Comparison of mu, delta, and kappa opiate binding sites in rat brain and spinal cord

The binding characteristics of mu, delta, and kappa opiate sites were studied in rat brain and spinal cord membrane homogenates. Scatchard analysis of 3H-Dihydromorphine, 3H-D-Ala2-D-Leu5-Enkephalin (in the presence of morphiceptin), and 3H-Ethylketocyclazocine (in the presence of morphiceptin and D-Ala2-D-Leu5-Enkephalin) binding sites revealed similar high affinities of these ligands for their respective sites in brain and spinal cord. The majority of binding in brain and spinal cord was attributed to mu and delta sites, with only about 10% of the combined total binding capacity being kappa.     

Dynorphin: potent analgesic effect in spinal cord of the rat

Evidence is presented to show a strong and long-lasting analgesic effect after injection of dynorphin into the subarachnoid space of the spinal cord of the rat. Calculating on a molar basis dynorphin was 6-10 times more potent than morphine and 65-100 times more potent than morphiceptin, the specific mu receptor agonist. Dynorphin analgesia was completely reversed by intrathecal injection of anti-dynorphin IgG and partially reversed by naloxone. Acute tolerance to morphine analgesia did not affect the occurrence of dynorphin analgesia. Evidence from different lines of approach suggest that dynorphin may bind with kappa receptors in the spinal cord to exert its analgesic effect.     

Characterization of opioid receptors on isolated canine gallbladder smooth muscle cells

Smooth muscle cells were isolated from the fundus of the canine gallbladder and examined for the presence of opioid receptors. The cells contracted in a concentration-dependent manner in response to three opioid peptides (Met-enkephalin, dynorphin1-13 and Leu-enkephalin), which are known derivatives of opioid precursors present in myenteric neurons of the gut. The order of potency was Met-enkephalin greater than dynorphin1-13 greater than Leu-enkephalin. The contractile response to opioid agonists was selectively inhibited by opioid antagonists (naloxone and Mr2266) but not by muscarinic, CCK/gastrin or tachykinin antagonists. Equivalent responses to the three opioid peptides exhibited differential sensitivity to preferential antagonists of mu (naloxone) and kappa (Mr2266) opioid receptors consistent with the presence of the three main types of opioid receptors (mu, delta and kappa) on canine gallbladder muscle cells.     

Selective activation of opioid receptors differentially affects lordosis behavior in female rats

The effects of opioid peptides that are highly selective ligands for mu receptors (morphiceptin). delta receptors (delta-receptor peptide), kappa receptors (dynorphin 1-9), and the mu/delta complex (beta-endorphin), were tested on lordosis behavior in ovariectomized rats primed with estrogen and progesterone. Intracerebroventricular infusions of beta-endorphin or morphiceptin both inhibited and facilitated lordosis in a dose-dependent fashion whereas all doses of delta-receptor peptide facilitated lordosis. Dynorphin 1-9 had no significant effect at any dose, although a trend toward increased lordosis quotients was observed 30 min after infusion. The effects of beta-endorphin, morphiceptin, and delta-receptor peptide were reversed with naloxone, although naloxone alone had no effect on lordosis behavior. These results indicate that the specific activation of opioid receptor subtypes differentially affects lordosis behavior. It appears that binding to high-affinity mu 1 receptors exerts an inhibitory influence on lordosis, whereas binding to low-affinity mu 2 receptors or delta receptors exerts a facilitatory influence. Binding to kappa receptors does not appear to affect lordosis behavior.     

Further studies on opioids and hibernation: delta opioid receptor ligand selectively induced hibernation in summer-active ground squirrels

To examine the possible involvement of multiple opioid receptors in animal hibernation, we infused opioids selective for mu, kappa, and delta opioid receptors into summer-active ground squirrels (Citellus tridecemlineatus). The effects of those opioid treatments on the hibernation induced by HIT (Hibernation Induction Trigger) were also examined. Mu opioids morphine (1.50 mg/kg/day) and morphiceptin (0.82 mg/kg/day) and kappa opioid peptide dynorphin A (0.82 mg/kg/day) did not induce hibernation. On the contrary, morphine, morphiceptin and dynorphin A antagonized HIT-induced hibernation in summer-active ground squirrels. Infusion of delta opioid DADLE (D-Ala2-D-Leu5 enkephalin; 1.50 mg/kg/day), however, induced summer hibernation in a manner comparable to that induced by HIT. It is concluded therefore that delta opioid receptor and its ligand may be intimately involved in animal hibernation. In view of the fact that HIT was obtained from winter hibernating animals and might therefore be responsible for natural hibernation, our results also suggest that naturally occurring mu and kappa opioids may play an important role in the arousal state of hibernation.     

