Dopamine receptor oligomerization visualized in living cells.

G protein-coupled receptors occur as dimers within arrays of oligomers. We visualized ensembles of dopamine receptor oligomers in living cells and evaluated the contributions of receptor conformation to the dynamics of oligomer association and dissociation, using a strategy of trafficking a receptor to another cellular compartment. We incorporated a nuclear localization sequence into the D1 dopamine receptor, which translocated from the cell surface to the nucleus. Receptor inverse agonists blocked this translocation, retaining the modified receptor, D1-nuclear localization signal (NLS), at the cell surface. D1 co-translocated with D1-NLS to the nucleus, indicating formation of homooligomers. (+)-Butaclamol retained both receptors at the cell surface, and removal of the drug allowed translocation of both receptors to the nucleus. Agonist-nonbinding D1(S198A/S199A)-NLS, containing two substituted serine residues in transmembrane 5 also oligomerized with D1, and both were retained on the cell surface by (+)-butaclamol. Drug removal disrupted these oligomerized receptors so that D1 remained at the cell surface while D1(S198A/S199A)-NLS trafficked to the nucleus. Thus, receptor conformational differences permitted oligomer disruption and showed that ligand-binding pocket occupancy by the inverse agonist induced a conformational change. We demonstrated robust heterooligomerization between the D2 dopamine receptor and the D1 receptor. The heterooligomers could not be disrupted by inverse agonists targeting either one of the receptor constituents. However, D2 did not heterooligomerize with the structurally modified D1(S198A/S199A), indicating an impaired interface for their interaction. Thus, we describe a novel method showing that a homogeneous receptor conformation maintains the structural integrity of oligomers, whereas conformational heterogeneity disrupts it.

Mechanisms of inverse agonism of antipsychotic drugs at the D(2) dopamine receptor: use of a mutant D(2) dopamine receptor that adopts the activated conformation.

The antipsychotic drugs have been shown to be inverse agonists at the D(2) dopamine receptor. We have examined the mechanism of this inverse agonism by making mutations in residue T343 in the base of the sixth transmembrane spanning region of the receptor. T343R, T343S and T343K mutant D(2) dopamine receptors were made and the T343R mutant characterized in detail. The T343R mutant D(2) dopamine receptor exhibits properties of a receptor that resides more in the activated state, namely increased agonist binding affinity (independent of G-protein coupling and dependent on agonist efficacy), increased agonist potency in functional tests (adenylyl cyclase inhibition) and increased inverse agonist effects. The binding of agonists to the mutant receptor also shows sensitivity to sodium ions, unlike the native receptor, so that isomerization of the receptor to its inactive state may be driven by sodium ions. The binding of inverse agonists to the receptor is, however, unaffected by the mutation. We conclude that inverse agonism at this receptor is not achieved by the inverse agonist binding preferentially to the non-activated state of the receptor over the activated state. Rather the inverse agonist appears to bind to all forms of the receptor but then renders the receptor inactive.

Silencing of the constitutive activity of the dopamine D1B receptor. Reciprocal mutations between D1 receptor subtypes delineate residues underlying activation properties.

Recently, we have shown that the dopamine D1B/D5 receptor displays binding and coupling properties that are reminiscent of those of the constitutively activated G protein-coupled receptors when compared with the related D1A/D1 receptor subtype (Tiberi, M., and Caron, M. G. (1994) J. Biol. Chem. 269, 27925-27931). The carboxyl-terminal region of the third cytoplasmic loop of several G protein-coupled receptors has been demonstrated to be important for the regulation of the equilibrium between inactive and active receptor conformations. In this cytoplasmic region, the primary structure of dopamine D1A and D1B receptors differs by only two residues: Phe264/Arg266 are present in D1A receptor compared with Ile288/Lys290 in the D1B receptor. To investigate whether these structural differences could account for the distinct binding and coupling properties of these dopamine receptor subtypes, we swapped the variant residues located in the carboxyl-terminal region by site-directed mutagenesis. The exchange of the D1A receptor residue Phe264 by the D1B receptor counterpart isoleucine led to a D1A receptor mutant exhibiting D1B-like constitutive properties. In contrast, substitution of D1B receptor Ile288 by the D1A receptor counterpart phenylalanine resulted in a loss of constitutive activation of the D1B receptor with binding and coupling properties similar to the D1A receptor. The Arg/Lys substitution had no effect on the function of either receptor. These results demonstrate that the carboxyl-terminal region, and in particular residue Ile288, is a major determinant of the constitutive activity of the dopamine D1B receptor. Moreover, these results establish that not only can agonist-independent activity of a receptor be induced, but when given the appropriate mutation, it can be reversed or silenced.

