A functionally coupled mu3-like opiate receptor/nitric oxide regulatory pathway in human multi-lineage progenitor cells

Ongoing studies from our group support the existence and biological importance of a distinct cellular signaling pathway involving endogenously synthesized, chemically authentic, l-morphine, its cognate mu(3) opiate receptor subtype, and constitutive NO synthase. Based on prior studies indicating evolutionary conservation and adaptation of morphinergic/NO-coupled signaling to mediate autocrine/paracrine control of cellular functions, our goal was to determine whether a functionally competent mu(3) opiate receptor/NO-coupled regulatory pathway exists in human multilineage progenitor cells (MLPC) prepared from umbilical cord blood. Real-time PCR analysis indicated significant expression of mu(3) opiate receptor-encoding RNA by undifferentiated human MLPC, in the absence of traditional mu(1) opioid receptor-encoding RNA expression. Unpredictably, confirmatory RT-PCR analyses indicated cellular expression of a splice variant of the previously characterized mu(3) opiate receptor-encoding mRNA. Pharmacological analyses provided critical validating evidence of functional mu(3)-like opiate receptor/NO-coupled signaling within primary cultures of undifferentiated human MLPC via morphine-evoke real-time release of NO. Control analyses indicated that morphine-stimulated NO release was markedly inhibited by prior treatment with the opiate antagonist l-naloxone or the constitutive NO synthase inhibitor N(G)-nitro-l-arginine methyl ester and unresponsive to stimulation by the opioid peptide methionine enkephalin. Complementary microarray analysis demonstrated that traditional mu(1), delta, and kappa opioid receptor gene expression is not detected in both undifferentiated and differentiated MLPC. Chemical differentiation of MLPC into neuronal progenitor cells effected significant phenotypic expression of a variety of neurally-associated genes. Our data provide compelling evidence in support of both the evolutionary primacy and primordial regulatory role of mu(3)-like opiate receptor/NO signaling in embryogenesis.     

Morphine upregulates mu opioid receptors of human and monkey lymphocytes

Opioid receptors of subtypes delta, kappa, and mu similar to those found in brain cells have been identified in immune cells. The current study demonstrates by competitive polymerase chain reaction the treatment of human lymphocytic cells with morphine resulting in an increased amount of gene expression of mu opioid receptors. Antibodies against the MOR-1, the neuronal mu opioid receptor, were used in Western blot analysis of mu proteins and the results revealed a single band of approximately 50 kDa, the intensity of which was increased by morphine treatment. Similar results of mu opioid receptor activation were observed when monkey lymphocytes were treated with morphine. These studies suggest that in addition to causing an immune effect through communication with the neuroendocrine system, the psychoactive drug morphine may modulate immune functions by acting directly on the mu opioid receptors expressed on lymphocytes.     

人源μ型阿片受体的cDNA克隆及转染CHO细胞的活性分析

μ型阿片受体是阿片类药物镇痛与成瘾的分子基础。从人脑组织总RNA通过RTPCR扩增获得μ型阿片受体的cDNA,将其克隆至pcDNA31(+)中,用酶切鉴定正确的重组质粒转染CHO细胞。筛选的单克隆细胞株,检测阳性的细胞克隆表达的μ型阿片受体介导胞内信号转导的能力。通过与激动剂和拮抗剂的信号转导分析证实,阳性的细胞克隆表达的μ型阿片受体与天然的μ型阿片受体具有基本一致的生物学特性,因此可以用来作为高效镇痛低成瘾药物筛选平台的候选细胞株。     

High and low affinity opioid binding sites: relationship to mu and delta sites

Binding and pharmacological studies suggest a common opiate and enkephalin binding site in addition to their previously reported selective sites. This common high affinity site has tentatively been named mu1, distinguishing it from the morphine-selective site (mu2) and enkephalin-selective site (delta). The existence of this additional common high affinity site and its association with opiate and opioid peptide analgesia may help explain some pharmacological observations, such as the cross tolerance between morphine and enkephalin analgesia and the lack of cross tolerance between them in the guinea pig ileum and mouse vas deferens bioassays.     

