Disposition and alpha(1)-adrenoceptor binding characteristics of JTH-601 and its metabolites in rat tissues.

The present study was performed to characterize the disposition and alpha(1)-adrenoceptor binding of JTH-601, a novel alpha(1L)-adrenoceptor antagonist, and its metabolites (beta-D-glucopyranosyl uronic acid, JTH-601-G1; hydrogen sulfate, JTH-601-S1) in the rat prostate and other tissues. JTH-601, JTH-601-G1, and JTH-601-S1 inhibited competitively specific [(3)H]tamsulosin binding in the prostate, submaxillary gland, and spleen of rats in vitro, and the inhibitory effect of JTH-601 was 2. 5 to 6.4 times more potent than that of its metabolites. JTH-601 and its metabolites inhibited dose dependently in vivo specific [(3)H]tamsulosin binding in the particulate fraction of the prostate, aorta, submaxillary gland, and spleen of rats. Compared with that of JTH-601, the in vivo inhibitory effect of JTH-601-G1 was 1.9 to 2. 9 times more potent, and the effect of JTH-601-S1 was 1.3 to 3.2 times less potent. Based on the ratios of ID(50) values, JTH-601 and JTH-601-G1 appeared to be 4.0 to 6.9 times more selective than prazosin as far as the alpha(1)-adrenoceptors in the prostate and submaxillary gland versus the spleen or aorta were concerned. The total radioactivity in rat tissues after i.v. injection of [(3)H]JTH-601-G1 was considerably lower than that of [(3)H]JTH-601. The plasma concentration of [(3)H]JTH-601-G1 at 10 min after i.v. injection in rats was 3 times higher than that of [(3)H]JTH-601, and conversely, the concentration in the prostate was 3 times lower. Although in vivo [(3)H]JTH-601-G1 binding at 10 min was significantly lower than that of [(3)H]JTH-601 in most rat tissues, there was comparable binding between these radioligands in the prostate and vas deferens. Specific binding of [(3)H]JTH-601, at 60 min after i.v. injection compared with that at 10 min, was considerably reduced in rat tissues except the prostate and vas deferens, both of which showed relatively sustained binding. In conclusion, the present study has shown that JTH-601 and its metabolites bind to alpha(1)-adrenoceptors in rat tissues in vivo and that JTH-601-G1 retains the prostatic alpha(1)-adrenoceptor subtype selectivity of its parent compound.     

Age-related change of the role of alpha1L-adrenoceptor in canine urethral smooth muscle.

To examine age-related alteration of the role of alpha1L-adrenoceptor in the urethra, young non-parous and aged parous female dogs were used. In a functional study, we evaluated phenylephrine-induced contraction and antagonistic effects of JTH-601, a newly synthesized alpha1-adrenoceptor antagonist, and prazosin; in a localization survey using autoradiographic technique, we investigated specific [3H]JTH-601 and [3H]tamsulosin binding. Concentration-response curves were obtained for phenylephrine (pD2 = 5.0-5.3). JTH-601 and prazosin antagonized this contraction with pA2 values of 8.2-8.3 and 8.0-8.1, respectively. Specific binding of both [3H]JTH-601 and [3H]tamsulosin were observed in the bladder neck and proximal section of urethra. There were no significant differences of the pD2, pA2, and radio ligand binding between young non-parous and aged parous dogs.     

Effect of JTH-601, a novel alpha(1)-adrenoceptor antagonist, on prostate function in dogs

We examined the effect of JTH-601 (3-?N-[2-(4-hydroxy-2-isopropyl-5-methylphenoxy)ethyl]-N-methylaminom ethyl?-4-methoxy-2,5,6-trimethylphenol hemifumarate), a new alpha(1L)-adrenoceptor antagonist, on prostatic function in isolated canine prostate and in anesthetized dogs. In the contraction study, phenylephrine and noradrenaline produced concentration-dependent contractions in canine prostate and carotid artery, respectively. In these tissues, JTH-601, prazosin (a non-selective alpha(1)-adrenoceptor antagonist), and tamsulosin (an alpha(1A)-adrenoceptor antagonist) competitively antagonized contraction in a concentration-dependent manner. The pA(2) (pK(B)) values with prostate were 8.49+/-0.07 for JTH-601, 7.94+/-0.04 for prazosin and 9.42+/-0.22 for tamsulosin. The ratio of pA(2) (carotid artery/prostate), i.e. prostatic selectivity, was 10.471 for JTH-601, 0.008 for prazosin and 0.371 for tamsulosin, respectively. In anesthetized dogs, JTH-601 (1 mg/kg, i.d.) significantly decreased urethral pressure by 15% without affecting blood pressure or heart rate. Tamsulosin (0.1 mg/kg, i.d.) decreased urethral pressure to the same extent as did JTH-601, but with a significant effect on blood pressure and heart rate. JTH-601 showed higher selectivity for canine prostate both in vitro and in vivo. In prostate, an important role of the alpha(1L)-adrenoceptor is suggested in the smooth muscle contraction mediated by alpha(1)-adrenoceptors. JTH-601 is expected to be an effective alpha(1)-adrenoceptor antagonist for the treatment of urinary outlet obstruction by benign prostatic hypertrophy with a minimum effect on the cardiovascular system.     

