Amphetamine decreases α2C-adrenoceptor binding of [11C]ORM-13070: a PET study in the primate brain.

BACKGROUND: The neurotransmitter norepinephrine has been implicated in psychiatric and neurodegenerative disorders. Examination of synaptic norepinephrine concentrations in the living brain may be possible with positron emission tomography (PET), but has been hampered by the lack of suitable radioligands. METHODS: We explored the use of the novel α2C-adrenoceptor antagonist PET tracer [(11)C]ORM-13070 for measurement of amphetamine-induced changes in synaptic norepinephrine. The effect of amphetamine on [(11)C]ORM-13070 binding was evaluated ex vivo in rat brain sections and in vivo with PET imaging in monkeys. RESULTS: Microdialysis experiments confirmed amphetamine-induced elevations in rat striatal norepinephrine and dopamine concentrations. Regional [(11)C]ORM-13070 receptor binding was high in the striatum and low in the cerebellum. After injection of [(11)C]ORM-13070 in rats, mean striatal specific binding ratios, determined using cerebellum as a reference region, were 1.4±0.3 after vehicle pretreatment and 1.2±0.2 after amphetamine administration (0.3mg/kg, subcutaneous). Injection of [(11)C]ORM-13070 in non-human primates resulted in mean striatal binding potential (BP ND) estimates of 0.65±0.12 at baseline. Intravenous administration of amphetamine (0.5 and 1.0mg/kg, i.v.) reduced BP ND values by 31-50%. Amphetamine (0.3mg/kg, subcutaneous) increased extracellular norepinephrine (by 400%) and dopamine (by 270%) in rat striata. CONCLUSIONS: Together, these results indicate that [(11)C]ORM-13070 may be a useful tool for evaluation of synaptic norepinephrine concentrations in vivo. Future studies are required to further understand a potential contribution of dopamine to the amphetamine-induced effect.

High-throughput screening with a miniaturized radioligand competition assay identifies new modulators of human α2-adrenoceptors.

Human α(2)-adrenoceptors (α(2)-ARs) are rhodopsin-like G-protein coupled receptors, and potential drug targets. The three different human α(2)-AR subtypes α(2A), α(2B) and α(2C) are widely distributed in tissues, but so far only a few subtype-selective ligands have been identified. In this project, we set off to conduct a large chemical screen for activity on the human α(2B)-AR and studied the selectivity of the active compounds towards the human α(2A)- and α(2C)-AR subtypes. We employed a radioligand competition binding assay that was optimized and miniaturized into a robotic environment. Membrane fractions containing recombinant human receptor subtypes were prepared from stably transfected Chinese hamster ovary (CHO) cell lines. Initially identified hits were followed up and characterized, and chemoinformatics tools were applied to gain better understanding of the relevance of the results. After a primary screen against α(2B)-AR, 176 compounds of the 17,952 included in the library were declared as active at 10 µM, of which 89 compounds were further selected for potency and affinity determinations using the three human α(2)-AR subtypes. One of the identified positive hits was 2″,2″″-Bisepigallocatechin digallate, which was found to have high affinity at all three human α(2)-AR subtypes. This represents the first non-protonable molecule identified as able to interact with these receptors. Additionally, results obtained with a functional assay (agonist-induced stimulation of [(35)S]GTPγS binding) supported the identification of another positive hit, lysergol, as a partial agonist of the human α(2)-AR subtypes. The dataset of confirmed active chemical species represents a readily available, high quality source for follow-up studies. Altogether, these results provide novel research approaches for drug discovery of modulators of the α(2)-AR subtypes.

Might the observed α(2A)-adrenoreceptor agonism or antagonism of allyphenyline analogues be ascribed to different molecular conformations?

We recently reported that the α(2)-adrenoreceptor (AR) ligand allyphenyline (9) significantly enhanced morphine analgesia (due to its α(2C)-AR agonism), was devoid of sedative side effects (due to its α(2A)-AR antagonism), prevented and reversed morphine tolerance and dependence. To highlight the molecular characteristics compatible with this behaviour and to obtain novel agents potentially useful in chronic pain and opioid addiction management, the allyl group of 9 was replaced by substituents of moderate steric bulk (MR) and positive or negative lipophilic (π) and electronic (σ) contributions in all the possible combinations. Effective novel α(2C)-agonists/α(2A)-antagonists (2, 3, 10, 12, and 17) were obtained. This study also demonstrated that contradictory combinations of the physicochemical parameters were similarly able to induce the α(2A)-activation. Since we had previously observed that the absolute configuration affected only the potency, but not the functional profile of the ligands, we hypothesized that the α(2A)-activation was governed by a ligand preferred conformation. From a structural overlay investigation it emerged that an extended conformation appeared to be associated with dual α(2C)-agonism/α(2A)-antagonism, whereas a folded conformation associated with α(2C)-/α(2A)-agonism.

