Three distinct binding sites for [3H]-prazosin in the rat cerebral cortex.

1. The putative alpha 1-adrenoceptor subtypes of rat cerebral cortex membranes were characterized in binding. 2. Specific binding of [3H]-prazosin was saturable between 20-5000 pm. Scatchard plots of the binding data were non-linear, indicating the presence of two distinct affinity sites for prazosin (pKD, high = 10.18, Rhigh = 308 fmol mg-1 protein; pKD, low = 8.96, Rlow = 221 fmol mg-1 protein). 3. In the membranes pretreated with chlorethylclonidine (CEC) two affinity sites for prazosin were also observed: the affinities were similar to those without CEC pretreatment, but the maximum numbers of binding sites were reduced by CEC pretreatment to 23 and 62% for prazosin-high (Rhigh) and low affinity sites (Rlow), respectively. 4. The prazosin-high affinity sites were further subdivided into two subclasses by WB4101(2-(2,6-dimethoxyphenoxyethyl)aminomethyl-1,4-benzodioxane) and phentolamine; the low affinity sites for WB4101 and phentolamine were more potently inactivated by CEC as compared with the high affinity sites. On the other hand, prazosin, HV723 (alpha-ethyl-3,4,5-trimethoxy-alpha-(3-((2-(2-methoxyphenoxy)ethyl)- amino )-propyl)benzeneacetonitrile fumarate) and yohimbine inhibited [3H]-prazosin binding to prazosin-high affinity sites monophasically. 5. In addition to the high affinity sites, the prazosin-low affinity sites were labelled at high concentrations of [3H]-prazosin. Thus, prazosin and WB4101 showed shallow displacement curves. On the other hand, HV723 and yohimbine did not discriminate between prazosin-high and low affinity sites. 6. Two distinct alpha 1-adrenoceptor subclassifications have been recently proposed (alpha 1A, alpha 1B subtypes and alpha 1H, alpha 1L, alpha 1N subtypes).(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of alpha 1-adrenergic receptor subtypes in rat brain: a reevaluation of [3H]WB4104 and [3H]prazosin binding

[3H]Prazosin and [3H]WB4101 [2-(2,6-dimethoxyphenoxyethyl)aminomethyl-1,4 benzodioxane] have both been proposed to label alpha 1-adrenergic receptors in the rat central nervous system. As many discrepancies between the binding of these two ligands have arisen, we conducted these studies in order to reevaluate their binding characteristics and resolve the similarities and differences in the pharmacological characteristics of their respective binding sites. [3H]Prazosin binding is characterized by a monophasic saturation isotherm. Prazosin, indoramine, and dihydroergocryptine competitions with [3H]prazosin are steep and monophasic, and model best to a single binding site. In contrast, phentolamine and WB4101 competition curves are shallow in rat cortex, exhibiting Hill coefficients significantly less than 1.0, and model to two binding sites of approximately equal proportions. The higher and lower affinity components are defined as alpha 1A and alpha 1B, respectively. [3H]WB4101 also labels two binding sites in rat cortex and hippocampus with picomolar and nanomolar affinity, respectively. However, the nanomolar binding site is serotonergic and not adrenergic. The picomolar site (KD = 150 pm) has characteristics of an alpha 1-receptor binding site: prazosin, WB4101, and phentolamine affinities for this [3H]WB4101 binding site correlate with their affinities for the highest affinity component (alpha 1A) of [3H]prazosin binding. In addition, the Bmax of this [3H] WB4101-labeled site is equal to one-half of the total [3H]prazosin Bmax. Agonist competitions with [3H]prazosin binding are multiphasic with pseudo-Hill slopes less than 1.0 and with a rank order of affinity of epinephrine greater than norepinephrine greater than phenylephrine. When binding to the alpha 1A component is blocked by a 30 nM phentolamine mask, the same rank order of agonist affinities is preserved. Although the affinities of epinephrine and norepinephrine at the two subtypes are identical, phenylephrine is weaker at the alpha 1B site. The ratio of the potency of phentolamine versus prazosin is about 4 at the alpha 1A component but about 80 at the alpha 1B binding site. We discuss these data in relation to the reported potencies of these antagonists in blocking alpha 1-receptor-mediated responses which may correlate with our designation of alpha 1A or alpha 1B binding sites.     

