Cardiovascular depressant effects of the kappa opioid receptor agonists U50488H and spiradoline mesylate

The cardiovascular effects of the selective kappa opioid receptor agonists U50488H and spiradoline mesylate were examined in pentobarbital-anesthetized mongrel dogs and chloralose-anesthetized cats. In the dog studies, U50488H (0.01-3.0 mg/kg, i.v.) produced a dose-related depression in mean arterial pressure (MAP), left ventricular systolic pressure (LVSP), left ventricular dp/dt, and heart rate. These effects were completely reversed by a 1 mg/kg i.v. dose of the opioid receptor antagonist naloxone. A second kappa agonist, spiradoline mesylate, also produced a naloxone-reversible cardiovascular depression. Furthermore, the compound did not interfere with the positive inotropic or hypertensive effects of norepinephrine (1 microgram/kg, i.v.), showing that the cardiovascular depressant effects of the kappa agonist are unrelated to interference with alpha- or beta-adrenergic receptor mechanisms. In normal cats anesthetized with chloralose, which produces less depression of sympathetic tone than does pentobarbital, spiradoline mesylate did not decrease the MAP in i.v. doses up to 1.0 mg/kg. However, a dose-related increase in sympathetic nerve discharge (SND) was observed (+290% at 1.0 mg/kg). In contrast, in baroreceptor-denervated cats, spiradoline mesylate caused a dose-related hypotensive effect with no change in SND. These results show that the cardiovascular effects of the kappa agonists are peripherally mediated and that reflex sympathetic activity, if uncompromised, can produce a full compensation.     

Pre- and Post-Synaptic Effects of Spiradoline and U-50488H,Selective Kappa Opioid Receptor Agonists,in Isolated Ileum

In guinea pig ileum, spiradoline (2 × 10^?6M or greater) and U-50488H (3 × 10^?6M or greater) suppressed contractile responses to acetylcholine (ACh), histamine, and BaCl₂. Inhibition by spiradoline (2 × 10^?5 M) of ACh-induced contractions was not antagonized by pretreatment with naloxone (3 × 10^?4 M). Spiradoline (2 × 10^?8 M or greater) and U-50488H (3 × 10^?8 M or greater) caused dose-dependent inhibition of the contractile response of guinea pig ileum to transmural electric stimulation. The inhibitory effect of spiradoline or of U-50488H at low concentrations was reduced by a high concentration of naloxone (3 × 10^?4 M). Spiradoline at low concentrations ranging from 2 × 10^?9 to 2 × 10^?7 M reduced spontaneous contractions in rabbit ileum. Naloxone (3 × 10^?4 g/ml) antagonized the spiradoline-induced inhibition, but marked inhibition by spiradoline at 10^?4 g/ml) was not restored by naloxone. These results suggest that both kappa agonists exert presynaptic inhibitory action on cholinergic nerve endings in the myenteric plexus at a low concentration range of 10^?9 to 10^?7 M and directly inhibit the smooth-muscle motility of the gut at greater concentrations.     

Opioid kappa receptors and the secretion of prolactin (PRL) and growth hormone (GH) in the rat. II. GH and PRL release-inhibiting effects of the opioid kappa receptor agonists bremazocine and U-50,488

