μ-opioid receptor-mediated inhibition of the release of radiolabelled noradrenaline and acetylcholine from rat amygdala slices

Presynaptic modulation by opioids of electrically-evoked neurotransmitter release from superfused rat amygdala slices prelabelled with [³H]noradrenaline (NA) and [¹⁴C]choline was examined. Both [³H]NA and [¹⁴C]acetylcholine release were strongly inhibited by morphine, the mixed δ/μ-receptor agonist [ -Ala², -Leu⁵]enkephalin (DADLE) and the highly selective μ-agonist [ -Ala², MePhe⁴, Gly-ol⁵]enkephalin (DAMGO), whereas the highly selective δ-agonist [ -Pen², -Pen⁵]enkephalin and the κ-agonist bremazocine were without effect. The inhibitory effects were potently antagonized by naloxone but not by the selective δ-receptor antagonist fentanylisothiocyanate. When the selective uptake inhibitor desipramine was used to prevent uptake of [³H]NA into noradrenergic nerve terminals, but sparing the uptake into dopaminergic nerve terminals, the electrically evoked release of tritium was strongly inhibited by bremazocine but not by DADLE or DAMGO.

The data indicate, that in the amygdala transmitter release from dopaminergic nerve fibres is inhibited only via activation of κ-receptors, whereas transmitter release from noradrenergic and cholinergic nerve fibers is subjected to inhibition by opioids via activation of μ-receptors only. Regional differences and similarities of modulation of neurotransmitter release by opioids in the rat brain are briefly discussed.     

Binding of [H][D-Ala, MePhe, Gly-ol] Enkephalin, [H][D-Pen, D-Pen]Enkephalin, and [H]U-69,593 to Airway and Pulmonary Tissues of Normal and Sensitized Rats

Bhargava, H. N., V. M. Villar, J. Cortijo and E. J. Morcillo. Binding of [³H][D-Ala², MePhe⁴, Gly-ol⁵]enkephalin, [³H][D-Pen², D-Pen⁵]enkephalin, and [³H]U-69,593 to airway and pulmonary tissues of normal and sensitized rats. Peptides 18(10) 1603–1608, 1997.—The role of endogenous opioid peptides in the regulation of bronchomotor tone, as well as in the pathophysiology of asthma is uncertain. We have studied the binding of highly selective [³H]labeled ligands of μ-([D-Ala², MePhe⁴, Gly-ol⁵]enkephalin; DAMGO), δ ([D-Pen², D-Pen⁵]enkephalin; DPDPE), and κ-(U-69,593) opioid receptors to membranes of trachea, main bronchus, lung parenchyma and pulmonary artery obtained from normal (unsensitized) and actively IgE-sensitized rats acutely challenged with the specific antigen. [³H]DAMGO, [³H]DPDPE and [³H]U-69,593 bound to membranes of normal and sensitized tissues at a saturable, single high-affinity site. The rank order of receptor densities in normal tissues was δ- ≥ κ- ≥ μ-, with lung parenchyma exhibiting the greatest binding capacity for δ- and μ- receptors compared to the other regions examined. The K_d values showed small differences between ligands and regions tested. The μ- and δ-opioid receptor densities were decreased in sensitized main bronchus and lung parenchyma, respectively, compared to normal tissues. By contrast, κ-opioid receptor density was augmented in sensitized lung parenchyma but an increase in K_d values was also observed. These differential changes in the density and affinity of opioid receptor types may be related to alterations in endogenous opioid peptides during the process of sensitization.     

