Multiple dopamine binding sites: subcellular localization and biochemical characterization.

Abstract— The biochemical and pharmacological characteristics of dopamine agonist and antagonist binding to rat striatal subcellular fractions were studied and compared to the localization of dopamine–sensitive adenylate cyclase activity. The highest specific activity of adenylate cyclase sensitive to dopamine was associated almost exclusively with the crude synaptic membrane fraction (P₂). Using [³H]-haloperidol, [³H]apomorphine and [³H]spiroperidol as markers for the dopamine receptor, high affinity and stereoselective specific binding was observed for the crude synaptic fraction and the microsomal fraction (P₃). Analysis of the binding of [³H]haloperidol to the striatal microsomal preparation revealed a homogeneous receptor site with a K_d value of 3.0 nm . The data for [³H]haloperidol binding to the crude synaptosomal fraction showed two saturable binding sites with K_d values of 2.5 nm and 12.5 nm . A similar heterogeneous binding profile was observed in the P₂ fraction using [³H]apomorphine. The K_d values for [³H]apomorphine in this fraction were determined to be 1.2 nm and 7.2 nm . The effects of various biochemical parameters including ionic strength, salt concentration and pH on the binding of [³H]haloperidol to the P₂ fraction were also studied. Overall, these data show that the subcellular localization of multiple binding sites in the crude synaptosomal fraction and the identification of specific binding to purified synaptosomes correlate with the subcellular distribution of striatal dopamine-sensitive adenylate cyclase activity.     

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.     

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.     

[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.     

Dopamine Receptors in Subcellular Fractions from Bovine Caudate: Enrichment of [3H]Spiperone Binding in a Postsynaptic Membrane Fraction

Abstract: Specific binding of tritiated dopamine, spiperone, and N-propylnorapomorphine was examined in subcellular fractions from bovine caudate nucleus. All fractions contained at least two sets of specific binding sites for [³H]spiperone (K_{D 1}^aPP= 0.2 nM, K_{D 2}^aPP= 2.2 nM), the higher affinity sites accounting for one-third to one-eighth of the total. [³H]Spiperone binding was slightly enriched over the total particulate fraction in P₂, P₃, SPM, and a crude fraction of synaptic mitochondria. A microsomal subfraction (P₃B₂) exhibited the highest specific binding capacity obtained, representing a fourfold enrichment over the total particulate fraction. [³H]Dopamine exhibited apparent binding to a single class of high-affinity sites in all fractions examined (K_D^aPP= 4.0 nM). A greater than twofold enrichment was observed in all fractions except myelin and P₃, with a fivefold enrichment in SPM and P₃B₂. At least two classes of receptors were labeled by [³H]-N-propylnorapomorphine (K_{D 1}^aPP= 0.55 nM, K_{D 2}^aPP= 20 nM), using 50 nM-spiperone together with 100 nM-dopamine to define nonspecific binding. Although binding to the higher affinity site was displaced by spiperone, and lower affinity binding by dopamine, comparison of receptor densities with values obtained by using [³H]spiperone and [³H]dopamine directly suggested that [³H]-N-propylnorapomorphine labeled additional sites. We have also examined a postsynaptic membrane (PSM) fraction obtained from SPM by successive extraction with salt and EGTA followed by sonication and separation on a density gradient. [³H]Spiperone binding in PSM was enriched two- to threefold over unfractionated SPM with a concomitant decrease in [³H]dopamine binding. The enrichment in spiperone receptors was almost entirely due to an increase in the number of lower affinity binding sites, suggesting that these sites may be associated with the postsynaptic membrane.     

