G Protein Activation by Human Dopamine D3 Receptors in High-Expressing Chinese Hamster Ovary Cells: A Guanosine-5'-O-(3-[35S]thio)-Triphosphate Binding and Antibody Study

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Vol. 55, Issue 3, 564-574, March 1999

G Protein Activation by Human Dopamine D₃ Receptors in High-Expressing Chinese Hamster Ovary Cells: A Guanosine-5'-O-(3-[³⁵S]thio)-Triphosphate Binding and Antibody Study

Adrian Newman-Tancredi,¹ Didier Cussac,¹ Valérie Audinot, Valérie Pasteau, Samantha Gavaudan, and Mark J. Millan

Department of Psychopharmacology, Institut de Recherches Servier, Croissy-sur-Seine (Paris), France

	Summary

Top Summary Introduction Materials and Methods Results Discussion References

Despite extensive study, the G protein coupling of dopamine D₃ receptors is poorly understood. In this study, we used guanosine-5'-O-(3-[³⁵S]thio)-triphosphate ([³⁵S]-GTP $gamma$ S) binding to investigate the activation of G proteinscoupled to human (h) D₃ receptors stably expressed in Chinesehamster ovary (CHO) cells. Although the receptor expression levelwas high (15 pmol/mg), dopamine only stimulated G protein activationby 1.6-fold. This was despite the presence of marked receptorreserve for dopamine, as revealed by Furchgott analysis afterirreversible hD₃ receptor inactivation with the alkylating agent,EEDQ (N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline). Thus, half-maximalstimulation of [³⁵S]-GTP $gamma$ S binding required only 11.8% receptor occupation of hD₃sites. In contrast, although the hD_2(short) receptor expressionlevel in another CHO cell line was 11-fold lower, stimulationby dopamine was higher (2.5-fold). G protein activation was increasedat hD₃ and, less potently, at hD₂ receptors by the preferentialD₃ agonists, PD 128,907 [(+)-(4aR,10bR)-3,4,4a,10b-tetrahydro-4-propyl-2H,5H-[1]benzopyrano[4,3-b]-1,4-oxazin-9-ol] and (+)-7-OH-DPAT (7-hydroxy-2-(di-n-propylamino)tetralin).Furthermore, the selective D₃ antagonists, S 14297 ((+)-[7-(N,N-dipropylamino)-5,6,7,8-tetrahydro-naphtho(2,3b)dihydro-2,3-furane])and GR 218,231 (2(R,S)-(dipropylamino)-6-(4-methoxyphenylsulfonylmethyl)-1,2,3,4-tetrahydronaphtalene), blocked dopamine-stimulated [³⁵S]GTP $gamma$ S binding more potently at hD₃ than at hD₂ sites. Antibodiesagainst G $alpha$ _i/ $alpha$ _o reduced dopamine-induced G protein activation atboth CHO-hD₃ and -hD₂ membranes, whereas G $alpha$ _S antibodies had noeffect at either site. In contrast, incubation with anti-G $alpha$ _q/ $alpha$ ₁₁antibodies, which did not affect dopamine-induced G protein activationat hD₂ receptors, attenuated hD₃-induced G protein activation.These data suggest that hD₃ receptors may couple to G $alpha$ _q/ $alpha$ ₁₁ andwould be consistent with the observation that pertussis toxinpretreatment, which inactivates only G_i/o proteins, only submaximally(80%) blocked dopamine-stimulated [³⁵S]GTP $gamma$ S binding in CHO-hD₃ cells. Taken together, the presentdata indicate that 1) hD₃ receptors functionally couple to G proteinactivation in CHO cells, 2) hD₃ receptors activate G proteinsless effectively than hD₂ receptors, and 3) hD₃ receptors maycouple to different G protein subtypes than hD₂ receptors, includingnonpertussis sensitive G_q/11proteins.

