The hepatic alpha 1-adrenergic receptor

Since the relatively recent advent of radioligand binding techniques, it has been possible to directly identify and characterize hepatic adrenergic receptors as well as study their physiological regulation. While it is now clear that alpha 1-adrenergic receptors constitute the major population of hepatic adrenergic receptors and are primarily responsible for the actions of catecholamines in liver, relatively little is known about the molecular mechanisms underlying alpha 1-responses. Recent results suggest that guanine nucleotides may be implicated in the transmission of the hormonal signal from the hepatic alpha 1-receptor to its effectors in a manner analogous to that described for adenylate cyclase-linked receptors. The lack of an easily measurable proximal membrane response for the alpha 1-receptor has been a severe handicap in our understanding of the mechanism of transmission of the hormonal signal. It is likely that until such a response is defined, alpha 1-adrenergic research will continue to lag behind research on the beta-adrenergic receptor.     

Glycogen phosphorylase activation by two different alpha 1-adrenergic receptor subtypes: methoxamine selectively stimulates a putative alpha 1-adrenergic receptor subtype (alpha 1a) that couples with Ca2+ influx

We compared the effects of methoxamine on alpha 1-adrenergic receptor-mediated phosphorylase activation in rat hepatocytes and rabbit aorta. Although methoxamine is a potent agonist in activating phosphorylase of rabbit aorta, it had little effect in rat hepatocytes. Using the phenoxybenzamine inactivation method, we found that the quantitative relationship between 125I-BE2254 (125I-BE) binding capacity and maximal norepinephrine-stimulated phosphorylase activation was nonlinear in rabbit aorta, whereas it was linear in rat hepatocytes. The potency of methoxamine in inhibiting specific 125I-BE binding is significantly (p less than 0.05) higher in rabbit aorta (Kd, 96.4 +/- 7.7 microM), compared with rat hepatocytes (Kd, 283 +/- 16 microM). However, these quantitative differences could not fully explain the blunted [Ca2+]c and phosphorylase responses to methoxamine in rat hepatocytes. Treatment with chlorethylclonidine dose dependently suppressed 125I-BE binding sites and norepinephrine-induced phosphorylase activation in rat hepatocytes, whereas in rabbit aorta it resulted in only a 31% decrease in 125I-BE binding sites, with little effect on phosphorylase activation. Furthermore, alpha 1-adrenergic receptor-mediated cellular events of phosphatidylinositol (PI) hydrolysis and phosphorylase activation were unaffected by the removal of extracellular Ca2+ in rat hepatocytes, whereas both responses were markedly attenuated in rabbit aorta. The results indicate that two different alpha 1-adrenergic receptor subtypes activate glycogen phosphorylase, through different mechanisms for increasing [Ca2+]c in the two systems. In rat hepatocytes, alpha 1 receptors are closely linked to PI hydrolysis and Ca2+ release from intracellular stores and cause phosphorylase activation. In rabbit aorta, on the other hand, activation of alpha 1 receptors increases [Ca2+]c by Ca2+ influx from the extracellular fluid as well as by Ca2+ release, and both PI hydrolysis and phosphorylase activation are caused mainly by the Ca2+ entry. Methoxamine interacts with both chlorethylclonidine-sensitive and -insensitive alpha 1 receptor subtypes but selectively stimulates the alpha 1 receptor subtype that closely couples with the Ca2+ influx.     

Inverse agonism and neutral antagonism at alpha(1a)- and alpha(1b)-adrenergic receptor subtypes.