Octopamine receptors from the barnacle balanus improvisus are activated by the alpha2-adrenoceptor agonist medetomidine.

G protein-coupled octopamine receptors of insects and other invertebrates represent counterparts of adrenoceptors in vertebrate animals. The alpha(2)-adrenoceptor agonist medetomidine, which is in clinical use as a veterinary sedative agent, was discovered to inhibit the settling process of barnacles, an important step in the ontogeny of this crustacean species. Settling of barnacles onto ship hulls leads to biofouling that has many harmful practical consequences, and medetomidine is currently under development as a novel type of antifouling agent. We now report that medetomidine induces hyperactivity in the barnacle larvae to disrupt the settling process. To identify the molecular targets of medetomidine, we cloned five octopamine receptors from the barnacle Balanus improvisus. We show by phylogenetic analyses that one receptor (BiOctalpha) belongs to the alpha-adrenoceptor-like subfamily, and the other four (BiOctbeta-R1, BiOctbeta-R2, BiOctbeta-R3, and BiOctbeta-R4) belong to the beta-adrenoceptor-like octopamine receptor subfamily. Phylogenetic analyses also indicated that B. improvisus has a different repertoire of beta-adrenoceptor-like octopamine receptors than insects. When expressed in CHO cells, the cloned receptors were activated by both octopamine and medetomidine, resulting in increased intracellular cAMP or calcium levels. Tyramine activated the receptors but with much lesser potency than octopamine. A hypothesis for receptor discrimination between tyramine and octopamine was generated from a homology three-dimensional model. The characterization of B. improvisus octopamine receptors is important for a better functional understanding of these receptors in crustaceans as well as for practical applications in development of environmentally sustainable antifouling agents.

Structure-activity relationship of quinoline derivatives as potent and selective alpha(2C)-adrenoceptor antagonists.

Starting from two acridine compounds identified in a high-throughput screening campaign (1 and 2, Table 1), a series of 4-aminoquinolines was synthesized and tested for their properties on the human alpha(2)-adrenoceptor subtypes (alpha(2A), alpha(2B), and alpha(2C)). A number of compounds with good antagonist potencies against the alpha(2C)-adrenoceptor and excellent subtype selectivities over the other two subtypes were discovered. For example, (R)-{4-[4-(3,4-dimethylpiperazin-1-yl)phenylamino]quinolin-3-yl}methanol 6j had an antagonist potency of 8.5 nM against, and a subtype selectivity of more than 200-fold for, the alpha(2C)-adrenoceptor. Investigation of the structure-activity relationship identified a number of structural features, the most critical of which was an absolute need for a substituent in the 3-position of the quinoline ring. The 3-position on the piperazine ring was also found to play an appreciable role, as substitutions in that position exerted a significant and stereospecific beneficial effect on the alpha(2C)-adrenoceptor affinity and potency. Replacing the piperazine ring proved difficult, with 1,4-diazepanes representing the only viable alternative.

Agonist-dependent trafficking of alpha2-adrenoceptor subtypes: dependence on receptor subtype and employed agonist.

Many G protein-coupled receptors (GPCRs) are internalized from the plasma membrane after agonist exposure. Previously, marked agonist-induced internalization of human alpha2A- and alpha2B-adrenergic receptors (AR) was observed in transfected neuronal rat pheochromocytoma (PC12) cells; alpha2A- and alpha2B-AR were internalized into partly distinct intracellular vesicles (Olli-Lähdesmäki et al., J. Neurosci. 19, 9281-9288, 1999). In this paper, the extent of alpha2-AR internalization was quantitated in human embryonic kidney (HEK-293) and PC12 cells by combined application of cell surface biotinylation and ELISA methods, which allow measurement of protein trafficking in intact, differentiated and undifferentiated cells. Significant subtype-specific (but not cell type-dependent) trafficking of human alpha2-AR was observed by quantitation and immunocytochemistry. Agonist-induced sequestration of alpha2B-AR was markedly reduced after blocking the formation of clathrin-coated vesicles by hyperosmotic sucrose pretreatment. The sequestration of alpha2A-AR was partly inhibited after sucrose pretreatment but could be further reduced after inhibiting the formation of both clathrin-coated and caveolin vesicles by combined pretreatment with hyperosmotic sucrose and filipin. Differences were also observed in the recycling of alpha2A- and alpha2B-AR. The extent of maximal agonist-induced sequestration in PC12 cells was not directly dependent on relative agonist efficacy.