[3H]Spiroxatrine labels a serotonin1A-like site in the rat hippocampus

[³H]Spiroxatrine was examined as a potential ligand for the labeling of 5-HT_1A sites in the rat hippocampus. Analysis of the binding of [³H]spiroxatrine in the absence and presence of varying concentrations of three monoamine neurotransmitters revealed that serotonin (5-HT) had high affinity (IC₅₀= 20.7 nM for the [³H]spiroxatrine binding sites, consistent with the labeling of 5-HT₁ sites, while dopamine and norepinephrine had very low affinity (IC₅₀=57600 nM and >10⁻⁴ M respectively). Saturation studies of the binding of [³H]spiroxatrine revealed a single population of sites with a K_d=2.21 nM. Further pharmacologic characterization with the 5-HT_1A ligands 8-hydroxy-2-(di-n-propylamino) tetralin, ipsapirone, and WB4101 and the butyrophenone compounds spiperone and haloperidol gave results that were consistent with [³H]spiroxatrine labeling 5-HT_1A sites. This ligand produced stable, reproducible binding with a good ratio of specific to nonspecific binding. The binding of [³H]spiroxatrine was sensitive to GTP, suggesting that this ligand may act as an agonist. This was supported by the finding that spiroxatrine inhibits forskolin-stimulated adenylate cyclase activity (a proposed 5-HT_1A receptor model) in the rat hippocampus. Since [³H]spiroxatrine is structurally distinct from other currently available radioligands for the 5-HT_1A site, it should provide new information about the properties of this putative serotonergic receptor.     

In vitro characterization of skeletal muscle β-adrenergic receptors coupled to adenylate cyclase

[³H]Dihydroalprenolol, a potent ß-adrenergic antagonist, was used to identify the adenylate cyclase-coupled ß-adrenoceptors in isolated membranes of rat skeletal muscle. The receptor sites, as revealed [³H]dihydroalprenolol binding, were predominantly localized in plasmalemmal fraction. That skeletal muscle fraction may also contain the plasmalemma of other intramuscular cells, especially that of blood vessels. Hence, the [³H]dihydroalprenolol binding observed in that fraction may be due partly to its binding to the plasmalemma of blood vessels. Small but consistent binding was also observed in sarcoplasmic reticulum and mitochondria. The level of [³H]dihydroalprenolol binding in different subcellular fractions closely correlated with the level of adenylate cyclase present in those fractions.The binding of [³H]dihydroalprenolol to plasmalemma exhibited saturation kinetics. The binding was rapid, reaching equilibrium within 5 min, and it was readily dissociable. From the kinetics of binding, association (K₁) and dissociation (K₂) rate constants of 2.21 · M^? · min^?1 and 3.21 · 10^?1, respectively, were obtained. The dissociation constant (K_d) of 15 nM for [³H]dihydroalprenolol obtained from saturation binding data closely agreed with the (K_d) derived from the ratio of dissociation and association rate constants (K₂/K₁).Several β-adrenergic agents known to be active on intact skeletal muscle also competed for [³H]dihydroalprenolol binding sites in isolated plasmalemma with essentially similar selectivity and stereospecificity. Catecholamines competed for [³H]dihydroalprenolol binding sites with a potency of isoproterenol > epinephrine > norepinephrine. A similar order of potency was noted for catecholamines in the activation of adenylate cyclase. Effects of catecholamines were stereospecific, (?)-isomers being more than potent than (+)-isomers. Phenylephrine, an α-adrenergic agonist, showed no effect either on [³H]dihydroalprenolol binding or on adenylate cyclase. Known ß-adrenergic antagonists, propranolol and alprenolol, stereospecifically inhibited the [³H]dihydroalprenolol binding and the isoproterenol-stimulated adenylate cyclase. The (K_i) values for the antagonists determined from inhibition of [³H]dihydroalprenolol binding agreed closely with the (K_i) values obtained from the inhibition of adenylate cyclase. The data suggest that the binding of [³H]dihydroalprenolol in skeletal muscle membranes possess the characteristics of a substance binding to the ß-adrenergic receptor.     