An analysis of the GH release-inhibiting action of the opioid kappa receptor agonists bremazocine and U-50,488, established earlier, was attempted by testing the agonists against activation of GH secretion by morphine or clonidine in male rats bearing right atrial cannulae for serial blood sampling and drug delivery. Both kappa agonists inhibited the effect of subsequent administration of clonidine in a dose-related manner. Bremazocine was approximately ten times more potent than U-50,488, a ratio corresponding to the known affinities of the two compounds for the kappa receptors. The inhibiting action of bremazocine was more strongly reversed by the preferential kappa receptor antagonist Mr-2266 than by naloxone, neither of which interfered with the GH-stimulating effect of clonidine. Bremazocine, however, did not alter the activation of GH secretion by exogenous growth hormone releasing factor. Thus, the inhibiting effect of bremazocine and probably U-50,488 seems to be derived from stimulation of the kappa receptors which in turn activates a GH release inhibiting mechanism of unknown identify which, however, does not involve release of somatostatin. Both kappa agonists also inhibited the effect of morphine, but in this case U-50,488 was approximately hundred times less effective than bremazocine. Since bremazocine and U-50,488 are antagonists of the delta receptors, which seem to mediate the GH-releasing effect to morphine, their inhibiting effect in this instance may be related to this property rather than to an action on the kappa receptors. Bremazocine, but not U-50,488, was also highly effective in inhibiting stimulation of PRL secretion by morphine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of mu and kappa opioid receptor agonists and antagonists on contraction of isolated colon strips of rats with cathartic colon

AIM: To study the effects of mu and kappa opioid receptor agonists and antagonists on the isolated colon strips of rats with cathartic colon. METHODS: Cathartic colon model was established by feeding rats with contact laxatives, and effects of mu and kappa opioid receptor agonists and antagonists on electricity-stimulated contraction of isolated colon strips of rats with cathartic colon were observed. RESULTS: Compared with control group, exogenous mu and kappa agonists inhibited significantly electricity-stimulated contraction of strips of cathartic colon (8.50+/-0.89 mm, 6.24+/-0.91 mm, 3.35+/-0.6 mm vs 11.40+/-0.21 mm P<0.01; 8.98+/-0.69 mm, 6.89+/-0.71 mm, 4.43+/-0.99 mm vs 11.40+/-0.21 mm, P<0.01). In contrast, the exogenous mu antagonist significantly enhanced electricity-stimulated contraction of isolated colon strips (13.18+/-0.93 mm, 15.87+/-0.98 mm, 19.46+/-1.79 mm vs 11.40+/-0.21 mm, P<0.01), but kappa antagonist had no effect on the isolated colon strips of rats with cathartic colon. CONCLUSION: Mu and kappa opioid receptors are involved in the regulation of colon motility of rats with cathartic colon.     

Inhibitory effect of spiradoline, a kappa opioid receptor agonist, on Ca2+ induced contraction and the intracellular Ca2+ concentration in porcine coronary artery.

STUDY OBJECTIVE--The aim was to clarify the inhibitory effect of the selective kappa agonist, spiradoline, on coronary arterial smooth muscle in relation to the intracellular Ca2+ concentration. DESIGN--The inhibitory effect of spiradoline was investigated (1) on the contractile response of pig coronary artery to the readmission of Ca2+, following initial exposure to Ca2+ free medium and depolarisation with 40 mM K+; (2) on the intracellular Ca2+ concentration as assessed using the fluorescent calcium indicator fura-2. Relaxant responses to spiradoline in isolated porcine coronary artery strips contracted with K+ and prostaglandin F2 alpha were also examined. EXPERIMENTAL MATERIAL--Coronary arteries isolated from pigs of both sexes were used. The right and left circumflex coronary arteries were cut into 3 mm wide strips which were used to measure the change in contractile force and the intracellular Ca2+ concentration. MEASUREMENTS AND MAIN RESULTS--Prior treatment with spiradoline at 2 x 10(-6) mol.litre-1 or more inhibited the contractile response to the readmission of Ca2+ in porcine coronary artery exposed to Ca2+ free medium in the presence of high K+. Naloxone at 3 x 10(-4) mol.litre-1 did not reverse the inhibitory action of 2 x 10(-5) M spiradoline. Ca2+ induced contraction was inhibited completely by 10(-4) M spiradoline. Moreover, spiradoline caused relaxation in arterial preparations that had been contracted with K+ (15 to 25 mmol.litre-1) or prostaglandin F2 alpha (10(-6) to 3 x 10(-6) mol litre-1), greater relaxation being seen in the K+ induced contraction. The intracellular Ca2+ concentration was significantly lowered by 2 x 10(-5) M spiradoline. CONCLUSIONS--The relaxant response of coronary artery to spiradoline is, in part, attributable to interference with Ca2+ entry into the arterial smooth muscle.     

