Interaction of convulsive ligands with benzodiazepine receptors.

The gamma-aminobutyric acid (GABA)-benzodiazepine receptor complex, which is composed of distinct proteins embedded in the neuronal plasma membrane, is important for several effects of benzodiazepines, including protection afforded against convulsions. During structural modification of ethyl beta-carboline-3-carboxylate an agent was discovered which has high affinity for brain benzodiazepine receptors but which is a potent convulsant. Also in contrast to benzodiazepines, this type of benzodiazepine receptor ligand favors benzodiazepine receptors in the non-GABA-stimulated conformation, which may explain the convulsive properties.

Actions of ZD0947, a novel ATP-sensitive K+ channel opener, on membrane currents in human detrusor myocytes.

BACKGROUND AND PURPOSE: ATP-sensitive K+ channels (K(ATP) channels) play important roles in regulating the resting membrane potential of detrusor smooth muscle. Actions of ZD0947, a novel KATP channel opener, on both carbachol (CCh)-induced detrusor contractions and membrane currents in human urinary bladder myocytes were investigated. EXPERIMENTAL APPROACH: Tension measurements and patch-clamp techniques were utilized to study the effects of ZD0947 in segments of human urinary bladder. Immunohistochemistry was also performed to detect the expression of the sulphonylurea receptor 1 (SUR1) and the SUR2B antigens in human detrusor muscle. KEY RESULTS: ZD0947 (> or = 0.1 microM) caused a concentration-dependent relaxation of the CCh-induced contraction of human detrusor, which was reversed by glibenclamide. The rank order of the potency to relax the CCh-induced contraction was pinacidil > ZD0947 > diazoxide. In conventional whole-cell configuration, ZD0947 (> or = 1 microM) caused a concentration-dependent inward K+ current which was suppressed by glibenclamide at -60 mV. When 1 mM ATP was included in the pipette solution, application of pinacidil or ZD0947 caused no inward K+ current at -60 mV. Gliclazide (< or =1 microM), a selective SUR1 blocker, inhibited the ZD0947-induced currents (Ki = 4.0 microM) and the diazoxide-induced currents (high-affinity site, Ki1 = 42.4 nM; low-affinity site, Ki2 = 84.5 microM) at -60 mV. Immunohistochemical studies indicated the presence of SUR1 and SUR2B proteins, which are constituents of KATP channels, in the bundles of human detrusor smooth muscle. CONCLUSIONS AND IMPLICATIONS: These results suggest that ZD0947 caused a glibenclamide-sensitive detrusor relaxation through activation of glibenclamide-sensitive KATP channels in human urinary bladder.

Nonpsychotropic cannabinoid receptors regulate microglial cell migration.

During neuroinflammation, activated microglial cells migrate toward dying neurons, where they exacerbate local cell damage. The signaling molecules that trigger microglial cell migration are poorly understood. In this paper, we show that pathological overstimulation of neurons by glutamate plus carbachol dramatically increases the production of the endocannabinoid 2-arachidonylglycerol (2-AG) but only slightly increases the production of anandamide and does not affect the production of two putative endocannabinoids, homo-gamma-linolenylethanolamide and docosatetraenylethanolamide. We further show that pathological stimulation of microglial cells with ATP also increases the production of 2-AG without affecting the amount of other endocannabinoids. Using a Boyden chamber assay, we provide evidence that 2-AG triggers microglial cell migration. This effect of 2-AG occurs through CB2 and abnormal-cannabidiol-sensitive receptors, with subsequent activation of the extracellular signal-regulated kinase 1/2 signal transduction pathway. It is important to note that cannabinol and cannabidiol, two nonpsychotropic ingredients present in the marijuana plant, prevent the 2-AG-induced cell migration by antagonizing the CB2 and abnormal-cannabidiol-sensitive receptors, respectively. Finally, we show that microglial cells express CB2 receptors at the leading edge of lamellipodia, which is consistent with the involvement of microglial cells in cell migration. Our study identifies a cannabinoid signaling system regulating microglial cell migration. Because this signaling system is likely to be involved in recruiting microglial cells toward dying neurons, we propose that cannabinol and cannabidiol are promising nonpsychotropic therapeutics to prevent the recruitment of these cells at neuroinflammatory lesion sites.