We have characterized the pharmacological antagonism, i.e., neutral antagonism or inverse agonism, displayed by a number of alpha-blockers at two alpha1-adrenergic receptor (AR) subtypes, alpha(1a)- and alpha(1b)-AR. Constitutively activating mutations were introduced into the alpha(1a)-AR at the position homologous to A293 of the alpha(1b)-AR where activating mutations were previously described. Twenty-four alpha-blockers differing in their chemical structures were initially tested for their effect on the agonist-independent inositol phosphate response mediated by the constitutively active A271E and A293E mutants expressed in COS-7 cells. A selected number of drugs also were tested for their effect on the small, but measurable spontaneous activity of the wild-type alpha(1a)- and alpha(1b)-AR expressed in COS-7 cells. The results of our study demonstrate that a large number of structurally different alpha-blockers display profound negative efficacy at both the alpha(1a)- and alpha(1b)-AR subtypes. For other drugs, the negative efficacy varied at the different constitutively active mutants. The most striking difference concerns a group of N-arylpiperazines, including 8-[2-[4-(5-chloro-2-methoxyphenyl)-1-piperazinyl]ethyl]-8-azaspiro [4, 5] decane-7,9-dione (REC 15/3039), REC 15/2739, and REC 15/3011, which are inverse agonists with profound negative efficacy at the wild-type alpha(1b)-AR, but not at the alpha(1a)-AR.     

Recent progress in α1-adrenergic receptor research

Alpha1-Adrenergic receptors (AR) play an important role in the regulation of physiological responses mediated by norepinephrine and epinephrine, particularly in the cardiovascular system. The three cloned alpha1-AR subtypes (alpha1A, alpha1B, and alpha1D) are G protein-coupled receptors that signal through the Gq/11 signaling pathway, each showing distinct pharmacological properties and tissue distributions. However, due to the lack of highly subtype-selective drugs, the functional roles of individual subtypes are still not clear. Development of new subtype-specific drugs will greatly facilitate the identification of the functions of each subtype. Conopeptide rho-TIA has been found to be a new alpha1B-AR selective antagonist with different modes of inhibition at alpha1-AR subtypes. In addition, recent studies using genetically engineered mice have shed some light on alpha1-AR functions in vivo, especially in the cardiovascular system and brain. Several proteins have been shown to interact directly with particular alpha1-AR, and may be important in regulating receptor function. Receptor heterodimerization has been shown to be important for cell surface expression, signaling and internalization. These new observations are likely to help elucidate the functional roles of individual alpha1-AR subtypes.     

Arylpiperazines with affinity toward alpha(1)-adrenergic receptors

In the last years, alpha(1) adrenoceptors (alpha(1)-AR) have been the subject of intense research, in part because receptor-binding studies and molecular biology have opened up new aspects of understanding but also because of the potential to find new drugs possibly acting toward pathophysiological processes where alpha(1)-AR are involved, such as benign prostatic hyperplasia (BPH) or hypertension. At present, arylpiperazines represent one of the most studied classes of molecules with affinity at alpha(1)-AR. In fact, a large amount of work has been done and reported, describing synthetic procedures, biological evaluation at both alpha(1)-AR and the corresponding subtypes, and structure-activity relationships (SARs). In this paper, a review based on a literature survey aimed at focusing on the structural properties that a compound should possess to show affinity toward alpha(1)-AR is presented. Moreover, the identification and optimization of the structural features of a hit compound derived from a pharmacophore-based database search, leading to a new class of arylpiperazinylalkyl pyridazinone derivatives with alpha(1)-AR affinity is reported.     

Inverse agonist activity at the alpha(2A)-adrenergic receptor

Constitutive activation of G protein-coupled receptors (GPCRs) is now well recognized and many classical GPCR antagonists have been found to be inverse agonists. For the alpha(2A)-adrenergic receptor (AR) we determine the relative inverse efficacies of a series of antagonists and utilize the extended ternary complex model to estimate the fraction of constitutively active mutant (CAM) receptors in the active state. Stable Chinese hamster ovary cell lines expressing the porcine alpha(2A)-AR in its wild-type (WT) and constitutively activated (CAM-T373K) form were isolated. Activation of both G(i) and G(s) was enhanced for CAM receptors. cAMP production was suppressed in cells with the CAM alpha(2A)-AR and this suppression was reversed by alpha(2)-adrenergic antagonists with an order of inverse efficacy of rauwolscine > yohimbine > RX821002 > MK912, whereas phentolamine and idazoxan were essentially neutral antagonists. This striking difference in inverse efficacy between idazoxan and RX821002 may account for in vivo pharmacological differences between these two alpha(2)-adrenergic antagonists. Agonist binding affinity to the non-G protein-coupled CAM receptor was 3- to 9-fold higher than to WT, whereas binding of the most efficacious inverse agonists, yohimbine and rauwolscine, was 1.7- and 2.1-fold weaker. Analysis of this difference by the extended ternary complex model indicates that approximately 50% of the CAM alpha(2A)-AR is in the active (R*) state although there is no detectable constitutive activity of the WT receptor in the absence of agonist.     