Effect of JTH-601, a novel alpha1-adrenoceptor antagonist, on the function of lower urinary tract and blood pressure.

In the present study, we investigated the effect of JTH-601 (3-{N-[2-(4-hydroxy-2-isopropyl-5-methylphenoxy)ethyl]-N-methylaminomethyl}-4-methoxy-2,5,6-trimethylphenol hemifumarate), a novel alpha1-adrenoceptor antagonist, in vitro and in vivo. JTH-601 (10(-9)-3 x 10(-8) M) competitively antagonized phenylephrine-induced contraction in lower urinary tract tissues (prostate, urethra and bladder trigon) in a concentration-dependent manner. The mean pA2 values for JTH-601 were 8.59+/-0.14, 8.74+/-0.09 and 8.77+/-0.11 for prostate, urethra and bladder trigon, respectively. In anesthetized rabbits, intraduodenal administration of JTH-601 (0.3-3 mg/kg), prazosin (0.03-0.3 mg/kg) and tamsulosin (0.03-0.3 mg/kg) dose dependently inhibited the phenylephrine-induced increase in urethral pressure for 3 h. Although these drugs also decreased mean blood pressure, JTH-601 was less potent than prazosin or tamsulosin. In conscious rabbits, administered JTH-601 (0.01-1 mg/kg, i.v.) had a tendency to augment orthostatic hypotension, but dose dependency was not evident. Prazosin (0.01-1 mg/kg) and tamsulosin (0.001-1 mg/kg) dose dependently augmented orthostatic hypotension. These results indicate that JTH-601 antagonized alpha1-adrenoceptor-mediated contractile responses more potently than prazosin or tamsulosin in rabbit lower urinary tract both in vitro and in vivo. JTH-601 is therefore expected to be effective in the treatment of urinary outlet obstruction in benign prostatic hypertrophy.     

Ex vivo and in vivo alpha1-adrenoceptor binding characteristics of a novel alpha1L-adrenoceptor antagonist, JTH-601, in rat tissues.

In vitro, ex vivo and in vivo alpha1-adrenoceptor binding of JTH-601 (3-[N-[2-(4-hydroxy-2-isopropyl-5-methylphenoxy)ethyl]-N-methylaminometh yl]-4-methoxy-2,5,6-trimethyl-phenol hemifumarate), a novel alpha1L-adrenoceptor antagonist, in rat tissues was investigated. JTH-601 competed in a concentration-dependent manner with [3H]prazosin for binding sites in the prostate, submaxillary gland and spleen of rats in vitro, and the inhibitory effect was not largely different among these tissues, as shown by the Ki values of 2-3 nM. At 0.25, 0.5 and 3 h after oral administration of JTH-601 (6.5 micromol/kg) in rats, there was a significant (57, 64 and 28%, respectively) increase in the apparent dissociation constant (Kd) for prostatic [3H]prazosin binding, compared to the control value. The administration of a higher dose (21.8 micromol/kg) of this agent produced greater (67-99%) increases in Kd values for prostatic [3H]prazosin binding at 0.5-12 h later. Similar significant increases in Kd values, as with the prostate, were seen in the submaxillary gland and heart 0.25-12 h after the oral administration of JTH-601 (6.5 and 21.8 micromol/kg), but significant increases in the spleen and cerebral cortex were seen only at 0.25-3 h and 0.5 h, respectively. At 10 min of i.v. injection of [3H]JTH-601 in rats, in vivo specific binding was observed in the prostate, cerebral cortex, submaxillary gland, spleen and heart but not in the aorta. The binding in the prostate, submaxillary gland and heart, but not in the cerebral cortex and spleen, lasted until 120 min. It is concluded that JTH-601 may exert a considerably sustained blockade of alpha1-adrenoceptors in the prostate of rats. This finding may be important in characterizing the therapeutic effect of JTH-601 for bladder outlet obstruction in patients with benign prostatic hyperplasia.     