Striatal muscarinic receptors: Regulation by dopaminergic agonists

The effects of apomorphine on the binding properties of striatal muscarinic receptors were investigated using the specific muscarinic antagonist, [³H](?)3-quinuclidinyl benzilate ([³H](?)QNB). When binding measurements were made in 50 mM sodium/HEPES buffer, pH 7.4, containing Mg⁺², the binding of [³H](?)QNB was consistent with the presence of two binding sites; 57% of the sites had a high affinity dissociation constant of 0.030 nM whereas the remaining sites had a low affinity dissociation constant of 0.64 nM. Apomorphine (1.0 μM) enhanced the binding of [³H](?)QNB by an apparent conversion of low to high affinity sites. A variety of other agents were screened for their ability to enhance [³H](?)QNB binding, and a pattern generally consistent with a dopaminergic effect was observed although some evidence for a β-adrenergic effect was demonstrable. The potent neuroleptics haloperidol, spiperone and sulpiride failed to antagonize the apomorphine enhancement of [³H](?)QNB binding as well as some adrenergic antagonists. However, the potent inhibitors of the dopamine-sensitive adenylate cyclase, α-flupenthixol and fluphenazine, specifically blocked the apomorphine enhancement of [³H](?)QNB binding with K_i values of approximately 0.1 μM.     

Evidence for Different States of the Dopamine Dl Receptor: Clozapine and Fluperlapine May Preferentially Label an Adenylate Cyclase-Coupled State of the Dl Receptor

Abstract: It has been shown previously that typical neuroleptics have higher affinities for 3,4-dihydroxyphenyl-ethylamine (dopamine) Dl receptors as labeled by(R)- (+)- 8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-1 -N-3-benzazepine-7-ol ([³H]SCH 23390) than for inhibiting dopamine-stimulated adenylate cyclase. We now report that the atypical neuroleptics, clozapine and fluperlapine, exhibit characteristics opposite to typical neuroleptics, i.e., they have higher affinity for inhibiting dopamine-stimulated adenylate cyclase than [³H]SCH 23390 binding. A variety of compounds, i.e., clozapine, fluperlapine, and dopamine, were tested for their capacity to affect the rate constants of [³H]SCH 23390 binding; these experiments revealed no effect of any tested compound on on-rate or off-rate of [³H]SCH 23390 binding. Treatment of striatal membranes with phospholipase A₂ (PLA₂) caused a rapid decrease in the B_max value of the [³H]SCH 23390 binding with no effect on the K_d value. The adenylate cyclase, both the unstimulated, the dopamine-, fluoride-, and forskolin-stimulated activity, was far less sensitive than [³H]SCH 23390 binding to PLA₂. Treatment of striatal membranes with filipine and (NH₄SO₄ produced, as did PLA₂ treatment, a rapid decline in [³H]SCH 23390 binding. However, opposite to PLA₂ treatment, these agents stimulated the adenylate cyclase. In conclusion, a comparison of the pharmacological characteristics of [³H]SCH 23390 binding and dopamine-stimulated adenylate cyclase suggests the existence of two different Dl binding sites. The rate experiments exclude the possibility of allosterically coupled sites. Instead our results favor that the Dl receptor exists in different states/conformations, i.e., both adenylate cyclase-coupled and uncoupled, and further, that the atypical neuroleptics clozapine and fluperlapine may have adenylate cyclase-coupled dopamine Dl receptors as target.     

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.     

