twice daily) and naloxone-precipitated withdrawal (1 mg/kg subcutaneous), GluR1 mice exhibited a more marked stereotyped sniffing behavior and less body tremors compared to Vehicle subjects, whereas less sniffing and teeth chattering were found in MDOR mice. The expected downregulation of mu receptor binding sites, induced by chronic morphine in vehicle subjects, was completely absent following MDOR immunization. CONCLUSIONS: These findings indicate an altered response to morphine-related reinforcing and aversive effects in MDOR mice and altered coping with the environment in GluR1 mice. Circulating aAbs to specific neuroreceptors may alter the response to opiates and play a role as determinants of vulnerability to opiate addiction.

DADLE enhances viability and anti-inflammatory effect of human MSCs subjected to 'serum free' apoptotic condition in part via the DOR/PI3K/AKT pathway.

AIM: Nutritional deprivation and inflammation-rich zones are the major causative reasons for poor survivability of transplanted mesenchymal stem cells (MSCs). Therefore in the present study, we demonstrated the cytoprotective and anti-inflammatory effects of activated delta (δ)-opioid receptor (DOR) with synthetic peptide [D-Ala2, D-Leu5]-enkephalin (DADLE) treatment on human MSCs cultured in serum-starved condition. MAIN METHODS: Cell viability was measured using MTT and Annexin V/PI assays. Expressions of pro-apoptotic (Bcl2) and anti-apoptotic genes (Bax/Bad), levels of activated p44/42 MAPK, Akt, PI3-kinase-p110γ and cleaved caspase-3 were determined by qPCR and western blot. Levels of secreted cytokines were measured by ELISA. KEY FINDINGS: In comparison to the control, DADLE significantly increased cell survivability under serum deprived condition as confirmed by MTT (71% vs 45%) and Annexin V/PI assays (25.9% vs 3.7%). Significant up-regulation of pro-apoptotic Bcl2 (~2.1 folds), down-regulations of anti-apoptotic Bax/Bad (~2.6/2.7 folds) as well as of cleaved caspase-3, increased expression of PI3kinase subunit p110γ and activation of Akt (Ser473) were observed following DADLE treatment in cells under 'serum deprivation' stress. In addition, DADLE treated hMSCs secreted increased levels of anti-inflammatory cytokines (IL10/IL4/TGF-ß) under serum deprived condition. LPS stimulated macrophages showed abated release of pro-inflammatory cytokines (IL1/TNFα/IL6) when grown in hMSC conditioned 'serum deprived' media treated with DADLE. Both the cytoprotective and anti-inflammatory effects of DADLE were inhibited by the DOR specific antagonist naltrindole. SIGNIFICANCE: The DOR signaling pathway improved cell viability and enhanced anti-inflammatory effect of hMSCs subjected to 'serum deprivation' stress that could have potential therapeutic benefits in reparative medicine.

Specific changes in levels of autoantibodies to glutamate and opiate receptors induced by morphine administration in rats.

Several groups of brain receptors are involved in the mechanisms underlying the development of opiate addiction, but the interactions occurring between these neuroreceptors and the immune system, including potential autoimmune responses, remain poorly understood. We studied in rats the effects of repeated administration of different psychotropic drugs on serum levels of autoantibodies (aAbs) to the mu delta-opiate receptor (MDOR), as well as to the alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate (AMPA) GluR1 and to the N-methyl-D-aspartate (NMDA) NR2 subunits of the glutamate receptor, as analyzed by ELISA. We found that repeated administration of morphine significantly elevated aAbs levels to MDOR and to the AMPA GluR1 subunit, but not to the NMDA NR2 subunit. In contrast, a similar regimen of a psychostimulant drug, such as D-amphetamine, or a commonly abused substance, such as nicotine, had no effect on these aAbs levels. A nonspecific elevating effect on aAbs to the brain structural protein S100B was observed for all drugs tested versus controls. These observations support the hypothesis that, following opiate administration, specific interactions between nervous and immune systems occur. Therefore, together with further investigations on their potential functional consequences, we propose a thorough exploration of aAbs to MDOR and to AMPA GluR1 subunit as early biomarkers signaling opiate addiction.

The immunomodulation mediated by a delta-opioid receptor for [Met(5)]-enkephalin in oyster Crassostrea gigas.