Comparison of alpha 1-adrenergic receptor subtypes distinguished by chlorethylclonidine and WB 4101

We showed previously that subtypes of alpha 1-adrenergic receptors can be differentiated by selective inactivation with chlorethylclonidine (CEC) [Mol. Pharmacol. 32:505-510 (1987)] or by their affinities for the competitive antagonist WB 4101 [Nature (Lond.) 329:333-335 (1987)]. Examining eight rat tissues, the proportions of 125IBE 2254-binding sites sensitive to inactivation by CEC correlated significantly (p less than 0.05) with the proportion having a low affinity for WB 4101. However, the proportion of CEC-sensitive sites was always smaller than the proportion of low affinity WB 4101 sites. Further experiments showed that repetitive pretreatment with CEC or pretreatment under hypotonic conditions caused a larger inactivation of binding sites, suggesting that CEC did not access all sites under the isotonic conditions used previously. The proportions of binding sites inactivated by 10 microM CEC under hypotonic conditions were quantitatively similar to and correlated significantly (p less than 0.01) with the proportion having a low affinity for WB 4101. Pretreatment of hippocampus and vas deferens with CEC caused a loss of all low affinity WB 4101-binding sites, leaving only high affinity sites. In vas deferens, CEC pretreatment decreased the potency of norepinephrine in stimulating 3H-inositol phosphate accumulation but not contractile responses. In rat liver slices, CEC inactivated norepinephrine-stimulated 3H-inositol phosphate accumulation in parallel with 125IBE-binding sites. These results suggest that: 1) the CEC-sensitive and -insensitive 125IBE 2254-binding sites are equivalent to those with a low and high affinity for WB 4101, respectively, and 2) the CEC-sensitive binding sites with a low affinity for WB 4101 are the alpha 1-adrenergic receptors linked to inositol phospholipid hydrolysis.     

Identification of subtypes of [3H]prazosin-labelled alpha 1 receptor binding sites in rat brain

Detailed antagonist competition curves for [3H]prazosin-labelled binding sites in rat cerebral cortex membranes reveal anomalous binding characteristics. Dihydroergocryptine and indoramine compete in a steep, monophasic manner while WB4101 and phentolamine exhibit shallow competition curves. Computer-assisted analysis of binding data indicate that both WB4101 and phentolamine discriminate identical subpopulations of [3H]prazosin binding sites, which each comprise approximately 50% of specific [3H]prazosin binding. These data suggest the presence of subtypes of [3H]prazosin-labelled alpha 1 adrenergic receptors in rat cerebral cortex.     

3H-prazosin binds specifically to ‘α1’-Adrenoceptors in rat brain

Prazosin is know to block postsynaptic alpha-adrenoceptors. In this study 3H-prazosin has been used to label biochemically central alpha-adrenoceptors. In rat brain membranes 3H-prazosin bound specifically in a rapid, reversible and saturable manner to a single class of high affinity sites. The relative order of potencies for inhibition of 3H-prazosin binding was WB4101 greater than ARC 239 greater than phentolamine greater than piperoxane greater than yohimbine which is a characteristic of the alpha 1 type of adrenoceptors. In contrast, the relative order of potencies for inhibition of 3H-clonidine binding was yohimbine greater than piperoxane greater than WB4101 greater than ARC239 greater than prazosin which is a characteristic of the alpha 2 type of adrenoceptors. These results indicate that 3H-prazosin binds to central 'alpha 1'-receptors and 3H-clonidine to 'alpha 2'-receptors and confirm the presence of two classes of alpha-adrenoceptors in rat brain membranes.     

Pharmacological characterization of alpha 1-adrenoceptor subtypes in rat heart: a binding study.