Cloning and pharmacological characterization of a rat kappa opioid receptor.

A full-length cDNA was isolated from a rat striatal library by using low-stringency screening with two PCR fragments, one spanning transmembrane domains 3-6 of the mouse delta opioid receptor and the other unidentified but homologous to the mouse delta receptor from rat brain. The novel cDNA had a long open reading frame encoding a protein of 380 residues with 59% identity to the mouse delta receptor and topography consistent with a seven-helix guanine nucleotide-binding protein-coupled receptor. COS-1 cells transfected with the coding region of this clone showed high-affinity binding to kappa opioid receptor-selective ligands such as dynorphin A and U-50,488 and also nonselective opioid ligands such as bremazocine, ethylketocyclazocine, and naloxone. Not bound at all (or bound with low affinity) were dynorphin A-(2-13), enantiomers of naloxone and levophanol [i.e., (+)-naloxone and dextrorphan], and selective mu and delta opioid receptor ligands. Activation of the expressed receptor by kappa receptor agonists led to inhibition of cAMP. Finally, in situ hybridization revealed a mRNA distribution in rat brain that corresponded well to the distribution of binding sites labeled with kappa-selective ligands. These observations indicate that we have cloned a cDNA encoding a rat kappa receptor of the kappa 1 subtype.     

Opioid kappa receptors and the secretion of prolactin (PRL) and growth hormone (GH) in the rat. I. Effects of opioid kappa receptor agonists bremazocine and U-50,488 on secretion of PRL and GH: comparison with morphine

The effects of bremazocine and U-50,488, two selective opioid kappa receptor agonists, and the preferential mu receptor agonist morphine on the secretion of PRL and GH were compared in conscious male rats bearing permanent right atrial cannulae for serial blood sampling and drug delivery. All three opioids stimulated PRL secretion in a dose-related manner, but the kappa agonists differed from morphine in several respects. They were considerably more potent than morphine in triggering a PRL response, but were unable to elevate PRL levels to more than 100 ng/ml, whereas morphine, at the highest dose (4.5 mg/kg), induced an almost twice larger response. Also their PRL-releasing effect was inhibited more strongly by the preferential kappa receptor antagonist Mr-2266 than by naloxone, whereas Mr-2266 and naloxone, which are equipotent as antagonists of the mu receptors, were equipotent in suppressing the PRL-stimulating effect of morphine, a mu agonist. In a complete contrast to morphine, which effectively stimulated GH secretion, the kappa agonists had no effect on GH release at lower doses and suppressed it at higher doses. It is concluded that the PRL-releasing effect of the kappa agonists is mediated by the kappa receptors which may participate with the mu receptors in regulation of PRL secretion by opioids. The GH-inhibiting effect of the kappa agonists requires further clarification.     

Opposing effects on infarction of delta and kappa opioid receptor activation in the isolated rat heart: implications for ischemic preconditioning