Opioid receptors (OR) are a group of G protein-coupled receptors with opioids as ligands, which play an important role in triggering the second messengers to modulate immune response in vertebrate immunocytes. In the present study, the full length cDNA of a homologue of δ-opioid receptor (DOR) for [Met(5)]-enkaphalin was cloned from oyster Crassostrea gigas (designated as CgDOR), which was 1104 bp encoding a peptide of 367 amino acids containing a conserved 7tm_1 domain. After the stimulation of [Met(5)]-enkephalin, the concentration of second messengers Ca(2+) and cAMP in the HEK293T cells decreased significantly (p <0.05) with the expression of CgDOR. However, this trend was reverted with the addition of DOR antagonist BNTX. The CgDOR transcripts were ubiquitously detected in the tested tissues including haemocytes, gonad, mantle, kidney, gill, adductor muscle and hepatopancreas, with the highest expression level in the hepatopancreas. After LPS stimulation, the expression level of CgDOR mRNA began to increase (4.05-fold, p <0.05) at 6 h, and reached the highest level (5.00-fold, p <0.05) at 12 h. Haemocyte phagocytic and antibacterial activities increased significantly after [Met(5)]-enkephalin stimulation, whereas the increase was repressed with the addition of DOR antagonist BNTX. These results collectively suggested that CgDOR for [Met(5)]-enkephalin could modulate the haemocyte phagocytic and antibacterial functions through the second messengers Ca(2+) and cAMP, which might be requisite for pathogen elimination and homeostasis maintenance in oyster.

Monoclonal antibody to the delta opioid receptor acts as an agonist in dual regulation of adenylate cyclase in NG108-15 cells.

Monoclonal antibodies generated against multiple antigenic peptides of the N-terminal sequence (3LVPSARAELQSSPLV17) of the cloned delta opioid receptor immunoprecipitated a 58 kDa protein from CHAPS-solubilized NG108-15 membranes. The immunoprecipitates bound [3H]DPDPE--but not [3H]DAMGO--with a Kd of 6.4 nM and a Bmax of 75 pM. Western blot analysis revealed a distinct band of 58 kDa. The antibodies inhibited basal and PGE1-stimulated cAMP levels, and mimicked the effect of agonists manifest in a compensatory increase in cAMP formation. The antibody will be potentially useful in the analysis of functional epitopes on the delta opioid receptor.

Localization of delta opioid receptor immunoreactivity in interneurons and pyramidal cells in the rat hippocampus.

To study possible cellular targets and subcellular sites of action of opioid ligands in the rat hippocampus, we examined the distribution of the delta opioid receptor (DOR) by immunocytochemistry. By light microscopy, numerous interneurons, or non-principal cells, were intensely labeled for DOR, whereas the CA1 and CA3 pyramidal cells were lightly labeled. DOR-immunoreactive interneurons were found throughout the hippocampus but were particularly concentrated in stratum oriens of the CA1 region. Double labeling immunofluorescence revealed that DOR-immunoreactivity was found in a subpopulation of gamma-aminobutyric acid (GABA)-containing interneurons, which included most somatostatin-immunoreactive cells. Electron microscopic analysis of sections singly labeled for DOR revealed that DOR-immunoreactive profiles were abundant and widespread throughout all hippocampal lamina and had a similar distribution in CA1 and CA3. DOR-immunoreactivity was sometimes found in dendrites, which corresponded in morphology to those of interneurons. In addition, DOR-labeling was found in the shafts and spines of many dendrites, which exhibited the morphology of pyramidal cell dendrites. Within dendrites, dense DOR-immunoreactivity was associated with the plasmalemmal surface at or near the postsynaptic density, usually of asymmetric synapses. In addition, DOR labeling was present in a heterogeneous population of axon terminals, as well as in astrocytic profiles. At mossy fiber synapses, DOR labeling was occasionally found at both pre-and post-synaptic sites. These studies demonstrate that DOR is present at multiple sites on diverse cell types where it may function to regulate neuronal activity in the hippocampus.

Anti-idiotypic antibodies: a useful alternative for studying the biochemical expression of mu/delta opioid binding sites in mammalian brain.

A polyclonal antiserum was produced against opioid binding sites using an anti-idiotypic approach whereby antibodies directed against the opioid agonist DSLET were used as immunogen. The anti-idiotypic antiserum recognized specific brain proteins with molecular masses of 76 +/- 4, 73 +/- 4 and 59 +/- 3 kDa, respectively. The immunolabeling of these proteins was mainly inhibited by mu, delta opioid agonists and a general antagonist, naloxone. The inhibition of immunoprecipitation by opioid agonists and antagonist and the developmental expression of these immunoreactive proteins found to occur during brain ontogeny strongly suggest that these three proteins were mu, delta but not kappa opioid binding sites. The anti-idiotypic antiserum both inhibits 3H-DADLE binding and mimics the inhibitory agonist effects on the stimulated cAMP level of NG 108-15 cells which expressed delta opiate receptors. Numerous mammalian brain opioid binding sites were labeled, due to the fact that the binding site was the epitope recognized by the anti-idiotypic antibodies. From the numerous studies performed with a view to characterizing the specificity of the anti-idiotypic antibodies, it was strongly suggested that the anti-idiotypic antibodies specifically recognize mu/delta opioid binding sites and they can therefore be powerful tools for studying the biochemical expression of these opioid binding sites in mammalian brains.