Exploration of universal cysteines in the binding sites of three opioid receptor subtypes by disulfide-bonding affinity labeling with chemically activated thiol-containing dynorphin A analogs.

A ligand containing an SNpys group, i.e. 3-nitro-2-pyridinesulfenyl linked to a mercapto (or thiol) group, can bind covalently to a free mercapto group to form a disulfide bond via the thiol-disulfide exchange reaction. This SNpys chemistry has been successfully applied to the discriminative affinity labeling of mu and delta opioid receptors with SNpys-containing enkephalins [Yasunaga, T. et al. (1996) J. Biochem. 120, 459-465]. In order to explore the mercapto groups conserved at or near the ligand binding sites of three opioid receptor subtypes, we synthesized two Cys(Npys)-containing analogs of dynorphin A, namely, [D-Ala2, Cys(Npys)8]dynorphin A-(1-9) amide (1) and [D-Ala2, Cys(Npys)12]dynorphin A-(1-13) amide (2). When rat (mu and delta) or guinea pig (kappa) brain membranes were incubated with these Cys(Npys)-containing dynorphin A analogs and then assayed for inhibition of the binding of DAGO (mu), deltorphin II (delta), and U-69593 (kappa), the number of receptors decreased sharply, depending upon the concentrations of these Cys(Npys)-containing dynorphin A analogs. It was found that dynorphin A analogs 1 and 2 effectively label mu receptors (EC50 = 27-33 nM), but also label delta receptors fairly well (160-180 nM). However, for kappa receptors they showed drastically different potencies as to affinity labeling; i.e., EC50 = 210 nM for analog 1, but 10,000 nM for analog 2. Analog 2 labeled kappa receptors about 50 times more weakly than analog 1. These results suggested that dynorphin A analog 1 labels the Cys residues conserved in mu, delta, and kappa receptors, whereas analog 2 only labels the Cys residues conserved in mu and delta receptors.     

Differential effects of opioid receptor agonists on nociception and cAMP level in the spinal cord of monoarthritic rats.

Changes in functional responsiveness of spinal opioid receptors in monoarthritic rats were investigated at the behavioral and the molecular level. After intrathecal administration of morphine, D-Ala2-D-Leu5-enkephalin (DADLE), D-Pen2-D-Pen5-enkephalin (DPDPE) and dynorphin monoarthritic rats showed an enhanced antinociceptive response as measured by a tail-flick latency. No such changes were observed following administration of the selective kappa agonists U50,488H and U69,593. The opioid mu and delta receptor agonists (0.1-1.0 microM) inhibited the basal, as well as the forskolin-stimulated cAMP formation in spinal cord slices obtained from monoarthritic rats, whereas no significant changes were found in control animals. Higher concentrations of the mu and delta opioid receptor agonists were required to attenuate the cAMP level in spinal cord of control animals. The selective kappa agonists U50,488H and U69,593 did not influence the cAMP formation in monoarthritic or control animals. Additionally, we found that the GppNHp-stimulated level of cAMP was higher in the spinal cord slices of monoarthritic rats, which points to an enhanced responsiveness of the adenylate cyclase effector system to the action of this GTP analog. Our data suggest that the enhanced antinociceptive response to intrathecally administered opioids in monoarthritic rats may be connected with the increased sensitivity of adenylate cyclase to the inhibitory effects of mu and delta agonists.     

Involvement of spinal kappa opioid receptors in the antagonistic effect of dynorphins on morphine antinociception.