Autoradiographic evidence for two classes of mu opioid binding sites in rat brain using [I]FK33824

Previous studies demonstrated that pretreatment of brain membranes with the irreversible mu antagonist, beta-funaltrexamine (beta-FNA), partially eliminated mu binding sites [25,35], consistent with the existence of two mu binding sites distinguished by beta-FNA. This paper tests the hypothesis that the FNA-sensitive and FNA-insensitive mu binding sites have different anatomical distributions in rat brain. Prior to autoradiographic visualization of mu binding sites, [³H]oxymorphone, [³H]D-ala²-MePhe⁴, Gly-ol⁵-enkephalin (DAGO), and [¹²⁵I]D-ala²-Me-Phe⁴-met(o)-ol]enkephalin (FK33824) were shown to selectively label mu binding sites using slide mounted sections of molded minced rat brain. As found using membranes, beta-FNA eliminated only a portion of mu binding sites. Autoradiographic visualization of mu binding sites using the mu-selective ligand [¹²⁵I]FK33824 in control and FNA-treated sections of rat brain demonstrated that the proportion of mu binding sites sensitive to beta-FNA varied across regions of the brain, particularly the dorsal thalamus, ventrobasal complex and the hypothalamus, providing anatomical data supporting the existence of two classes of mu binding sites in rat brain.     

Selective labeling of κ2 opioid receptors in rat brain by [I]IOXY: Interaction of opioid peptides and other drugs with multiple κ2a binding sites

Recent studies from our laboratory resolved two subtypes of the κ₂ binding site, termed κ_2a and κ_2b, using guinea pig, rat, and human brain membranes depleted of μ and δ receptors by pretreatment with the site-directed acylating agents BIT (μ-selective) and FIT (δ-selective). 6β-Iodo-3,14-dihydroxy-17-cyclopropylmethyl-4,5-epoxymorphinan (IOXY), an opioid antagonist that has high affinity for κ₂ sites, was radioiodinated to maximum specific activity (2200 Ci/mmol) and purified by high pressure liquid chromotography and used to characterize multiple κ₂ binding sites. The results indicated that [¹²⁵I]IOXY, like [³H]bremazocine, selectively labels κ₂ binding sites in rat brain membranes pretreated with BIT and FIT. Using 100 nM [ -Ala²-MePhe⁴,Gly-ol⁵]enkephalin to block [¹²⁵I]IOXY binding to the κ_2b site, two subtypes of the κ_2a binding site were resolved, both in the absence and presence of 50 μM 5′-guanylyimidodiphosphate. Viewed collectively, these results provide further evidence for heterogeneity of the κ opioid receptor, which may provide new targets for drug design, synthesis, and therapeutics.     

Probing the opioid receptor complex with (+)-trans-SUPERFIT. II. Evidence that mu ligands are noncompetitive inhibitors of the delta cx opioid peptide binding site.

Previous studies delineated two classes of δ binding sites; a δ binding site not associated with the opioid receptor complex, termed the δ_ncx site, and a δ site associated with the opioid receptor complex, termed the δ_cx site. The δ_ncx site has high affinity for [ -Pen², -Pen⁵]enkephalin, and is synonymous with what is now identified as the δ₁ binding site. Pretreatment of membranes with the δ-selective acylating agents FIT, or (+)-trans-SUPERFIT, deplete membranes of the δ_ncx binding site, which permits the selective labeling of the δ_cx binding site with [³H][ -Ala²,Leu⁵]enkephalin. The present study compared the properties of the δ_cx binding site present in brain membranes pretreated with (+)-trans-SUPERFIT with the properties of the δ_cx site present in untreated membranes. The major findings are: 1) pretreatment of membranes with (+)-trans-SUPERFIT decreased the IC₅₀ values of δ-preferring drugs, and increased the IC₅₀ values of μ-preferring drugs, for the δ_cx binding site; 2) the degree of δ selectivity was highly correlated with the magnitude of the (+)-trans-SUPERFIT-induced shift in the IC₅₀ values; 3) the ligand-selectivity patterns of the μ and δ_cx sites present in (+)-trans-SUPERFIT-pretreated membranes were poorly correlated; 4) whereas μ-preferring drugs were noncompetitive inhibitors of [³H][ -Ala²,Leu⁵]enkephalin binding to the δ_cx site, δ-preferring drugs were competitive inhibitors. Viewed collectively, these data support the hypothesis that the μ and δ_cx binding sites are distinct, provide additional evidence for δ receptor heterogeneity, and suggest that ( (+)-trans-SUPERFIT-pretreated membranes will provide a useful preparation for studying the δ_cx binding site.     