	Introduction

Top Summary Introduction Materials and Methods Results Discussion References

Dopaminergic neurotransmission is mediated by five receptor subtypes (D₁ to D₅) which can be grouped into two receptor families.D₁-like receptors include the D₁ and D₅ subtypes, whereas D₂-likereceptors include the D₂, D₃, and D₄ subtypes. D₂ and D₃ receptors,in particular, display marked sequence homology and pharmacologicalsimilarity in their in vitro ligand binding profiles (Levant,1997; Missale et al., 1998). However, D₃ receptors may be distinguishedfrom D₂ receptors by several factors. D₃ receptors are concentratedin limbic rather than striatal brain regions (Liu et al., 1996;Hall et al., 1996). Furthermore, they mediate stimulation, ratherthan inhibition, of c-fos expression in striatal neurones (Pilonet al., 1994; Morris et al., 1997), and inhibition, rather thanstimulation, of locomotor activity in rats (Svensson et al., 1994;Starr and Starr, 1995). In addition, whereas D₂ receptors coupleefficiently to second-messenger systems, markedly inhibiting adenylylcyclase activity, such responses have proved elusive and complexfor D₃ receptors (e.g., Freedman et al., 1994; MacKenzie et al.,1994; Tang et al., 1994; Griffon et al., 1997). Indeed, D₃ receptorscouple selectively to inhibition of adenylyl cyclase type V, butnot type I or VI, and only weakly to type II (Robinson and Caron,1997; Watts and Neve, 1997). In vitro studies of agonist efficacyhave employed other measures of receptor activation, includingmedium acification (Cox et al., 1995), and stimulation of mitogenesis(Pilon et al., 1994; Svensson et al., 1994; Sautel et al., 1995).However, these approaches measure responses "downstream" of thereceptor in the intracellular activation cascade and the relevanceof an increase in mitogenesis for postmitotic central nervoussystem neurones is unclear. A more promising approach may be tomeasure receptor-mediated G protein activation by stimulationof guanosine-5'-O-(3-[³⁵S]thio)-triphosphate ([³⁵S]GTP $gamma$ S) binding: this corresponds to the first step of the intracellularactivation cascade and directly reflects ligand binding eventsat the receptor itself (Pregenzer et al., 1997; Malmberg et al.,1998). Thus, the present study adopted this strategy to addressseveral questions concerning, principally, the functional propertiesof human (h) D₃ receptors. In addition, in some tests resultsat hD₃ receptors were compared with those at hD₂ receptors. First,differences in the second-messenger actions of D₃ and D₂ receptorsmay be related to differing capacities for stimulation of G proteins.We addressed this issue by investigating the ability of hD₃ receptorsto mediate dopamine-stimulated [³⁵S]GTP $gamma$ S binding. Second, the relationship between binding affinityand functional potency of dopaminergic agonists and antagonistswas investigated using the most potent and selective D₃ receptorligands reported to date: the agonists (+)-7-OH-DPAT (7-hydroxy-2-(di-n-propylamino)tetralin)and PD 128,907 [(+)-(4aR,10bR)-3,4,4a,10b-tetrahydro-4-propyl-2H,5H-[1]benzopyrano[4,3-b]-1,4-oxazin-9-ol] (Pugsley et al., 1995)and the antagonists, S 14297 ((+)-[7-(N, N-dipropylamino)-5,6,7,8-tetrahydro-naphtho(2,3b)dihydro-2,3-furane])and GR 218,231 (2(R,S)-(dipropylamino)-6-(4-methoxyphenylsulfonylmethyl)-1,2,3,4-tetrahydronaphtalene)(Millan et al., 1995b; Murray et al., 1996). The hD₃/hD₂ selectivitiesbased on K_i ratios were compared with those based on EC₅₀ andK_B ratios (Burris et al., 1995; Levant, 1997). Third, the signaltransduction differences between D₃ and D₂ receptors, such asthe differential coupling to adenylyl cyclase isoforms, couldbe due to receptor interactions with different G protein populations.Indeed, at least 16 distinct G protein $alpha$ subunits have been identified,divided into four families: G_i, G_S, G_q/11, and G_12/13 (Simon etal., 1991). Although a previous study suggested differences incoupling profiles of D₂ and D₃ receptors for modulation of outwardK⁺ currents (Liu et al., 1996), no information is available froma functional test more proximal to the receptor and the G proteinsubtypes involved in D₃ coupling are unclear (cf. Tang et al.,1994). The present study, therefore, examined G protein couplingspecificity directly at the G protein activation level by challengingthe receptor-mediated stimulation of [³⁵S]GTP $gamma$ S binding with specific antisera raised against differentG $alpha$ subunits. In fact, antibodies raised against the COOH terminalpart of G $alpha$ subunits have proved useful to determine the G proteinspecificity of several other 7-transmembrane domain receptors(Harris-Warrick et al., 1988; McFadzean et al., 1989; Lledo etal., 1992; Izenwasser and Côté, 1995).

