Dopamine receptors in canine caudate nucleus

Summary Physiological, pharmacological, histochemical and biochemical studies indicate that dopamine receptors are heterogenous in the, central nervous system with each individual functions. This review describes pharmacological and biochemical characteristics of dopamine receptors, particularly in canine caudate nucleus, which have been studied in our laboratory with a brief comparison to the current studies by other workers in similar research fields.Two distinct dopamine receptors have been characterized by means of [³H]dopamine binding to the synaptic membranes from canine caudate nucleus. One of the receptors with a Kd of about 3 M for dopamine may be associated with adenylate cyclase and referred to as D, receptor. The other receptor with a Kd of about 10 nM for dopamine is independent of adenylate cyclase and referred to as D₂. A photochemical irreversible association of [³H]dopamine with the membraneous receptors makes it possible to separate D₁ and D₂ receptors from one another by gel filtration on a Sephadex G-200 column after solubilization with Lubrol PX. On the basis of selective inhibition of [³H]dopamine binding to D₁ and D₂ receptors, dopamine antagonists can be classified into three classes: D₁-selective (YM-09151-2), D₂-selective (sulpiride) and nonselective (haloperidol, chlorpromazine). Effects of these typical antagonists on the metabolism of rat brain dopamine suggest that D₁ receptor is more closely associated with the neuroleptic-induced increase in dopamine turnover. Studies with 28 benzamide derivatives and some classical neuroleptics reveal that apomorphine-induced stereotypy displays a greater association with D₁ than with D₂ receptors.Dopamine-sensitive adenylate cyclase in canine caudate nucleus can be solubilized with Lubrol PX in a sensitive form to either dopamine, Gpp(NH)p or fluoride. Sephadex G-200 gel filtration separates adenylate cyclase from D₁ receptors with a concomitant loss of dopamine sensitivity. Addition of the D₁ receptor fraction to the adenylate cyclase restores the responsiveness to dopamine. The solubilized dopamine-unresponsive adenylate cyclase can be further separated into two distinct fractions by a batch-wise treatment with GTP-sepharose: a catalytic unit which does not respond to fluoride, and a guanine nucleotide regulatory protein. The regulatory protein confers distinct responsiveness to Gpp(NH)p and fluoride upon adenylate cyclase. These results indicate that dopamine-sensitive adenylate cyclase is composed of at least three distinct units; D₁ receptor, guanine nucleotide regulatory protein and adenylate cyclase.     

STIMULATION OF GLYCOGENOLYSIS IN RAT CAUDATE NUCLEUS SLICES BY L-ISOPROPYLNOREPINEPHERINE, DIBUTYRYL CYCLIC AMP AND 2-CHLOROADENOSINE

Dopamine (DA), L-isópropylnorepinepherine (IPNE), 2-chloroadenosine (2-Cl-Ado), 3-isobutyl, I-methylxanthine (IBMX) and N⁶,O^2′-dibutyryl cyclic AMP have been investigated for their effects on glycogen levels in rat caudate nucleus slices. Incubation of slices with 1 mM-dibutyryl cyclic AMP, or with 50 μM-IPNE in the presence of 1mM-IBMX, or with 5-500 μM-2-Cl-Ado reduced glycogen levels to about 50% of control. Incubation of slices with 1 mM-IBMX alone, or with 50μM-IPNE alone, or with 50μM-DA either alone or in the presence of 1 mM-IBMX was without significant effect on glycogen levels. The effect of IPNE + IBMX was completely abolished by the prior addition of 10 μM-propranolol. The effect of 10 μM-2-Cl-Ado was not effectively prevented by either 100 μM-theophylline or 100 μM-cordycepin. The results indicate that the β-adrenergic adenylate cyclase in the rat caudate nucleus plays a role in the regulation of glycogen metabolism, while the DA-stimulated adenylate cyclase is not significantly involved. The 2-Cl-Ado-stimulated adenylate cyclase may be involved in the control of glycogen metabolism, but other mechanisms for the 2-CI-Ado action, such as interference with allosteric regulatory sites on glycogen phosphorylase, have not been ruled out.     

Dopamine receptor binding: differentiation of agonist and antagonist states with 3H-dopamine and 3H-haloperidol.