δ-Opioid receptors are known to participate in the protection found following ischemic preconditioning (IPC), but the role of κ-receptors in IPC is currently controversial. Langendorff-perfused rat hearts received 35 min regional ischemia and 2 h reperfusion. PC (2 cycles 5 min global ischemia) substantially reduced infarct size. Pharmacological PC with the δ-agonist DADLE (10 nmol/L) had similar protective effects. However, higher dose DADLE (1 μmol/L) had a less beneficial effect, and in conjunction with the δ-antagonist naltrindole unexpectedly increased infarct size (61.5 ± 2.0%, p < 0.05 v 45.9 ± 2.3% in controls) sugggesting a non-δ effect. The universal κ-opioid agonist bremazocine (30 nmol/L) increased infarct size (61.3 ± 1.6%, p < 0.05 v controls), an effect abrogated by the selective κ₁-antagonist nor-binaltorphimine (BNI). Since opiates are known to have anti-adrenergic effects, which hypothetically may help to mediate IPC, cyclic AMP levels were measured in DADLE and in bremazocine-treated hearts. Decreased levels of cyclic AMP at the start of the regional ischemic period were found in low dose DADLE hearts (0.485 ± 0/020, n = 8, vs controls, 0.654 ± 0.025 nmol/g wet weight, p < 0.001), but not in high dose DADLE nor in bremazocine treated hearts. Thus, in the isolated rat heart κ₁-opioid receptor activation exacerbates infarct size through an as yet unknown mechanism, suggesting that there could be an “anti-preconditioned state”. In contrast, δ-activity mediates protection which may be associated with a reduction of tissue cyclic AMP levels. Received: 16 November 1999, Accepted: 7 December 1999     

From the Cover: Zyklophin,a systemically active selective kappa opioid receptor peptide antagonist with short duration of action

The cyclic peptide zyklophin {[N-benzylTyr¹,cyclo(D-Asp⁵,Dap⁸)-dynorphin A-(1–11)NH₂, Patkar KA, et al. (2005) J Med Chem 48: 4500–4503} is a selective peptide kappa opioid receptor (KOR) antagonist that shows activity following systemic administration. Systemic (1–3 mg/kg s.c.) as well as central (0.3–3 nmol intracerebroventricular, i.c.v.) administration of this peptide dose-dependently antagonizes the antinociception induced by the selective KOR agonist U50,488 in C57BL/6J mice tested in the 55 °C warm water tail withdrawal assay. Zyklophin administration had no effect on morphine- or SNC-80-mediated antinociception, suggesting that zyklophin selectively antagonizes KOR in vivo. Additionally, the antagonism of antinociception induced by centrally (i.c.v.) administered U50,488 following peripheral administration of zyklophin strongly suggests that the peptide crosses the blood-brain barrier to antagonize KOR in the CNS. Most importantly, the antagonist activity of zyklophin (3 mg/kg s.c.) lasts less than 12 h, which contrasts sharply with the exceptionally long duration of antagonism reported for the established small-molecule selective KOR antagonists such as nor-binaltorphimine (nor-BNI) that last weeks after a single administration. Systemically administered zyklophin (3 mg/kg s.c.) also prevented stress-induced reinstatement of cocaine-seeking behavior in a conditioned place preference assay. In conclusion, the peptide zyklophin is a KOR-selective antagonist that exhibits the desired shorter duration of action, and represents a significant advance in the development of KOR-selective antagonists.     

Comparison of cardiovascular responses to intra-hippocampal mu, delta and kappa opioid agonists in spontaneously hypertensive rats and isolation-induced hypertensive rats.