	Materials and Methods

Top Summary Introduction Materials and Methods Results Discussion References

Membrane Preparations of Chinese Hamster Ovary (CHO)-hD₃ and CHO-hD₂ Cells. CHO cells expressing hD₃ receptors were grown as described previously (Sokoloff et al., 1992). Cells were harvested from adherentculture and homogenized using a Kinematica Polytron (KinematicaGmBH, Littau, Switzerland) in a buffer containing 50 mM Tris (pH7.4), 5 mM MgCl₂. The suspension was then centrifuged at 20,000gfor 15 min at 4°C and the pellet was resuspended in the appropriatebinding buffer (see below) and stored at $-$ 80°C. CHO-hD_2(short)cell membranes were purchased from Receptor Biology (Baltimore,MD). The "short" hD₂ isoform, which lacks a 29-amino acid insertin the putative third intracellular loop, is processed fasterto mature receptors at the cell surface than the "long" form andmay couple more efficiently to certain G protein subtypes (Fishburnet al., 1995; Boundy et al., 1996).

[¹²⁵I]Iodosulpride Binding to hD₃ and hD₂ Receptors. Saturation binding at hD₂ and hD₃ receptors was carried out with 12 concentrations of [¹²⁵I]iodosulpride (1000 Ci/mmol; Amersham, Les Ulis, France). Forcompetition binding experiments, membranes (10 to 20 µg protein)of CHO-hD₂ or CHO-hD₃ cells were incubated with [¹²⁵I]iodosulpride (0.1 nM for hD₂ and 0.2 nM for hD₃) at 30°C for30 min in a buffer containing 50 mM Tris (pH 7.4), 120 mM NaCl,5 mM KCl, 1 mM EDTA, and 5 mM MgCl₂. Nonspecific binding was definedwith raclopride (10 µM). Isotherms were analyzed by nonlinearregression, using the computer program PRISM (Graphpad SoftwareInc., San Diego, CA) to yield IC₅₀ values. Inhibition constants(K_i values) were derived from IC₅₀ values according to the Cheng-Prusoffequation. The goodness of fit was tested by runs test. For compoundsthat yielded P < .05 in the runs test and/or shallow inhibitionisotherms (nH values markedly inferior to unity), 14-point competitionbinding experiments were carried out and one- and two-site fitswere compared by Ftest.

Measurement of Agonist Efficacy and Antagonist Potency at hD₃ and hD₂ Receptors. Receptor-linked G protein activation by dopamine at hD₂ and hD₃ receptors was determined by measuring the stimulation of [³⁵S]GTP $gamma$ S (1332 Ci/mmol; NEN, Les Ulis, France) binding inducedby dopamine. CHO-hD₂ membranes (30-40 µg protein) were incubated(60 min, 22°C) with agonists and/or antagonists in a buffer containing20 mM HEPES (pH 7.4), 3 µM GDP, 10 mM MgCl₂, 150 mM NaCl, and0.1 nM [³⁵S]GTP $gamma$ S. CHO-hD₃ membranes (30-50 µg protein) were incubated (40min, 22°C) with agonists and/or antagonists in a buffer containing20 mM HEPES (pH 7.4), 3 µM GDP, 3 mM MgCl₂, 100 mM NaCl, and 1.0nM [³⁵S]GTP $gamma$ S. Nonspecific binding was defined with GTP $gamma$ S (10 µM). Agonistefficacy is expressed relative to that of dopamine (100%), whichwas tested at a maximally effective concentration (10 µM) in eachexperiment. For all tests, membranes were preincubated with agonistand/or antagonist for 15 min before the addition of [³⁵S]GTP $gamma$ S. K_B values for inhibition of dopamine (1 and 3 µM forhD₃ and hD₂ respectively)-stimulated [³⁵S]GTP $gamma$ S binding were calculated according to Lazareno and Birdsall(1993):

K_B = IC₅₀/{[(2+(agonist/EC₅₀)^nH)^nH¹] $-$ 1};

where IC₅₀ is the inhibitory concentration₅₀ of the antagonist, agonist is the dopamine concentration, EC₅₀ is the effectiveconcentration₅₀ of dopamine alone, and nH is the Hill coefficientof the dopamine stimulationisotherm.