Pharmacological characterization and autoradiographic localization of dopamine receptors in the rat adrenal medulla.

The pharmacological profile and the anatomical localization of dopamine D1-like and D2-like receptors were studied in sections of rat adrenal medulla, with radioligand binding and autoradiographic techniques, respectively. [3H]([R]-(+)-chloro-2,3,4,5-tetrahydro-5-phenyl-1 H-3benzazepin-al hemimaleate) (SCH 23390) was used as a ligand for dopamine D1-like receptors and [3H]spiperone was used as a ligand for dopamine D2-like receptors. Radioligand binding and light microscope autoradiography did not show specific [3H]SCH 23390 binding in sections of rat adrenal medulla. This suggests that rat adrenal medulla does not express dopamine D1-like receptors. [3H]Spiperone was specifically bound to sections of rat adrenal medulla. The binding was time-, temperature- and concentration-dependent, with a dissociation constant (Kd) of 1.05 nM and a maximum density of binding sites (Bmax) of 100.2 +/- 3.8 fmol/mg tissue. The pharmacological profile of [3H]spiperone binding to rat adrenal medulla was similar to that displayed by neostriatum, which is known to express dopamine D2 receptors. Light microscope autoradiography showed the accumulation of specifically bound [3H]spiperone as silver grains within sections of adrenal medulla. Silver grains were found primarily over the cellular membrane of chromaffin cells. The above data indicate that chromaffin cells of the rat adrenal medulla express dopamine receptors belonging to the dopamine D2 receptor subtype. These receptors are probably involved in the modulation of catecholamine release from chromaffin cells, as documented by functional studies.

Specific [3H]raclopride binding to neostriatal dopamine D2 receptors: role of disulfide and sulfhydryl groups.

Receptor binding studies were performed in rabbit neostriatum (caudate-putamen) using the dopamine D2 antagonist [3H]raclopride. Treatment of the membrane preparations with the reducing agent L-dithiothreitol (L-DTT) as well as with the alkylating compound N-ethylmaleimide (NEM), produced dose-dependent decreases of specific [3H]raclopride binding; the IC50 values were of 3.1 and 1.2 mM, respectively. Saturation experiments showed that the reduction of disulfide (-S-S-) bonds by L-DTT (1 mM) decreased the number of binding sites, with only a slight increase in the affinity. On the other hand, alkylation of sulfhydryl (-SH) groups by NEM (1 mM) decreased both receptor number and affinity. The properties of the remaining binding sites were examined in competition curves with the physiological substrate dopamine and the dopaminergic antagonist (+)butaclamol. The IC50 values for (+)butaclamol in control and in L-DTT and NEM treated membranes were between 3.4 and 4.8 nM, with Hill coefficients (nH) of 1, indicating that the remaining binding sites conserved a high affinity for antagonist binding. In the case of dopamine, the curves were shallow (nH 0.45-0.64) and both compounds increased the IC50 from 0.7 microM (control) to 8 microM and 11 microM, for L-DTT and NEM respectively. Iterative analysis revealed that L-DTT produced a very important (greater than 60%) decrease in the number of high-affinity (RH) binding. After NEM, there was a decrease in both the number of (RH) and the affinity (KH) of the high-affinity binding sites, and in the affinity (KL) of the low-affinity sites. These results demonstrate the participation of -S-S- and -SH groups in the agonist conformation of the primary ligand recognition site of the dopamine D2 receptor. Alternatively, -S-S- and -SH groups could be related to the coupling of the primary ligand recognition protein with adenylate cyclase by means of an inhibitory type of G protein.