Pharmacological characteristics of inhibitory action of the selective alpha1-antagonist JTH-601 on the positive inotropic effect mediated by alpha1-adrenoceptors in isolated rabbit papillary muscle

Influence of JTH-601 [N-(3-hydroxy-6-methoxy-2,4,5-trimethylbenzyl)-N-methyl-2-(4-hydroxy-2-isopropyl-5-methylphenoxy)ethylamine hemifumarate], a selective alpha1-adrenoceptor antagonist, on alpha1-mediated positive inotropic effect (PIE) was studied in isolated rabbit papillary muscle (1 Hz at 37 degrees C). JTH-601 (0.1-10 microM) shifted the concentration-response curve (CRC) for PIE of phenylephrine mediated by alpha1-adrenoceptor (with timolol at 1 microM) to the right and downward. In the presence of 100 nM WB 4101, an alpha1A antagonist, the shift to the right disappeared and JTH-601 (1-3 microM) shifted CRC for phenylephrine downward. The antagonistic action of JTH-601 was unchanged by 100 nM (+)-niguldipine, another alpha1A antagonist. Following pretreatment with 10 microM chloroethylclonidine, an alpha1B antagonist, the shift of CRC for phenylephrine to the right disappeared and JTH-601 (3-10 microM) shifted CRC downward. Antagonistic action of JTH-601 (3 microM) was unaltered by 100 nM BMY 7378, an alpha1D antagonist. JTH-601 (10 microM) had no effect on beta-mediated PIE of isoproterenol. These results indicate that JTH-601 exerts an inhibitory action on alpha1-mediated PIE through antagonism of alpha1A- and/or alpha1B-adrenoceptors in rabbit ventricular myocardium. As an alpha1 antagonist, JTH-601 is much less potent in rabbit ventricular muscle than in smooth muscle.     

Effect of JTH-601, a putative alpha(1L)-adrenoceptor antagonist, on guinea pig nasal mucosa vasculature

The existence of alpha(1)-adrenoceptors with low affinity for prazosin, an alpha(1L) subtype, has been proposed in addition to alpha(1)-adrenoceptor subtypes with high affinity for prazosin, i.e. the alpha(1H) group: alpha(1A), alpha(1B) and alpha(1D) subtypes. In the present study, we investigated the effect of JTH-601 (3-(N-[2-(4-hydroxy-2-isopropyl-5-methylphenoxy)ethyl]-N-methylaminomethyl)-4-methoxy-2,5,6-trimethylphenol hemifumarate), a putative alpha(1L)-adrenoceptor antagonist, on the isolated guinea pig nasal mucosa vasculature. JTH-601 (0.01-0.03 microM) competitively antagonized the noradrenaline-induced contraction of the tissue in a concentration-dependent manner. The pA(2) value for JTH-601 was 8.14 +/- 0.04 (means +/- SEM, n = 6). The data suggests that the alpha(1L)-subtype is involved in the noradrenaline-induced contraction of the guinea pig nasal mucosa vasculature.     

Analysis of alpha 1L-adrenoceptor pharmacology in rat small mesenteric artery.

1. To illuminate the controversy on alpha 1A- or alpha 1L-adrenoceptor involvement in noradrenaline-mediated contractions of rat small mesenteric artery (SMA), we have studied the effects of subtype-selective alpha 1-adrenoceptor agonists and antagonists under different experimental conditions. 2. The agonist potency order in rat SMA was: A61603 > SKF89748-A > cirazoline > noradrenaline > ST-587 > methoxamine. Prazosin antagonized all agonists with a low potency (pA2: 8.29-8.80) indicating the involvement of alpha 1L-rather than alpha 1A-adrenoceptors. 3. The putative alpha 1L-adrenoceptor antagonist JTH-601, but not the alpha 1B-adrenoceptor antagonist chloroethylclonidine (10 microM) antagonized noradrenaline-induced contractions of SMA. The potency of the selective alpha 1D-adrenoceptor antagonist BMY 7378 against noradrenaline (pA2 = 6.16 +/- 0.13) and of the selective alpha 1A-adrenoceptor antagonist RS-17053 against noradrenaline (pKB = 8.35 +/- 0.10) and against the selective alpha 1A-adrenoceptor agonist A-61603 (pKB = 8.40 +/- 0.09) were too low to account for alpha 1D- and alpha 1A-adrenoceptor involvement. 4. The potency of RS-17053 (pKB/pA2's = 7.72-8.46) was not affected by lowering temperature, changing experimental protocol or inducing myogenic tone via KCl or U46619. 5. Selective protection of a putative alpha 1A-adrenoceptor population against the irreversible action of phenoxybenzamine also failed to increase the potency of RS-17053 (pA2 = 8.25 +/- 0.06 against A61603). 6. Combined concentration-ratio analysis demonstrated that tamsulosin, which does not discriminate between alpha 1A- and alpha 1L-adrenoceptors, and RS-17053 competed for binding at the same site in the SMA. 7. In summary, data obtained in our experiments in rat SMA indicate that the alpha 1-adrenoceptor mediating noradrenaline-induced contraction displays a distinct alpha 1L-adrenoceptor pharmacology. This study does not provide evidence for the hypothesis that alpha 1L-adrenoceptors represent an affinity state of the alpha 1A-adrenoceptor in functional assays. Furthermore, there is no co-existing alpha 1A-adrenoceptor in the SMA.     