Regulation of human B lymphocyte activation by opioid peptide hormones. Inhibition of IgG production by opioid receptor class (mu-, kappa-, and delta-) selective agonists.

Opioid peptides have been reported by many laboratories to modulate in vitro and in vivo cell-mediated and humoral immune responses. However, less attention has been afforded to the class or classes of opioid receptors involved in these immunomodulatory effects. Previous studies by this laboratory indicated that beta-endorphin and methionine-enkephalin were potent inhibitors of Staphylococcus aureus, Cowen strain I (SAC)-induced IgG production by human B lymphocytes. Results obtained from the present studies indicate that, at pharmacological concentrations, mu-, delta-, and kappa-receptor-selective agonists are potent inhibitors of SAC-induced IgG-secreting cells (IgG-ISC) by human B lymphocytes. Moreover, the suppression of IgG-ISC formation was reversed by mu-, delta-, and kappa-receptor class-selective antagonists, [D'Tic]cTAP, ICI 174,864, and nor-BNI, respectively. These findings are in agreement with other studies showing that more than one class of receptors are involved in opioid peptide-mediated immunoregulation. Additional studies indicated that all three class-selective receptor agonists were found to suppress SAC-induced IL-6 production in intact PBMC cultures. As observed for suppression of IgG-ISC formation, inhibition of IL-6 production was found to be reversed by the appropriate receptor class-selective antagonist. These results support the hypothesis that one mechanism of opioid peptide-mediated inhibition of antibody production is via the down regulation of cytokine synthesis.

Delta opioid receptors expressed by stably transfected jurkat cells signal through the map kinase pathway in a ras-independent manner.

Delta opioid receptors (DOR) are G-protein coupled 7-transmembrane receptors (GPCR), expressed by thymic and splenic T cells, that modulate interleukin (IL)-2 production and proliferation in response to concanavalin A or crosslinking the TCR. Mitogen-activated protein kinases (MAPKs) are involved in mediating intracellular responses to TCR crosslinking. In addition, MAPKs can be activated by signaling cascades that are initiated by the release of G-proteins from GPCRs. To determine whether DORs expressed by T cells signal through the MAPKs, extracellular-regulated kinases (ERKs) 1 and 2, two delta opioid peptides, deltorphin and [D-Ala2,D-Leu5]-enkephalin (DADLE), were studied in Jurkat cells that had been stably transfected with DOR (DOR-Ju.1). These peptides rapidly and dose-dependently induced ERK phosphorylation; pretreatment with naltrindole (NTI), a selective DOR antagonist, abolished this. Pertussis toxin (PTX) also inhibited phosphorylation, indicating the involvement of the Gi/o proteins. Herbimycin A, a protein tyrosine kinase (PTK) inhibitor, reduced the DADLE-induced ERK phosphorylation by 68%. ERK phosphorylation was inhibited by Bisindolylmaleimide 1 (GF109203X), an inhibitor of PKC, and by pretreatment with PMA prior to DADLE. A GTP/GDP exchange assay was used to assess the potential role of Ras in the pathway leading to ERK phosphorylation; DADLE failed to stimulate GTP/GDP exchange in comparison to PMA. Additional studies showed that DADLE stimulated an increase in cfos mRNA; this was reduced by the inhibitor of MAPK/ERK kinase (MEK), PD98059. Therefore, in DOR-Ju.1 cells, DOR agonists stimulate ERK phosphorylation in a Ras independent and PKC-dependent manner; PTKs appear to be involved. MAPKs mediate the increase in cfos mRNA induced by DOR agonists.

Immunomodulation of human T cell responses with receptor selective enkephalins.

The delta-opioid receptor selective [2-D-penicillamine-5-D-penicillamine] enkephalin (DPDPE) and the mu receptor selective Tyr-D-Orn-Phe-Asp-NH2 (TOPA) were found respectively, to have marked immunostimulant and immunosuppressant activities in both normal subjects and patients suffering from leprosy and tuberculosis. Antigen specific lymphoproliferation and numbers of rosette forming T cells were significantly (P < 0.05) enhanced on in vitro treatment with Met-enkephalin. This was further increased (P < 0.001) in the presence of the delta selective DPDPE. In contrast, treatment with mu selective TOPA inhibited lymphoproliferation substantially (P < 0.01) and rosette formation to a lesser extent.

Immunocytochemical localization of delta opioid receptors in mouse brain.

An affinity-purified anti-peptide antibody generated against the carboxy-terminal region of the delta opioid receptor was used to localize delta opioid receptors in mouse brain. delta Opioid receptor immunoreactivity was found in axons and nerve terminals in regions of the olfactory bulb, hippocampal formation, cerebral and cerebellar cortex, midbrain and hindbrain. The immunocytochemical distribution correlated well, though not completely with autoradiographic distribution of delta opioid receptors in mouse brain using either [3H][2-D-penicillamine, 5-D-penicillamine]-enkephalin (DPDPE) or [3H]naltrindole. Confocal microscopy of double-labeled tissue provided direct evidence that delta opioid receptors are principally expressed on GABAergic terminals in the hippocampus. These anatomical findings complement extensive physiological studies to provide a more detailed description of endogenous opioid circuitry.