Identification and structural characterization of alpha 1-adrenergic receptor subtypes

Rat liver and brain membrane alpha 1-adrenergic receptors were purified greater than 500-fold by successive chromatographic steps using heparin-agarose, an affinity matrix constructed by coupling a novel derivative of the alpha 1-selective antagonist prazosin to Affigel-102 and wheat germ agglutinin-agarose. Several lines of evidence were obtained for the existence in brain of an alpha 1-adrenergic receptor subtype that is structurally distinct from that previously characterized in liver and other tissues using photoaffinity labeling, protein purification, and DNA cloning techniques. The alpha 1-selective ligand chlorethylclonidine (CEC) (an alkylating agent) irreversibly inactivates 100% of [3H]prazosin binding sites in partially purified preparations of rat liver. Under identical conditions, only 50% of brain receptors are irreversibly inactivated. Computer modeling of data obtained from the competition by the alpha antagonists WB4101 and phentolamine for [3H]prazosin binding to partially purified preparations of rat liver is best fit by assuming a single class of low affinity sites for both ligands. However, analysis of partially purified brain preparations indicates the presence of two binding sites with different affinities for these antagonists. Additionally, prior alkylation of brain receptors with CEC results in the loss of low affinity phentolamine and WB4101 binding sites. The CEC-insensitive site in brain, which displays high affinity for phentolamine and WB4101, is resistant to photoaffinity labeling by [125I]azidoprazosin. This is not due to a markedly lower affinity of the CEC-insensitive sites for the photoaffinity label, because competition studies with [127I]azidoprazosin revealed a single class of high affinity sites in partially purified brain samples. Photoaffinity labeling of partially purified liver and brain samples not treated with CEC results in the specific labeling of a single protein of Mr 80,000. No specifically labeled protein is observed for partially purified brain samples that had previously been incubated with CEC. Treatment of photoaffinity-labeled liver and brain receptors with N-glycanase to cleave N-linked oligosaccharides results in a single Mr 55,000 protein. Taken together, these data provide evidence for the existence of a single receptor subtype (alpha 1b) in rat liver and for two subtypes (alpha 1a and alpha 1b) in rat brain. Furthermore, the insensitivity of the alpha 1a subtype to CEC and the resistance of the alpha 1a subtype to covalent labeling by an alpha 1b-selective photoaffinity probe suggest that the primary structures of the two receptor subtypes differ, such that an amino acid(s) in the alpha 1b subtype that incorporates CEC and the photoaffinity label is lacking in the alpha 1a subtype.     

Adenosine A(1) receptor stimulation inhibits alpha(1)-adrenergic activation of the cardiac sarcolemmal Na(+)/H(+) exchanger

Sarcolemmal Na(+)/H(+) exchanger (NHE) activity is increased by stimulation of G(q) protein-coupled receptors (G(q)PCRs), but the roles of other GPCRs are largely unknown. We determined the effects of N-[(1S,trans)-2-hydroxycyclopentyl]adenosine (GR79236), a selective agonist of the G(i)PCR adenosine A(1) receptor, on sarcolemmal NHE activity in adult rat ventricular myocytes (n=8-10 per group). NHE activity was indexed by the H(+) efflux rate after intracellular acidification, measured by microepifluorescence. GR79236 alone (0.01-10 microM) had no effect on NHE activity. However, co-administration of GR79236 inhibited, in a concentration-dependent manner, the stimulation of NHE activity by the alpha(1)-adrenoceptor agonist phenylephrine (10 microM). The inhibitory effect of GR79236 (10 microM) was abolished by (1) the selective A(1) antagonist 1,3-dipropyl-8-cyclopentylxanthine (0.1 microM), confirming an A(1) receptor-mediated action, and (2) pre-treatment with pertussis toxin (5 microgram ml(-1) for 60 min), indicating a G(i) protein-mediated mechanism. Our data suggest the existence of inhibitory crosstalk between the G(i)PCR adenosine A(1) receptor and the G(q)PCR alpha(1)-adrenoceptor in the regulation of sarcolemmal NHE activity.     