Hyperactivity versus explosive motor behavior induced by opioids in the rat. Mechanisms elucidated with enkephalin-tyrosine-o-sulfate and morphine congeners

A relatively mild hyperactive state (HAS), characterized by agitation and hypermotility, is induced by opiate drugs and opioid peptides in general and is blocked by naloxone. HAS can be distinguished from the profound hyperresponsiveness of an explosive motor behavior (EMB). Sulfation of the phenolic moiety in morphine or in methionine enkephalin essentially abolishes opiate receptor binding activity. The sulfated peptide lacks detectable pharmacological activity in the rat, whereas sulfated morphine is several hundred-fold more potent than morphine in eliciting (EMB). Thus, EMB is elicited only by congeners of morphine having appropriate hydrophilic substitution at C-6 and which is mediated through a receptor that is insensitive to naloxone.     

Characterization of Opioid Receptor Subtypes in Solution

Stable opioid receptor binding activity that retains distinct subtype specificities (mu, delta, and kappa) has been obtained in high yields in digitonin extracts of rat brain membranes that had been preincubated with Mg2+ prior to solubilization. The dependence on Mg2+ ions for receptor activity is also expressed in the soluble state, where the presence of Mg2+ leads to high-affinity and high-capacity opioid peptide binding to the delta, mu, and kappa sites (the latter subtype measured by the binding of [3H]dynorphin1-8). Binding of opiate alkaloids to soluble receptor sites is less dependent on Mg2+ than is opioid peptide binding. Soluble opioid binding activity shows the same sensitivity to Na+ ions and guanine nucleotides as the membrane-bound receptor. The ligand-receptor interactions give evidence of strong positive cooperativity, which is interpreted in terms of association-dissociation of receptor subunits on ligand binding in solution. Binding of enkephalin peptides is associated with the large macromolecules present (apparent Stokes radii greater than 60 A), whereas both those and several small species present (less than 60 A) bind opiate alkaloids and dynorphin1-8.     

Orally administered kappa as well as mu opiate agonists delay gastrointestinal transit time in the guinea pig

When an orally administered opiate agonist is systemically bioavailable, the relative activity of that opioid in delaying gastrointestinal transit (GIT) depends on its relative action at central and peripheral sites. This in turn depends on the density of opioid receptor specific subtypes at those sites of action in the species under study. In rats the kappa selective agonist U-50,488H has no effect on GIT. We have found that this same agonist is equipotent to mu agonists morphine and 1-methadone in delaying the orocecal transit of a charcoal meal when administered orally to guinea pigs. Thus, both kappa as well as mu receptor subtypes are involved in the mechanisms of opiate induced slowing of GIT in the guinea pig in contrast to the rat. Interspecies differences must be considered when determining the contribution of opiate receptor subtypes to the mechanisms of opiate-induced constipation.     

MAP kinase activation by mu opioid receptor involves phosphatidylinositol 3-kinase but not the cAMP/PKA pathway.

The involvement of protein kinases was studied in mu opioid receptor activation of mitogen-activated protein (MAP) kinase using cells transfected with the receptor clone. The cAMP/protein kinase A (PKA) pathway is known to be the major biochemical pathway for mu opioid receptor signaling. However, our data showed that stimulating adenylyl cyclase or activating PKA had no effect on mu receptor enhancement of MAP kinase activity, suggesting that the cAMP/PKA pathway is not involved in mediating the mu receptor activation of MAP kinase. Inhibition of phosphatidylinositol (PI) 3-kinase reduced mu receptor enhancement of MAP kinase activity, suggesting PI 3-kinase involvement. Together, these results show that cross-talk between the mu opioid receptor and the MAP kinase cascade is not mediated by the cAMP/PKA pathway, but involves PI 3-kinase.     

High-affinity naloxone binding to filamin a prevents mu opioid receptor-Gs coupling underlying opioid tolerance and dependence

Ultra-low-dose opioid antagonists enhance opioid analgesia and reduce analgesic tolerance and dependence by preventing a G protein coupling switch (Gi/o to Gs) by the mu opioid receptor (MOR), although the binding site of such ultra-low-dose opioid antagonists was previously unknown. Here we show that with approximately 200-fold higher affinity than for the mu opioid receptor, naloxone binds a pentapeptide segment of the scaffolding protein filamin A, known to interact with the mu opioid receptor, to disrupt its chronic opioid-induced Gs coupling. Naloxone binding to filamin A is demonstrated by the absence of [(3)H]-and FITC-naloxone binding in the melanoma M2 cell line that does not contain filamin or MOR, contrasting with strong [(3)H]naloxone binding to its filamin A-transfected subclone A7 or to immunopurified filamin A. Naloxone binding to A7 cells was displaced by naltrexone but not by morphine, indicating a target distinct from opioid receptors and perhaps unique to naloxone and its analogs. The intracellular location of this binding site was confirmed by FITC-NLX binding in intact A7 cells. Overlapping peptide fragments from c-terminal filamin A revealed filamin A(2561-2565) as the binding site, and an alanine scan of this pentapeptide revealed an essential mid-point lysine. Finally, in organotypic striatal slice cultures, peptide fragments containing filamin A(2561-2565) abolished the prevention by 10 pM naloxone of both the chronic morphine-induced mu opioid receptor-Gs coupling and the downstream cAMP excitatory signal. These results establish filamin A as the target for ultra-low-dose opioid antagonists previously shown to enhance opioid analgesia and to prevent opioid tolerance and dependence.     