OBJECTIVE: To investigate the cardiovascular effects of microinjection into the hippocampus of selective mu, delta and kappa opioid receptor agonists in anesthetized spontaneously hypertensive rats, isolation-induced hypertensive rats and their normotensive Wistar-Kyoto and group-housed Sprague-Dawley controls. METHODS AND RESULTS: The microinjection of a selective kappa agonist, spiradoline mesylate, (+/-)-(5alpha, 7alpha, 8beta)-3,4-dichloro-N-methyl-N-[7-(1-pyrrolidinyl)-1-oxaspiro++ +[4.5]dec-8-yl]-benzeneacetamide mesylate) (5 nmol) into the dorsal region of hippocampus, where injection of control saline failed to affect cardiovascular activities, induced centrally mediated decreases in mean blood pressure and heart rate in both hypertensive and normotensive rats. The effects were blocked by prior treatment of the hippocampus with nor-binaltorphimine dihydrochloride, a selective kappa opioid receptor antagonist The hypotensive and bradycardic effects were quantitatively similar between spontaneously hypertensive rats and Wistar-Kyoto rats and between isolated hypertensive rats and normotensive group-housed rats. The sequential administration of increasing doses (5, 10, 50 nmol) of the selective mu agonist [D-Ala2, N-Me-Phe4, Gly5-ol]-enkephalin and delta agonists [D-Ala2, D-Leu5]-enkephalin or [D-Pen2, D-Pen5]-enkephalin into the same areas of the hippocampus as used for the kappa agonist had no significant effects on mean blood pressure and heart rate in either hypertensive or normotensive rats. CONCLUSION: The present results extend our previous findings of a hippocampally mediated hypotensive effect of kappa agonists in the spontaneously hypertensive rat to the isolated rat model of hypertension and they establish that mu and delta opioid receptor agonists similarly applied are ineffective. Hippocampal kappa receptors may have a greater role in cardiovascular control than mu and delta receptors.     

Effect of the opioid kappa-receptor agonist U50488H on the secretion of arginine vasopressin. Study on the mechanism of U50488H-induced diuresis

The effect of U50488H, a potent opioid kappa-receptor agonist, was investigated on the urine volume and on the secretion of arginine vasopressin (AVP) in response to dehydration or hyperosmolar or hypovolemic stimulation in conscious rats. This agonist markedly increased the urine volume in normally hydrated rats and suppressed plasma AVP in a dose-dependent manner in rats given hyperosmolar saline. This suppression of plasma AVP was completely reversed by concurrent injection of naloxone. U50488H also inhibited the release of AVP in dehydrated or hypovolemic rats. These findings indicate that the diuresis induced by U50488H is mainly caused by the suppression of plasma AVP. They also suggest that the kappa-opioid receptor plays an important role in regulating the secretion of AVP.     

Agonists and antagonists bind to different domains of the cloned kappa opioid receptor.

Opium and its derivatives are potent analgesics that can also induce severe side effects, including respiratory depression and addiction. Opioids exert their diverse physiological effects through specific membrane-bound receptors. Three major types of opioid receptors have been described, termed delta, kappa, and mu. The recent molecular cloning of these receptor types opens up the possibility to identify the ligand-binding domains of these receptors. To identify the ligand-binding domains of the kappa and delta receptors, we have expressed in COS-7 cells the cloned mouse delta and kappa receptors and chimeric delta/kappa and kappa/delta receptors in which the NH2 termini have been exchanged. The opioid antagonist naloxone binds potently to wild-type kappa receptor but not to wild-type delta receptor. The kappa/delta chimera bound [3H]naloxone with high affinity. In contrast, the kappa-specific agonist [3H]U-69,593 did not bind to the kappa/delta chimera. These findings indicate that selective agonists and antagonists interact with different recognition sites in the kappa receptor and localize the antagonist-binding domain to the NH2 terminus. Consistent with the results of radioligand-binding studies, the kappa/delta chimera did not mediate kappa-agonist inhibition of cAMP formation. In contrast, the delta/kappa chimera did mediate kappa-agonist inhibition of cAMP formation, but this effect was not blocked by naloxone. Furthermore, a truncated kappa receptor lacking its NH2 terminus was able to mediate agonist inhibition of cAMP accumulation in a naloxone-insensitive manner. This result further indicates that the NH2 terminus of the kappa receptor contains the selective antagonist-binding domain. The ability to dissociate agonist- and antagonist-binding sites will facilitate the development of more specific kappa agonists, which could have analgesic properties devoid of side effects.     