Alpha(1L)-, but not alpha(1H)-, adrenoceptor antagonist prevents allergic bronchoconstriction in guinea pigs in vivo

alpha-Adrenoceptors have been classified into alpha(1)- and alpha(2)-adrenoceptors. Recently, the alpha(1)-adrenoceptors were divided into two subtypes: alpha(1L) with low affinity and alpha(1H) with high affinity for prazosin. Little is known concerning the role of each subtype of alpha(1)-adrenoceptor in asthma. We investigated the effects of specific antagonists of alpha(1)- and alpha(2)-, alpha(1H)-, alpha(1L)-, and alpha(2)-adrenoceptors, namely moxisylyte, prazosin, 3-[N-[2-(4-hydroxy-2-isopropyl-5-methylphenoxy) ethyl]-N-methylaminomethyl]-4-methoxy-2, 5, 6-trimethylphenol hemifumarate (JTH-601), and yohimbine, respectively, on antigen-induced airway reactions in guinea pigs. Fifteen minutes after intravenous administration of moxisylyte (0.01, 0.1 or 1 mg/kg), prazosin (0.01, 0.1, 1 or 10 mg/kg), JTH-601 (1, 3, 6 or 10 mg/kg) or yohimbine (0.1 or 1 mg/kg), passively sensitized and artificially ventilated animals received an aerosolized antigen challenge. Bronchial responsiveness to inhaled methacholine was assessed as the dose of methacholine required to produce a 200% increase in the pressure at the airway opening (PC(200)) in non-sensitized animals. JTH-601 and moxisylyte, but not prazosin or yohimbine, dose dependently inhibited antigen-induced bronchoconstriction. None of the tested drugs altered PC(200). JTH-601 significantly reduced leukotriene C(4) levels in bronchoalveolar lavage fluid obtained 5 min after antigen challenge, but prazosin did not. These results indicate that prevention of antigen-induced bronchoconstriction by blockade of alpha-adrenoceptors is due to the inhibition of mediator release via alpha(1L)-adrenoceptor antagonism.     

Binding and functional characterization of alpha1-adrenoceptor subtypes in the rat prostate

The alpha1-adrenoceptor subtypes of rat prostate were characterized in binding and functional experiments. In binding experiments, [3H]tamsulosin bound to a single class of binding sites with an affinity (pKD) of 10.79+/-0.04 and Bmax of 87+/-2 fmol mg(-1) protein. This binding was inhibited by prazosin, 2-(2,6-dimethoxy-phenoxyethyl)-aminomethyl-1,4-benzodioxane hydrochloride (WB4101), 5-methylurapidil, alpha-ethyl-3,4,5,-trimethoxy-alpha-(3-((2-(2-methoxyphenoxy)ethyl)-amin o)-propyl)benzeneacetonitrile fumarate (HV723) and oxymetazoline with high efficacy, resulting in a good correlation with the binding characteristics of cloned alpha1a but not alpha1b and alpha1d-adrenoceptor subtypes. In functional studies, noradrenaline and oxymetazoline produced concentration-dependent contractions. These contractions were antagonized by tamsulosin, prazosin, WB4101 and 5-methylurapidil with an efficacy lower than that exhibited by these agents for inhibition of [3H]tamsulosin binding. The relationship between receptor occupancy and contractile amplitude revealed the presence of receptor reserve for noradrenaline, but the contraction induced by oxymetazoline was not in parallel with receptor occupation and developed after predicted receptor saturation. From these results, it is suggested that alpha1A-adrenoceptors are the dominant subtype in the rat prostate which can be detected with [3H]tamsulosin, but that the functional subtype mediating adrenergic contractions has the characteristics of the alpha1L-adrenoceptor subtype, having a lower affinity for prazosin and some other drugs than the alpha1A-adrenoceptor subtype.     

Comparative study on pharmacokinetics and in vivo alpha1-adrenoceptor binding of [3H]tamsulosin and [3H]prazosin in rats.