Opioid agonist/antagonist effect of naloxone in modulating rabbit jejunum contractility in vitro.

Opioid peptides are the most effective drugs in controlling pain; their action is elicited by binding to specific membrane receptors. The gastrointestinal tract represents, after the nervous system, the site in which the opioid receptors are expressed at high levels. The opioid agonist morphine has a significant inhibitory effect on intestinal motility, this action is blocked by naloxone an opioid antagonist mainly active at mu and kappa receptors. In this study the presence of mu opioid receptor on rabbit jejunum was investigated by western blot. The effects of beta-endorphin, the endogenous opioid peptide with the highest affinity to the mu opioid receptor and those of naloxone on spontaneous rabbit jejunum contractions were evaluated. Beta-endorphin (10(-6) M) showed a relaxant effect on jejunum contractility while naloxone showed a dual effect inducing an increase of spontaneous contractility at low concentrations (10(-6) M, 10(-7) M, 10(-8) M) and a decrease when high concentrations (10(-3) M, 10(-4) M, 10(-5) M) were utilized. The obtained results demonstrate that mu opioid receptor is expressed in rabbit jejunum and suggest that this receptor may be involved in mediating the effects of both opioid agonist and antagonist on jejunum contractions.     

Identification and characterization of two new human mu opioid receptor splice variants,hMOR-1O and hMOR-1X

The mouse gene encoding the mu opioid receptor, Oprm, undergoes extensive alternatively splicing, with 14 variants having been identified. However, only one variant of human mu opioid receptor gene (Oprm), MOR-1A, has been described. We now report two novel splice variants of the human Oprm gene, hMOR-1O and hMOR-1X. The full-length cDNAs of hMOR-1O and hMO-1X contained the same exons 1, 2, and 3 as the original hMOR-1, but with exon O or exon X as the alternative fourth exon, respectively. Northern blots revealed several bands with the exon O probe in both human neuroblastoma BE(2)C cells and human brain and a single band (5.5kb) with the exon X probe in selected human brain regions. When transfected into CHO cells, both variants showed high selectivity for mu opioids in binding assays. These two new human mu opioid receptors are the first human MOR-1 variants containing new exons and suggest that the complex splicing present in mice may extend to humans.     

Multiple actions of spinophilin regulate mu opioid receptor function

Spinophilin, a dendritic spine-enriched scaffold protein, modulates synaptic transmission via multiple functions mediated by distinct domains of the protein. Here, we show that spinophilin is a key modulator of opiate action. Knockout of the spinophilin gene causes reduced sensitivity to the analgesic effects of morphine and early development of tolerance but a higher degree of physical dependence and increased sensitivity to the rewarding actions of the drug. At the cellular level, spinophilin associates with the mu opioid receptor (MOR) in striatum and modulates MOR signaling and endocytosis. Activation of MOR by opiate agonists such as fentanyl and morphine promotes these events, which feedback to suppress MOR responsiveness. Our findings support a potent physiological role of spinophilin in regulating MOR function and provide a potential new target for the treatment of opiate addiction.     