Binding of [3H]SCH23390 to a non-dopaminergic site in bovine kidney.

Binding of the D1 dopamine receptor antagonist [3H]SCH23390 to bovine renal cortical membranes has been studied. Specific binding of [3H]SCH23390 was saturable and reversible and stereoisomers of SCH23390 competed stereoselectively. In contrast, competition with the isomers of butaclamol was not stereoselective and dopamine failed to compete for the [3H]SCH23390 binding site. The site is therefore not a D1 dopamine receptor. Competition studies with a very wide range of compounds failed to define the nature of the [3H]SCH23390 binding sites in renal cortex whereas in parallel studies the characteristics of [3H]SCH23390 binding in caudate nucleus were entirely consistent with those of D1 dopamine receptors. The nature of [3H]SCH23390 binding in preparations of tubular and glomerular membranes was found to be virtually identical to those of crude renal cortical membranes indicating lack of compartmentation of these sites. Autoradiographic studies of [3H]SCH23390 binding in bovine kidney showed significantly higher levels of binding sites in renal cortex compared with renal medulla and this was confirmed by direct ligand binding studies.

Growth of cultured human cerebral meningiomas is inhibited by dopaminergic agents. Presence of high affinity dopamine-D1 receptors.

We have found that microM concentrations of the dopamine agonist bromocriptine significantly decrease the proliferation rate of human meningioma cells in culture (25-56% inhibition). This effect was also seen with direct application of dopamine, as well as the dopamine-D1 agonist (+)-SKF-38393 (both applied in microM concentrations) to meningioma cell cultures. Receptor studies with the dopamine-D1 ligand (125I)SCH-23982 (dopamine-D1 antagonist) indicated that dopamine-D1 binding sites were present in the membranes of meningioma tissue. The mean dissociation constant (Kd) was 325 ( +/- 74.5 SEM) pM and the receptor density (Bmax) was 25.4 ( +/- 1.5 SEM) fmol/mg pellet protein in 5 human meningiomas. The pharmacological specificity was proven by (+)-SKF-38393, ( +/-SKF-83566 or (+)-butaclamol and their inactive isomers (-)-SKF-38393 and (-)-butaclamol in a 1000 fold excess. These results provide evidence that human meningiomas possess high affinity dopamine-D1 receptors and that dopamine agonists have an antiproliferative effect on these tumors in culture. We conclude that the proliferation of cerebral meningiomas may be under dopaminergic control and that dopamine agonists may have a role in the medical treatment of patients with meningiomas.

Direct visualization and cellular localization of D1 and D2 dopamine receptors in rat forebrain by use of fluorescent ligands.

The regional and cellular localization of the two subtypes of dopamine receptors, D1 and D2, have been ascertained in rat forebrain by use of fluorescent dopaminergic antagonist ligands. (R,S)-5-(4'-aminophenyl)-8-chloro-2,3,4,5-tetrahydro-3- methyl-[1H]-3-benzazepin-7-ol, the 4'-amino derivative of the high-affinity D1-specific antagonist SCH 23390, and the D2 selective antagonist N-(p-aminophenethyl)spiperone were chemically derivatized using the fluorescent compound tetramethylrhodamine. The modification of these antagonist ligands has allowed the specific, cellular resolution of the D1 and D2 receptor binding sites in intact, highly organized regions of forebrain slices in a very rapid experimental time frame. The regional localization of receptors labeled by the fluorescent probes is in agreement with previous receptor autoradiography studies. Moreover, the specific cellular binding patterns for both receptors can now be compared and contrasted to one another in the same tissue by using these fluorescent ligands. D1 receptor sites are most evident within the striatum and exhibit regions of intense "patch" fluorescence corresponding to receptor reactivity in cells and their processes. The distribution of D1 receptor binding is highly analogous to the pattern of dopamine terminal histofluorescence in the caudate nucleus. D2 receptor sites are less prevalent overall and may be localized to a subpopulation of the D1 fluorescent neurons in the caudate nucleus and nucleus accumbens regions.