The plasma concentration, total radioactivity and in vivo alpha1-adrenoceptor binding in rat tissues after intravenous (i.v.) injection of [3H]tamsulosin were measured and they were compared with those obtained after the injection of [3H]prazosin. The plasma concentration of [3H]tamsulosin was consistently higher than that of [3H]prazosin, with 1.4 times greater areas under the curve (AUC(0-infinity)) of plasma concentration. As there was a significantly lower value of apparent volume of central compartment (Vd(c)) and distribution volume at steady state (Vd(ss)) for [3H]tamsulosin than [3H]prazosin with little difference in elimination rate constant (beta), the higher concentration of [3H]tamsulosin in plasma might be associated mainly with the smaller volume of distribution. The ratio of total radioactivity in tissues to the plasma unbound concentration of [3H]tamsulosin after i.v. injection of the ligand was consistently lower than that of [3H]prazosin. These observations suggest that [3H]tamsulosin is distributed in rat tissues in a more limited manner than [3H]prazosin. A significantly lower level of in vivo specific binding of [3H]tamsulosin than [3H]prazosin was observed in the spleen, heart and liver. Further, the apparent dissociation constant (Kd) and maximal number of binding sites (Bmax) for in vivo specific [3H]tamsulosin binding were considerably lower than those for [3H]prazosin binding. Therefore, these findings suggest that [3H]tamsulosin labels preferentially a subpopulation of the alpha1-adrenoceptor sites in rat tissues labeled by [3H]prazosin. In conclusion, the present study has shown that there is a significant difference in the pharmacokinetics and in vivo alpha1-adrenoceptor binding characteristics between tamsulosin and prazosin.     

Mutational analysis of the alpha 1a-adrenergic receptor binding pocket of antagonists by radioligand binding assay

Computer simulations of the human alpha 1a-adrenergic receptor (alpha 1a-AR) based on the crystal structure of rhodopsin have been combined with experimental site-directed mutagenesis to investigate the role of residues in the transmembrane domains in antagonist binding. Previous molecular dynamics studies from our laboratory indicated that the amino acids Asp106 in the third transmembrane domain (TMD), Gln167 in TMD IV of alpha 1a-AR were directly involved in prazosin, tamsulosin and KMD-3213 binding. The Asp106Ala mutant did not exhibit any affinity for [3H]prazosin. On the other hand, the Gln167Phe mutant alpha 1a-AR showed reduced binding affinity for [3H]prazosin. In competition binding experiment the binding affinities of prazosin and tamsulosin were increased 11-fold and 33-fold respectively to Gln167Phe mutant in comparison with wild type receptor. It seems that mutation of this residue by phenylalanine has offered more interaction for the ligands with its aromatic ring. The results provide direct evidence that these amino acid residues are responsible for the interactions between alpha 1a-AR and radioligand [3H]prazosin as well as tamsulosin and KMD-3213.     

Human cloned alpha1A-adrenoceptor isoforms display alpha1L-adrenoceptor pharmacology in functional studies.

The recombinant alpha1A-adrenoceptor displays a distinct pharmacological profile ('classical alpha1A-adrenoceptor') in homogenate binding assays, but displays the properties of the so-called alpha1L-adrenoceptor in functional studies in whole cells at 37 degrees C. As three splice variants of the human alpha1A-adrenoceptor have been described previously (alpha1A-1, alpha1A-2 and alpha1A-3), we have compared their functional pharmacological profiles, when expressed stably in Chinese hamster ovary (CHO-K1) cells (antagonist inhibition of noradrenaline-stimulated [3H]inositol phosphates accumulation). A fourth, novel isoform (alpha1A-4) has also been studied: alpha1A-4 mRNA predominates in several human tissues including prostate, liver, heart and bladder. In homogenate binding studies, all four isoforms displayed essentially identical affinity profiles, with prazosin (1-(4-amino-6,7-dimethoxy-2-quinazolinyl)-4-(2-furoyl)piperazine), tamsulosin (5-[2-[[2-(2-ethoxyphenoxy)ethyl]-amino]propyl]-2-methoxybenzen esulfonamide), RS-17053 (N-[2-(2-cyclopropylmethoxyphenoxy)ethyl]-5-chloro-alpha,alphad imethyl-1H-indole-3-ethanamine hydrochloride), WB 4101 ((2,6-dimethoxyphenoxyethyl)aminomethyl-1,4-benzodioxane hydrochloride) and 5-Me-urapidil (5-methyl-6[[3-[4-(2-methoxyphenyl)-1-piperazinyl]propyl]amino]-1,3-d imethyuracil) all displaying subnanomolar affinities. In functional studies, noradrenaline accelerated [3H]inositol phosphates production with potencies (p[A]50) of between 5.8 and 6.6. The affinities of prazosin, RS-17053, WB 4101 and 5-Me-urapidil, at antagonizing responses to noradrenaline, were reduced by approximately 10-fold (cf. binding data), while those for tamsulosin and indoramin (N-[1-[2-(1H-indol-3-yl)ethyl]-4-piperidinyl]benzamide) remained constant or increased, consistent with the previously described alpha1L-adrenoceptor. Thus, all four human recombinant alpha1A-adrenoceptor isoforms display the pharmacology of the alpha1L-adrenoceptor when studied in functional assays, consistent with the hypothesis that the putative alpha1L-adrenoceptor represents a functional phenotype of the alpha1A-adrenoceptor.     