Characterization of a dopamine-sensitive [3H]LSD binding site in honeybee (Apis mellifera) brain

[³H]Lysergic acid diethylamide ([³H]LSD) binds on membrane homogenate of honeybee brain to both a dopamine-sensitive site (D-site) and a serotonin-sensitive site (S-site). Under suitable conditions the properties of the two sites can be studied separately. Specific binding of [³H]LSD to both the D-site and the S-site has high affinity and is saturable. The mean equilibrium dissociation constants (K_D) were 3.8 nM for the D- and 0.89 nM for the S-site. The densities (B_max values) of both binding sites were 1.7 pmol/mg protein for the D-site and 0.79 pmol/mg protein for the S-site. [³H]LSD binding to the D-site was reversible and reached equilibrium in about 30 min. Pharmacological displacement studies display a high binding affinity of the putative natural agonist dopamine to the D-site (K_i = 22 nM). The most potent displacers of D-site binding were lisuride, (+)-bromocriptine, chlorpromazine, S(+)-butaclamol, and 6,7-ADTN. The [³H]LSD labelled D-site seems to be G-protein coupled, since addition of the stable GTP analogue GTPγS or NaCl to the incubation medium evoked a decrease of specific [³H]LSD binding to the D-site.     

[3H]2-amino-6,7-dihydroxy-1,2,3,4-tetrahydronaphthalen (ADTN)

The regional distribution and in vivo binding of the dopamine analog 2-amino-6,7-dihydroxy-1,2,3,4-tetrahydronaphthalen (ADTN) was studied in the brain. The highest density of binding sites was in the striatum, with virtually no binding in the cerebellum. The binding of [³H]ADTN reflects an occupation of specific dopamine sites because the binding was diminished by the simultaneous administration of the dopamine antagonist haloperidol or the dopamine precursorl-3,4-dihydroxyphenylalanine (l-dopa). Chronic administration of haloperidol orl-dopa prior to assaying for in vivo binding resulted in an increase in the number of sites for [³H]ADTN which correlates to the increase observed in in vitro assays following long-term treatment with these agents. The subcellular distribution of in vivo labeled ADTN sites in the caudate nucleus indicate a high density of specific binding sites in the microsomal fraction, P₃. Overall, these data demonstrate that the aminotetralins, such as ADTN, which bind with high affinity to the dopamine receptor in the caudate nucleus in vitro and in vivo, can provide precise information on the topography of this receptor.     

Hormone action at the membrane level VI. Binding of (—)-[3H]dihydroalprenolol and (±)-[3H]isoproterenol to turkey erythrocytes and correlation with adenylate cyclase activity

The binding of (±)-[³H]isoproterenol and (—)-[³H]dihydroalprenolol to intact turkey erythrocytes was studied using a rapid centrifugation technique. The binding of both ligands is rapid, dissociable, stereospecific and inhibited by (—)-propranolol. The total number of isoproterenol binding sites is 2800 sites/ cell. This consists of a low and high affinity site both of which show stereospecific binding. The high affinity isoproterenol site has a K_d of 15.5—19.5 nM and has 600 sites/cell. The low affinity isoproterenol site has a K_d of 195 nM and has 2200 sites/cell. The binding of (—)-[³H]dihydroalprenolol shows one type of site with a K_d of 7.8 nM and has 2500 sites/cell. The agonists epinephrine, norepinephrine, soterenol and p-hydroxyphenylisoproterenol which were tested by competition for binding showed a 6—25-fold greater affinity for the high affinity site determined by (±)-[³H]isoproterenol as compared to the (—)-[³H]dihydroalprenolol binding site. However, the antagonists propranolol, practolol and metrapolol showed similar affinities for the binding sites as determined by competition of binding of either labeled isoproterenol or dihydroalprenolol. These studies indicate that isoproterenol binding can recognize two independent stereospecific β-adrenergic receptors or can recognize two different conformational states of a single receptor. Provisional calculations are made on the turnover number of adenylate cyclase under physiological conditions using intact erythrocytes. The turnover number is 4000 molecules of cyclic AMP/10 min per high affinity receptor.     

Selective labeling of alpha-noradrenergic receptors in rat brain with [3H]dihydroergokryptine.