Characterization of binding sites for 3H-spiroperidol in human retina.

Binding sites for the D-2-selective antagonist (3H)-spiroperidol were characterized in human retina. Nonspecific binding, measured in the presence of 2 microM (+)-butaclamol, made up 20% of total binding. Scatchard analysis of the binding of (3H)-spiroperidol resulted in linear plots and yielded a Kd value of 87 pM and a Bmax value of 1500 fmol/mg protein. In studies of the inhibition of the binding of (3H)-spiroperidol, (+)-butaclamol was approximately 1000-fold more potent than the (-)-stereoisomer. The inhibition curve for dopamine was shifted to the right and the Hill coefficient was increased by the addition of 300 microM GTP. This effect was agonist-specific and suggests that some of the receptors are coupled to stimulation or inhibition of the enzyme adenylate cyclase. The inhibition curves for most of the antagonists had Hill coefficients between 0.6 and 0.8. Hill coefficients were also consistently less than 1.0 for agonists even in the presence of GTP. Nonlinear regression analysis of untransformed data revealed that these shallow inhibition curves were best explained by the presence of two populations of binding sites, 40% of the sites having a high affinity for dopamine in the presence of GTP and domperidone and the remaining 60% having a lower affinity for these ligands. The larger population of sites had a higher affinity for sulpiride, fluphenazine, and N-propylnorapomorphine in the presence of GTP. The possibility that either of these classes of sites consisted of serotonin receptors was ruled out by the finding that the 5-HT2 antagonist ketanserin had a low affinity for both classes of sites.

Thermodynamic analysis of antagonist and agonist interactions with dopamine receptors.

The binding of [3H]spiperone to dopamine D-2 receptors and its inhibition by antagonists and agonists were examined in microsomes derived from the sheep caudate nucleus, at temperatures between 37 and 1 degree C, and the thermodynamic parameters of the binding were evaluated. The affinity of the receptor for the antagonists, spiperone and (+)-butaclamol, decreased as the incubation temperature decreased; the affinity for haloperidol did not further decrease at temperatures below 15 degrees C. The binding of the antagonists was associated with very large increases in entropy, as expected for hydrophobic interactions. The enthalpy and entropy changes associated with haloperidol binding were dependent on temperature, in contrast to those associated with spiperone and (+)-butaclamol. The magnitude of the entropy increase associated with the specific binding of the antagonists did not correlate with the degree of lipophilicity of these drugs. The data suggest that, in addition to hydrophobic forces, other forces are also involved in the antagonist-dopamine receptor interactions, and that a conformational change of the receptor could occur when the antagonist binds. Agonist binding data are consistent with a two-state model of the receptor, a high-affinity state (RH) and a low-affinity state (RL). The affinity of dopamine binding to the RH decreased with decreasing temperatures below 20 degrees C, whereas the affinity for the RL increased at low temperatures. In contrast, the affinity of apomorphine for both states of receptor decreased as the temperature decreased from 30 to 8 degrees C. A clear distinction between the energetics of high-affinity and low-affinity agonist binding was observed. The formation of the high-affinity complex was associated with larger increases in enthalpy and entropy than the interaction with the low-affinity state was. The results suggest that the interaction of the receptor with the G-proteins, induced or stabilized by the binding of agonist, leads to an increase in entropy and to negative heat capacity changes in the system.

In vitro characterisation of dopamine receptors in the superior colliculus of the rat.