Buspirone functionally discriminates tissues endowed with alpha1-adrenoceptor subtypes A, B, D and L.

The affinity for functional alpha1-adrenoceptor subtypes of buspirone in comparison with its close structural analogs and selective alpha1D-adrenoceptor antagonists, BMY 7378 (8-[2-[4-(2-methoxyphenyl)-1-piperazinyl]ethyl]-8-azaspiro[4.5]dec ane-7,9-dione) and MDL 73005EF (8-[2-(1,4-benzodioxan-2-ylmethylamino)ethyl]-8-azaspiro+ ++[4.5]decane-7,9-dione), was determined, namely at subtype A in rat vas deferens and perfused kidney, at subtype B in guinea-pig and mouse spleen, at subtype L in rabbit spleen, and at subtype D in rat aorta and pulmonary artery against noradrenaline-evoked contractions. BMY 7378 and MDL 73005EF were confirmed as 30- and 20-fold selective antagonists, respectively, for alpha1D- over both alpha1A- and alpha1B-adrenoceptors. Buspirone was a weak antagonist without intrinsic activity at alpha1A-adrenoceptors in rat vas deferens (pA2 = 6.12), at alpha1B-adrenoceptors in guinea-pig and mouse spleen (pA2 = 5.54 and 5.59) and at alpha1L-adrenoceptors in rabbit spleen (pA2 = 4.99), but caused partial vasoconstriction in rat kidney that was attenuable by the subtype D-selective adrenoceptor antagonist BMY 7378, but hardly by the subtype A-selective adrenoceptor antagonist B8805-033 ((+/-)-1,3,5-trimethyl-6-[[3-[4-((2,3-dihydro-2-hydroxymethyl)-1,4-be nzodioxin-5-yl)-1-piperazinyl]propyl]amino]-2,4(1H,3H)-pyrimidinedion e), confirming the additional presence of alpha1D-adrenoceptors mediating rat renal vasoconstriction. Buspirone behaved as a partial agonist at alpha1D-adrenoceptors in rat aorta (pD2 = 6.77, intrinsic activity (i.a.)= 0.40) and pulmonary artery (pD2 = 7.16, i.a. = 0.59). With buspirone as agonist in these tissues, the pA2 values of subtype-discriminating antagonists were consistent with their alpha1D-adrenoceptor affinity determined in rat aorta against noradrenaline and with published binding data on cloned alpha1d-adrenoceptors. The results provide pharmacological evidence that (1) in functional preparations for the A subtype, like rat vas deferens and perfused kidney, for the B subtype, like guinea-pig and mouse spleen, and for the L subtype, like rabbit spleen, buspirone is a weak antagonist without intrinsic activity, but (2) behaves as a partial agonist in rat aorta and pulmonary artery as models for the D subtype and (3) detects an additional vasoconstrictor alpha1D-adrenoceptor in rat kidney. Buspirone, like its close analogs BMY 7378 and MDL 73005EF, thus might also be a useful tool for functionally discriminating alpha1D- from alpha1A-, alpha1B- and alpha1L-adrenoceptors in various tissues.     

Non-adrenergic binding of [3H]atipamezole in rat kidney--regional distribution and comparison to alpha2-adrenoceptors

1 Atipamezole (4-(2-ethyl-2,3-dihydro-1H-inden-2-yl)-1H-imidazole) was first introduced as a potent and specific alpha2-adrenoceptor antagonist, but in some tissues [3H]atipamezole identifies an additional population of binding sites, distinct from both classical alpha2-adrenoceptors and I1- and I2-imidazoline receptors identified with [3H]para-aminoclonidine or [3H]idazoxan. 2 In the present study we have characterized [3H]atipamezole binding sites in rat kidney by receptor autoradiography and membrane binding assays and determined whether they are pharmacologically identical with the previously described binding sites for [3H]para-aminoclonidine and [3H]idazoxan. [3H]RX821002 and [3H]rauwolscine were used to compare the regional distribution of alpha2-adrenoceptors to that of non-adrenergic binding sites of [3H]atipamezole. 3 Comparative autoradiographic experiments demonstrated the differential localisation of [3H]atipamezole, [3H]RX821002 and [3H]rauwolscine binding sites in rat kidney. The pattern of distribution of non-adrenergic [3H]atipamezole binding sites is clearly distinct from that of alpha2-adrenoceptors. 4 The non-adrenergic binding of [3H]atipamezole in rat kidney does not fall into any of the previously identified three classes of imidazoline receptors studied with [3H]para-aminoclonidine, [3H]idazoxan and [3H]RX821002. 5 Atipamezole had no inhibitory effect on MAO-A or MAO-B activity in renal membranes, which speaks against the involvement of MAOs in the observed radioligand binding.     