The modulatory effects of intrathecally (i.t.) administered dynorphin A(1-17) and dynorphin A(1-13) on morphine antinociception have been studied previously in rats by other investigators. However, both potentiating and attenuating effects have been reported. In this study, the modulatory effects of i.t. administered dynorphin A(1-17) as well as the smaller fragment, dynorphin A(1-8), were studied in mice. In addition, nor-binaltorphimine (nor-BNI), a highly selective kappa opioid receptor antagonist, and naltrindole (NTI), a highly selective delta opioid receptor antagonist, were used to characterize the possible involvement of spinal kappa and delta opioid receptors in the modulatory effects of the dynorphins. Dynorphin A(1-17) and dynorphin A(1-8) administered i.t. at doses that did not alter tail-flick latencies, were both able to antagonize in a dose-dependent manner, the antinociceptive action of s.c. administered morphine sulfate. The antinociceptive ED50 of morphine sulfate was increased 3.9- and 5.3-fold by 0.4 nmol/mouse of dynorphin A(1-17) and dynorphin A(1-8), respectively. Injections of 0.4 and 0.8 nmol/mouse of nor-BNI i.t., but not its inactive enantiomer (+)-1-nor-BNI, inhibited dose-dependently the antagonistic effects of the dynorphins. These doses of nor-BNI alone did not affect the antinociceptive action of morphine sulfate. Intrathecal administration of 5 nmol/mouse of NTI also did not affect the modulatory effects of dynorphins. These observations that dynorphins exert their antagonistic effects on morphine-induced antinociception stereoselectively through spinal kappa opioid receptors may suggest a coupling between spinal kappa and mu opioid receptors.     

Analgesia induced by intrathecal injection of dynorphin B in the rat

A dose-dependent analgesic effect of intrathecally injected dynorphin B was observed in rats using the tail flick as nociceptive test. Intrathecal injection of 20 nmol of dynorphin B increased the tail flick latency by 90 +/- 23%, an effect that lasted about 90 min. For the same degree of analgesia, dynorphin B was 50% more potent than morphine on a molar basis. The analgesic effect of this dose of dynorphin B was partially blocked by 10 mg/kg, but not by 1 mg/kg, of subcutaneous naloxone, showing a relative resistance to naloxone reversal as compared with morphine analgesia. The analgesia produced by dynorphin B was unchanged in morphine-tolerant rats but was significantly decreased in rats tolerant to ethylketazocine. These results suggest that dynorphin B produces its potent analgesic effect by activation of kappa rather than mu opioid receptors in the rat spinal cord.     

Distribution Pattern of Metorphamide Compared with Other Opioid Peptides from Proenkephalin and Prodynorphin in the Bovine Brain

Metorphamide is a [Met]-enkephalin-containing opioid octapeptide with a C-terminal alpha-amide group. It is derived from proenkephalin and is, so far, the only endogenous opioid peptide with a particularly high affinity for mu opioid (morphine) receptors, a somewhat lesser affinity for kappa opioid receptors, and a relatively low affinity for delta opioid receptors. The concentrations of metorphamide in the bovine caudate nucleus, the hypothalamus, the spinal cord, and the neurointermediate pituitary were determined by radioimmunoassay and chromatography separation procedures. Metorphamide concentrations were compared with the concentrations of eight other opioid peptides from proenkephalin and prodynorphin in identical extracts. The other opioid peptides were [Met]-enkephalyl-Arg6-Phe7 and [Met]-enkephalyl-Arg6-Gly7-Leu8 from proenkephalin; alpha-neoendorphin, beta-neoendorphin, dynorphin A(1-8), dynorphin A(1-17), and dynorphin B from prodynorphin; and [Leu]-enkephalin, which can be derived from either precursor. All opioid peptides were present in all four bovine neural tissues investigated. Metorphamide concentrations were lower than the concentrations of the other proenkephalin-derived opioid peptides. They were, however, similar to the concentrations of the prodynorphin-derived opioid peptides in the same tissues. Marked differences in the relative ratios of the opioids derived from prodynorphin across brain regions were observed, a finding suggesting differential posttranslational processing. Differences in the ratios of the proenkephalin-derived opioids across brain regions were less pronounced. The results from this study together with previous findings on metorphamide's mu opioid receptor binding and bioactivities suggest that the amounts of metorphamide in the bovine brain are sufficient to make this peptide a candidate for a physiologically significant endogenous mu opioid receptor ligand.     