In membrane preparations of superior colliculus of the rat, the binding of [3H]spiperone (0.15 nM) was displaced by the incorporation of (+)-butaclamol, haloperidol, apomorphine and (+/-)-sulpiride, but not by (-)-butaclamol, prazosin, propranolol, ketanserin or cinanserin. The Ki values for the displacement of [3H]spiperone by (+/-)-sulpiride, (+)-butaclamol and haloperidol were similar in tissue preparations from superior colliculus and striatum. Equilibrium analysis of the specific binding of [3H]spiperone (0.03-1.0 nM), defined by 10(-5) M (+/-)-sulpiride, to membrane preparations of the superior colliculus, showed the interaction to be saturable and of high affinity. However, the Bmax was only approximately 10% of that found in preparations of striatum; the apparent dissociation constant (KD) was the same in both preparations of the superior colliculus and striatum. Uptake of [3H]dopamine into synaptosomal preparations of the superior colliculus was approximately 20% of that found in synaptosomes from the striatum. In preparations of striatum nomifensine, but not desipramine or fluoxetine, inhibited the uptake of [3H]dopamine. However, in preparations from the superior colliculus, nomifensine, desipramine and fluoxetine were without effect on the uptake of [3H]dopamine. Dopamine, 3,4-dihydroxyphenylacetic acid (DOPAC) and 3-methoxytyramine (3-MT) were present in small concentrations in the superior colliculus. Homovanillic acid (HVA) was present in larger concentrations and the HVA plus DOPAC/dopamine ratios were greater in the superior colliculus than in the striatum. The superior colliculus contained only small amounts of noradrenaline but 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) were present in larger amounts.(ABSTRACT TRUNCATED AT 250 WORDS)

Cyclo (Leu-Gly) attenuates the striatal dopaminergic supersensitivity induced by chronic morphine.

Cyclo(Leu-Gly) (CLG), a diketopiperazine analog of Pro-Leu-Gly-NH2 (MIF), has direct effects on dopamine (DA) mediated behaviors as well as on D-2 DA receptors. Endogenous opioids, as well as morphine have also been implicated as neuromodulators of dopaminergic function. We studied these interactions in an animal model in which chronic morphine administration induces a dopaminergic supersensitivity that can be detected during the 48 hour (h) period following withdrawal of morphine. At 24 h following morphine withdrawal, there was a 3.5-fold increase in stereotypic behavior in rats following a challenge dose of apomorphine (APO) (0.5 mg/kg). By 48 h this effect had disappeared. Co-administration of CLG (8 mg/kg s.c.) with morphine attenuated the development of the behavioral supersensitivity to APO. D-2 DA receptor binding analysis indicated that parallel molecular changes occurred. There was a morphine-induced increase in the affinity (+167 percent) in antagonist (i.e. 3H-spiroperidol displaced by butaclamol) binding at 24 h after withdrawal. Co-administration of CLG with morphine attenuated these DA receptor changes at 24 hours which is consistent with the peptide's effect on stereotyped behavior. However, antagonist binding parameters did not parallel changes in behavior at 48 h. Agonist binding was then studied by examining DA displaceable 3H-spiroperidol (75 pM) binding to the D-2 DA receptor. Two receptor subpopulations D-2-HI and D-2-LO were revealed. Morphine caused an increase in the affinity for agonist binding to the D-2-HI site (83-fold increase). Affinity changes at the D-2-HI site correlated positively and strongly with the behavioral changes in all groups at both 24 and 48 h. We conclude that changes in agonist binding to D-2 DA receptors rather than antagonist binding is more consistent with the behaviors induced by morphine and CLG.

125I-LSD autoradiography confirms the preferential localization of caudate-putamen S2 receptors to the caudal (peripallidal) region.

The in vitro binding of 125I-lysergic acid diethylamide (LSD) to horizontal sections of rat brain was quantified with computer-assisted autoradiography. Specific binding of 125I-LSD to D2 and S2 sites, defined with 5 microM (+)-butaclamol, was 65-94% of the total binding. Identification of S2 sites with 50 nM ketanserin showed that over 90% of the butaclamol-displaced 125I-LSD binding in the frontal, cingulate and parietal neocortex was to S2 sites (22-55 fmol/mg protein). 125I-LSD also labeled a dense population of S2 sites (16 fmol/mg protein) in the caudal caudate-putamen at the level of the globus pallidus which exceeded by 5-fold the concentration of S2 sites (3 fmol/mg protein) in more rostral portions of the caudate-putamen. The peripallidal distribution of S2 sites was identical to that observed previously with the less selective S2 label, [3H]spiperone. The dense concentration of S2 sites in the caudal caudate-putamen and their overlap with D2 binding sites indicates that the peripallidal neostriatum may play an important role in interactions between dopamine and serotonin.