The diversity in the vanilloid (TRPV) receptor family of ion channels.

Following cloning of the vanilloid receptor 1 (VR1) at least four other related proteins have been identified. Together, these form a distinct subgroup of the transient receptor potential (TRP) family of ion channels. Members of the vanilloid receptor family (TRPV) are activated by a diverse range of stimuli, including heat, protons, lipids, phorbols, phosphorylation, changes in extracellular osmolarity and/or pressure, and depletion of intracellular Ca2+ stores. However, VR1 remains the only channel activated by vanilloids such as capsaicin. These channels are excellent molecular candidates to fulfil a range of sensory and/or cellular roles that are well characterized physiologically. Furthermore, as novel pharmacological targets, the vanilloid receptors have potential for the development of many future disease treatments.

An evolutionary view of drug-receptor interaction: the bioamine receptor family.

The large molecular diversity of receptors and their subtypes means that the pharmacologist is faced with many puzzling characterization questions. First, the molecular diversity of the receptors is deciphered only in part by a pharmacological approach, which precludes a satisfactory receptor classification based solely on pharmacological characteristics. Second, the physiological counterpart of the numerous subtypes of receptors specifically activated by single endogenous ligands remains unclear. Here, Philippe Vernier and colleagues use the example of the bioamine G protein-coupled receptors to show that many of the apparent inconsistencies that emerge from pharmacological and molecular characterizations of receptors can be better understood if the evolutionary history of the receptors is taken into account.

Pharmacology of cannabinoid CB1 and CB2 receptors.

There are at least two types of cannabinoid receptors, CB1 and CB2, both coupled to G-proteins. CB1 receptors are present in the central nervous system and CB1 and CB2 receptors in certain peripheral tissues. The existence of endogenous cannabinoid receptor agonists has also been demonstrated. These discoveries have led to the development of selective cannabinoid CB1 and CB2 receptor ligands. This review focuses on the classification, binding properties, effector systems and distribution of cannabinoid receptors. It also describes the various cannabinoid receptor agonists and antagonists now available and considers the main in vivo and in vitro bioassay methods that are generally used.

Receptor classification: post genome.

Most of the G-protein-coupled receptors (GPCRs) in the human genome have been described. Investigation will now shift from discovery to analysis. Like many other genes, those encoding GPCRs are frequently found adjacent to each other in clusters. Duplicated genes often share ligands, signalling pathways and amino acid sequence. But, GPCRs do not have to be adjacent to be similar to each other. Phylogenetic analysis divides Family A GPCRs into many clusters that, more often than not, share similar types of ligands. Communication of these types of data for hundreds of GPCRs requires a robust and accepted nomenclature, Locus Link symbols are suggested.

The endogenous cannabinoid anandamide is a lipid messenger activating cell growth via a cannabinoid receptor-independent pathway in hematopoietic cell lines.

The effect of anandamide, an endogenous ligand for central (CB1) and peripheral (CB2) cannabinoid receptors, was investigated on the growth of the murine IL-6-dependent lymphoid cell line B9 and the murine IL-3-dependent myeloblastic cell line FDC-P1. In conditions of low serum level, anandamide potentiated the growth of both cytokine-dependent cell lines. Comparison with other fatty acid cannabinoid ligands such as (R)-methanandamide, a ligand with improved selectivity for the CB1 receptor, or palmitylethanolamide, an endogenous ligand for the CB2 receptor, showed a very similar effect, suggesting that cell growth enhancement by anandamide or its analogs could be mediated through either receptor subtype. However, several lines of evidence indicated that this growth-promoting effect was cannabinoid receptor-independent. First, the potent synthetic cannabinoid agonist CP 55940, which displays high affinity for both receptors, was inactive in this model. Second, SR 141716A and SR 144528, which are potent and specific antagonists of CB1 and CB2 receptors respectively, were unable, alone or in combination, to block the anandamide-induced effect. Third, inactivation of both receptors by pretreatment of cells with pertussis toxin did not affect the potentiation of cell growth by anandamide. These data demonstrated that neither CB1 nor CB2 receptors were involved in the anandamide-induced effect. Moreover, using CB2-transfected Chinese hamster ovary cells, we demonstrated that after complete blockade of the receptors by the specific antagonist SR 144528, anandamide was still able to strongly stimulate a mitogen-activated protein (MAP) kinase activity, clearly indicating that the endogenous cannabinoid can transduce a mitogenic signal in the absence of available receptors. Finally, arachidonic acid, a structurally related compound and an important lipid messenger without known affinity for cannabinoid receptors, was shown to trigger MAP kinase activity and cell growth enhancement similar to those observed with anandamide. These findings provide clear evidence for a functional role of anandamide in activating a signal transduction pathway leading to cell activation and proliferation via a non-cannabinoid receptor-mediated process.