1. The alpha 1-adrenoceptor subtypes of rat heart were characterized in binding experiments performed with [3H]-prazosin as the radiolabel. The specific binding to the alpha 1-adrenoceptors was determined with 0.3 microM prazosin, because phentolamine (10 microM) was insufficient to inhibit completely the specific binding of high concentrations of [3H]-prazosin. 2. In saturation experiments, [3H]-prazosin bound to two distinct affinity sites (pKD = 10.39 and 8.19). The proportion of the low affinity sites was approximately 84% of total specific binding. Membranes pretreated with chloroethylclonidine (CEC, 10 microM) also showed two distinct affinity sites for [3H]-prazosin, although the maximum numbers of high and low affinity sites were reduced by 86 and 64%, respectively. 3. In competition experiments, [3H]-prazosin (100 pM) binding was inhibited by WB4101 (2-(2,6-dimethoxy-phenoxyethyl)aminomethyl-1,4-benzodioxane) and 5-methylurapidil. The inhibition curves displayed shallow slopes which could be subdivided into high and low affinity components (pKi = 10.43 and 8.36 for WB4101, 8.62 and 6.61 for 5-methylurapidil). However, unlabelled prazosin or HV723 (alpha-ethyl-3,4,5-trimethoxy-alpha-(3-((2-(2-methoxyphenoxy)-ethyl)amin o) propyl)benzeneacetonitrile fumarate) competed for [3H]-prazosin binding monophasically (pKi = 10.34 and 8.28, respectively). In CEC-pretreated membranes, prazosin, WB4101, 5-methylurapidil and HV723 antagonized the [3H]-prazosin (100 pM) binding monophasically (pKi = 9.70, 9.56, 8.60 and 8.82, for each antagonist). 4. On the other hand, 1000 pM [3H]-prazosin binding was inhibited by unlabelled prazosin biphasically (pKi = 10.49 and 8.49). HV723 did not discriminate both prazosin-high and low affinity sites (pKi = 8.18).(ABSTRACT TRUNCATED AT 250 WORDS)     

Assessment of imiloxan as a selective alpha 2B-adrenoceptor antagonist

1. The alpha 2-adrenoceptor binding sites of rabbit spleen and rat kidney, labelled with [3H]-rauwolscine, were characterized using a range of subtype selective ligands. 2. In rabbit spleen, the alpha-2-adrenoceptor binding sites displayed high affinity for oxymetazoline and WB 4101 and low affinity for prazosin and chlorpromazine suggesting the presence of an alpha 2A subtype. 3. There was evidence for heterogeneity of the alpha 2-adrenoceptor binding sites present in rabbit spleen. The results obtained with oxymetazoline and WB 4101 indicated that at least 75% of the [3H]-rauwolscine binding sites in this preparation displayed a pharmacology consistent with the presence of an alpha 2A subtype. 4. In rat kidney, the alpha 2-adrenoceptor binding sites displayed high affinity for prazosin and chlorpromazine and low affinity for oxymetazoline and WB 4101 suggesting the presence of an alpha 2B subtype. 5. The inclusion of guanylylimidodiphosphate (Gpp(NH)p, 0.1 mM) did not modify the pharmacology of the alpha 2-adrenoceptor binding sites present in the two preparations. Furthermore, when the two membrane preparations were combined, the resultant pharmacology was still consistent with the presence of two receptors that retained the characteristics of the alpha 2A and alpha 2B subtypes. 6. Imiloxan was identified as a selective alpha 2B ligand while benoxathian displayed a high degree of selectivity for the alpha 2A-adrenoceptor binding site. The selectivity of imiloxan for the alpha 2B-adrenoceptor binding site, coupled with its specificity for alpha 2-adrenoceptors, should make it a valuable tool in the classification of alpha 2-adrenoceptor subtypes.     

Interaction of subtype-selective antagonists with alpha 1-adrenergic receptor binding sites in rat tissues.

(+)-Niguldipine inhibited specific 125I-BE 2254 binding more potently in membrane preparations from rat tissues enriched in the alpha 1A subtype (hippocampus and vas deferens) than those with the alpha 1B subtype (liver and spleen). Inhibition curves for (+)-niguldipine were better fit by a two-site model in most tissues, although Kl values for each site varied markedly between tissues. The potency of this lipophilic drug was highly dependent on tissue concentration, probably accounting for most of this variability. Pretreatment of membranes with chloroethylclonidine (CEC) to inactivate the alpha 1B subtype did not completely eliminate the low affinity sites for (+)-niguldipine, particularly in heart. Saturation analysis showed that (+)-niguldipine competitively inhibited both alpha 1A and alpha 1B subtypes. However, substantial non-competitive inhibition was also observed in several tissues. Analysis of inhibition curves for 5-methylurapidil gave similar proportions of alpha 1A and alpha 1B receptor sites as were calculated for (+)-niguldipine in various tissues. Although (+)-niguldipine and 5-methylurapidil revealed variable proportions of low affinity sites in CEC-pretreated hippocampus and heart, this was not observed with inhibition curves for WB 4101 and phentolamine. These results are generally consistent with the previously defined alpha 1A and alpha 1B subtypes. 5-Methylurapidil currently appears to be the best antagonist for discriminating these subtypes; (+)-niguldipine shows similar selectivity but is complicated by a high lipophilicity. However, the persistence of low affinity sites for 5-methylurapidil and (+)-niguldipine after CEC pretreatment and the noncompetitive effects of (+)-niguldipine in some tissues raise the possibility of an additional subtype(s) of alpha 1-adrenergic receptors in rat tissues.     