Dopaminergic activity of four analogs of butaclamol.

The displacing potency of four analogs of the neuroleptic drug butaclamol were evaluated using dog striatal tissue and [3H]-Spiroperidol as ligand. Although significantly less powerful than the parent compound, two of them (N-isobutyl butaclamol equatorial; N-methyl butaclamol equatorial) could be used for dopaminergic receptor studies.

A comparison between dopamine-stimulated adenylate cyclase and 3H-SCH 23390 binding in rat striatum.

Methods for measuring 3H-SCH 23390 binding and dopamine (DA) stimulated adenylate cyclase (AC) were established in identical tissue preparations and under similar experimental conditions. Pharmacological characterization revealed that both assays involved interaction with the D1 receptor or closely associated sites. In order to investigate whether the binding sites for 3H-SCH 23390 and DA in fact are identical, the antagonistic effects of a variety of pharmacologically active compounds were examined. Surprisingly, the Ki-values obtained from Schild-plot analysis of the antagonism of DA-stimulated AC, were 80-240 times higher than the Ki-values obtained from competition curves of 3H-SCH 23390 binding. Since both assays were performed under identical conditions, the differences in Ki-values indicate the possibility of different binding sites for DA and 3H-SCH 23390 or, that DA and 3H-SCH 23390 label different states of the same receptor.

D2 dopamine receptors in calf globus pallidus: agonist high- and low-affinity sites not regulated by guanine nucleotide.

By use of the radioligand [3H]spiroperidol, D2 3,4-dihydroxyphenylethylamine (dopamine) receptor binding characteristics were studied in calf globus pallidus and compared with those of neostriatum. Antagonist competition curves were monophasic and revealed similar affinities for neostriatum and globus pallidus, suggesting a uniform receptor population with one affinity state for antagonists. In both regions, competition curves with the agonist dopamine were biphasic, distinguishing a high- and low-agonist-affinity state. In neostriatum and globus pallidus, respectively, 45% and 19% of [3H]spiroperidol binding was displaced with high affinity and the remainder with low affinity. In neostriatum, the addition of 0.4 mM GTP resulted in a partial conversion from high- to low-affinity state with a remaining high-affinity component of 15%. In globus pallidus, dopamine binding was not altered by GTP. The capability of GTP to modulate agonist binding to D2 receptors appears to be dependent on their neuroanatomical localization.

Brain dopamine and serotonin receptor sites revealed by digital subtraction autoradiography.

Autoradiography combined with image analysis permitted quantitative visualization of dopamine (D2) and serotonin (S2) binding sites in rat brain. Forebrain sections were incubated with tritiated spiroperidol alone or with tritiated spiroperidol plus unlabeled compounds that saturated the D2 or S2 sites. By subtracting the digitized image of an autoradiograph derived from the latter sections from that of the former, the D2 or S2 sites were specifically revealed. The resulting quantitative images demonstrate the differing anatomical distributions of these sites. The D2 site is largely restricted to the striatal complex (caudate-putamen, nucleus accumbens septi, and olfactory tubercle), whereas the S2 site is enriched in layer 5 of motor cortex, the perirhinal and cingulate cortices, and the claustrum.

Binding of 3H-spiperone to human lymphocytes: a biological marker in schizophrenia?

The specific binding of the dopamine antagonist 3H-spiperone to lymphocytes from a healthy control group (n = 40), a group of acute, unmedicated schizophrenic patients (n = 27), and a psychiatric control group (n = 16) was investigated. There were no differences in binding parameters between the healthy controls (Bmax 2.6 +/- 0.7 fmoles/10(6) cells; Kd 0.17 +/- 0.07 nM) and the psychiatric control group. Binding capacity of 3H-spiperone was significantly increased in lymphocytes from the schizophrenic patients (Bmax 14.4 +/- 9.3 fmoles/10(6) cells). Moreover, a slight decrease in affinity was observed (Kd 0.44 +/- 0.21 nM). Because the increase in binding appeared only in schizophrenic patients, this peripheral model could prove valuable as a diagnostic criterion.