A non-pungent resiniferatoxin analogue, phorbol 12-phenylacetate 13 acetate 20-homovanillate, reveals vanilloid receptor subtypes on rat trigeminal ganglion neurons.

Capsaicin, the vanilloid responsible for the pungent taste of hot peppers, binds to receptors found primarily in polymodal nociceptors. Capsaicin initially stimulates polymodal nociceptors and subsequently inhibits them from responding to a variety of stimuli. This property makes it useful clinically as an analgesic and anti-inflammatory compound. There is mounting, albeit indirect, evidence for the existence of several subtypes of vanilloid receptors. One such piece of evidence comes from studying analogues of capsaicin, such as phorbol 12-phenylacetate 13 acetate 20-homovanillate. This compound binds to (capsaicin) vanilloid receptors on sensory neurons, but unlike capsaicin it is non-pungent and does not produce hypothermia. To determine how sensory neurons respond to phorbol 12-phenylacetate 13 acetate 20-homovanillate, and to compare these responses with those evoked by capsaicin, whole-cell patch-clamp measurements were performed on cultured rat trigeminal ganglion neurons. It was found that 63% of the neurons held at -60 mV were activated by 3 microM, phorbol 12-phenylacetate 13 acetate 20-homovanillate, and 87% of these were also activated by 1 microM capsaicin. In a given neuron, phorbol 12-phenylacetate 13 acetate 20-homovanillate, like capsaicin, could activate kinetically distinct inward currents. The current-voltage curves characterizing phorbol 12-phenylacetate 13 acetate 20-homovanillate responses were asymmetric and had reversal potentials at -5.8 +/- 6.0 mV and 10.4 +/- 4 mV. The averaged dose-response curves for phorbol 12-phenylacetate 13 acetate 20-homovanillate were fit to the Hill equation and had binding constants (K(1/2)s) of 2.73 microM and 0.96 microM and Hill coefficients (ns) of approximately 1 for a rapidly- and slowly-activating current, respectively. These parameters are consistent with those obtained from binding experiments and calcium-influx experiments on sensory nerves. Repeated applications of phorbol 12-phenylacetate 13 acetate 20-homovanillate every 3 min caused a complete reduction in the rapidly-activating currents leaving only a reduced slowly-activating current. This provides strong evidence for the independence of these currents and the existence of subtypes of vanilloid receptors. Additional evidence for the existence of receptor subtypes is that 10 microM capsazepine, a specific and competitive inhibitor of capsaicin-evoked responses, did not inhibit the phorbol 12-phenylacetate 13 acetate 20-homovanillate-induced currents in some neurons and partially inhibited them in other neurons. Thus, there are capsazepine-sensitive and capsazepine-insensitive subtypes of vanilloid receptors. In summary, we have obtained electrophysiological and pharmacological evidence for distinct subtypes of vanilloid receptors.

The relative contribution of affinity and efficacy to agonist activity: organ selectivity of noradrenaline and oxymetazoline with reference to the classification of drug receptors.