Functional α1-adrenergic receptor subtypes in human right gastroepiploic artery

AIM: To study the functional alpha1-adrenergic receptor (alpha1-AR) subtypes in human right gastroepiploic artery (RGA). METHODS: The effects of alpha2-AR, alpha1-AR, and alpha1-AR subtype selective antagonists on norepinephrine (NE)-induced vasoconstriction in isolated human RGA were observed by contractile function experiment. RESULTS: Cumulative concentration-response curves for NE were competitively antagonized in RGA by alpha2-AR selective antagonist yohimbine (pA2 6.82+/-0.28, slope 1.12+/-0.40),alpha1-AR selective antagonist prazosin (pA2 9.77+/-0.22, slope 0.90+/-0.22),alpha1A-AR selective antagonists RS17053 (pA2 8.42+/-0.20, slope 0.93+/-0.20) and 5-MU (pA2 8.42+/-0.22, slope 0.88+/-0.18),alpha1D-AR selective antagonist BMY7378 (pA2 6.84+/-0.32, slope 1.05+/-0.17), and alpha1A-,alpha1B-AR selective antagonist WB4101 (pA2 8.88+/-0.20, slope 1.15+/-0.16). The correlation coefficients between these pA2 values of alpha1-AR selective antagonists with pKi values of which obtained from alpha1A-, alpha1B- and alpha1D-AR cloned cells are 0.95, 0.82, and 0.42. After the vessels were pretreated by chlorethylclonidine (CEC), an alpha1B- and alpha1D-AR irreversible alkylating agent, the pD2 values were changed from 5.9+/-0.5 to 5.6+/-0.6 and the maximal contraction was changed from (8.9+/-3.2) g to (8.0+/-3.2) g, respectively. The difference was not significant. CONCLUSION: In human RGA, the contraction response is mainly mediated by alpha1-AR, of which alpha1A-AR plays an important role, whereas alpha1B- and alpha1D-AR are not involved in the contraction response.     

Role of the postsynaptic alpha(2)-adrenergic receptor subtypes in catecholamine-induced vasoconstriction

Catecholamines induce direct vasoconstriction mediated by postsynaptic alpha-adrenergic receptors (alpha-ARs) of both the alpha(1) and alpha(2) type. To evaluate the contribution of each alpha(2)-AR subtype (alpha(2A), alpha(2B), and alpha(2C)) to this function, we used groups of genetically engineered mice deficient for the gene to each one of these subtypes and compared their blood pressure (BP) responses to their wild-type counterparts. Blood pressure responses to a bolus of norepinephrine (NE) were assessed before and after sequential blockade of alpha(1)-ARs with prazosin and alpha(2)-ARs with yohimbine. The first NE bolus elicited a brief 32 to 44 mm Hg BP rise (p < 0.001 from baseline) in all six groups. Prazosin decreased BP by 23 to 33 mm Hg in all groups, establishing a new lower baseline. Repeat NE at that point elicited lesser but still significant (p < 0.001) brief pressor responses between 32% and 45% of the previous BP rise in five of the six groups. Only the alpha(2A)-AR gene knockouts differed, responding instead with a 20-mm Hg fall in BP, a significant change from baseline (p < 0.001) and different from the pressor response of their wild-type counterparts (p < 0.001). The addition of yohimbine produced no further BP change in the five groups, but it did produce a small 7. 5-mm Hg fall (p < 0.05) in the alpha(2A)-AR knockouts. Norepinephrine bolus during concurrent alpha(1) and alpha(2)-AR blockade produced significant (p < 0.001) hypotensive responses in all subgroups, presumably attributable to unopposed stimulation of beta(2)-vascular wall ARs. We conclude that the alpha(2)-AR-mediated vasoconstriction induced by catecholamines is attributable to the alpha(2A)-AR subtype because mice deficient in any one of the other subtypes retained the capacity for normal vasoconstrictive responses. However, the alpha(1)-ARs account for the major part (as much as 68%) of catecholamine-induced vasoconstriction.     

