Mouse Forebrain Membranes Research Articles

Low dosage of rimonabant leads to anxiolytic-like behavior via inhibiting expression levels and G-protein activity of kappa opioid receptors in a cannabinoid receptor independent manner

What is knownThere is an increasing number of studies demonstrating the direct effect of the cannabinoid receptor 1 (CB1) antagonist/inverse agonist rimonabant on the opioid system. The kappa opioid receptors (KORs) are well known to mediate depression- and anxiety-like behavior. Clinical studies on chronic rimonabant administration have revealed that rimonabant leads to a very similar pathophysiology, suggesting a potential impact of rimonabant on KORs. ObjectivesOur objectives were to examine the putative effects of rimonabant on KOR ligand binding, G-protein activity, protein expression and how all these contribute to the development of depression- and anxiety-like behavior. ResultsIn Chinese hamster ovary (CHO) cell membranes transfected with rat KOR (CHO-rKOR) rimonabant inhibited KOR agonist [3H]U69593 binding in the micromolar range in competition binding experiments and specifically reduced KOR basal activity at lower micromolar concentrations in [35S]GTPγS binding assays. Rimonabant significantly inhibited dynorphin (1–11)-induced [35S]GTPγS binding in micromolar range in CHO-rKOR cells, CB1 knockout (CB1 K.O.) and CB1/CB2 double knockout mouse forebrain membranes. A single dose of i.p. 0.1 mg/kg rimonabant significantly reduced dynorphin (1–11)-induced KOR G-protein activity and KOR protein expression levels 24 h following the administration in both wild type and CB1 K.O. mice forebrain. Furthermore, in elevated plus maze mice showed an anxiolytic-like effect upon rimonabant injection that could be reversed by 1 mg/kg KOR antagonist norbinaltorphimine. The anxiolytic-like effects were further confirmed with the light–dark box test. ConclusionRimonabant reduced KOR ligand binding, receptor mediated G-protein activity and protein expression level, which overall leads to altered anxiety-like behavior.

Micromolar concentrations of rimonabant directly inhibits delta opioid receptor specific ligand binding and agonist-induced G-protein activity

What is knownThere is a growing number of evidence showing, that the cannabinoid receptor 1 (CB1) antagonist rimonabant has many non-cannabimimetic actions, such as affecting the opioid system. The direct effect of rimonabant on opioid receptors has been studied so far mainly on μ-opioid receptors. However recently the δ-opioid receptor (DOR) receives much more attention as before, due to its potential therapeutic applications, such as nociception or treatment for psychiatric disorders. ObjectivesTo investigate the direct effect of rimonabant on DOR specific ligand binding and on the DOR mediated G-protein activation. ResultsMicromolar concentrations of rimonabant directly inhibited the DOR specific agonist binding in radioligand competition binding experiments using Chinese hamster ovary cells stably transfected with mouse DOR (CHO-mDOR). However the inhibition occurred also in the subnanomolar range during DOR specific antagonist binding in similar experimental conditions. In functional [35S]GTPγS binding assays rimonabant significantly decreased the basal receptor activity in CHO-mDOR but also in parental CHO cell membranes. During DOR agonist stimulation, micromolar concentration of rimonabant attenuated the DOR G-protein activation and the potency of the activator ligand in [35S]GTPγS binding assays performed in CHO-mDOR, in wild type and also in CB1/CB2 double knock-out mouse forebrain membranes. Yet again this inhibitory action was DOR specific, since it did not occur during other specific GPCR agonist mediated G-protein activation. ConclusionRimonabant directly inhibited DOR function in the micromolar concentrations. The inhibitory actions indicate an antagonistic behavior towards DOR which was established by the followings: (i) rimonabant inhibited DOR antagonist binding more effectively than agonist binding, (ii) the inverse agonistic, agonistic effect of the compound can be excluded, and (iii) additionally according to previous findings the allosteric mechanism can also be foreclosed.