³H-Dopamine and ³H-haloperidol bind with high affinity and selectivity to synaptic dopamine receptors in membrane preparations of the calf caudate. Binding of both ligands shows marked regional variations with greatest density in caudate, putamen, globus pallidus, nucleus accumbens and olfactory tubercle, areas rich in dopamine nerve terminals. The rank-order of phenothiazines and related agents as well as catecholamines in displacing both dopamine and haloperidol binding closely parallels their pharmacological potencies and affinities for the dopamine-sensitive adenylate cyclase. Dopamine's affinity for specific ³H-dopamine binding sites is 100 times its apparent affinity for the dopamine sensitive adenylate cyclase. Agonists have about 50 times more affinity for dopamine than haloperidol sites, whereas antagonists display about 100 times greater affinity for haloperidol than dopamine sites.     

Adrenocorticotropin/α-Melanocyte-Stimulating Hormone (ACTH/MSH)-Like Peptides Modulate Adenylate Cyclase Activity in Rat Brain Slices: Evidence for an ACTH/MSH Receptor-Coupled Mechanism

Abstract: The regulation of adenylate cyclase activity by adrenocorticotropin/α-melanocyte–stimulating hormone (ACTH/MSH)-like peptides was investigated in rat brain slices using a superfusion method. Adenylate cyclase activity was concentration-dependently increased by ACTH-(1–24), α-MSH (EC₅₀ values 16 and 6 nM, respectively), and [Nle⁴,D-Phe⁷]α-MSH (EC₅₀ value 1.6 nM), in the presence of forskolin (1 μM, optimal concentration). 1-9-Dideoxy-forskolin did not augment the response of adenylate cyclase to ACTH-(1–24). Various peptide fragments were tested for their ability to enhance [³H]cyclic AMP production. [Nle⁴,D-Phe⁷]α-MSH increased [³H]cyclic AMP formation with a maximal effect of 30% and was more potent than ACTH-(1–24), ACTH-(1–16)-NH₂, α-MSH, ACTH-(1–13)-NH₂, [MetO⁴]α-MSH, [MetO₂⁴,D-Lys⁸,Phe⁹]ACTH-(4–9), ACTH-(7–16)-NH₂, ACTH-(1–10), and ACTH-(11–24), in order of potency. This structure–activity relationship resembles that found for the previously described peptide-induced display of excessive grooming. ACTH-(1–24) stimulated adenylate cyclase activity in both striatal (maximal effect, ?20%) and septal slices (maximal effect, ?40%), but not in hippocampal or cortical slices. Lesioning of the dopaminergic projections to the striatum did not result in a diminished effect of [Nle⁴,D-Phe⁷]α-MSH on [³H]cyclic AMP accumulation, which indicates that the ACTH/MSH receptor–stimulated adenylate cyclase is not located on striatal dopaminergic terminals. ACTH-(1–24) did not affect the dopamine D₁ or D₂ receptor–mediated modulation of adenylate cyclase activity. Based on the present data, we suggest that the binding of endogenous ACTH or α-MSH to a putative ACTH/MSH receptor in certain brain regions leads to the activation of a signal transduction pathway using cyclic AMP as a second messenger.     

ACTIVATION OF GLYCOGEN PHOSPHORYLASE IN RAT CAUDATE NUCLEUS SLICES BY l-ISOPROPYLNOREPINEPHERINE AND DIBUTYRYL CYCLIC AMP

Abstract— l -Isopropylnorepinepherine (IPNE), 3-isobutyl-1-methylxanthine (IBMX) and N⁶,O²'-dibutyryl cyclic AMP have been found to stimulate the conversion of glycogen phosphorylase (GPase) from b to a forms in rat caudate nucleus slices. The average percentage of total GPase in the a form in control incubations was 32%. The percentage of total GPase in the a form was increased to 1.5 times the control value in the presence of 1 mM-IBMX, to twice the control value in the presence of 0.05 mM-IPINE and to 2.5 times the control in the presence of 0.05 mM-IPNE and 1 mM-IBMX in combination. The increase in GPase activation correlated well with the elevation of cyclic AMP levels by these agents in caudate slices. The percentage of total GPase in the a form was also increased to 2.5 times the control by 1 mM dibutyryl cyclic AMP. Dopamine (DA) and 2-chloroadenosine (2-CI-Ado), which also elevate cyclic AMP levels in rat caudate slices, were without significant effect on GPase. The results indicate that the β-adrenergc adenylate cyclase in the rat caudate nucleus plays a role in the regulation of glycogen metabolism, while the DA-stimulated adenylate cyclase is not significantly involved. 2-CI-Ado does have effects on glycogen metabolism in the caudate, but these effects do not appear to be mediated by GPase activation.     