Adenosine receptors in an enriched fraction of plasma membranes from canine ventricular myocardium

[3H]Phenylisopropyladenosine ([3H]PIA) was used to characterize adenosine receptor sites in a sarcolemma-enriched membrane fraction from canine ventricle. Specific [3H]PIA binding to the cardiac membrane preparation was rapid, readily reversible, and saturable with increasing free ligand concentrations. Scatchard analysis indicated a single class of binding sites having a Bmax of 601 fmol/mg protein. The Kd of [3H]PIA for its binding site was 52-85 nM as determined independently from kinetic and equilibrium studies, respectively. Binding was stereospecific in that (-)PIA was ninefold more potent than (+)PIA in competing for [3H]PIA binding sites. Adenosine receptor agonists such as N6-cyclohexyladenosine, (-)PIA, 2-chloroadenosine, N6-methyladenosine, and adenosine-5'-ethylcarboxamide were the most potent agents found to compete for [3H]PIA binding sites and displayed IC50 values of 14-224 nM, while 2',5'-dideoxyadenosine, a potent P-site agonist, inhibited binding only weakly. Alkylxanthines also inhibited [3H]PIA binding with relative potency relationships that paralleled their known pharmacological activity as adenosine receptor antagonists. (-)PIA inhibited activation of membrane adenylate cyclase by isoproterenol in a concentration-dependent manner with a maximum of 22% inhibition occurring at 1 microM PIA. It is concluded that the specific binding of [3H]PIA to the sarcolemma-enriched fraction of canine ventricle represents an Ri adenosine receptor on the surface of the myocardial cell. Such a receptor has been postulated to mediate the adenosine-induced attenuation of the effects of catecholamines on intact ventricular myocardium.     

Tamsulosin: assessment of affinityof (3)H-P razosin binding to two alpha-1- adrenoceptor subtypes in the canine aorta.

This study was performed to assess the affinity of tamsulosin to the alpha(1L)- in addition to alpha(1B)-adrenoceptor (alpha(1)-AR) subtypes coexisting in the canine aorta using the radioligand binding assay. The antagonistic effects of this drug on contraction of the rat aorta were also assessed, and the results were compared with those obtained with prazosin, amosulalol, labetalol, ketanserin, clonidine and propranolol. The pKi value of tamsulosin to the alpha(1L)-subtype was lower than those of prazosin and HV-723, but higher than those of amosulalol, ketanserin and labetalol. The pKi value of tamsulosin for the alpha(1B)-subtype in the canine aorta was similar to that of prazosin. However, this drug showed a higher pKi value than amosulalol, HV-723, labetalol and ketanserin. On the other hand, the order of inhibition potencies for contraction of the rat aorta by phenylephrine was as follows: prazosin > tamsulosin > amosulalol > HV-723 > labetalol > ketanserin > clonidine > propranolol. Thus, although the affinity of tamsulosin to the alpha(1B)-AR subtype in the canine aorta was as high as that in the bovine prostate reported in our previous study, the affinity (pKi 7. 87) of this drug to alpha(1L)-AR in the canine aorta was lower than that (pKi 8.99) in the bovine prostate. These observations suggested that the pharmacological potencies of tamsulosin in the aorta and prostate may be different.     

Quantitative in vitro and ex vivo autoradiography of the alpha 2-adrenoceptor antagonist [3H]atipamezole.

Atipamezole is an alpha-adrenoceptor antagonist with high affinity and selectivity for the alpha 2-receptor. In vitro autoradiography of [3H]atipamezole on rat and human brain sections revealed a pattern virtually identical to the one observed using 3H-labeled antagonists such as idazoxan or methoxyidazoxan or agonists such as p-aminoclonidine and 5-bromo-6-(2-imidazolin-2-yl-amino-quinoxaline (UK-14304). In vivo studies of [3H]atipamezole demonstrated good penetration into the brain (0.3-1.8% injected dose/g at 5 min, depending upon brain region). In addition, [3H]atipamezole displayed rapid in vivo clearance of nonspecific binding such that at 1 h following an i.v. injection of the drug (100 microCi/animal, rat tail vein administration) the pattern of radioactivity in the brain correlated very well with the receptor distribution as seen by in vitro autoradiography. Atipamezole binding in vivo was displaceable by idazoxan. These results demonstrate the potential of suitably labeled atipamezole for regional studies of brain alpha 2-adrenoceptors in vitro and in vivo, in experimental animals as well as in human positron emission tomography (PET) studies.     