Immunofluorescent identification of a delta (delta)-opioid receptor on primary afferent nerve terminals.

Antisera were produced against synthetic peptides predicted from the recent cloning of a delta opioid receptor, DOR-1. Confocal microscopic examination of immunostained spinal cord sections revealed that DOR-1 immunoreactive (-ir) nerve fibers and terminals form a moderately dense plexus within the superficial dorsal horn of rats and mice. These fibers decreased dramatically following dorsal rhizotomy and consistent with these observations a population of small diameter neurons in ganglia exhibited DOR-1-ir. DOR-1-ir ganglion neurons were also immunoreactive for calcitonin gene-related peptide (CGRP), and their terminals in the spinal cord contained both CGRP- and DOR-1-ir, the latter presumably located as a 'presynaptic' receptor. Interestingly, terminals containing DOR-1-ir appeared to be closely apposed by fibers and terminals containing enkephalin (ENK)-ir, which suggests that ENK may be a physiologically relevant ligand for the receptor encoded by DOR-1, and that DOR-1 may act to regulate the release of transmitters from small diameter primary afferent neurons.

In vitro exposure to peptidic delta opioid receptor antagonists results in limited immunosuppression.

Previous studies by our group have demonstrated that in vitro exposure to delta-opioid receptor agonists results in a significant immunostimulation, whereas in vitro exposure to non-peptidic delta-opioid receptor antagonists results in significant suppression of various immune functions. The present study assessed potential immunomodulation by the peptidic delta-opioid receptor antagonists TIPP, D-TIPP, and ICI 174864 using a panel of in vitro immune function assays. Splenocytes from female B6C3F1 mice were cultured with the peptides at concentrations of 0.00001-10 microM. B cell proliferation was quantified following cellular activation, T cell function was assessed by cytokine production following stimulation with anti-CD3 monoclonal antibody, natural immunity was assessed by quantitating natural killer (NK) cell activity following a 24-h exposure, and macrophage function was assessed by quantification of interleukin-6 (IL-6) production. None of the peptides examined significantly affected B cell proliferation. Production of IL-2 by T cells was not consistently affected by exposure to either TIPP or D-TIPP, but was significantly suppressed at 10 microM ICI 174864. Production of IL-4, however, was significantly suppressed by low concentrations of either TIPP or D-TIPP, and by 10 microM ICI 174864. IL-6 production by macrophages was unaffected except for sporadic incidents of enhanced production in cells exposed to ICI 174864. NK cell function exhibited a differential pattern of suppression, with the greatest degree of suppression observed following exposure to TIPP and only slight suppression in cells exposed to either D-TIPP or ICI 174864. These data suggest that peptidic delta-opioid receptor antagonists do not exhibit the same pattern or degree of immunosuppressive activity as the non-peptidic antagonists at equivalent in vitro concentrations.

Dual ultrastructural immunocytochemical labeling of mu and delta opioid receptors in the superficial layers of the rat cervical spinal cord.

The delta opioid receptor (DOR) and mu opioid receptor (MOR) are abundantly distributed in the dorsal horn of the spinal cord. Simultaneous activation of each receptor by selective opiate agonists has been shown to result in synergistic analgesic effects. To determine the cellular basis for these functional associations, we examined the electron microscopic immunocytochemical localization of DOR and MOR in single sections through the superficial layers of the dorsal horn in the adult rat spinal cord (C2-C4). From a total of 270 DOR-labeled profiles, 49% were soma and dendrites, 46% were axon terminals and small unmyelinated axons, and 5% were glial processes. 6% of the DOR-labeled soma and dendrites, and < 1% of the glial processes also showed MOR-like immunoreactivity (MOR-LI). Of 339 MOR-labeled profiles, 87% were axon terminals and small unmyelinated axons, 12% were soma and dendrites, and 2% were glial processes. 21% of the MOR-labeled soma and dendrites, but none of the axon terminals also contain DOR-LI. The subcellular distributions of MOR and DOR were distinct in axon terminals. In axon terminals, both DOR-LI and MOR-LI were detected along the plasmalemma, but only DOR-LI was associated with large dense core vesicles. DOR-labeled terminals formed synapses with dendrites containing MOR and conversely, MOR-labeled terminals formed synapses with DOR-labeled dendrites. These results suggest that the synergistic actions of selective MOR- and DOR-agonists may be attributed to dual modulation of the same or synaptically linked neurons in the superficial layers of the spinal cord.