Characterization and visualization of rat and guinea pig brain kappa opioid receptors: evidence for kappa 1 and kappa 2 opioid receptors.

kappa opioid receptors (kappa receptors) have been characterized in homogenates of guinea pig and rat brain under in vitro binding conditions. kappa receptors were labeled by using the tritiated prototypic kappa opioid ethylketocyclazocine under conditions in which mu and delta opioid binding was suppressed. In the case of guinea pig brain membranes, a single population of high-affinity kappa opioid receptor sites (kappa sites; Kd = 0.66 nM, Bmax = 80 fmol/mg of protein) was observed. In contrast, in the case of rat brain, two populations of kappa sites were observed--high-affinity sites at low density (Kd = 1.0 nM, Bmax = 16 fmol/mg of protein) and low-affinity sites at high density (Kd = 13 nM, Bmax = 111 fmol/mg of protein). To test the hypothesis that the high- and low-affinity kappa sites represent two distinct kappa receptor subtypes, a series of opioids were tested for their abilities to compete for binding to the two sites. U-69,593 and Cambridge 20 selectively displaced the high-affinity kappa site in both guinea pig and rat tissue, but were inactive at the rat-brain low-affinity site. Other kappa opioid drugs, including U-50,488, ethylketocyclazocine, bremazocine, cyclazocine, and dynormphin (1-17), competed for binding to both sites, but with different rank orders of potency. Quantitative light microscopy in vitro autoradiography was used to visualize the neuroanatomical pattern of kappa receptors in rat and guinea pig brain. The distribution patterns of the two kappa receptor subtypes of rat brain were clearly different. The pattern of rat high-affinity kappa sites paralleled that of guinea pig in the caudate-putamen, mid-brain, central gray substance of cerebrum, and substantia nigra; interspecies differences were apparent throughout most of the rest of the brain. Collectively, these data provide direct evidence for the presence of two kappa receptor subtypes; the U-69,593-sensitive, high-affinity kappa 1 site predominates in guinea pig brain, and the U-69,593-insensitive, low-affinity kappa 2 site predominates in rat brain.     

Effects of U50488 and bremazocine on [Ca2+]i and cAMP in naive and tolerant rat ventricular myocytes: evidence of kappa opioid receptor multiplicity in the heart

To explore the existence of multiplicity of kappa receptor in the heart, two series of experiments were performed. In the first we studied the antagonistic actions of nor-BNI, a selective kappa 1 antagonist, and quadazocine, a preferential kappa 2 antagonist, against the effects of U50488, a selective kappa 1 agonist, and bremazocine, a universal agonist preferentially binding to kappa 2 receptor, on the electrically stimulated [Ca2+]i transient and forskolin-stimulated cAMP accumulation in the rat ventricular myocyte. In the second series of experiments, we determined and compared the effects of above two kappa receptor agonists in the ventricular myocytes made insensitive to kappa 1 and kappa 2 agonists by prior exposure to the respective agonists. At the concentration range of 3 x 10(-6)-3 x 10(-5) M, both U50488 and bremazocine dose-dependently inhibited the [Ca2+]i transient induced by electrical stimulation. The inhibitory effects of U50488 and bremazocine were antagonized by nor-BNI and quadazocine. The antagonistic actions of nor-BNI were significantly greater against the effects of U50488, but smaller against the effects of bremazocine than those of quadazocine. At 1 x 10(-6)-5 x 10(-5) M, both U50488 and bremazocine dose-dependently and significantly inhibited the forskolin-induced cAMP accumulation. The inhibitory effect of 30 microM U50488 on cAMP accumulation was significantly attenuated by 5 microM nor-BNI, but not by quadazocine at the same concentration; whereas the effect of 30 microM bremazocine was significantly blocked by 5 microM quadazocine, but not by nor-BNI at the same concentration. The inhibitory effect of 30 microM U50488 on electrically stimulated [Ca2+]i was abolished by preincubation of myocytes with 10(-6) M U50488 for 24 h, but not with 10(-6) M bremazocine for h; whereas the inhibitory effect of 30 microM bremazocine on electrically stimulated [Ca2+]i transient was significantly attenuated after incubation of the myocyte with 10(-6) M bremazocine for 24 h, but not with 10(-6) M U50488 for 24 h. The observations indicate the existence of kappa receptor subtypes in the rat heart.     