Interaction between antidepressants and alpha 1-adrenergic receptor antagonists on the binding to alpha 1-acid glycoprotein

alpha 1-Receptor antagonists and antidepressant agents are basic (cationic) drugs that are known to bind to alpha 1-acid glycoprotein (AAG). Since these drugs are frequently co-administered and since they bind to the same protein, this investigation was designed to evaluate the "in vitro" ability of antidepressants, alpha 1-receptor antagonists, and propranolol to displace [3H]imipramine and [3H]prazosin from the AAG binding site(s). Equilibrium dialysis was employed. Of the drugs studied, the following order of potency in displacing [3H]prazosin was found: trazodone greater than prazosin greater than doxazosin greater than propranolol greater than doxepin = amoxapine = trimazosin = amitriptyline greater than imipramine greater than nortriptyline = desipramine = nomifensine greater than bupropion = maprotiline. [3H]lmipramine binding from AAG was displaced with the following potency order: prazosin greater than imipramine greater than propranolol greater than doxazosin greater than nortriptyline greater than desipramine greater than trimazosin. Tricyclic antidepressants produced similar degrees of displacement of both [3H]imipramine and [3H]prazosin from AAG; whereas, alpha 1-receptor antagonists were more effective displacers of [3H]prazosin than of [3H]imipramine. Furthermore, the demethylated metabolites of imipramine and amitriptyline were less potent displacers than their parent compounds. These results suggest that more than a single binding site may be available for binding to AAG and that hydrophobic bonding is important in the binding of drugs to AAG.     

Protein kinase C-dependent coupling of alpha(2A/D)-adrenergic receptors to phospholipase D

To clarify the role of protein kinase C (PKC) in regulating the coupling pathway of alpha(2)-adrenergic receptors, we examined receptor activation of phospholipase D (PLD) in PC12 cells overexpressing alpha(2A/D) receptors, using [(3)H]phosphatidylbutanol formation as an index of PLD activity. In intact PC12/alpha(2A/D) cells, the ability of either epinephrine or the alpha(2)-receptor-selective agonist UK14304 to stimulate PLD was completely dependent on concomitant PKC activation. Pretreatment with the PKC activator phorbol dibutyrate revealed an agonist-stimulated PLD activity which was blocked by the alpha(2)-receptor-selective antagonist rauwolscine and by pertussis toxin treatment. Removal of extracellular calcium or tyrosine kinase inhibition by genistein pretreatment also eliminated the ability of epinephrine to stimulate PLD. These results indicate that alpha(2A/D)-adrenergic receptors couple via pertussis toxin-sensitive G proteins to PLD in a PKC-requiring and tyrosine kinase regulated manner.     

Bolus intravenous injection of phosphorothioate oligonucleotides causes hypotension by acting as alpha(1)-adrenergic receptor antagonists.

Bolus intravenous injections of phosphorothioate oligonucleotides (PS-ODN) into primates cause profound hypotension, which has been attributed to complement activation, the biochemical pathway leading to acute inflammatory response. Because the hypotension was not accompanied by peripheral or pulmonary edema and epinephrine was not effective, but administration of 200 ml Ringer's lactate was effective, we examined the possibility that the 15-base PS-ODN interferes with sympathetic tone. We administered doses ranging from 3.3 to 10 mg/kg of a 15-base PS-ODN as a 30-60 s iv bolus into the right atrium of conscious Macaca mulatta. Blood pressure fell to 27 mm Hg following a 5.0 mg/kg dose, but no hypotension was observed after a 3.3 mg/kg dose; 10 mg/kg was lethal. Adrenergic receptor binding was evaluated in radioligand binding assays using rat cerebral cortex membranes with radiolabeled prazosin. The 15-base PS-ODN competes with prazosin for the alpha(1)-adrenergic receptor with an IC50 of 14 microM, which favors binding over serum albumin (K(d) = 37 to 48 microM). Admixing serum albumin with 5.0 mg/kg 15-base PS-ODN prior to injection prevented hypotension, suggesting that unbound PS-ODN interferes with sympathetic tone before binding to plasma proteins. Interactions of the 15-base PS-ODN with the alpha(1)-adrenergic receptor in vivo were confirmed by a decreased response to phenylephrine. Reducing the length from 15 to 9 or 5 bases abolished alpha(1)-adrenergic receptor binding in vitro and bolus infusion of 5.0 mg/kg of 9-base PS-ODN no longer produced hypotension. In conclusion, the 15-base PS-ODN shows cooperative binding to the alpha(1)-adrenergic receptor, which produces cardiovascular effects that are oligomer length, dose, and formulation dependent.     