A possible structural determinant of selectivity of boldine and derivatives for the alpha 1A-adrenoceptor subtype.

1. The selectivity of action of boldine and the related aporphine alkaloids, predicentrine (9-O-methylboldine) and glaucine (2,9-O-dimethylboldine) and alpha 1-adrenoceptor subtypes was studied by examining [3H]-prazosin competition binding in rat cerebral cortex. WB 4101 and benoxathian were used as selective alpha 1A-adrenoceptor antagonists. 2. In the competition experiments [3H]-prazosin (0.2 nM) binding was inhibited by WB 4101 and benoxathian. The inhibition curves displayed shallow slopes which could be subdivided into high and low affinity components (pKi = 9.92 and 8.29 for WB 4101, 9.35 and 7.94 for benoxathian). The two antagonists recognized approximately 37% of the sites with high affinity from among the total [3H]-prazosin specific binding sites. 3. Boldine, predicentrine and glaucine also competed for [3H]-prazosin (0.2 nM) binding with shallow and biphasic curves recognizing 30-40% of the sites with high affinity. Drug affinities (pKi) at the high and low affinity sites were, 8.31 and 6.50, respectively, for boldine, 8.13 and 6.39 for predicentrine, and 7.12 and 5.92 for glaucine. The relative order of selectivity for alpha 1A-adrenoceptors was boldine (70 fold alpha 1A-selective) = predicentrine (60 fold, alpha 1A-selective) > glaucine (15 fold, alpha 1A-selective). 4. Pretreatment of rat cerebral cortex membranes with chloroethylclonidine (CEC, 10 microM) for 30 min at 37 degrees C followed by thorough washing out reduced specific [3H]-prazosin binding by approximately 70%. The CEC-insensitive [3H]-prazosin binding was inhibited by boldine monophasically (Hill slope = 0.93) with a single pKi value (7.76). 5. These results suggest that whereas the aporphine structure shared by these alkaloids is responsible for their selectively of action for the alpha 1A-adrenoceptor subtype in rat cerebral cortex, defined functional groups, namely the 2-hydroxy function, induces a significant increase in alpha 1A-subtype selectivity and affinity.     

Pharmacological characterization of two distinct alpha 1-adrenoceptor subtypes in rabbit thoracic aorta.

1. alpha 1-Adrenoceptor subtypes in rabbit thoracic aorta have been examined in binding and functional experiments. 2. [3H]-prazosin bound to two distinct populations of alpha 1-adrenoceptors (pKD,high = 9.94, Rhigh = 79.2 fmol mg-1 protein; pKD,low = 8.59, Rlow = 215 fmol mg-1 protein). Pretreatment with chloroethylclonidine (CEC, 10 microM) almost inactivated the prazosin-high affinity sites and reduced the number of the low affinity sites without changing the pKD value. 3. In the displacement experiments with CEC-untreated membranes, unlabelled prazosin, WB4101 and HV723 displaced the binding of 200 pM [3H]-prazosin monophasically; the affinities for WB4101 (pK1 = 8.88) and HV723 (8.49) were about 10 times lower than that for prazosin (9.99). In the CEC-pretreated membranes also, the antagonists inhibited the binding of 1000 pM [3H]-prazosin monophasically; the pK1 values for prazosin, WB4101 and HV723 were 9.09, 8.97 and 8.17, respectively. These results suggest that the prazosin-high and low affinity sites can be independently appraised in the former and latter experimental conditions. Noradrenaline, but not methoxamine, showed slightly higher affinity for the prazosin-high affinity site than for the low affinity site. 4. In the functional experiments, noradrenaline (0.001-100 microM) and methoxamine (0.1-100 microM) produced concentration-dependent contractions. Pretreatment with CEC inhibited the contractions induced by low concentrations of noradrenaline but without effect on the responses to methoxamine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rat pineal alpha 1-adrenoceptor subtypes: studies using radioligand binding and reverse transcription-polymerase chain reaction analysis.