Using concentrations of [³H] dihydroergokryptine between 0.1 and 5 nM, saturable binding can be demonstrated in rat cerebral cortical membranes with a dissociation constant (K_D) of about 0.8 nM. α-Noradrenergic agonists and antagonists compete for the sites labeled by these low concentrations of [³H] dihydroergokryptine with relative potencies characteristics of classical α-noradrenergic receptors. The very low potency of serotonin in competing for these binding sites indicates that, in contrast to findings with higher concentrations of [³H] DHE, low concentrations do not label serotonin receptors. Moreover, the low potency of dopamine in competing for [³H] dihydroergokryptine binding in both striatal and cortical membranes indicates that no detectable portion of binding is associated with postsynaptic dopamine receptors.     

[3H]norepinephrine binding by rat glial cells in culture lack of correlation between binding and adenylate cyclase activation

Subcellular fractions prepared from rat glial cells in culture (clonal line C₆) were used in an attempt to characterize the adrenergic receptor involved in adenylate cyclase activation. Both [³H]norepinephrine binding and enzyme activation were measured under identical experimental conditions.Binding sites for norepinephrine could be detected; their main characteristics were: apparent K_m : 4 · 10⁻⁶ M, maximal capacity: 20 pmol/mg protein.Their stereospecificity towards structually related drugs was found to be different from the stereospecificity of the receptor involved in adenylate cyclase activation. Thus, 3-methoxydopamine (a competitive inhibitor of norepinephrine for adenylate cyclase activation), phenylephrine (a partial adrenergic agonist) and the blocking agent propranolol were unable to compete with [³H]norepinephrine for binding. On the other hand, several molecules like dopa bearing a catechol group and which are unable to interact with the adenylate cyclase as agonists or competitive inhibitors strongly inhibited [³H]norepinephrine binding.As in several other systems so far studied, the presence on the glial cell's membrane of a large number of “catechol-binding sites” makes it difficult to characterize the β-adrenergic receptor.     

Alterations in cerebral β-adrenergic receptor-adenylate cyclase system induced by halothane,ketamine and ethanol

The effect of halothane, ketamine and ethanol on β-adrenergic receptor adenylate cyclase system was studied in the brain of rats. An anesthetic concentration of halothane and ketamine added in vitro decreased the stimulatory effect of norepinephrine on cyclic AMP formation in slices from the cerebral cortex. On the other hand, ethanol increased the basal activity of cerebral adenylate cyclase without affecting on the norepinephrine-stimulated activity. The increase of the basal activity induced by ethanol was not antagonized by propranolol, a β-adrenergic antagonist. In the crude synaptosomal (P₂) fraction, these drugs had no significant effect on the basal adenylate cyclase activity, binding of [³H]dihydroalprenolol to β-receptor, and binding of [³H]guanylylimido diphosphate ([³H]Gpp(NH)p) to guanyl nucleotide binding site. In contrast, the adenylate cyclase activity stimulated by Gpp(NH)p or NaF was significantly inhibited by an anesthetic concentration of these drugs. An anesthetic concentration of these drugs increased the membrane fluidity of P₂ fraction monitored by the fluorescence polarization technique. The addition of linoleic acid (more than 500 μM) also induced not only the increase of fluidity, but also the decrease of Gpp(NH)p- or NaF-stimulated adenylate cyclase activity in the cerebral P₂ fraction. The present results suggest that general anesthetics may interfere with the guanyl nucleotide binding regulatory protein-mediated activation of cerebral adenylate cyclase by disturbing the lipid region of synaptic membrane.     

Dopamine inhibition of anterior pituitary adenylate cyclase is mediated through the high-affinity state of the D2 receptor

The diterpinoid forskolin stimulated adenylate cyclase activity (measured by conversion of [³H]-ATP to [³H]-cAMP) in anterior pituitary from male and female rats. Inhibition of stimulated adenylate cyclase activity by potent dopaminergic agonists was demonstrable only in female anterior pituitary. The inhibition of adenylate cyclase activity displayed a typically dopaminergic rank order of agonist potencies and could be completely reversed by a specific dopamine receptor antagonist. The IC₅₀ values of dopamine agonist inhibition of adenylate cyclase activity correlated with equal molarity with the dissociation constant of the high-affinity dopamine agonist-detected receptor binding site and with the IC₅₀ values for inhibition of prolactin secretion. These findings support the hypothesis that it is the high-affinity form of the D₂ dopamine receptor in anterior pituitary which is responsible for mediating the dopaminergic function of attenuating adenylate cyclase activity.     