Allosteric interactions between the antagonist prazosin and amiloride analogs at the human alpha(1A)-adrenergic receptor

It has been demonstrated previously that amilorides can interact with a well defined allosteric site on the human alpha(2A)-adrenergic receptor. In this study, the question was explored as to whether the human alpha(1A)-adrenergic receptor also possesses an equivalent allosteric site. The six amilorides examined strongly increased the dissociation rate of the antagonist [(3)H]prazosin from the alpha(1A)-adrenergic receptor in a concentration-dependent manner. With the parent amiloride, the dissociation data were well fitted by an equation derived from the ternary complex allosteric model, compatible with amiloride acting at a defined allosteric site on the alpha(1A)-adrenergic receptor. In contrast, the dissociation data for [(3)H]prazosin in the presence of the amiloride analogs were not compatible with the equation derived from a one-allosteric-site model, but could be fitted well by an equation derived from a two-allosteric-site model. However, certain individual parameters could not be resolved. The observed dissociation rate constants increased steeply with increasing amiloride analog concentration, and in some cases the data could be fitted with a logistic equation. The slope factors calculated from such fits were 1.2 to 2.1. It is concluded that the structure-binding relationships of the amilorides at the alpha(1A)- and alpha(2A)-adrenergic receptors are different. The interactions of the five amiloride analogs, but not the parent amiloride, with the alpha(1A)-adrenergic receptor are compatible with the presence of two (but not one) allosteric sites, and is thus more complex than that found for the alpha(2A)-adrenergic receptor.     

Cloning, cell-type specificity, and regulatory function of the mouse alpha(1B)-adrenergic receptor promoter

The functionality of a 3422-base pair promoter fragment from the mouse alpha(1B)-adrenergic receptor (alpha(1B)AR) gene was examined. This fragment, cloned from a mouse genomic library, was found to have significant sequence homology to the known human and rat alpha(1B)AR promoters. However, the consensus motif of several key cis-acting elements is not conserved among the rat, human, and mouse genes, suggesting species specificity. Confirming fidelity of the murine promoter, robust in vitro expression of a chloramphenicol acetyltransferase (CAT) reporter was detected in known alpha(1B)AR-expressing BC(3)H1, NB41A3, and DDT(1)MF-2 cells transiently transfected with a promoter-CAT construct. Conversely, minimal CAT expression was detected in known alpha(1B)AR-negative RAT-1 and R3T3 cells. These findings were extended by transfecting the same promoter-CAT construct into various primary cell types. In support of the hypothesis that alpha(1)ARs are differentially expressed in the smooth muscle of the vasculature, primary cultures of superior mesenteric and renal artery vascular smooth muscle cells showed significantly stronger CAT expression than did vascular smooth muscle cells derived from pulmonary, femoral, and iliac arteries. Primary osteoblastic bone-forming cells, which are known to be alpha(1B)AR negative, showed minimal CAT expression. Indicating regulatory function through cis-acting elements, RAT-1, R3T3, NB41A3, BC(3)H1, and DDT(1)MF2 cells transfected with the promoter-CAT construct all showed increased CAT production when challenged with forskolin or hypoxic conditions. Additionally, tissue-specific regulation of the promoter was observed when cells were simultaneously challenged with both forskolin and hypoxia. These results collectively demonstrate that a 3.4-kb PvuII fragment of the murine alpha(1B)AR gene promoter can: 1) drive tissue-specific production of a CAT reporter in both clonal and primary cell lines; and 2) confer tissue-specific regulation of that CAT reporter when induced by challenge with forskolin and/or hypoxic conditions.     

Expression of renal alpha 1-adrenergic receptor subtypes in established hypertension.