Oxymetazoline demonstrated a pronounced organ selectivity, when compared to noradrenaline, by being a potent full agonist in rat anococcygeus muscle and a partial agonist in rat vas deferens. Responses of rat anococcygeus muscles to oxymetazoline were relatively more sensitive to antagonism by phenoxybenzamine (Pbz) an alkylating alpha-adrenoceptor antagonist. Therefore, although oxymetazoline was more potent than noradrenaline in this tissue, after Pbz (0.3 microM for 10 min), the responses to oxymetazoline were completely inhibited while those to noradrenaline were only partially inhibited. Schild analysis with phentolamine, corynanthine, prazosin and yohimbine indicated no alpha-adrenoceptor heterogeneity within the rat anococcygeus muscle or between this tissue and rat vas deferens. Measurement of agonist Kd values and Schild analysis of oxymetazoline antagonism of responses to noradrenaline (after alkylation) confirmed the homogeneity of alpha-adrenoceptors with respect to these two agonists. The above profiles of activity would be predicted if oxymetazoline had a higher affinity but lower efficacy than noradrenaline. Experimentally this was confirmed when it was found that oxymetazoline had 5 times the affinity but 0.2 to 0.3 times the efficacy of noradrenaline. These results serve as a caveat to the use of selective receptor desensitization and/or selective receptor alkylation (or protection from alkylation) as means of differentiating drug receptors. Theoretical modelling and these experimental results indicate that high affinity/low efficacy agonists are much more sensitive to receptor coupling. The implications for therapeutic selectivity could be important in that high affinity/low efficacy agonists theoretically have a much greater potential for organ selectivity.

Current status of drug receptor nomenclature: receptor closure? The role of NC-IUPHAR.

Pharmacology is at a crucial point, because we now have access to sequences, by homology, for almost all of the receptors in the human genome. The International Union of Pharmacology Committee on Receptor Nomenclature and Drug Classification (NC-IUPHAR) has set up > 50 subcommittees to define the receptors, and their recommendations, when approved, are posted on a website freely available to all scientists. A major new effort is to functionally define relevant receptor polymorphisms. This initiative is open to all, and works only because of the freely given voluntary effort of scientists.

Imidazoline receptors, subclassification, and drug-induced regulation.

Overall, as summarized in TABLE 6, a variety of responses to chronic drug treatment were observed depending on the drug, the tissue, and the ligand. Taken together these studies support the concept that the three ligands bind to distinct sites. In addition, they suggest that idazoxan and possibly yohimbine act as agonists at the I2 site in kidney. Finally, the lack of regulation of the I1 site in hindbrain is consistent with the low incidence of withdrawal symptoms reported with imidazoline-preferring drugs.

Presynaptic imidazoline receptors. New developments in characterization and classification.

Presynaptic imidazoline receptors (IRs) which inhibit norepinephrine (NE) release from sympathetic nerve endings have been identified in cardiovascular tissue of man, rabbit, rat, and guinea pig. They do not belong to one of the classical presynaptic inhibitory receptor classes such as alpha 2-adrenoceptors or H3 histamine receptors, and there is also no relation to I1- and I2-imidazoline binding sites. Segments of human right atrial appendages preincubated with [3H]NE were used to determine unknown pharmacologic properties of the presynaptic IRs. In the presence of 1 microM rauwolscine, S23230, the (-)-enantiomer of the racemic oxazoline derivative S22687 (5-(2(methyl-phenoxy-methyl)-1,3-oxazoline-2-yl)amine) exhibited low potency in inhibiting the electrically evoked [3H]NE release (pIC30% = 4.96), whereas the (+)-enantiomer S23229 and the racemate S22687 were ineffective. The IR-mediated inhibitory effect of the imidazoline BDF 6143 (4-chloro-2-(2-imidazolin-2-ylamino)-isoindoline) and the guanidine aganodine on evoked [3H]NE release from sympathetic nerves in human atrial appendages was counteracted by rauwolscine (with very low potency) and by the cannabinoid CB1-receptor antagonist SR141715A (N-[piperdin-1-yl]-5-[4-chlorophenyl]-2,4-dichlorophenyl]-4- methyl-1H-pyrazole-3-carboxamide). The inhibitory effect of moxonidine on evoked [3H]NE release (which is exclusively mediated via activation of alpha 2-autoreceptors) was antagonized with high potency by rauwolscine, but not by SR141716A. The cannabinoid CB1 receptor agonists CP55,940([(-)-Cis-3-[2-hydroxy-4-(1,1-dimethylheptyl)phenyl] -trans-4- (3-hydroxy-propyl)cyclohexane]) and anandamide inhibited evoked [3H]NE release. Inhibition by CP55,940 and anandamide was abolished by 1 microM SR141716A as well as by 30 microM rauwolscine. In radioligand binding experiments on membranes from human atrial appendages (alpha 2- and sigma-binding sites were masked), cannabinoid receptor ligands and IR agonists displaced the radiolabeled guanidine derivative [3H]DTG (1,3-di-o-tolyguanidine, an agonist at presynaptic IRs) from its binding sites. Comparison of the potencies of these drugs determined in the competition experiments with [3H]DTG with those in inhibiting NE release via activation of the presynaptic IRs in the same tissue revealed a correlation. The present results suggest, e.g., that the presynaptic IRs may have certain binding domains in common with presynaptic cannabinoid receptors or that both receptors are different proteins which interact with each other in an unknown manner.