1. The pharmacological characteristics of alpha 1-adrenoceptor binding sites in rat pineal gland membranes, detected by use of a selective alpha 1-adrenoceptor antagonist ([125I]-iodo-2-[beta-(4-hydroxyphenyl) ethylaminomethyl]tetralone, [125I]-HEAT), were investigated with the alkylating agent, chloroethylclonidine (CEC), and in competition experiments with a number of adrenoceptor agonists and antagonists. 2. Chloroethylclonidine (CEC) treatment (10 microM, 10 min) of rat pineal membranes inactivated approximately 70% of specific [125I]-HEAT binding sites. Higher concentrations of CEC (up to 100 microM) or longer treatment periods (up to 40 min) were no more effective. 3. Adrenoceptor agonists and antagonists competitively inhibited [125I]-HEAT binding with Hill coefficients close to unity indicating a single alpha 1-adrenoceptor subtype is present. The affinity (Ki) of subtype selective agonists (oxymetazoline, SDZ NVI-085) and antagonists (5-methylurapidil, WB4101, benoxathian, phentolamine) was consistent with binding to an alpha 1B-adrenoceptor subtype. 4. The (-)- and (+)-enantiomers of niguldipine had an equal and low affinity for alpha 1-adrenoceptor binding sites both in untreated (log Ki-6.66 and -6.90 respectively) and CEC-treated membranes in which approximately 70% of sites had been inactivated (log Ki-6.41 and -6.86 respectively). This indicates that the small proportion of alpha 1-adrenoceptors insensitive to CEC are not alpha 1A-adrenoceptors. 5. mRNA was isolated from rat pinealocytes, cDNA was synthesized and then amplified by the polymerase chain reaction with alpha 1-adrenoceptor subtype specific primers. These experiments identified both alpha 1A- and alpha 1B-adrenoceptor mRNA, but not alpha 1D-mRNA in rat pinealocytes, although all three adrenoceptor subtypes were readily identified in rat brain cortex. 6. These data indicate that although both alpha 1A- and alpha 1B-adrenoceptor mRNAs are present in the pineal the major subtype of alpha 1-adrenoceptor expressed is the alpha 1B.     

Pharmacological subclassification of alpha 1-adrenoceptors in vascular smooth muscle

1. We examined whether alpha 1-adrenoceptors in various blood vessels can be divided into subtypes by antagonist affinity or by susceptibility to chloroethylclonidine or nifedipine. 2. Noradrenaline or phenylephrine produced concentration-dependent contractions in all the tissues tested, which were competitively inhibited by phentolamine, yohimbine, prazosin, WB4101 and HV723. However, there were large differences between the tissues in the pA2 values for all the antagonists except phentolamine. 3. The blood vessels could be classified into three groups (I, II and III) on the basis of their affinity variation. In group I (dog mesenteric artery and vein, saphenous vein), the pA2 values for HV723 were greater than 9, and those for HV723 and WB4101 were approximately 1 log unit higher than for prazosin. This rank order of affinity reversed in group II (dog carotid artery and rat thoracic aorta), where prazosin was more potent (pA2 values greater than 9.5) than HV723 or WB4101. In group III (rabbit mesenteric artery, thoracic aorta and carotid artery and guinea-pig thoracic aorta), on the other hand, prazosin, HV723 and WB4101 inhibited the noradrenaline response with a similar affinity (pA2 values ranging from 8 to 9). 4. Yohimbine inhibited the responses to noradrenaline and phenylephrine with a lower affinity than prazosin, HV723 or WB4101. The pA2 values for yohimbine were similar in groups I and II (the values greater than 6.5), which were greater than those in group III (values less than 6.4).(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of electroconvulsive shock or imipramine on subtypes of alpha 1-adrenoceptors in the frontal cortex of the rat.