An analysis of GABA receptor changes in the discrete regions of mouse brain after acute and chronic treatments with morphine

Abstract: The effects of morphine on the affinity and distribution of GABA receptors in the mouse regions (striatum, medulla, diencephalon, cortex, and cerebellum) were investigated in relation to: (a) acute administration, (b) chronic administration (tolerance), (c) precipitated withdrawal by naloxone, an opiate antagonist, and (d) abrupt withdrawal for 8 and 24 h. The alterations in the affinity as reflected by the dissociation constant (K_D) and the number of receptors (B_max) in the synaptic membranes obtained from controls and various treatments were determined by radioligand binding assay using [³H]muscimol as a ligand. Significant changes were observed in striatum, medulla, and diencephalon, whereas other regions including whole brain exhibited marginal changes. In general the number of GABA receptors increased after tolerance development, which upon abrupt withdrawal returned to control levels except in the case of naloxone-induced precipitated withdrawal. The affinity changes in different regions were diverse in nature and were not evident in the whole brain membranes. These results indicate that: (a) the regional alterations in the affinity and distribution of GABA receptors may play a role in the induction, maintenance, and regression of morphine tolerance; (b) abrupt withdrawal and antagonist precipitated withdrawal affect the GABA system differently, (c) chronic morphine treatment appears to influence the GABA receptors in the cerebellum, a region generally known for its lack of opiate receptors.     

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

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

Release of Neuropeptide FF, an Anti-Opioid Peptide, in Rat Spinal Cord Slices Is Voltage- and Ca2+-Sensitive: Possible Involvement of P-Type Ca2+ Channels

Abstract: Neuropeptide FF (NPFF), an FMRFamide-like peptide with antiopioid properties, inhibits morphine-induced analgesia but also produces hyperalgesia. In the present study, the mechanisms of NPFF release were investigated in an in vitro superfusion system with rat spinal cord slices. The opening of voltage-sensitive Na⁺ channels with veratridine (20 µ M ) induced calcium-dependent NPFF release, which was abolished by tetrodotoxin (1 µ M ), suggesting that NPFF release depends on nerve impulse activity. We also showed that NPFF release was a function of the extent of depolarization and was calcium dependent. The 30 m M K⁺-induced release was blocked by Co²⁺ or Ni²⁺ (2.5 m M ) but was unaffected by Ca²⁺ channel blockers of the L type—Cd²⁺ (100 µ M ), nifedipine or nimodipine (10 µ M ), diltiazem (20 µ M ), or verapamil (50 µ M )—or the N type—ω-conotoxin GVIA (1 µ M ). In contrast, ω-agatoxin IVA (1 µ M ) led to a 65% reduction in NPFF release, suggesting that P-type Ca²⁺ channels play a prominent role. The 35% remaining release resulted from activation of an unknown subtype. The NPFF-like material in superfusates recognized spinal NPFF receptors, suggesting that NPFF release in the spinal cord has a physiological role.     

μ Receptors and opioid cardiovascular effects in the NTS of rat

In order to assess the potential role of mu (μ) and delta (δ) opiate receptors in the central regulation of the cardiovascular and respiratory systems, the cardiovascular and respiratory effects of the relatively selective μ-opioid agonist D-Ala², MePhe⁴, Gly-ol⁵ enkephalin (DAGO) and relatively selective δ-agonist D-Ala²-D-Leu⁵ enkephalin (DADL) were compared following microinjection of these compounds into the nucleus tractus solitarius of pentobarbital-anesthetized rats. Both opioid agonists produced dose dependent increases in systolic and diastolic blood pressure as well as heart rate; but DAGO was nearly ten times more potent in eliciting these changes. Respiratory rate was increased by DADL and by lower doses of DAGO, but was depressed by higher doses of DAGO. Tidal volume was depressed by both peptides. These data support the concept that the cardiovascular pressor responses and tachycardia as well as the respiratory effects of opioids in the rat NTS are mediated by μ receptors.     