Possible structural and functional relationships between imidazoline receptors and alpha 2-adrenoceptors.

Although it is now well established that imidazoline receptors and alpha 2-adrenoceptors are discrete entities with distinct endogenous ligands, the two receptor classes apparently have several common features. While the catecholamines stimulate alpha 2-adrenoceptors but not imidazoline receptors, agmatine, a guanidine analog that may be an endogenous imidazoline receptor ligand, can interact with both I1 and I2 imidazoline receptors as well as alpha 2-adrenoceptors, although, interestingly, other guanidines such as guanabenz are highly selective for alpha 2-adrenoceptors versus I1 receptors. Most I1 receptor agonists such as moxonidine, rilmenidine, and clonidine can also stimulate alpha 2-adrenoceptors, and the same physiological response is produced by activation of central I1 receptors and alpha 2-adrenoceptors, but their anatomical locations differ. The imidazoline idazoxan is an antagonist at I1, I2, and alpha 2-receptors, but minor structural alterations of idazoxan can result in molecules with selectivity for either alpha 2-adrenoceptors or imidazoline receptors. The precise mode of interaction of imidazoline agonists and antagonists with the alpha 2-adrenoceptor is not yet understood, and structures of the imidazoline receptors are still unknown. Nevertheless, the fact that many agents can stimulate or block both receptor classes, combined with the fact that alpha 2-adrenoceptors and I1 receptors can mediate identical physiological responses, suggests that many common structural features may be present.

Pharmacologic and molecular discrimination of I2-imidazoline receptor subtypes.

I2-imidazoline receptors (I2-IR) are characterized by their high affinity for imidazolines and guanidines and medium affinity for imidazolidines. The differential recognition of I2-IR by amiloride led to subtype these sites as amiloride-sensitive (I2A-IR) and amiloride-insensitive (I2B-IR). I2-IR labeled with [3H]idazoxan or [3H]2-BFI in the rabbit cerebral cortex (I2A-IR) displayed higher affinities for amiloride and amiloride analogs than in the rat cerebral cortex (I2B-IR). Other drugs tested displayed biphasic curves in competition experiments, indicating the existence of high and low affinity sites for both I2-IR subtypes. The drugs (+)- and (-)-medetomidine, bromoxidine, moxonidine, and clorgyline were more potent on the high and/or low affinity sites of I2B-IR than on I2A-IR. Preincubation (30 min at 25 degrees C) with 10(-6) M isothiocyanatobenzyl imidazoline (IBI) or with 10(-6) M clorgyline reduced by 40% and 26%, respectively, the binding of [3H]2-BFI to I2B-IR, but it did not alter the binding of the radioligand to I2A-IR. These results indicated that the I2-IR subtypes differ in their pharmacologic profiles and in the nature of the imidazoline binding site involved in clorgyline and IBI alkylation. In rat cortical membranes, western blot detection of immunoreactive imidazoline receptor proteins revealed a double band of approximately 29/30 kD and three less intense bands of approximately 45, approximately 66, and approximately 85 kD. In rabbit cortical membranes the antibody detected proteins of approximately 30, approximately 57, approximately 66, and approximately 85 kD. It is suggested that I2-IR may be related to more than one receptor protein and that I2-IR subtypes differ in the nature of the proteins implicated.

Therapeutic potential of cannabinoids in CNS disease.