The regulation of steroidogenesis by opioid peptides in porcine theca cells

The present study was designed to investigate basal and LH-induced steroidogenesis in porcine theca cells from large follicles in response to various concentrations (1-1000 nM) of mu opioid receptor agonists (beta-endorphin, DAMGO, FK 33-824), delta receptor agonists (met-enkephalin, leu-enkephalin, DPLPE) and kappa receptor agonists (dynorphin A, dynorphin B, U 50488). Agonists of mu opioid receptors suppressed basal androstenedione (A4), testosterone (T) and oestradiol-17beta (E2) secretion and enhanced LH-induced A4 and T release by theca cells. The inhibitory effect of the agonists on E2 secretion was abolished in the presence of LH. All delta receptor agonists depressed basal progesterone (P4) output. However, the influence of these agents on LH-treated cells was negligible. Among delta receptor agonist used only leu-enkephalin and DPLPE at the lowest concentrations inhibited basal A4 release. The presence of LH in culture media changed the influence of these opioids from inhibitory to stimulatory. Similarly, DPLPE reduced T secretion by non-stimulated theca cells and enhanced T secretion of stimulated cells. All of delta agonists inhibited basal E2 secretion and unaffected its release from LH-treated theca cells. Agonists of kappa receptors inhibited basal, non-stimulated, P4 secretion and two of them (dynorphin B, U 50488) potentiated LH-induced P4 output. Basal A4 and T release remained unaffected by kappa agonist treatment, but the cells cultured in the presence of LH generally increased both androgen production in response to these opioids. Basal secretion of E2 was also suppressed by kappa agonists. This inhibitory effect was not observed when the cells were additionally treated with LH. In view of these findings we suggest that opioid peptides derived from three major opioid precursors may directly participate in the regulation of porcine theca cell steroidogenesis.     

Opioid receptors in the rat spinal cord after longlasting deafferentation.

In vitro binding of specific opioid ligands to their respective sites in membrane fractions and the contribution of individual receptor classes (mu, delta, kappa) was studied in rats after longlasting (up to 22 months) section of spinal dorsal roots at the cervical (C5-8) or thoracic (Th1-4) level. This procedure leads to autotomy or scratching of the skin on the operated side. The total number of receptors in the cervical and thoracic spinal cord was more than doubled in both operated and contralateral part of the cord in comparison with intact controls of the same age. In the cervical region, this increase mainly represented a rise in the number of free receptors, whilst in the thoracic region both free and saturated receptors were increased. On the deafferented side, receptor selectivity, especially in the delta and kappa types was decreased.     

High and low frequency electroacupuncture analgesia are mediated by different types of opioid receptors at spinal level: a cross tolerance study

Previous studies have shown that rats subjected to low or high frequency electroacupuncture (EA) stimulation release enkephalins or dynorphins respectively to produce analgesia. This conclusion was tested in the present study by using cross tolerance technique for further analysing their receptor mechanisms. The main results were as follows: (1) In rats subjected to 2 Hz EA for 6 h, there was a gradual decrease in the analgesic effect, leading to a state of tolerance to 2 Hz EA analgesia. These rats, however, still responded to 100 Hz EA. Likewise, rats made tolerant to 100 Hz EA were still effective to 2 Hz EA stimulation, showing not significant cross tolerance between 2 Hz and 100 Hz EA analgesia. (2) Rats made-tolerant to 100 Hz EA analgesia showed a diminished response to intrathecal dynorphin A (1-13), a kappa agonist, whereas the analgesic effect of the delta agonist [D-Pen2, D-pen5] enkephalin (DPDPE) remained intact. (3) Rats made tolerant to 2 Hz EA analgesia showed a cross tolerance to DPDPE, but not to dynorphin A (1-13). Results obtained from aforementioned cross tolerance studies suggest that 2 Hz and 100 Hz EA analgesia are mediated by delta and kappa opioid receptors, respectively, at the spinal cord of the rat.     