Characteristics of high-affinity [3H]adenosine binding to rat brain synaptosomes and turkey erythrocyte membranes

High affinity binding sites for [³H]adenosine in rat brain and in turkey erythrocytes can be identified by binding experiments. Displacement experiments using a number of adenosine analogs indicate that these high affinity sites do not represent the R-type adenosine receptors which mediate activation of adenylate cyclase, although the binding is theophylline sensitive. Similarly, the binding of [³H]adenosine is not to the P-site, which mediates inhibition of adenylate cyclase, since the high affinity binding persists in the presence of 2′,5′-dideoxyadenosine. Furthermore, these results remain qualitatively similar also in the presence of dipyridamole which blocks adenosine transport sites. We conclude that theophylline sensitivity does not indicate that [³H]adenosine binding sites correspond to adenosine receptors coupled to adenylate cyclase.     

Reconstitution of dopamine-sensitive adenylate cyclase from dissociated components in canine caudate nucleus

The catalytic component of adenylate cyclase and [${}^3\text{H}$]dopamine binding protein were solubilized with 2% Lubrol PX in the presence of NaF from the synaptic membranes of canine caudate nucleus and were separated into distinct fractions by gel exclusion chromatography on a Sephadex G-200 column. The dissociated adenylate cyclase was no longer responsive to dopamine but was considerably stimulated by 10 mm NaF. Dissociated [${}^3\text{H}$]-dopamine binding protein possessed the apparent dissociation constant of 3.2 μm for dopamine, almost identical to that of the particulate preparations. The affinities of [${}^3\text{H}$]-dopamine binding protein to catecholamines and neuroleptics were also very similar to those of particulate preparations. After the adenylate cyclase and [${}^3\text{H}$]dopamine binding protein were preincubated together at 4 °C for 30 min, the cyclase activity displayed a dose-dependent increase by dopamine with the K_a of 1.6 μm, the concentration of dopamine to stimulate half-maximally. Stimulation of the reconstituted adenylate cyclase by dopamine was maximally 2.7-fold and was strongly inhibited by neuroleptics such as chlorpromazine and haloperidol. These results suggest that [${}^3\text{H}$]dopamine binding protein is identical to the regulatory subunit of dopamine-sensitive adenylate cyclase in the synaptic membranes of canine caudate nucleus.     

3H-SCH 23390 binding sites in the rat substantia nigra: evidence for a presynaptic localization and innervation by dopamine

Chronic treatment with SCH 23390, a selective D-1 dopamine receptor antagonist, elicited a 32% increase in the density of 3H-SCH 23390 binding sites in nigral membrane preparations but failed to change the apparent KD of the ligand for its binding sites. Haloperidol, a D-2 dopamine receptor antagonist which blocks the dopamine-sensitive adenylate cyclase and (-) sulpiride, a selective D-2 dopamine receptor blocker, which does not block the dopamine-sensitive adenylate cyclase, failed to change both the Bmax and KD of 3H-SCH 23390 binding. Finally, the intrastriatal injection of kainic acid produced a marked decrease of both GAD activity and GABA content and 3H-SCH 23390 binding sites (65%) in the homolateral substantia nigra. The results show that in the rat substantia nigra most of the 3H-SCH 23390 binding sites have a presynaptic localization on the striato-nigral GABAergic afferent terminals and suggest that dopamine released from nigral dendrites exerts a tonic influence on these presynaptic D-1 dopamine receptors.