Identification of Membrane-bound Variant of Metalloendopeptidase Neurolysin (EC 3.4.24.16) as the Non-angiotensin Type 1 (Non-AT1), Non-AT2 Angiotensin Binding Site

Recently, we discovered a novel non-angiotensin type 1 (non-AT1), non-AT2 angiotensin binding site in rodent and human brain membranes, which is distinctly different from angiotensin receptors and key proteases processing angiotensins. It is hypothesized to be a new member of the renin-angiotensin system. This study was designed to isolate and identify this novel angiotensin binding site. An angiotensin analog, photoaffinity probe 125I-SBpa-Ang II, was used to specifically label the non-AT1, non-AT2 angiotensin binding site in mouse forebrain membranes, followed by a two-step purification procedure based on the molecular size and isoelectric point of the photoradiolabeled binding protein. Purified samples were subjected to two-dimensional gel electrophoresis followed by mass spectrometry identification of proteins in the two-dimensional gel sections containing radioactivity. LC-MS/MS analysis revealed eight protein candidates, of which the four most abundant were immunoprecipitated after photoradiolabeling. Immunoprecipitation studies indicated that the angiotensin binding site might be the membrane-bound variant of metalloendopeptidase neurolysin (EC 3.4.24.16). To verify these observations, radioligand binding and photoradiolabeling experiments were conducted in membrane preparations of HEK293 cells overexpressing mouse neurolysin or thimet oligopeptidase (EC 3.4.24.15), a closely related metalloendopeptidase of the same family. These experiments also identified neurolysin as the non-AT1, non-AT2 angiotensin binding site. Finally, brain membranes of mice lacking neurolysin were nearly devoid of the non-AT1, non-AT2 angiotensin binding site, further establishing membrane-bound neurolysin as the binding site. Future studies will focus on the functional significance of this highly specific, high affinity interaction between neurolysin and angiotensins.

Changes in [ 3H]glibenclamide binding to mouse forebrain membranes during morphine tolerance

The characteristics of specific binding of the ATP-sensitive K + (K ATP) channel blocker [ 3H]glibenclamide to forebrain membranes (P 2 fraction, 4°C) obtained from morphine-naive and -tolerant mice were evaluated. Morphine tolerance was induced by osmotic minipumps that released 45 mg/kg/day of morphine subcutaneously for 6 days. This treatment enhanced the antinociceptive ED 50 of morphine without changing its E max. In morphine-naive animals, (1) both the association and the dissociation of [ 3H]glibenclamide were biphasic; (2) [ 3H]glibenclamide was displaced by other sulfonylureas (order of potency: glibenclamide>glipizide≫tolbutamide) with pseudo-Hill coefficients lower than unity and biphasic Hofstee plots; and (3) Scatchard plots of saturation experiments were curvilinear, showed a Hill coefficient of 0.81±0.04 and suggested the presence of two binding sites with a K D of 0.13 and 3.17 nM and a B max of 12.30 and 84.47 fmol/mg protein, respectively. By contrast, in membranes obtained from morphine-tolerant animals, (1) the Scatchard plots showed only one population of binding sites with a K D of 0.87 nM and a B max of 77.99 fmol/mg protein, and the Hill coefficient was very close to unity (0.96±0.1); (2) competition experiments (using glibenclamide as displacer) showed a pseudo-Hill coefficient of 0.99±0.04; and (3) dissociation experiments showed only one phase of dissociation. These results suggest that [ 3H]glibenclamide binds to two different sites in membranes obtained from morphine-naive animals, but to only one site in morphine-tolerant animals. Consequently, it seems that morphine tolerance in mice involves adaptive changes in K ATP channels.

Immunological identification of the mammalian H3 histamine receptor in the mouse brain.