The major psychoactive constituent of Cannabis sativa, delta(9)-tetrahydrocannabinol (delta(9)-THC), and endogenous cannabinoid ligands, such as anandamide, signal through G-protein-coupled cannabinoid receptors localised to regions of the brain associated with important neurological processes. Signalling is mostly inhibitory and suggests a role for cannabinoids as therapeutic agents in CNS disease where inhibition of neurotransmitter release would be beneficial. Anecdotal evidence suggests that patients with disorders such as multiple sclerosis smoke cannabis to relieve disease-related symptoms. Cannabinoids can alleviate tremor and spasticity in animal models of multiple sclerosis, and clinical trials of the use of these compounds for these symptoms are in progress. The cannabinoid nabilone is currently licensed for use as an antiemetic agent in chemotherapy-induced emesis. Evidence suggests that cannabinoids may prove useful in Parkinson's disease by inhibiting the excitotoxic neurotransmitter glutamate and counteracting oxidative damage to dopaminergic neurons. The inhibitory effect of cannabinoids on reactive oxygen species, glutamate and tumour necrosis factor suggests that they may be potent neuroprotective agents. Dexanabinol (HU-211), a synthetic cannabinoid, is currently being assessed in clinical trials for traumatic brain injury and stroke. Animal models of mechanical, thermal and noxious pain suggest that cannabinoids may be effective analgesics. Indeed, in clinical trials of postoperative and cancer pain and pain associated with spinal cord injury, cannabinoids have proven more effective than placebo but may be less effective than existing therapies. Dronabinol, a commercially available form of delta(9)-THC, has been used successfully for increasing appetite in patients with HIV wasting disease, and cannabinoid receptor antagonists may reduce obesity. Acute adverse effects following cannabis usage include sedation and anxiety. These effects are usually transient and may be less severe than those that occur with existing therapeutic agents. The use of nonpsychoactive cannabinoids such as cannabidiol and dexanabinol may allow the dissociation of unwanted psychoactive effects from potential therapeutic benefits. The existence of other cannabinoid receptors may provide novel therapeutic targets that are independent of CB(1) receptors (at which most currently available cannabinoids act) and the development of compounds that are not associated with CB(1) receptor-mediated adverse effects. Further understanding of the most appropriate route of delivery and the pharmacokinetics of agents that act via the endocannabinoid system may also reduce adverse effects and increase the efficacy of cannabinoid treatment. This review highlights recent advances in understanding of the endocannabinoid system and indicates CNS disorders that may benefit from the therapeutic effects of cannabinoid treatment. Where applicable, reference is made to ongoing clinical trials of cannabinoids to alleviate symptoms of these disorders.

[3H]dexmedetomidine, an alpha 2-adrenoceptor agonist, detects a novel imidazole binding site in adult rat spinal cord.

Binding properties of [3H]dexmedetomidine [(+)-(S)-4-[1-(2,3-dimethylphenyl)ethyl]-1H-imidazole] as an agonist-type radioligand for alpha 2-adrenoceptors were characterised for the first time in tissues relevant to its analgesic (spinal cord from neonatal or adult rats) and behavioural (rat cerebral cortex) actions. In membranes of rat cerebral cortex (KdHigh 0.2 +/- 0.03 nM, KdLow 8.8 +/- 1.4 nM with Bmax High 130 +/- 11 fmol/mg protein, RHigh 16%) and neonatal spinal cord (KdHigh 0.3 +/- 0.04 nM, KdLow 14 +/- 3.7 nM with Bmax High 290 +/- 40 fmol/mg protein, RHigh 25%) Gpp(NH)p modifies the biphasic binding to monophasic and binding is competed with specifically by alpha 2-adrenoceptor compounds. Binding to rat cerebral cortex is not modified by pretreatment with the noradrenergic neurotoxin, DSP-4 (N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine). In contrast, [3H]dexmedetomidine binding to adult rat spinal cord membranes is more complex and both saturation analysis and competition experiments indicate the presence of a non-adrenergic component of binding (about 40% of total binding) which is sensitive to imidazole-type compounds. This non-adrenergic component of [3H]dexmedetomidine binding can be defined as a novel type of imidazole binding site such that, of the imidazoline I1 or I2 receptor ligands, only cimetidine has relatively high affinity. In conclusion, [3H]dexmedetomidine shows very complex binding characteristics that limit its use as an agonist-type radioligand for alpha 2-adrenoceptors but it may be a useful tool for imidazoline receptor characterisation.

Pharmacological and molecular discrimination of brain I2-imidazoline receptor subtypes.

