Catecholamine binding

Abstract: We compared the pharmacological properties of the alpha 2-adrenergic radioligand [3H]idazoxan with those of [3H]rauwolscine in rat and [3H]yohimbine in human renal cortical membranes. The density of "specific" [3H]idazoxan binding sites (defined by 100 microM tolazoline) was twice as high as that of [3H]rauwolscine in rat kidney and four times as high as that of [3H]yohimbine in human kidney. A variety of structurally different drugs fully competed for specific [3H]rauwolscine and [3H]yohimbine binding, with affinities appropriate for the interaction with alpha 2-adrenergic receptors. Specific [3H]idazoxan binding, however, was only partially competed for by the catecholamines epinephrine and norepinephrine in both tissues. Thus, [3H]idazoxan labels both alpha 2-adrenergic receptors and a nonadrenergic site. Clonidine, B-HT 920, moxonidine, phentolamine, prazosin, yohimbine, dopamine, and serotonin also could not compete for this site. However, UK 14,304, guanabenz, indanidine, tolazoline, oxymetazoline, and SK&F 104,078 competed for the additional [3H]idazoxan sites with affinities similar to those at alpha 2-adrenergic receptors. [3H]idazoxan binding substantially in excess of [3H]rauwolscine or [3H]yohimbine binding was also found in human platelets, myometrium, and erythroleukemia (HEL) cells but not in three cell lines lacking alpha 2-receptors (MDCK, BC3H1, and Jurkat cells). Although we have been unsuccessful thus far in defining the precise nature of the additional [3H]idazoxan binding sites, we hypothesize that these sites may be closely affiliated with alpha 2-adrenergic receptors but clearly distinct from the catecholamine binding site of the receptor. The results indicate that care must be taken in the use of [3H]idazoxan or drugs that are recognized at its nonadrenergic site when studying alpha 2-adrenergic effects and receptor subtypes.

Abstract: The adenylate cyclase-coupled beta-adrenergic receptors of frog erythrocyte membranes have been identified by direct radioligand binding techniques using the potent catecholamine agonist (+/-)[3H]hydroxybenzylisproterenol (2-[3, 4-dihydroxyphenyl]-2-hydroxy-1', 1'-dimethyl-2'-[4-hydroxyphenyl]-diethylamine). The successful experimental conditions included the use of (i) high concentrations of catechol and ascorbic acid to suppress nonreceptor binding, (ii) a very potent radiolabeled catecholamine (10 times more potent than isoproterenol), and (iii) membranes rich in binding sites for beta-adrenergic receptors. Thus, previous problems in accomplishing successful catecholamine binding to the beta-receptors have been overcome. The binding sites identified with (+/-)[3H]hydroxybenzylisoproterenol in the erythrocyte membranes have all the characteristics expected of true beta-adrenergic receptors. These include rapidity of binding, saturability, specificity for beta-agonists and antagonists, and stereospecificity [(-)isomers more potent than (+)isomers]. Physiologically inactive compounds containing a catechol moiety do not compete for occupancy of these binding sites. Dissociation of the radiolabeled agonist from the receptors is slow and incomplete in the absence of guanine nucleotides. In the presence of nucleotide, however, dissociation is rapid and complete. beta-Adrenergic agonists and antagonists compete for the (+/-)[3H]hydroxybenzylisoproterenol binding sites in a fashion parallel to their competition for the receptors, as previously delineated with the beta-adrenergic antagonist (-)[3H]dihydroalprenolol.

Abstract: The human genome encodes nine different adrenoceptor genes. These are grouped into three families, namely, the α1-, α2-, and β-adrenoceptors, with three family members each. Adrenoceptors are expressed by most cell types of the human body and are primary targets of the catecholamines epinephrine and norepinephrine that are released from the sympathetic nervous system during its activation. Upon catecholamine binding, adrenoceptors change conformation, couple to and activate G proteins, and thereby initiate various intracellular signaling cascades. As the primary receivers and transducers of sympathetic activation, adrenoceptors have a central role in human physiology and disease and are important targets for widely used drugs. All nine adrenoceptor subtypes display substantial genetic variation, both in their coding sequence as well as in adjacent regions. Despite the fact that some of the adrenoceptor variants range among the most frequently studied genetic variants assessed in pharmacogenetics to date, their functional relevance remains ill defined in many cases. A substantial fraction of the associations reported from early candidate gene approaches have not subsequently been confirmed in different cohorts or in genome-wide association studies, which have increasingly been conducted in recent years. This review aims to provide a comprehensive overview of all adrenoceptor variants that have reproducibly been detected in the larger genome sequencing efforts. We evaluate these variants with respect to the modulation of receptor function and expression and discuss their role in physiology and disease.