Opioid pharmacology in the rat hippocampal slice

The ability of several opioids in potentiating the synaptic activation of CA1 pyramidal cells in the rat hippocampal slice were compared. Morphine and the opioid peptides, (D-ala2, D-leu5)-enkephalin (DADL), morphiceptin, beta-endorphin, and Tyr-D-Ser-Gly-Phe-Leu-Thr (DSThr) caused a concentration-dependent, naloxone-reversible shift to the left in the input-output (IO) curve constructed by plotting the population spike as a function of the field EPSP. These opioids then produced an increase in the size of the population spike while leaving the EPSP unaffected. In contrast, the kappa agonist prototype, ethylketazocine, had no effect on the IO curve when perfused in concentrations up to 10 microM. The rank order of potency for the opioids in the CA1 region of the hippocampus was DADL greater than DSThr greater than beta-endorphin greater than morphiceptin greater than morphine much greater than ethylketazocine. Thus, opioids that are more specific for delta opiate receptors were the most potent and mu receptor agonists, the least potent in this action. Taken together with previous studies suggesting that morphine and DADL may interact with a common opiate receptor in the CA1 region, the results are consistent with the notion that these epileptiform effects may be primarily mediated by delta opiate receptors in this area although the potency of morphiceptin indicates that mu receptors play some role in this effect.     

Dynorphin A analogs containing a conformationally constrained phenylalanine derivative in position 4: reversal of preferred stereochemistry for opioid receptor affinity and discrimination of kappa vs. delta receptors

Analogs of the opioid peptide [D-Ala8]dynorphin A-(1-11)NH2 containing optically pure (R)- and (S)-2-aminotetralin-2-carboxylic acid (Atc) in position 4 were synthesized and evaluated for opioid receptor affinity. These peptides are the first reported dynorphin A analogs containing a conformationally constrained amino acid in place of the important aromatic residue Phe4. By incorporating resolved Atc isomers, the opioid receptor affinity and the stereochemistry of the constrained residue could be unambiguously correlated. Both Dyn A analogs containing Atc in position 4 retained nanomolar affinity for kappa and mu opioid receptors. Unexpectedly the peptide containing (R)-Atc, corresponding to a conformationally constrained D-Phe analog, displaying higher affinity for both kappa and mu receptors than the peptide containing (S)-Atc. In contrast [D-Phe4,D-Ala8]Dyn A-(1-11)NH2 exhibited significantly lower affinity for kappa and mu receptors than the parent peptide, as expected. Conformational restriction of the Phe4 sidechain or incorporation of D-Phe in position 4 had the largest effect on delta receptor affinity, yielding compounds with negligible affinity for these receptors. Thus, there appear to be distinctly different structural requirements for this residue for kappa vs. delta receptors, and it is possible to completely distinguish between these two receptors by changing a single residue in Dyn A.     

Discrete mapping of brain Mu and delta opioid receptors using selective peptides: quantitative autoradiography, species differences and comparison with kappa receptors

The opioid peptides, [3H]DAGO and [3H]DPDPE, bound to rat and guinea pig brain homogenates with a high, nanomolar affinity and to a high density of mu and delta receptors, respectively. [3H]DAGO binding to mu receptors was competitively inhibited by unlabelled opioids with the following rank order of potency: DAGO greater than morphine greater than DADLE greater than naloxone greater than etorphine much greater than U50488 much greater than DPDPE. In contrast, [3H]DPDPE binding to delta receptors was inhibited by compounds with the following rank order of potency: DPDPE greater than DADLE greater than etorphine greater than dynorphin(1-8) greater than naloxone much greater than U50488 much greater than DAGO. These profiles were consistent with specific labelling of the mu and delta opioid receptors, respectively. In vitro autoradiographic techniques coupled with computer-assisted image analyses revealed a discrete but differential anatomical localization of mu and delta receptors in the rat and guinea pig brain. In general, mu and delta receptor density in the rat exceeded that in the guinea pig brain and differed markedly from that of kappa receptors in these species. However, while mu receptors were distributed throughout the brain with "hotspots" in the fore-, mid- and hindbrain of the two rodents, the delta sites were relatively diffusely distributed, and were mainly concentrated in the forebrain with particularly high levels within the olfactory bulb (OB), n. accumbens and striatum. Notable regions of high density of mu receptors in the rat and guinea pig brain were the accessory olfactory bulb, striatal "patches" and "streaks," amygdaloid nuclei, ventral hippocampal subiculum and dentate gyrus, numerous thalamic nuclei, geniculate bodies, central grey, superior and inferior colliculi, solitary and pontine nuclei and s. nigra. Tissues of high delta receptor concentration included, OB (external plexiform layer), striatum, n. accumbens, amygdala and cortex (layers I-II and V-VI). Delta receptors in the guinea pig were, in general, similarly distributed to the rat, but in contrast to the latter, the hindbrain regions such as the thalamus, geniculate bodies, central grey and superior and inferior colliculi of the guinea pig were apparently more enriched than the rat. These patterns of mu and delta site distribution differed dramatically from that of the kappa opioid sites in these species studied with the peptide [125I]dynorphin(1-8).     