The effects of repeated treatment (14 days) with electroconvulsive shock (ECS) or imipramine on binding sites on alpha 1-adrenoceptors in the rat were studied. The binding of [3H]prazosin studied with WB4101 and phentolamine, as binding inhibitors, showed the existence of two subtypes of alpha 1-adrenoceptor (alpha 1A and alpha 1B). Proportions of the alpha 1A and alpha 1B binding sites were about 3:7 in the frontal cortex and 9:1 in the hippocampus. Pretreatment of the membranes with chlorethylclonidine (CEC) almost abolished the alpha 1B binding sites. Inhibition of the binding of [3H]prazosin studied with antidepressants (imipramine, desipramine, maprotiline and mianserin) showed that these drugs bound to alpha 1-adrenoceptors with low affinity, in an apparent monophasic manner. The characteristics of the alpha 1A and alpha 1B binding sites were studied by the binding assay with [3H]prazosin, in the presence of a small concentration (2 nM) of WB4101 to mask the alpha 1A binding sites, as well as the assay without WB4101, for the total alpha 1-adrenoceptor (alpha 1A and alpha 1B) binding. Repeated treatment with electroconvulsive shock increased but that with imipramine decreased, the density of the alpha 1B binding sites in the frontal cortex, without change of the affinity. Neither treatment affected the alpha 1A binding sites in the frontal cortex. The alpha 1-adrenoceptors (alpha 1A and alpha 1B) in the hippocampus were not affected at all by these repeated treatments. The electroconvulsive shock-induced increase in the alpha 1B binding sites in the frontal cortex of the rat could contribute to differences in clinical effects between electroconvulsive shock and antidepressant drugs.     

Alpha 1-adrenoceptor subtypes in aorta (alpha 1A) and liver (alpha 1B).

The effect of several alpha 1 adrenoceptor antagonists on the alpha 1-adrenoceptor-mediated stimulation of phosphatidylinositol labeling was studied comparatively in rat hepatocytes and rabbit aorta. It was observed that 5-methyl urapidil and WB 4101 were much more potent in rabbit aorta than in hepatocytes. The orders of potency were prazosin much greater than 5-methyl urapidil greater than or equal to WB 4101 in liver cells and WB 4101 greater than or equal to 5 methyl urapidil = prazosin in aorta. Treatment with chlorethylclonidine inhibited 70-80% of the stimulation of labeling induced by epinephrine in rat liver, but only 30-40% of that in aorta. Our data suggest the existence of two pharmacologically distinct receptors in these tissues i.e.m alpha 1A-adrenoceptors in aorta and alpha 1B in liver cells.     

Evidence for a complex interaction between the subtypes of the alpha 1-adrenoceptor.

Ligand binding studies with WB 4101 revealed that the rat aorta contains both the alpha 1a- and alpha 1b-adrenoceptor subtypes. Results obtained following treatment with the irreversible antagonists phenoxybenzamine, chlorethylclonidine or SZL-49 (4-amino-6,7-dimethoxy-2-quinazolinyl-4-(2-bicyclo[2,2,2]octa-2,5- dienylcarbonyl-2-piperazine) suggest that there is a complex interaction between the alpha 1-adrenoceptor subtypes in the aorta. Chlorethylclonidine affects only the alpha 1b-adrenoceptor, whereas the predominant action of SZL-49 is on the alpha 1a-subtype. Chlorethylclonidine significantly inhibited the response to either methoxamine or phenylephrine, agents which are selective alpha 1a-adrenoceptor agonists. Following inactivation with either chlorethylclonidine or SZL-49, the response of the rat aorta to phenylephrine was only partially antagonized by either prazosin or WB 4101. SZL-49 also inhibited the response of the rat tail artery to electrical stimulation. The response of the tail artery obtained following inactivation with SZL-49 was effectively antagonized by prazosin. Phenylephrine, prazosin or WB 4101 afforded complete protection from chlorethylclonidine adrenoceptor inactivation, while these same ligands were only partially effective against SZL-49. Either SZL-49 or chlorethylclonidine significantly impaired the irreversible adrenoceptor blocking actions of phenoxybenzamine. These results suggest: (1) only the alpha 1a-adrenoceptor subtype appears to be associated with nerve terminals in the tail artery, (2) there may be a complex interaction between the alpha 1-adrenoceptor subtypes such that both receptors must be intact and functional to observe normal agonist and antagonist interactions, (3) there may be three sites of action for agonists associated with the rat aorta.     