Amino acids of the human alpha1d-adrenergic receptor involved in antagonist binding

Computer simulations of the human alpha(1d)-adrenergic receptor (alpha(1d)-AR) based on the crystal structure of rhodopsin have been combined with experimental site-directed mutagenesis to investigate the role of residues in the transmembrane domains in antagonist binding. Our results indicate that the amino acids Asp176 in the third transmembrane domain (TMD), Glu237 in TMD IV, and Ser258 in TMD V of alpha(1d)-AR were directly involved in prazosin and tamsulosin binding. The Asp176Ala mutant did not exhibit any affinity for [(3)H]prazosin and neither did it show agonist-stimulated inositol phosphates (IP) formation. On the other hand, the Glu237Ala and Ser258Ala mutant alpha(1d)-AR showed increased binding affinity for [(3)H]prazosin. Competition binding experiments showed that prazosin affinity had increased to 5-fold and 3-fold in the Glu237Ala and Ser258Ala mutants, respectively, versus wild-type; and tamsulosin affinity only increased in the Ser258Ala mutant (2-fold vs wild-type). It seems that these two residues constrain the receptor by interaction with other residues and this disruption of the interaction increased the receptor's binding affinity towards antagonists. However, the Glu237Ala and Ser258Ala mutant receptors retained the ability to stimulate the formation of myo-[(3)H]inositol but had activities lower than that of the wild-type receptor. The present results provide direct evidence that these amino acid residues are responsible for the interactions between alpha(1d)-AR and the radioligand [(3)H]prazosin as well as tamsulosin.     

Comparison of guinea-pig,bovine and rat alpha 1-adrenoceptor subtypes.

1. To elucidate a possible role of species differences in the classification of alpha 1-adrenoceptor subtypes, we have characterized the alpha 1-adrenoceptors in guinea-pig spleen, kidney and cerebral cortex and in bovine cerebral cortex using concentration-dependent alkylation by chloroethylclonidine and competitive binding with 5-methlurapidil, methoxamine, (+)-niguldipine, noradrenaline, oxymetazoline, phentolamine, SDZ NVI-085, tamsulosin and (+)-tamsulosin. Rat liver alpha 1B-adrenoceptors were studied for comparison. Chloroethylclonidine-sensitivity and (+)-niguldipine affinity were also compared at cloned rat and bovine alpha 1a-adrenoceptors. 2. Chloroethylclonidine concentration-dependently inactivated alpha 1-adrenoceptors in all five tissues. While chloroethylclonidine inactivated almost all alpha 1-adrenoceptors in rat liver and guinea-pig kidney and brain, 20-30% of alpha 1-adrenoceptors in guinea-pig spleen and bovine brain were resistant to alkylation by 10 microM chloroethylclonidine. With regard to concentration-dependency guinea-pig kidney and brain were approximately 10 fold less sensitive than guinea-pig spleen or rat liver. 3. In rat liver, all drugs tested competed for [3H]-prazosin binding with steep and monophasic curves. Drug affinities were relatively low and resembled most closely those of cloned rat alpha 1b-adrenoceptors. 4. In guinea-pig spleen, all drugs tested competed for [3H]-prazosin binding with steep and monophasic curves. Drug affinities were relatively low and resembled most closely those of cloned rat alpha 1b-adrenoceptors. 5. In guinea-pig kidney most drugs tested competed for [3H]-prazosin binding with steep and monophasic curves and had relatively low drug affinities close to those of cloned rat alpha 1b- and alpha 1d-adrenoceptors. However, noradrenaline and tamsulosin had consistently biphasic competition curves recognizing 36-39% high and 61-64% low affinity sites. 6. In guinea-pig cerebral cortex, all drugs tested competed for [3H]-prazosin binding with shallow and biphasic curves. While most drugs recognized approximately 25% high affinity sites, tamsulosin and noradrenaline recognized approximately 50% high affinity sites. Drug affinities at the high and low affinity sites except those for tamsulosin and noradrenaline resembled those at cloned alpha 1a- and alpha 1b-adrenoceptors, respectively. 7. In bovine cerebral cortex all drugs tested except for noradrenaline competed for [3H]-prazosin binding with shallow and biphasic curves. All drugs recognized approximately 70% high affinity sites. Drug affinities at the high and low affinity sites resembled those at cloned alpha 1a- and alpha 1b-adrenoceptors, respectively. Noradrenaline competition curves in bovine cerebral cortex were steep and monophasic. 8. When cloned rat and bovine alpha 1a-adrenoceptors transiently expressed in COS cells were studied in a direct side-by-side comparison, both species homologues had similar chloroethylclonidine-sensitivity and (+)-niguldipine affinity. 9. We conclude that properties of bovine alpha 1A- and alpha 1B-adrenoceptors are very similar to those of other species such as rat. alpha 1-Adrenoceptor subtypes in guinea-pigs resemble alpha 1A- and alpha 1B-adrenoceptors in other species but chloroethylclonidine sensitivity and competition binding profiles of noradrenaline and tamsulosin are not compatible with previously established alpha 1-adrenoceptor subtype classification.