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

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

Antinociception, tolerance and withdrawal symptoms induced by 7-hydroxymitragynine, an alkaloid from the Thai medicinal herb Mitragyna speciosa

7-Hydroxymitragynine is a potent opioid analgesic alkaloid isolated from the Thai medicinal herb Mitragyna speciosa. In the present study, we investigated the opioid receptor subtype responsible for the analgesic effect of this compound. In addition, we tested whether development of tolerance, cross-tolerance to morphine and naloxone-induced withdrawal signs were observed in chronically 7-hydroxymitragynine-treated mice. Subcutaneous (s.c.) administration of 7-hydroxymitragynine produced a potent antinociceptive effect mainly through activation of mu-opioid receptors. Tolerance to the antinociceptive effect of 7-hydroxymitragynine developed as occurs to morphine. Cross-tolerance to morphine was evident in mice rendered tolerant to 7-hydroxymitragynine and vice versa. Naloxone-induced withdrawal signs were elicited equally in mice chronically treated with 7-hydroxymitragynine or morphine. 7-Hydroxymitragynine exhibited a potent antinociceptive effect based on activation of mu-opioid receptors and its morphine-like pharmacological character, but 7-hydroxymitragynine is structurally different from morphine. These interesting characters of 7-hydroxymitragynine promote further investigation of it as a novel lead compound for opioid studies.     

Interaction of opioid peptides and other drugs with multiple delta ncx binding sites in rat brain: further evidence for heterogeneity.

Recent pharmacological data strongly support the hypothesis of δ receptor subtypes as mediators of both supraspinal and spinal antinociception (δ₁ and δ₂ receptors). In vitro ligand binding data, which are fully supportive of the in vivo data, are still lacking. A previous study indicated that [³H][ -Ala², -Leu⁵]enkephalin labels two binding sites in membranes depleted of μ binding sites by pretreatment with the site-directed acylating agent, 2-(p-ethoxybenzyl)-1-diethylaminoethyl-5-isothiocyanatobenzimidazole-HCI (BIT). The main goal of the present study was to develop a ligand-selectivity profile of the two δ_ncx binding sites. The data indicated that naltrindole and oxymorphindole were relatively selective for site 1 (20-fold). [ -Ser²,Thr⁶]Enkephalin and deltorphin-II were only 2.7-fold and 2.2-fold selective for site 1. [ -Pen², -Pen⁵]Enkephalin and deltorphin-I were 80-fold and 38-fold selective for site 2.3-Iodo-Tyr- -Ala-Gly-Phe- -Leu was 52-fold selective for site 1. Morphine had moderate affinity for site 1 (K_i = 16 nM), and was about 11-fold selective for site 1. Thus, of the 10 drugs studied, only DPDPE and DELT-I were selective for site 2. Viewed collectively with other data, it is likely that the δ₁ receptor and the δ_ncx binding site are synonymous.     

Potentiation of opioid analgesia by cocaine: the role of spinal and supraspinal receptors.

These studies examined the effect of cocaine on the analgesia produced by systemically and centrally administered opioid agonists. Cocaine (50 mg/kg, s.c.) increased the analgesic potency of systemic, ICV and IT morphine; and the ICV and IT analgesic effects of the delta selective peptide, [D-Pen2,D-Pen5]enkephalin (DPDPE). Cocaine also increased the analgesic potency of the mu selective ligand [D-Ala2,NMePhe4,Gly-ol5]enkephalin (DAGO) administered ICV. However, cocaine did not alter the ED50 for IT DAGO. GC-MS studies indicated that brain cocaine concentration was approximately 3.0 micrograms/g wet weight 45 min following s.c. administration. These results suggest that cocaine-induced increases in opioid analgesic potency are mediated at brain mu and delta receptors and spinal mu receptors. Furthermore, there might be functional differences between spinal and supraspinal sites at which DAGO produces analgesia.     