The alpha-adrenergic receptor: radiohistochemical analysis of functional characteristics and biochemical differences

The partial agonist [3H]para-aminoclonidine was used to label alpha 2-adrenergic binding sites in intact sections of the rat central nervous system using in vitro labeling receptor autoradiographic techniques. The distribution of alpha 2-agonist binding sites closely parallels the reported distribution of noradrenergic and adrenergic cell groups and their terminal fields, particularly the projections of the medullary catecholamine neurons. This distribution of alpha 2 binding sites confirms physiological studies which indicate that the anti-hypertensive actions of alpha 2-agonist compounds are mediated centrally in medullary and spinal centers involved in the control of parasympathetic and sympathetic outflow. Further, the high concentrations of alpha 2 binding sites in pontine and limbic areas such as the locus coeruleus, parabrachial nucleus, dorsal raphe, hypothalamus, amygdala, bed nucleus of the stria terminalis, septum and entorhinal cortex offer an anatomical basis for understanding the anxiolytic and antidepressant actions of drugs like clonidine. The antagonists [3H]prazosin and [3H]WB4101 were used to study the distribution of alpha 1-adrenergic binding sites in the rat forebrain and biochemical studies were performed to analyze the marked differences that were initially seen in the distribution of [3H]prazosin and [3H]WB4101 binding sites. Several pieces of evidence derived from both biochemical and autoradiographic studies suggest that [3H]prazosin and [3H]WB4101 act at distinctly different binding sites. However, both sites may represent components of an alpha 1-adrenergic receptor-effector complex since a high degree of overlap was seen in the binding site distribution of these two ligands and since kinetic interactions could be demonstrated in at least one region of the brain, the hippocampus. Differences noted in the relative displacements of [3H]prazosin and [3H]WB4101 binding in various forebrain regions could reflect differences in the coupling efficiency of the [3H]prazosin and [3H]WB4101 component of the hypothesized complex. Further, in some regions, [3H]WB4101 labeled a binding site that is different from the alpha 1-receptor. Thus, [3H]prazosin and [3H]WB4101 binding sites seen in forebrain regions such as lamina V of the cortex, thalamic nuclei and dorsal raphe probably represent alpha 1-adrenergic receptors and confirm electrophysiological and biochemical studies which demonstrate that adrenergic transmission in these regions can be mediated through an alpha 1-receptor.     

Two pharmacologically distinct alpha 1-adrenoceptor subtypes in the contraction of rabbit aorta: each subtype couples with a different Ca2+ signalling mechanism and plays a different physiological role

Using the alpha 1-adrenoceptor subtype-selective antagonists chlorethylclonidine (CEC), WB4101, and 5-methyl-urapidil, we have examined the possible heterogeneity in the alpha 1-adrenoceptor populations in rabbit aorta. The alpha 1-adrenoceptor alkylating agent CEC selectively inhibited the phasic component of the norepinephrine-induced contractile response, with little effect on the tonic component. The alpha 1-adrenoceptor occupancy-response relationship defined by the phenoxybenzamine inactivation method was rectangular hyperbolic for the tonic response, whereas that for the phasic response was linear, indicating the different degree of receptor reserve for the two responses. Radioligand binding studies with the nonselective alpha 1-adrenoceptor antagonist radioligand 125I-BE2254 showed that 73-87% of the binding sites in rabbit aorta are CEC sensitive and they are predominantly low affinity sites both for WB4101 (pKd = 8.1) and for 5-methylurapidil (pKd = 7.1). Moreover, alpha 1-adrenoceptor-mediated phosphatidylinositol (PI) hydrolysis was CEC sensitive, and fractional inactivation of alpha 1 receptors with CEC showed equivalent increments in the reduction of PI hydrolysis and phasic contractile response, suggesting that both responses are linearly related to the CEC-sensitive receptor sites. The Schild plots for the competitive antagonists WB4101 and 5-methyl-urapidil against alpha 1a-adrenoceptor-selective agonist methoxamine-induced contraction were linear and had slopes not significantly different from unity, with a pA2 of 9.07 +/- 0.07 (n = 5) for WB4101 and 9.09 +/- 0.05 (n = 3) for 5-methyl-urapidil. However, the Schilod plots for these antagonists against norepinephrine were curvilinear. Computer-assisted analysis of these curvilinear Schild plots in a two-receptor system indicated that alpha 1-adrenoceptor populations responsible for the constrictive response are predominantly (approximately 80-90%) low affinity sites for the two antagonists (pKd approximately 8.1 for WB4101 and pKd approximately 7.1 for 5-methyl-urapidil) and a small population (approximately 10-20%) are high affinity sites (pKd approximately 9.1 for both WB4101 and 5-methyl-urapidil), which was in good agreement with radioligand binding studies.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of a single alpha 1-adrenoceptor corresponding to the alpha 1A-subtype in rat submaxillary gland.