Affinity-purified antibodies raised against the peptide sequence H3 (349-358) receptor specifically recognized two protein species with Mr 62,000 and 93,000 in adult mouse forebrain membranes. Both immunoreactive species were suppressed greatly by preincubation of the antibody with the respective peptide. Immunohistochemical analysis using affinity-purified anti-H3 (349-358) antibodies yielded a high degree of coincidence with ligand-autoradiographical information, with high levels detected in the CA3 and dentate gyrus of the hippocampus, laminae V of the cerebral cortex, the olfactory tubercle, Purkinje cell layer of the cerebellum, substantia nigra, globus pallidus, thalamus and striatum. This study suggests further biochemical evidence for multiple H3 receptor subtypes and the widespread distribution of the H3 receptor in the mammalian brain.

Anticonvulsive Effect of Swim Stress in Mice

PERIČIĆ, D., D. ŠVOB, M. JAZVINŠĆAK AND K. MIRKOVIĆ. Anticonvulsive effect of swim stress in mice. PHARMACOL BIOCHEM BEHAV 66(4) 879–886, 2000. —To explore the possible involvement of glucocorticoids in the previously observed anticonvulsive effect of swim stress, mice were, prior to administration of convulsants, subjected to treatments that diminish or enhance plasma corticosterone levels. Aminoglutethimide, the inhibitor of steroid synthesis, failed to modify convulsant doses of picrotoxin, but enhanced threshold doses of pentylenetetrazole producing myoclonus and death, both in unstressed and stressed animals. The same drug prevented the effect of stress on pentylenetetrazole-induced running bouncing clonus (RB clonus) and abolished the appearance of tonic hindlimb extension (THE). Doses of kainic acid producing convulsions and death were not affected by stress, but they were enhanced by aminoglutethimide. Corticosterone administration could not imitate the effect of swim stress. Finasteride, a 5α-reductase inhibitor, did not interfere with the effect of stress on picrotoxin-induced convulsions. Swim stress failed to modify the binding of the convulsant t[ 3H]-butylbicycloorthobenzoate [ 3H]TBOB, to washed mouse forebrain membranes. The results confirmed an anticonvulsant effect of swim stress against convulsions produced by GABA-related convulsants, but they do not support the hypothesis suggesting the involvement of glucocorticoids or neurosteroids in this effect.

Further studies on nociceptin-related peptides: discovery of a new chemical template with antagonist activity on the nociceptin receptor.

Three series of nociceptin (NC)-related peptides were synthesized and their abilities (i) to bind to the NC sites expressed in mouse forebrain membranes, (ii) to inhibit the electrically evoked contraction of the mouse vas deferens, and (iii) to inhibit forskolin-stimulated cAMP accumulation in Chinese hamster ovary cells expressing the human recombinant NC receptor (CHONCR) were investigated. The compounds of the first series (a series) have an ordinary Xaa1-Gly2 bond, those of the second series (b series) have a Xaa1psi(CH2-NH)Gly2 pseudopeptide bond, and those of the third series (c series) have a peptoid (Nxaa1-Gly2) structure. The affinity values measured in the binding assay and in the two functional assays with the compounds of the three series showed high levels of correlation. Thus, (I) the compounds of the a series in which Phe1 was substituted with Tyr, Cha, or Leu acted as potent NC receptor agonists; (II) the b series compounds behaved as NC receptor antagonists in the mouse vas deferens and as full agonists in CHO(NCR) cells with different potencies depending on the first amino acid residue, [Phe1psi(CH2-NH)Gly2]NC(1-17)NH2 and [Phe1psi(CH2-NH)Gly2]NC(1-13)NH2 being the most potent compounds; (III) the compounds of the third series were all inactive both as agonists and as antagonists with the exception of [Nphe1]NC(1-17)NH2 and [Nphe1]NC(1-13)NH2, which behaved as NC receptor antagonists both in the isolated tissue and in CHO(NCR) cells (pKB 6.1-6.4). In conclusion, this study demonstrates that chemical requirements for NC receptor agonists are different from those of antagonists. Moreover, modifications of the steric orientation of the aromatic residue Phe1 in the NC sequence as obtained with the pseudopeptide bond between Phe1 and Gly2 or with the displacement of the benzyl side chain by one atom, as in Nphe1, lead respectively to reduction or elimination of efficacy. Indeed, in contrast to [Phe1psi(CH2-NH)Gly2]NC(1-13)NH2 which has been reported to exhibit agonist activity in several assays involving either central or recombinant NC receptors, [Nphe1]NC(1-13)NH2 antagonizes the effect of NC at human recombinant NC receptors and in the mouse tail withdrawal assay.