Dopamine receptors in the goldfish retina: 3H-spiroperidol and 3H-domperidone binding; and dopamine-stimulated adenylate cyclase activity

Dopamine receptors in the goldfish retina have been examined by binding studies using ³H-spiroperidol and ³H-domperidone as specific ligands, and by measuring retinal adenylate cyclase activities in the presence and absence of dopamine. Our results indicate that washed membranes from goldfish retinal homogenate bind a variety of dopamine agonists and antagonists with high affinities and with characteristics similar to those reported for the brain, with the exception that in this retina there is virtually no binding of the specific D₂ receptor antagonist, ³H-domperidone. In addition, there is a very low basal activity of adenylate cyclase which can be greatly stimulated by dopamine, possibly reflecting a high degree of coupling between this enzyme and the dopamine receptor. Taken together, our findings indicate that the goldfish retina contains a high density of D₁ type dopamine receptors and few, if any, D₂ type receptors.     

Adenylate cyclase coupled beta adrenergic receptors of Rauscher erythroleukemia cells

Rauscher murine erythroleukemia cells undergo erythroid differentiation in response to the hormonal inducer erythropoietin and to synthetic inducers. Incubation of these cells with (?) isoproterenol or (?) epinephrine results in a 2–3-fold increase in cyclic AMP levels. This effect is completely blocked by propranolol, identifying the response as due to a β-adrenergic receptor·adenylate cyclase system. Experiments with [¹²⁵I]iodohydroxybenzylpindolol demonstrate 1700 β-adrenergic receptors/cell with a K_D of 320 pM. These results form the basis for further studies of the β-adrenergic receptor·adenylate cyclase complex during erythropoiesis.     

Effect of neuropeptide-EI on the binding of [3H]SCH 23390 to the dopamine D1 receptor in rat striatal membranes

We have previously demonstrated that neuropeptide-EI, at high doses, stimulates the production of cAMP, in caudate putamen, through the activation of adenylate cyclase coupled to specific D₁ receptors. The aim of the present work was to find evidences for a probable interaction between this neuropeptide and the dopamine D₁ receptor in the mammalian central nervous system. The present data show that neuropeptide-EI, at high concentrations, affected both the maximum binding and the apparent affinity of [n-methyl-³H] (R)-(+)-8 chloro-2,3,4,5- tetrahydro-3-methyl-5-phenyl-1H-3-benzazepin-7-ol hemimaleate to the dopamine D₁ receptor in a concentration-dependent manner.     

Preparation and properties of a cell-free, hormonally responsive adenylate cyclase from guinea pig brain

—The accumulation of cyclic adenosine 3′,5′-monophosphate (cyclic AMP) was studied in cell-free homogenates of guinea pig brain. Homogenates, prepared in Krebs-Ringer buffer, responded markedly to the addition of neurohormones with an increased rate of cyclic AMP synthesis; preparations from cerebellum, cerebral cortex, and hippocampus responded to a degree approximating that achieved with slices of these areas of guinea pig brain. Adenylatc cyclase activity was seen only when cyclic AMP was measured by a [³H]adenine prelabelling technique or when total cyclic AMP was measured by radioimmunoassay; [³²P]ATP did not serve as a substrate for this preparation of the enzyme. The adenylate cyclase was paniculate and required a Krebs Ringer buffer; use of tris, or tris with Mg²⁺ and Ca²⁺, resulted in a preparation totally devoid of hormonal stimulation. Digestion by purified beef heart cyclic nucleotide phosphodiesterase, Dowex chromatography, solubility in Ba(OH)₂-ZnSO₄ mixtures, and two thin layer chromatographic systems demonstrated that the product of the hormonally stimulated adenylate cyclase preparation was cyclic AMP. The selectivity of hormonal stimulation and the adrenergic character of the hormonal receptors from different brain areas were maintained in the cell-free preparation. However, simultaneous stimulation with two different neurohormones resulted in additive responses, rather than in the potentiation observed in preparations of slices of brain.     