1. The alpha 1-adrenoceptors present in membranes of rat liver, cortex and submaxillary gland were labelled with [3H]-prazosin and the affinity of 15 ligands for these receptors was determined. 2. In saturation studies, [3H]-prazosin bound with high affinity (Kd = 30-39 pM) to a single population of sites in all three preparations. 3. In competition studies using rat cortex, evidence for heterogeneity of the alpha 1-adrenoceptor binding sites was obtained. Displacement isotherms for amidephrine, benoxathian, oxymetazoline, phentolamine and WB 4101 were biphasic and were consistent with the presence of both alpha 1A- and alpha 1B-adrenoceptor subtypes as described by Morrow & Creese (1986) and Han et al. (1987). 4. The rat liver and submaxillary gland membrane preparations both possessed homogeneous populations of alpha 1-adrenoceptors. However, there were pharmacological differences between the receptors in these two preparations. Rat submaxillary gland alpha 1-adrenoceptors displayed high affinity for amidephrine, benoxathian, oxymetazoline, phentolamine and WB 4101 and therefore appeared to represent alpha 1A-adrenoceptors. Rat liver alpha 1-adrenoceptors possessed lower affinity for these ligands (6-65 fold) suggesting that these receptors were of the alpha 1B-subtype. 5. Spiperone exhibited 12.9 fold higher affinity for rat liver alpha 1B-adrenoceptors than for rat submaxillary gland alpha 1A-adrenoceptor and may therefore represent the first alpha 1B-adrenoceptor selective ligand.     

5-Methylurapidil may discriminate between alpha 1-adrenoceptors with a high affinity for WB4101 in rat lung.

The alpha 1-adrenoceptors of rat lung with a high affinity for [3H]-prazosin were subdivided into two populations (high and low affinity sites) by WB4101 and 5-methylurapidil but the proportions were different between both drugs. After pretreatment with chlorethylclonidine, WB4101 recognized only high affinity sites, while 5-methylurapidil still detected high and low affinity sites. These results indicate that alpha 1-adrenoceptors with a high affinity for WB4101 are not homogeneous in the rat lung, suggesting the possible existence of a new alpha 1-adrenoceptor subtype in addition to alpha 1A and alpha 1B subtypes.     

Alpha 1-adrenergic receptor subtypes and formation of inositol phosphates in dispersed hepatocytes and renal cells

The ability of alpha 1a- and alpha 1b-adrenergic receptor subtypes to stimulate [3H]inositol phosphate [( 3H]InsP) formation was examined in collagenase-dispersed hepatocytes and renal cells. alpha 1-Adrenergic receptor binding sites were labeled with 125I-BE 2254, and the proportion of alpha 1a and alpha 1b subtypes was determined with chloroethylclonidine (CEC) and WB 4101. Hepatocytes contained only alpha 1b-adrenergic receptors, whereas renal cells had approximately equal proportions of both subtypes. Pretreatment of renal cells with CEC selectively inactivated the alpha 1b subtype, leaving a homogeneous population of alpha 1a receptors. Norepinephrine stimulated [3H]InsP accumulation to a similar extent in both hepatocytes and renal cells. Pretreatment with CEC inactivated this response completely in hepatocytes but only partially in renal cells. WB 4101 was 1000-fold more potent in inhibiting the [3H]InsP response in renal cells than hepatocytes; however, some of this difference was due to rapid metabolism of WB 4101 by hepatocytes. After correction for metabolism, WB 4101 was still 11-fold more potent in inhibiting norepinephrine-stimulated [3H]InsP formation in hepatocytes (alpha 1b) than in CEC-pretreated renal cells (alpha 1a). These results demonstrate that both alpha 1a- and alpha 1b-adrenergic receptor subtypes activate formation of [3H]InsP, although the molecular mechanisms by which these responses occur remain to be determined.