Nociceptin receptor binding in mouse forebrain membranes: thermodynamic characteristics and structure activity relationships.

The present study describes the labelling of the nociceptin (NC) receptor, ORL1, in mouse forebrain membranes with a new ligand partially protected from metabolic degradation at the C-terminal; the ligand, [3H]-NC-NH2, has a specific activity of 24.5 Ci mmol(-1). Saturation experiments revealed a single class of binding sites with a KD value of 0.55 nM and Bmax of 94 fmol mg(-1) of protein. Non specific binding was 30% of total binding. Kinetic binding studies yielded the following rate constants: Kobs = 0.104 min(-1); K1 =0.034 min(-1): T1/2=20 min; K(+1)=0.07 min nM(-1). Thermodynamic analyses indicated that [3H]-NC-NH2 binding to the mouse ORL1 is totally entropy driven, similar to what has been observed for the labelled agonists to the opioid receptors OP1(delta), OP2(kappa) and OP3(mu). Receptor affinities of several NC fragments and analogues, including the newly discovered ORL-1 receptor antagonist [Phe1psi(CH2-NH)Gly2]NC(1-13)-NH2([F/G]NC(1-13)-NH2), were also evaluated in displacement experiments. The competition curves for these compounds were found to be parallel to that of NC and the following order of potency was determined for NC fragments: NC-OH = NC-NH2-NC(1-13)-NH2 > > NC(1-12)-NH2 > NC(1-13)-OH > > NC(1-11)-NH2, and for NC and NC(1-13)-NH2 analogues: [Tyr1]NC-NH2 > or = [Leu1]NC(1-13)-NH2 > or = [Tyr1]NC(1-13)-NH2 > or = [F/G]NC(1-13)-NH2 > > [Phe3]NC(1-13)-NH2 > [DF/G]NC(1-13)-NH2. Standard opioid receptor ligands (either agonists or antagonists) were unable to displace [3H]-NC-NH2 binding when applied at concentrations up to 10 microM indicating that this new radioligand interacts with a non opioid site, probably the ORL1 receptor.

The novel anticonvulsant SB 204269 binds to a stereospecific site in the mouse brain

The novel compound SB 204269 ( trans-(+)-6-acetyl-4 S-(4-fluorobenzoylamino)-3,4-dihydro-2,2-dimethyl-2 H-benzo[ b]pyran-3 R-ol,hemihydrate) shows potent anticonvulsant activity in the mouse maximal electroshock seizure threshold test. The binding of [ 3H]SB 204269 to mouse forebrain membranes is saturable ( B max 217 fmol/mg protein, K d 32 nM) and stereospecific. The excellent anticonvulsant profile of SB 204269, combined with the identification of a unique central binding site for the compound, suggest that it has potential clinical utility as a novel treatment for epilepsy.