Dopamine D2 receptors in the anterior pituitary: a single population without reciprocal antagonist/agonist states.

Although dopamine agonists can recognize two states of the D2 dopamine receptor in the anterior pituitary (D2high and D2low), we examined whether the dopamine antagonists such as [3H]spiperone could recognize these two sites with different affinities. Using up to 30 concentrations of [3H]spiperone, however, we could only detect a single population of binding sites (porcine anterior pituitary homogenates) with a dissociation constant (KD) of 130 pM. When specific [3H]spiperone binding was defined by a low concentration of (+)-butaclamol (100 nM), the apparent density was low. When defined by a high concentration of (+)-butaclamol (10 microM), nonspecific sites became detectable, thus revealing two apparent populations of sites for [3H]spiperone, only one of which was specific for dopamine. Sodium chloride reduced the KD of the single population of specific D2 sites to 64 pM. Guanine nucleotide by itself had no effect on the KD, but enhanced the density by 25%. Since the density-enhancement could be eliminated by extensive washing of membranes, and could be restored by preincubation with dopamine, the nucleotide-induced elevation of D2 density appeared to be a result of the release of tightly bound endogenous dopamine. Thus, monovalent cations and guanine nucleotides appear to have separate regulatory effects on the anterior pituitary D2 receptor that modulate antagonist-receptor interactions. Several maneuvers were used to test whether [3H]spiperone could differentiate between the two agonist-detected subpopulations of sites. Twentyfold different concentrations of [3H]spiperone (47 pM and 1000 pM) were found to label identical proportions of receptors in the D2high and D2low states as detected by the agonist 6,7-dihydroxyaminotetralin (ADTN), suggesting that spiperone labelled equal proportions of D2high and D2low sites without differential affinity for them. In addition, competition of spiperone for D2high sites selectively labelled by the agonist [3H]n-propylnorapomorphine (NPA) had a virtually identical KD for spiperone as did the total D2 receptor population as determined by direct binding studies (75 pM versus 64 pM). [3H]Spiperone also bound to a uniform population of D2low sites induced by preincubation with guanine nucleotide with identical affinity as to the total D2 population. Thus, these data do not support a "reciprocal model" for the D2 receptor (i.e., antagonist having low affinity for D2high and high affinity for D2low in a manner reciprocal to agonists).(ABSTRACT TRUNCATED AT 400 WORDS)

Drug potencies on partially purified brain D2 dopamine receptors.

To examine the sensitivities of partially purified dopamine receptors to various dopaminergic agonists and antagonists, canine brain striatum dopamine receptors were enriched by isoelectric focusing. The digitonin-solubilized receptors were prelabelled with [3H]spiperone and focused for two time periods. After 5 h (incomplete focusing), radioactive peaks were detected at pH 6 and 9-11. Only the pH 6 peak revealed drug sensitivities expected of D2 receptors. Receptor recovery of the pH 6 peak was 79% with purification being sevenfold. After focusing overnight to equilibrium, the pH 6 peak further separated into peaks at pH 4.6 and 6.8. The receptor was identified only in the pH 4.6 fraction. The recovery of receptors in the pH 4.6 peak was low (10%), indicating little enrichment of the receptor. The rank order of binding of neuroleptics and dopamine agonists to the purified material was similar to that of the original preparation of soluble receptors. Dopamine did not bind to the purified pH 4.6 fraction unless the phosphate buffer (used during focusing) was replaced with Tris buffer. The absence of receptors in the pH 6.8 and pH 10 fractions, although both contained prelabeled [3H]spiperone, indicates the importance of testing agonists and antagonists on each fraction at each step in purification.