T-cell suppression and contrasuppression induced by histamine H2 and H1 receptor agonists, respectively.

The intensity of Lyl+T helper and delayed type hypersensitivity effector cell activities is governed, in part, by an interplay between two classes of immunoregulatory T cells: suppressor cells and contrasuppressor cells. We asked whether histamine, at concentrations and duration of exposure that we calculated might be achieved at local sites of inflammation, could activate either or both of these classes of regulatory cells in vitro. To answer this question we used spleen cells from mice treated in vivo with the toleragen trinitrobenzenesulfonic acid as regulators of in vitro generation of primary anti-trinitrophenyl self-cytotoxic T lymphocytes. Under the conditions used, these spleen cells had no major regulatory effects. However, if these cells were preincubated with histamine at 0.1 mM for 30-60 min, suppressor activity was induced, but this occurred inconsistently and with nonstoichiometric results. The use of synthetic histamine agonists revealed that histamine may activate both suppressor and contrasuppressor cell subsets. A histamine H1 receptor agonist [2-(2-pyridyl)-ethylamine dihydrochloride] had a propensity to activate contrasuppression, whereas an H2 receptor agonist (dimaprit) tended to activate suppressor cells. Thus, histamine may have opposing actions that obscure suppression. This duality was shown by treatment of pyridylethylamine-induced contrasuppressor cells with complement and anti-I-J antibody that kills contrasuppressor cells. This treatment revealed a high level of suppressor cell activity that was not expressed until the opposing contrasuppressor cells were removed. Because histamine is released at local sites of delayed type hypersensitivity, these results indicate that histamine may serve as an inducer of microenvironmental immunomodulation by activating regulatory T cells at sites where immune responses are taking place.     

Anoretic effects of neuropeptide FF are mediated via central mu and kappa subtypes of opioid receptors and receptor ligands

Recently, we demonstrated that neuropeptide FF (NPFF) causes anorexigenic effects in chicks that were associated with the hypothalamus. The present study was designed to better understand some of the central mechanisms that mediate these effects. Co-injection of NPFF and beta-funaltrexamine (FNA, a mu opioid receptor antagonist) did not suppress food intake more than when NPFF and FNA were injected alone. However, co-injection of NPFF and ICI-174,864 (ICI, a delta opioid receptor antagonist) caused a greater reduction in food intake than when NPFF and ICI were injected alone. Co-injection of NPFF and nor-binaltorphimine (BNI, a kappa opioid receptor antagonist) did not cause a greater suppression of food intake than when NPFF and BNI were injected alone. Hyperphagia induced by neuropeptide Y and beta-endorphin (both ligands of opioid receptors) was reversed by NPFF. These results suggest that NPFF-induced satiety has a relationship with mu and kappa but not delta subtypes of opioid receptors, and since NPFF does not bind opioid receptors itself NPFF-associated satiety is likely mediated by effects on opioid receptor ligands such as NPY and beta-endorphin. Thus, NPFF induced satiety may be mediated via modulation of the chick's innate opioid-associated orexigenic system.     

Primary structure and functional expression of a guinea pig kappa opioid (dynorphin) receptor.

A full-length cDNA encoding the guinea pig kappa opioid (dynorphin) receptor has been isolated. The deduced protein contains 380 aa and seven hydrophobic alpha-helices characteristic of the G protein-coupled receptors. This receptor is 90% identical to the mouse and rat kappa receptors, with the greatest level of divergence in the N-terminal region. When expressed in COS-7 cells, the receptor displays high affinity and stereospecificity toward dynorphin peptides and other kappa-selective opioid ligands such as U50, 488. It does not bind the mu- and delta-selective opioid ligands. The expressed receptor is functionally coupled to G protein(s) to inhibit adenylyl cyclase and Ca2+ channels. The guinea pig kappa receptor mRNA is expressed in many brain areas, including the cerebellum, a pattern that agrees well with autoradiographic maps of classical guinea pig kappa binding sites. Species differences in the pharmacology and mRNA distribution between the cloned guinea pig and rat kappa receptors may be worthy of further examination.     