Evidence for a defect in the number of β-adrenergic receptors and in the adenylate cyclase responsiveness to guanine nucleotides in fat cells after adrenalectomy

Receptor binding studies (?)-[³H]dihydroalprenolol as the ligand revealed, in adrenalectomized rat fat cells, a 50% decrease in the number of β-adrenergic receptors. er cell with no change in the receptor affinity for this ligand. Adrenalectomy caused no change in the binding affinity for isoproterenol of both high affinity and low affinity populations of the β-adrenergic receptors. Guanine nucleotide sensitivity of the agonist binding to β-receptors was also unaltered by adrenalectomy. Adrenalectomy caused a 30–40% decrease in the maximal response of adenylate cyclase to (?)-isoproterenol only when guanine nucleotides were present in the assay, without altering the (?)-isoproterenol concentration giving half-maximal adenylate cyclase stimulation (K_act values). The maximal response of adenylate cyclase to Gpp(NH)p also was lower in adrenalectomized membranes, indicating a defect at the guanine nucleotide regulatory site. Removal of adenosine by addition of adenosine deaminase failed to reverse the decreased adenylate cyclase response to isoproterenol in adrenalectomized rats. However, in intact fat cells, in which cyclic AMP accumulation in response to isoproterenol was decreased by adrenalectomy, removal of adenosine almost completely corrected this defect. These results indicate that the observed changes in the number of β-adrenergic receptors and in the ability of guanine nucleotides to stimulate adenylate cyclase, though explaining the decreased adenylate cyclase responsiveness to catecholamines, do probably not contribute significantly to the mechanism by which adrenalectomy decreases the lipolytic responsiveness of adipocyte to catecholamines. In addition, this study also suggests that the increased sensitivity to adenosine of lipolysis reported in adipocytes from adrenalectomized rats may result from an action of adenosine at a post-adenylate cyclase step, possibly on the cyclic AMP phosphodiesterase.     

Effects of serotonin,dopamine and prostaglandin E2 on adenylate cyclase activity and cyclic AMP levels in different ganglia of the freshwater snail Planorbis corneus L.

The effects of different neuroactive agents on cyclic AMP level of selected ganglia of Planorbis corneus were studied. Serotonin, dopamine and prostaglandin E₂ were capable of increasing significantly cyclic AMP synthesis in all the preparations. When such substances were tested in pairs, supra-additive effects were always observed. In high Ca²⁺-high Mg²⁺ solutions dopamine action was blocked, meanwhile serotonin and prostaglandin E₂ were still effective in stimulating cyclic AMP synthesis. In the same experimental condition the supra-additive increases of the nucleotide level by drug combinations disappeared. Serotonin, but not dopamine, significantly stimulated adenylate cyclase activity in all the preparations, while prostaglandin E₂ was effective only in the Viscero-Parietal Complex. The presence of the adenylate cyclase activity in the nervous tissue of Planaorbis was substained by histochemical studies.These results demonstrating that in the nervous system of Planorbis cyclic AMP level is affected by neurotransmitters and neuromodulators, might support the idea of the crucial role of the cyclic nuclotide in the modulation of synaptic transmission.     

The dopamine receptor: differential binding of d-LSD and related agents to agonist and antagonist states.

Dopamine receptor binding is calf striatal membranes of ³H-dopamine and ³H-haloperidol appears to differentiate agonist and antagonist states of the receptor. Agonists and antagonists have selective affinities for dopamine and haloperidol sites respectively. In evaluating relative affinities for dopamine and haloperidol binding sites, we have observed that d-LSD interacts with considerable affinity at the dopamine receptor. Its similar competition petition for binding of the two tritiated ligands suggests that it is a mixed agonist-antagonist, which is consistent with its interactions with the dopamine-sensitive adenylate cyclase. The effects of LSD on dopamine receptor binding are stereospecific, with d-LSD being 1,000 times more potent than d-LSD. 2-Bromo-LSD has more of an antagonist profile than d-LSD for the dopamine receptor. In binding experiments methiothepin behaves like a potent and relatively pure antagonist at dopamine receptors.     

Evidence for a Distinct D1Like Dopamine Receptor that Couples to Activation of Phosphoinositide Metabolism in Brain

Abstract: Dopamine and the D₁, receptor agonist SKF 38393 activate the phospholipase C-rnediated hydrolysis of phosphoinositides in brain slices. This action is selectively inhibited by SCH-23390, thus suggesting its mediation through the dopamine D₁ receptor. To determine if the dopamine receptor that mediates Phosphoinositide hydrolysis is the adenylyl, cyclase-linked D₁ receptor or a different subtype of the dopamine D₁ receptor, 20 benzazepine compounds that were previously characterized as selective dopamine D₁ receptor agonists were tested for stimulation of Phosphoinositide hydrolysis in rat striatal slices and for activation of adenylyl cyclase in rat striatal membranes. The compounds displayed a range of potencies and efficacies in stimulating adenylyl cyclase or Phosphoinositide hydrolysis. Compounds such as SKF 81427 and SKF 38393 were as efficacious as dopamine in stimulating Phosphoinositide hydrolysis, whereas other compounds, including SKF 85174 and SKF 86284, although showing high efficacy in stimulating cyclic AMP, failed to stimulate inositol phosphate formation. There was no correlation between the potencies (r= 0.016; p < 0.95) or efficacies (r=?0.294; p < 0.24) of the tested compounds in stimulating cyclic AMP formation and phosphoinositide hydrolysis. These observations indicate that the D₁-like dopamine receptor that mediates phosphoinositide hydrolysis is pharmacologically distinct from the classic D₁ receptor that is coupled to stimulation of cyclic AMP formation.     