Immunological and Physical Characterization of the Brain G Protein-Gated Muscarinic Potassium Channel

The subunit composition of the G protein-gated inwardly rectifying K+ (KG) channel protein extracted from mouse forebrain membranes was examined. A polyclonal antibody (anti-GIRK1C1) was prepared against the carboxyl terminal region of GIRK1, the major subunit of the KG channel. The anti-GIRK1C1 IgG detected a single protein at ∼ 65 kDa in SDS-PAGE of brain membranes. This IgG immunoprecipitated a macroprotein complex composed of GIRK1 and several associated proteins whose molecular weights ranging from 50 to 62 kDa on SDS-polyacrylamide gel. Upon size fractionation by both sucrose density gradient centrifugation and gel filtration, the solubilized KG channel proteins migrated into a single peak, which suggests that the component subunits form a single macromolecule. On the basis of the values of size fractionation, the molecular mass of the KG channel macromolecule could be estimated at ∼ 231,000. These results suggest that the KG channel is most likely a tetrameric macroprotein composed of GIRK1 and co-immunoprecipitated proteins in the forebrain.

Effects of Amperozide in Two Animal Models of Anxiety

The novel psychotropic agent amperozide (amp) was investigated in two different rat anxiety models, Vogel's conflict test (VT) and Montgomery's conflict test (MT). In the VT, amp in lower doses (0.2-0.6 mg/kg subcutaneously) increased the number of shocks accepted, as compared to controls. Pretreatment with the specific benzodiazepine receptor antagonist Ro 15-1788 (10.0 mg/kg orally) or the GABA-A receptor antagonist bicuculline (2.0 mg/kg intraperitoneally) antagonized the anticonflict effect of amp (0.4 mg/kg subcutaneously). At the highest dose tried (2.0 mg/kg subcutaneously) amp instead decreased the number of shocks accepted. Both 0.4 mg/kg and 2.0 mg/kg of amp raised the shock threshold, as compared to controls. The latter dose also decreased the motivation to drink. Pretreatment with Ro 15-1788 (10.0 mg/kg orally) did not significantly change the shock threshold or the drinking motivation, as compared to the group receiving amp alone. In the MT, amp (0.05-0.1 mg/kg subcutaneously) increased the percentage time spent in the open arms, while no changes were seen in the number of entries made into these arms. After higher doses (0.4-0.8 mg/kg subcutaneously) no differences, as compared to controls, were observed. Amp (1 nM-10microM) exhibited no affinity for 3H-flunitrazepam binding sites in mouse forebrain membranes in vitro. Taken together, the present data suggest that amp in low doses produces anticonflict (anxiolytic-like) effects. These effects appear to be mediated through an indirect (via 5-HT and/or DA systems?) activation of the GABA/benzodiazepine chloride ionophore receptor complex.

Effect of picrotoxinin on benzodiazepine receptor binding.

The effect of picrotoxinin on [3H]flunitrazepam binding to benzodiazepine receptors was investigated. In mouse forebrain membranes, picrotoxinin inhibited basal, GABA- and pentobarbital-stimulated [3H]flunitrazepam binding; this inhibitory activity was temperature- and chloride ion-dependent. Scatchard analysis of the data indicates that picrotoxinin decreases the number of binding sites without altering binding affinity. In cerebellar membranes, picrotoxinin did not alter [3H]flunitrazepam receptor binding.

Effect of pyrethroids on [ 3H]kainic acid binding to mouse forebrain membranes

The effect of the pyrethroid insecticides, decamethrin, cis-permethrin, and trans-permethrin, was examined on the in vitro specific binding of [ 3H]kainic acid ([ 3H]KA) to receptor sites in mouse forebrain homogenates. All three pyrethroids gave rise to dose-dependent decreases in levels of specific binding. Decamethrin was the most potent in displacing bound [ 3H]KA giving rise to significant decreases at decamethrin concentrations of 10 −7 m and above. Intracere-broventricular injections of the pyrethroids into unanesthetized mice gave rise to neurotoxic symptoms including hyperactivity, tremor, and tonic seizures. The order of potency of the three compounds in causing these symptoms of toxicity (decamethrin > cis-permethrin > trans-permethrin) was found to be the same as their order of potency in displacing bound [ 3H]KA from binding sites in the mouse brain. These preliminary results suggest that the neurotoxic actions of pyrethroids in mammals may be at least partially mediated via interactions with a kainic acid binding site.