Radioligand binding studies were undertaken in renal membranes of normotensive and hypertensive rats in order to test the hypothesis that there are alterations in renal alpha 1-adrenergic subtypes of genetic hypertensive animals. The highly selective competitive compound, (+)-niguldipine, was used to distinguish high-affinity (alpha 1a) from low-affinity (alpha 1b) sites, after initial studies demonstrated that this compound had greater selectivity than 5-methylurapidil in distinguishing alpha 1a and alpha 1b sites in rat renal membranes. In contrast to the significant difference in the blood pressure of the spontaneously hypertensive rats (delta BP = 74 mm Hg), there was no difference in the renal alpha 1-adrenergic receptor density. Membranes from the whole kidneys of spontaneously hypertensive rats (SHRs) possessed 31% alpha 1a and 69% alpha 1b sites with -log(Ki) values of 10.0 +/- 0.3 and 7.1 +/- 0.1, respectively, for (+)-niguldipine. However, these values were not different from those obtained from renal membranes of the normotensive Wistar-Kyoto (WKY) rats. These results indicate that in spite of the elevated blood pressure during the established phase of hypertension, the number, the affinity, and the ratio of the alpha 1a and alpha 1b appear not to be responsible for the manifestation of hypertension during this phase.     

A-315456: a selective alpha(1D)-adrenoceptor antagonist with minimal dopamine D(2) and 5-HT(1A) receptor affinity.

In functional assays, A-315456, N-[3-(cyclohexylidene-(1H-imidazol-4-ylmethyl))phenyl]ethanesulfonamide, behaved as an alpha(1D)-adrenoceptor subtype selective antagonist (pA(2)=8.34) in the rat aorta. It was 83-fold less potent at the alpha(1B)-adrenoceptor subtype expressed in the rat spleen, and was inactive at the alpha(1A)-adrenoceptor subtype expressed in the rat vas deferens. Radioligand binding assays also revealed high affinity (pK(i)=8.71) for the alpha(1D)-adrenoceptor subtype and weaker affinities at the alpha(1A)-adrenoceptor (pK(i)=6.23) and alpha(1B)-adrenoceptor (pK(i)=7.86). In comparison to its potent affinity at the alpha(1D)-adrenoceptor subtype, A-315456 was 3020-, 794- and 38-fold weaker at the dopamine D(2)-, 5-HT(1A)-, and alpha(2a)-adrenoceptors, respectively. These studies indicate that A-315456 is a potent and selective alpha(1D)-antagonist that may serve as a useful pharmacological ligand to probe the physiological role of the alpha(1D)-adrenoceptor subtype in normal and disease states.     

The relationship between alpha 1-adrenergic receptor occupancy and response in BC3H-1 muscle cells

The relationship between alpha 1-adrenergic receptor occupancy by agonists or antagonists and the regulation of intracellular Ca2+ was examined. Receptor occupancy was measured using the antagonist [3H]prazosin and correlated with agonist-elicited 45Ca2+ fluxes. The agonists epinephrine (E), norepinephrine (NE), and phenylephrine (PE) coordinately activated Ca2+ efflux, reflecting a substantial mobilization of intracellular Ca2+, as well as a smaller 45Ca2+ influx. The agonist concentration dependences for influx and efflux were similar, with the order of potency expected for alpha 1 receptors (E greater than or equal to NE greater than PE). To determine the relationship between receptor occupancy and response, the slowly dissociating antagonist prazosin was used to inactivate specified fractions of the receptor population. A linear relationship was observed between the remaining activatable receptors and residual 45Ca2+ efflux elicited by E or NE, except at saturating agonist concentrations where some curvature was observed. Moreover, the concentration dependence for agonist-elicited 45Ca2+ efflux was shifted toward slightly higher concentrations of E or NE following prazosin inactivation. These results suggest the presence of a modest receptor reserve which is revealed by E or NE, but not by PE. Agonist occupation was measured over the same interval as receptor activation by competition with the initial rate of [3H]prazosin association. All three agonists exhibited the major fraction of receptor occupation over the same concentration ranges required for the functional response. Exposure of receptors to specified agonist concentrations for 30 min had little effect on the number of receptors or their ligand affinities, whereas a 2.5-hr exposure to agonist decreased apparent agonist affinity as well as the number of receptors recognized by [3H]prazosin.