Neuroblastoma cell adenylate cyclase: direct activation by adenosine and prostaglandins.

—Adenylate cyclase activity of permeabilized neuroblastoma cells was measured by the conversion of [α³²P]ATP into labelled cyclic AMP. Adenosine (10^?6 - 10^?4m ) induced a dose-dependent increase in cyclic AMP formation. This effect could not be accounted for either by an adenosine-induced inhibition of the phosphodiesterase activity present in the enzyme preparation, or by a direct conversion of adenosine into cyclic AMP. This indicates that the observed increase in cyclic AMP accumulation reflected an activation of adenylate cyclase. Adenosine is partially metabolized during the course of incubation with the enzyme preparation. However, none of the identified non-phosphorylated adenosine metabolites were able to induce an adenylate cyclase activation. This suggests that adenosine itself is the stimulatory agent. The apparent K_m of the adenylate cyclase for adenosine was 5 ± 10^?6-10^?5m . Maximal activation represented 3-4 times the basal value (10-100 pmol cyclic AMP formed/10 min/mg protein). The adenosine effect was stereospecific, since structural analogues of adenosine were inactive. Adenosine increased the maximal velocity of the adenylate cyclase reaction. The stimulatory effect of adenosine was inhibited by theophylline. Prostaglandin PGE₁ had a stimulatory effect much more pronounced than that of adenosine (6-10-fold the basal value at 10^?6m ). Dopamine and norepinephrine induced a slight adenylate cyclase activation which was not potentiated by adenosine. It is concluded that adenosine is able to activate directly neuroblastoma cell adenylate cyclase. It seems very likely that such a direct activation is also present in intact nervous tissue and account, at least partly, for the observed cyclic AMP accumulation in response to adenosine.     

Comparison of the effects of prostaglandin I2 and prostaglandin E2 stimulation of the rat kidney adenylate cyclase-cyclic AMP systems

Prostacyclin (Prostaglandin I₂) effects on the rat kidney adenylate cyclase-cyclic AMP system were examined. Prostaglandin I₂ and prostaglandin E₂, from 8 · 10^?4 to 8 · ^?7 M stimulated adenylate cyclase to a similar extent in cortex and outer medulla. In inner medulla, prostaglandin I₂ was more effective than prostaglandin E₂ at all concentrations tested. Both prostaglandin I₂ and prostaglandin E₂ were additive with antidiuretic hormone in outer and inner medulla. Prostaglandin I₂ and prostaglandin E₂ were not additive in any area of the kidney, indicating both were working by similar mechanisms. Prostaglandin I₂ stimulation of adenylate cyclase correlated with its ability to increase renal slice cyclic AMP content. Prostaglandin I₂ and prostaglandin E₂ (1.5 · 10^?4 M) elevated cyclic AMP content in cortex and outer medulla slices. In inner medulla, with Santoquin® (0.1 mM) present to suppress endogenous prostaglandin synthesis, prostaglandin I₂ and prostaglandin E₂ increased cyclic AMP content. 6-Ketoprostaglandin F_1α, the stable metabolite of prostaglandin I₂, did not increase adenylate cyclase activity or tissue cyclic AMP content. Thus, prostaglandin I₂ activates renal adenylate cyclase. This suggests that the physiological actions of prostaglandin I₂ may be mediated through the adenylate cyclase-cyclic AMP system.     