C-terminal splice variants of the mouse mu-opioid receptor differ in morphine-induced internalization and receptor resensitization

The main analgesic effects of the opioid alkaloid morphine are mediated by the mu-opioid receptor. In contrast to endogenous opioid peptides, morphine activates the mu-opioid receptor without causing its rapid endocytosis. Recently, three novel C-terminal splice variants (MOR1C, MOR1D, and MOR1E) of the mouse mu-opioid receptor (MOR1) have been identified. In the present study, we show that these receptors differ substantially in their agonist-selective membrane trafficking. MOR1 and MOR1C stably expressed in human embryonic kidney 293 cells exhibited phosphorylation, internalization, and down-regulation in the presence of the opioid peptide [d-Ala(2),Me-Phe(4),Gly(5)-ol]enkephalin (DAMGO) but not in response to morphine. In contrast, MOR1D and MOR1E exhibited robust phosphorylation, internalization, and down-regulation in response to both DAMGO and morphine. DAMGO elicited a similar desensitization (during an 8-h exposure) and resensitization (during a 50-min drug-free interval) of all four mu-receptor splice variants. After morphine treatment, however, MOR1 and MOR1C showed a faster desensitization and no resensitization as compared with MOR1D and MOR1E. These results strongly reinforce the hypothesis that receptor phosphorylation and internalization are required for opioid receptor reactivation thus counteracting agonist-induced desensitization. Our findings also suggest a mechanism by which cell- and tissue-specific C-terminal splicing of the mu-opioid receptor may significantly modulate the development of tolerance to the various effects of morphine.     

Morphine regulates gene expression of alpha- and beta-chemokines and their receptors on astroglial cells via the opioid mu receptor

The brain is a target organ for recreational drugs and HIV-1. Epidemiological data demonstrate that opioid abuse is a risk factor for HIV-1 infection and progression to AIDS. Chemokines and their receptors have been implicated in the neuropathogenesis of HIV-1 infections. However, little is known about the effects of opioids on the expression of chemokines and their receptors (the latter also are HIV-1 coreceptors) by cells of the CNS. Herein we describe the effects of morphine on gene expression of the alpha- and beta-chemokines and their receptors by the astrocytoma cell line U87 and by primary normal human astrocyte (NHA) cultures. U87 cells treated with morphine showed significant down-regulation of IL-8 gene expression, whereas expression of the IL-8 receptor CXCR2 was reciprocally up-regulated as detected by RT-PCR. Treatment of NHAs with morphine suppressed IL-8 and macrophage-inflammatory protein-1beta gene expression, whereas expression of their receptor genes, CCR3 and CCR5, was simultaneously enhanced. These morphine-induced effects on U87 and NHA cells were reversed by the opioid mu receptor antagonist beta-funaltrexamine. Morphine also enhanced the constitutive expression of the opioid mu receptor on astroglial cells. Our results support the hypothesis that opioids play a significant role in the susceptibility of the CNS to HIV-1 infection and subsequent encephalopathy by inhibiting local production of HIV-1-protective chemokines (IL-8 and macrophage-inflammatory protein-1beta) and enhancing expression of HIV-1 entry coreceptor genes (CCR3, CCR5, and CXCR2) within the CNS. These effects of opioids appear to be mediated through the opioid mu receptor that we demonstrated on astroglial cells.     

Internalization and recycling of human mu opioid receptors expressed in Sf9 insect cells

Internalization and recycling of G protein-coupled receptors (GPCRs), such as the mu-opioid receptor, largely depend on agonist stimulation. Agonist-promoted internalization of some GPCRs has been shown to mediate receptor desensitization, resensitization, and down-regulation. In this study, we investigated whether different mu opioid agonists displayed different effects in receptor internalization and recycling, the potential mechanisms involved in ohmefentanyl-induced internalization process. In transfected Sf9 insect cells expressing 6His-tagged wild type mu opioid receptor, exposure to 100 nM ohmefentanyl caused a maximum internalization of the receptor at 30 min and receptors seemed to reappear at the cell membrane after 60 min as determined by radioligand binding assay. Ohmefentanyl-induced human mu opioid receptor internalization was concentration-dependent, with about 40% of the receptors internalized following a 30-min exposure to 1 microM ohmefentanyl. 10 microM morphine and 1 microM DAMGO could also induce about 40% internalization. The antagonist naloxone and pretreatment with pertussis toxin both blocked ohmefentanyl-induced internalization without affecting internalization themselves. Incubation with sucrose 0.45 M significantly inhibited ohmefentanyl-induced internalization of the mu receptor. The removal of agonists ohmefentanyl and morphine resulted in the receptors gradually returning to the cell surface over a 60 min period, while the removal of agonist DAMGO only partly resulted in the receptor recycling. The results of this study suggest that ohmefentanyl-induced internalization of human mu opioid receptor in Sf9 insect cells occurs via Gi/o protein-dependent process that likely involves clathrin-coated pits. In addition, the recycling process displays the differential modes of action of different agonists.     

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

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