In Vitro and In Vivo Expression of Opioid and σ Receptors in Rat C6 Glioma and Mouse N18TG2 Neuroblastoma Cells

Abstract: Mouse N18TG2 neuroblastoma and rat C6 glioma cell lines were injected into male nude mice, and the tumors were passaged serially. At each generation, tumors were analyzed for δ opioid binding using [³H][ d -Ala², d -Leu⁵]enkephalin and for σ₁ and σ₂ binding with 1,3-[³H]di- o -tolylguanidine in the presence and absence of 1 µ M pentazocine. Receptor density ( B _max) and affinity ( K _D) were estimated by homologous competition binding assays. Opioid and σ B _max values in the solid tumors were significantly lower than their original levels in vitro. K _D values for opioid/σ ligands were similar in vitro and in vivo. With successive passages in the murine host, δ opioid and σ₁ binding of the neuroblastoma-derived solid tumors became undetectable. In contrast, σ₂ receptor B _max values were unchanged with successive passages of the neuroblastoma-derived tumors and doubled in the nude mouse-borne gliomas. When neuroblastoma-derived solid tumors that were devoid of δ opioid binding were returned to culture, opioid receptors appeared to be up-regulated as compared with their original in vitro levels. Serial passaging of these recultured cells in vivo again resulted in a rapid decline in opioid receptor content. The opioid data are consistent with our prior findings on opioid binding diminution in human brain tumors. The pattern of change for σ binding was more complex, with the σ₂ response in late passages of the glioma being reminiscent of the formerly observed increase in number of σ sites in transformed human meninges, kidney, and colon tissue.     

Inhibition of mu and delta but not kappa opioid binding to membranes by Fab fragments from a monoclonal antibody directed against the opioid receptor

Fab fragments from a monoclonal antibody, OR-689.2.4, directed against the opioid receptor, selectively inhibited opioid binding to rat and guinea pig neural membranes. In a titratable manner, the Fab fragments noncompetitively inhibited the binding of the mu selective peptide [D-Ala2,(Me)Phe4,Gly(OH)5][3H] enkephalin and the delta selective peptide [D-Pen2,D-Pen5] [3H]enkephalin (where Pen represents penicillamine) to neural membranes. In contrast, kappa opioid binding, as measured by the binding of [3H]bremazocine to rat neural membranes and guinea pig cerebellum in the presence of mu and delta blockers, was not significantly altered by the Fab fragments. In addition to blocking the binding of mu and delta ligands, the Fab fragments displaced bound opioids from the membranes. When mu sites were blocked with [D-Ala2,(Me)Phe4,Gly(OH)5]enkephalin, the Fab fragments suppressed the binding of [D-Pen2,D-Pen5][3H]enkephalin to the same degree as when the mu binding site was not blocked. The Fab fragments also inhibited binding to the mu site regardless of whether or not the delta site was blocked with [D-Pen2,D-Pen5]enkephalin. This monoclonal antibody is directed against a 35,000-dalton protein. Since the antibody is able to inhibit mu and delta binding but not kappa opioid binding, it appears that this 35,000-dalton protein is an integral component of mu and delta opioid receptors but not kappa receptors.     

Effects of morphine administration and its withdrawal on rat brain aminopeptidase activities

The endogenous opioid neuropeptide system seems to be involved in the neural processes which underlie drug addiction. Several studies have reported that the administration of morphine induces changes in the levels and/or activity of endogenous opioid peptides (enkephalin, dynorphin) and their precursors in specific brain regions of the adult CNS. The aim of this work was to study the effects of chronic morphine exposure and its withdrawal on certain aminopeptidases capable of degrading opioid peptides in brain areas including the amygdala, hypothalamus, hippocampus, striatum and brain cortices. In animals treated with morphine, aminopeptidase N presented higher enzyme activity levels in the striatum, the hypothalamus and the amygdala compared to control animals, although statistically significant differences were observed only in the case of the striatum. In addition, the activity of soluble puromycin-sensitive aminopeptidase (PSA) was found to be higher in the frontal cortex of these rats. In contrast, rats experiencing withdrawal symptoms presented decreased levels of aminopeptidase activity in certain brain areas. Thus, the activity of aminopeptidase N in the hippocampus and soluble puromycin-sensitive aminopeptidase in the frontal cortex were found to be lower in rats experiencing naloxone precipitated withdrawal symptoms, compared to the corresponding controls. Finally, the activity of the three studied aminopeptidases in vitro was unaltered by incubation with morphine, suggesting that the observed effects are not due to a direct action of this opioid upon the aminopeptidases. The results of the present report indicate that aminopeptidases may play an important role in the processes of tolerance and withdrawal associated with morphine administration.     