Involvement of kappa/dynorphin system in the development of tolerance to nicotine-induced antinociception

The aim of the present study was to explore the possible role of kappa/dynorphin system in the development of tolerance to nicotine antinociception in mice. First, we observed that kappa-opioid receptor (KOP-r) participates in the acute spinal antinociception produced by nicotine (3 and 5 mg/kg, s.c.) since the pre-treatment with the selective kappa antagonist nor-binaltorphimine (3 mg/kg, i.p.) attenuated this response in the tail-immersion test but not in the hot-plate test nor in locomotor responses. Possible changes in the expression of KOP-r were investigated in tolerant mice to nicotine antinociception by using autoradiography of [³H]CI-977 binding. The density of KOP-r decreased in the spinal cord of tolerant mice. In addition, bi-directional cross-tolerance between nicotine (3 and 5 mg/kg, s.c.) and the selective kappa agonist U50,488H (10 mg/kg, s.c.) was found in the tail-immersion test. Recent evidences indicate that an up-regulation of dynorphin levels in the spinal cord and subsequent activation of NMDA receptors participate in the development of tolerance to opioid and cannabinoid antinociception. In this study, dynorphin content in the lumbar spinal cord was similar in control and nicotine tolerant mice. Furthermore, the administration of the NMDA antagonist MK-801 (0.03 and 0.01 mg/kg, i.p.) before each daily nicotine injection did not modify the development of nicotine tolerance. In summary, these data indicate that KOP-r is directly involved in the development of tolerance to nicotine antinociception by a mechanism independent from dynorphin and NMDA receptors.     

Spinal administration of selective opioid antagonists in amphibians: evidence for an opioid unireceptor

In mammals, opioids act by interactions with three distinct types of receptors: mu, delta, or kappa opioid receptors. Using a novel assay of antinociception in the Northern grass frog, Rana pipiens, previous work demonstrated that selective mu, delta, or kappa opioids produced a potent antinociception when administered by the spinal route. The relative potency of this effect was highly correlated to that found in mammals. Present studies employing selective opioid antagonists, beta-FNA, NTI, or nor-BNI demonstrated that, in general, these antagonists were not selective in the amphibian model. These data have implications for the functional evolution of opioid receptors in vertebrates and suggest that the tested mu, delta, and kappa opioids mediate antinociception via a single type of opioid receptor in amphibians, termed the unireceptor.     

Autoradiographic Visualization of Kappa Opioid Receptors with Labelled Dynorphins in Guinea Pig Brain

Abstract

The distribution of kappa opioid receptors in guinea pig brain was measured by in vitro receptor autoradiography using [³H]dynorphin A_1–9, [³H]dynorphin A_1–8 and [³H]bremazocine as ligands. The sites labelled by the two dynorphins had identical, heterogeneous distributions in brain sections. High levels of kappa receptors were seen in striatum, claustrum, nucleus accumbens and laminae V and VI of the cerebral cortex. The substantia nigra and superior colliculus also had high dynorphin binding levels. The [³H]dynorphin autoradiographs were closely similar to those obtained using [³H]bremazocine in the presence of mu and delta receptor displacers. It is concluded that tritiated dynorphin A fragments can be used for autoradiographic studies of kappa opioid receptors in brain.     

Characterization of dynorphin A-converting enzyme in human spinal cord. An endoprotease related to a distinct conversion pathway for the opioid heptadecapeptide?

A highly specific proteinase, converting dynorphin A (1-17) to enkephalins, was isolated from the human spinal cord and subjected to further characterization. The enzyme was found to be a thiol-dependent protein with a relative molecular mass of 50 kDa and a pH optimum between 5.0 and 5.5. This proteinase appears to exclusively convert dynorphin A (1-17) to Leu-enkephalin and its COOH-terminal extensions Leu-enkephalin-Arg6 (which was a major conversion product) and Leu-enkephalin-Arg6-Arg7 but not the other prodynorphin- or proenkephalin-derived peptides. This high specificity toward a single structure is suggested to be involved in a distinct processing pathway associated with the generation of the opioid peptides with selectivity for delta-opioid receptors.