Molecular mechanisms of glucocorticoid action and selective glucocorticoid receptor agonists

Glucocorticoids (GC) are the most common used anti-inflammatory and immunosuppressive drugs in the treatment of rheumatic and other inflammatory diseases. Their therapeutic effects are considered to be mediated by four different mechanisms of action: the classical genomic mechanism of action caused by the cytosolic glucocorticoid receptor (cGCR); secondary non-genomic effects which are also initiated by the cGCR; membrane-bound glucocorticoid receptor (mGCR)-mediated non-genomic effects; non-specific, non-genomic effects caused by interactions with cellular membranes. The classical, genomic mechanism of GC-action can be divided into two processes: "transrepression", which is responsible for a large number of desirable anti-inflammatory and immunomodulating effects, and "transactivation" which is associated with frequently occurring side effects as well as with some immunosuppressive activities [Ehrchen, J., Steinmuller, L., Barczyk, K., Tenbrock, K., Nacken, W., Eisenacher, M., Nordhues, U., Sorg, C., Sunderkotter, C., Roth, J., 2007. Glucocorticoids induce differentiation of a specifically activated, anti-inflammatory subtype of human monocytes. Blood 109, 1265-1274]. Great efforts have been made to diminish glucocorticoid-induced adverse effects, but the improvement of conventional glucocorticoids has almost reached its limits. As a consequence, new variations of the conventional "good old drugs" are being tested and nitro-steroids and long circulating liposomal glucocorticoids indeed show promising results. Nevertheless, crux of the matter should be the design of qualitatively new drugs, such as selective glucocorticoid receptor agonists (SEGRAs). These innovative steroidal or non-steroidal molecules induce transrepression, while transactivation processes are less affected. First reports on two different GCR ligands, A276575 and ZK216348, show promising results. Here, we review the above-mentioned mechanisms of glucocorticoid action and give particular attention to the development of optimized glucocorticoids and SEGRAs.     

Activation of the kappa opioid receptor in the dorsal raphe nucleus mediates the aversive effects of stress and reinstates drug seeking

Although stress has profound effects on motivated behavior, the underlying mechanisms responsible are incompletely understood. In this study we elucidate a functional pathway in mouse brain that encodes the aversive effects of stress and mediates stress-induced reinstatement of cocaine place preference (CPP). Activation of the dynorphin/kappa opioid receptor (KOR) system by either repeated stress or agonist produces conditioned place aversion (CPA). Because KOR inhibition of dopamine release in the mesolimbic pathway has been proposed to mediate the dysphoria underlying this response, we tested dopamine-deficient mice in this study and found that KOR agonist in these mice still produced CPA. However, inactivation of serotonergic KORs by injection of the KOR antagonist norBNI into the dorsal raphe nucleus (DRN), blocked aversive responses to the KOR agonist U50,488 and blocked stress-induced reinstatement of CPP. KOR knockout (KO) mice did not develop CPA to U50,488; however, lentiviral re-expression of KOR in the DRN of KOR KO mice restored place aversion. In contrast, lentiviral expression in DRN of a mutated form of KOR that fails to activate p38 MAPK required for KOR-dependent aversion, did not restore place aversion. DRN serotonergic neurons project broadly throughout the brain, but the inactivation of KOR in the nucleus accumbens (NAc) coupled with viral re-expression in the DRN of KOR KO mice demonstrated that aversion was encoded by a DRN to NAc projection. These results suggest that the adverse effects of stress may converge on the serotonergic system and offers an approach to controlling stress-induced dysphoria and relapse.