I2-imidazoline receptors labelled with [3H]-idazoxan in the rabbit and rat brains displayed high and low affinity, respectively, for the guanidide amiloride; reinforcing the previous definition of I2A-imidazoline receptors expressed in the rabbit brain and I2B-imidazoline receptors expressed in the rat brain. Other drugs tested displayed biphasic curves in competition experiments, indicating the existence of high and low affinity sites for both subtypes of I2-imidazoline receptors. Among the drugs studied, bromoxidine, moxonidine, (+)- and (-)-medetomidine and clorgyline were more potent on the high and/or low affinity sites of I2B-than on their corresponding of I2A-imidazoline receptors (KiH ratios 20 to 65). No correlation was found for the potencies of the drugs tested at the low affinity sites of both I2-imidazoline receptor subtypes. Preincubation (30 min at 25 degrees C) with 10(-6) M clorgyline reduced by 60% the Bmax of [3H]-idazoxan binding to I2B-imidazoline receptors in the rat brain, but it did not affect the binding parameters of the radioligand saturation curves to I2A-imidazoline receptors in the rabbit brain. These results indicated that I2A- and I2B-imidazoline receptor subtypes differ in the pharmacological profiles of their high and low affinity sites and in the ability to irreversibly bind clorgyline. In rat cortical membranes western blot detection of immunoreactive imidazoline receptors proteins revealed a double band of approximately 29/30 kDa and two less intense bands of approximately 45 and approximately 66 kDa. In rabbit cortical membranes the antibody used detected proteins of approximately 30, approximately 57 and approximately 66 kDa. It is suggested that different imidazoline receptor proteins (approximately 45 vs approximately 57 kDa) may account for the different pharmacological profiles of I2-imidazoline receptor subtypes.

Presynaptic cannabinoid and imidazoline receptors in the human heart and their potential relationship.

Segments of human right atrial appendages preincubated with [3H]noradrenaline and superfused with physiological salt solution containing desipramine and corticosterone were used to examine whether the cardiac sympathetic nerves are endowed with cannabinoid receptors and to further study pharmacological properties of presynaptic imidazoline receptors. The cannabinoid CB1 receptor agonists CP55,940, HU210 and anandamide inhibited evoked [3H]noradrenaline release. The inhibition by CP55,940 and anandamide was abolished by the CB1 receptor antagonists SR141716A (1 microM) and LY320135 (1 microM). Rauwolscine at the imidazoline receptor-blocking concentration of 30 microM abolished the inhibitory effect of CP55,940 and anandamide. After blockade of alpha2-adrenoceptors with 1 microM rauwolscine, the imidazoline binding site ligand S23230, which is the (-)-enantiomer of the racemic oxazoline derivative S22687, exhibited low potency in inhibiting electrically evoked [3H]noradrenaline release (pIC30%=4.96), whereas the (+)-enantiomer S23229 and the racemate S22687 were ineffective. In the presence of 30 microM rauwolscine, S23230 did not significantly inhibit evoked release. The imidazoline receptor-mediated inhibitory effect of BDF 6143 and aganodine on evoked [3H]noradrenaline release was abolished by 1 microM SR141716A and by 1 microM LY320135. The inhibitory effect of moxonidine on evoked [3H]noradrenaline release, which is exclusively mediated via activation of alpha2-autoreceptors, was not antagonized by 1 microM SR141716A. In conclusion, inhibitory cannabinoid CB1 receptors are present on the sympathetic axon terminals of human atrial appendages. Presynaptic imidazoline receptors share the property of other receptors in that they can be stereoselectively activated. The cross-antagonism of imidazoline receptor agonists/antagonists with CB1 receptor antagonists/agonists suggests that these receptors may have certain binding domains in common or that they interact with each other in an unknown manner.

Characterization of methadone receptor subtypes present in human brain and lung tissues.

In addition to their use in pain control, opioids can function as regulators of tumor cell growth. We have found that the therapeutic opioid, methadone, significantly inhibits the in vitro and in vivo growth of human lung cancer cells, and this effect appears to be mediated by specific, high affinity, non-conventional opioid binding sites. The present study indicates the existence of multiple subtypes of binding sites mediating the peripheral and central nervous system actions of this drug. Pharmacological and biochemical characterizations of the methadone binding sites expressed in human brain and normal lung tissues indicate that these sites are distinct from each other and from other opioid receptor types present on human and rat brain membranes, as well as those expressed in human lung cancer cells. The identification of distinct methadone receptor types in the different tissues could lead to the development of more selective and less toxic drugs targeted toward the tumor cells.