A behavioural and biochemical comparison of dopamine receptor blockade produced by haloperidol with that produced by substituted benzamide drugs

Haloperidol inhibited dopamine (DA) mediated behaviours and induced pronounced catalepsy in rodents. Metoclopramide, sulpiride, sultopride, tiapride and clebopride, in general, also inhibited these behaviours but only clebopride induced marked catalepsy. Haloperidol displaced ³H-haloperidol and ³H-spiperone from striatal binding sites and inhibited DA stimulated cyclase from striatal and mesolimbic regions. In general, substituted benzamide drugs displaced labelled ligands, but did not inhibit adenylate cyclase. Elevations of striatal HVA produced by haloperidol and sulpiride, but not other benzamide drugs, were partially reversed by atropine. Hypophysectomy did not prevent the elevation of forebrain HVA produced by sulpiride and metoclopramide. Substituted benzamide drugs appear to act on cerebral DA receptors that are independent of DA-sensitive adenylate cyclase and are not balance by a cholinergic input.     

Receptor-mediated inhibition of octopamine-stimulated adenylate cyclase in the optic lobe of Octopus vulgaris

1. Inhibition of octopamine-stimulated adenylate cyclase was studied in the optic lobe of Octopus vulgaris.2. The octopamine antagonist, mianserin, and the dopamine D₂ agonists, PPHT and metergoline, induced dose-dependent inhibition of octopamine-stimulated adenylate cyclase activity.3. The binding of the tritiated benzazepine neuroleptic YM-09151-2 to octopus membranes and the displacement of [³H]YM-09151-2 by PPHT, metergoline and spiperone were consistent with the presence of a D₂-like dopamine receptor in the octopus optic lobe.4. The conclusion is drawn that octopamine-stimulated adenylate cyclase in the octopus is negatively regulated by a dopamine D₂-like receptor.     

[3H]Dopamine Labeling of D3 Dopaminergic Sites in Human, Rat, and Calf Brain

Abstract: The binding of [³H]dopamine to brain regions of calf, rat, and human was investigated. The calf caudate contained the highest density of [³H]dopamine binding sites, with a B_max value of 185 fmol/mg protein, whereas rat and human striatum contained one-third this number of sites. The K_D values for [³H]dopamine in all tissues were 2–3 nM. Dopaminergic catecholamines (dopamine, apomorphine, 6,7-dihydroxy-2-aminotetralin, and N-propylnorapomorphine) inhibited the binding of [³H]dopamine in all three species, at low concentrations, with IC₅₀ values of 1.5 to 6 nM. Neuroleptics, in contrast, inhibited the binding at high concentrations (with IC₅₀ values of 200 to 40,000 nM). The [³H]dopamine binding sites were saturable, heat-labile, and detectable only in dopamine-rich brain regions; these sites differed from D₂ dopamine sites (labeled by [³H]butyrophenone neuroleptics), and from D_l dopamine sites (labeled by [³H]thioxanthene neuroleptics) associated with the dopamine-stimulated adenylate cyclase. We have, therefore, called these high-affinity [³H]dopamine binding sites D₃ sites. [³H]Apomorphine and [³H]ADTN also appeared to label D₃ sites. These ligands however, were less selective than [³H]dopamine, and labeled sites other than D₃ as well. Assay conditions were important in determining the parameters of [³H]dopamine binding. The optimum conditions for selective labeling of the D₃ dopaminergic sites, using [³H]dopamine, required the presence of EDTA and ascorbate.     

Functional receptors for vasoactive intestinal peptide in cultured vascular smooth muscle cells from rat aorta

Specific binding sites for vasoactive intestinal peptide (VIP), a potent vasodilatory polypeptide, and its effect on formation of intracellular cyclic AMP levels were studied in cultured vascular smooth muscle cells (VSMC) from rat aorta. Specific binding of ¹²⁵I-labeled-VIP to cultured VSMCs was time- and temperature-dependent. Scatchard analysis of binding studies suggested the presence of two classes of high and low affinity binding sites for VIP; the apparent K_d and the number of maximal binding capacity were ∼8×10⁻⁹ M and 60,000 sites/cell (high-affinity sites) and ∼4×10⁻⁸ M and 140,000 sites/cells (low-affinity sites), respectively. Unlabeled VIP competitively inhibited the binding of ¹²⁵I-labeled-VIP to its binding sites, whereas neither peptides structurally related to VIP, nor other vasoactive substances affected the binding. VIP stimulated formation of intracellular cyclic AMP in cultured VSMCs in a dose-dependent manner; the stimulatory effect of VIP on cyclic AMP formation was not blocked by propranolol and was additive with isoproterenol. The present study first demonstrates the presence of specific receptors for VIP in VSMCs functionally coupled to adenylate cyclase system. It is suggested that VIP exerts its vasodilatory effect through its specific receptors distinct from β-adrenergic receptors.