RGS14 prevents morphine from internalizing Mu-opioid receptors in periaqueductal gray neurons

Opioid agonists display different capacities to stimulate mu-opioid receptor (MOR) endocytosis, which is related to their ability to provoke the phosphorylation of specific cytosolic residues in the MORs. Generally, opioids that efficiently promote MOR endocytosis and recycling produce little tolerance, as is the case for [d-Ala², N-MePhe⁴,Gly-ol⁵] encephalin (DAMGO). However, morphine produces rapid and profound antinociceptive desensitization in the adult mouse brain associated with little MOR internalization. The regulator of G-protein signaling, the RGS14 protein, associates with MORs in periaqueductal gray matter (PAG) neurons, and when RGS14 is silenced morphine increased the serine 375 phosphorylation in the C terminus of the MOR, a GRK substrate. Subsequently, these receptors were internalized and recycled back to the membrane where they accumulated on cessation of antinociception. These mice now exhibited a resensitized response to morphine and little tolerance developed. Thus, in morphine-activated MORs the RGS14 prevents GRKs from phosphorylating those residues required for β-arresting-mediated endocytosis. Moreover morphine but not DAMGO triggered a process involving calcium/calmodulin-dependent kinase II (CaMKII) in naïve mice, which contributes to MOR desensitization in the plasma membrane. In RGS14 knockdown mice morphine failed to activate this kinase. It therefore appears that phosphorylation and internalization of MORs disrupts the CaMKII-mediated negative regulation of these opioid receptors.     

Attenuation of morphine tolerance and dependence by alpha-melanocyte stimulating hormone(alpha-MSH).

Repeated administration of morphine resulted in significant reduction of its analgesic potency. If 0.1 mg/kg α-MSH was coadministered, the tolerance development was attenuated, 1 mg/kg MIF (MSH release inhibiting factor), given simultaneously with morphine, did not affect tolerance. Injecting, however, MIF 1 hour prior to the daily opiate treatment resulted in accelerated development of tolerance supposedly by lowering the plasma α-MSH level at the time of morphine administration. Of the morphine abstinence symptoms the naloxone-induced jumping in morphine pretreated mice could not be modified either by α-MSH coadministration or by MIF pretreament, but the withdrawal body weight loss was found to be diminished by the former and increased by the latter peptide. The possible role of α-MSH in preventing the development of tolerance to the analgesic effect of endogenous opioid peptides is discussed.     

Modulation of naloxone-precipitated morphine withdrawal syndromes in rats by neuropeptide FF analogs

Neuropeptide FF (NPFF) has been reported to be an endogenous anti-opioid peptide that has significant effects on morphine tolerance and dependence. In the present study, we examined the chronic effects of NPFF and its synthetic analogs: the putative agonist, PFRFamide, and the putative antagonists, dansyl-PQRamide and PFR(Tic)amide on naloxone-precipitated morphine withdrawal syndromes in rats. After a 5-day co-administration with morphine [5 mg/kg, intraperitoneally (i.p.), twice per day (b.i.d.)] and the tested peptide [intracerebroventricularly (i.c.v.) or i.p., b.i.d.], naloxone (4 mg/kg, i.p.) was given systemically to evaluate the severity of the morphine withdrawal syndromes. Our results revealed that NPFF significantly potentiated the overall morphine withdrawal syndromes and, on the contrary, dansyl-PQRamide attenuated these syndromes. These results clearly indicate that modulation of the NPFF system in the mammalian central nervous system has significant effects on opiate dependence. In addition, morphine withdrawal syndromes could be practically applied as a valid parameter to functionally characterize the putative NPFF agonists and antagonists.