For dopamine concentration-response curves determined in the presence of fixed concentrations of the antagonist, GR 218,231,pA₂ values were derived by Schild analysis. In isotopic dilutionexperiments, the basal and dopamine (10 µM)-stimulated bindingof radiolabeled [³⁵S]GTP $gamma$ S was inhibited with unlabeled GTP $gamma$ S. Saturation bindingcurves were derived to estimate the number of G proteins activatedby dopamine, as described previously (Newman-Tancredi et al.,1997

Experiments were terminated by rapid filtration through Whatman GF/B filters (pretreated with 0.1% polyethyleneimine in thecase of [¹²⁵I]iodosulpride binding) using a Brandel cell harvester. Radioactivityretained on the filters was determined by liquid scintillationcounting. All data are expressed as mean ± S.E.M. of $>=$ 3 independentdeterminations. Protein concentration was determined colorimetricallyusing a bicinchonic acid assay kit (Sigma Chemical Co., S. QuentinFallavier,France).

hD₃ Receptor Alkylation with N-Ethoxycarbonyl-2-Ethoxy-1,2-Dihydroquinoline (EEDQ). CHO-hD₃ cell membranes were treated by EEDQ at a final concentration between 0 and 300 µM (0, 10, 33, 100, and 300 µM). Themembrane suspension (3 ml final volume) was vortexed and immediatelycentrifuged at 4°C for 15 min at 20,000g. The supernatant wasdiscarded and the membrane pellet was resuspended in the appropriatebuffer and [³⁵S]GTP $gamma$ S or [¹²⁵I]iodosulpride binding was performed as described above. K_A valueswere determined by Furchgott analysis, as described by Atkinsonand Minneman (1992) and Adham et al. (1993), with CHO-hD₃ membranestreated with 33 µM EEDQ. Plots were derived of 1/[A] versus 1/[A'];where [A] and [A'] are equiactive concentrations for stimulationof [³⁵S]GTP $gamma$ S binding before and after receptor alkylation, respectively.K_A was calculated from

K_A = (slope-1)/y-intercept.

Percentage receptor occupancy (O) was calculated by

O = 100 * L/(L + K_A);

where L is the concentration ofagonist.

Characterization of G proteins by Immunoblotting and ADP-Ribosylation. Immunoblotting of G $alpha$ subunits was performed using antisera purchased from Santa Cruz Biotechnology Inc. (Santa Cruz, CA) raisedagainst G $alpha$ _i/O (C10), G $alpha$ _S (C18), and G $alpha$ _q/11 (C19). Approximately2 µg protein from CHO-hD₂ and CHO-hD₃ membrane preparation wasseparated on 10% polyacrylamide gel and transferred onto nitrocellulose.Antisera were incubated at 1/1000 followed by enhanced chemiluminescencedetection with horseradish peroxidase as secondary antibody (Amersham,Buckinghamshire,UK).

ADP-ribosylation by Bordetella pertussis toxin (PTX) was carried out as described by Cussac et al. (1996)

. Briefly, membranes(10 µg) from untreated CHO-hD₃ cells and cells preincubated withPTX (100 ng/ml) or cholera toxin (1 µg/ml) for 6 h were incubatedfor 60 min in buffer containing 8 µM [³²P]NAD (2 µCi), 70 mM Tris/HCl, pH 8.0, 1 mM ATP, 0.1 mM GTP, 1mM EDTA, 25 mM dithiothreitol, 10 mM nicotinamide, 0.1 mM MgCl₂,and 100 ng of PTX in a 40-µl assay volume. PTX was preactivatedwith 25 mM dithiothreitol for 30 min at 37°C. The reaction wasstopped by addition of 40 µl of Laemmi buffer 2× and the samplewas boiled 3 min at 95°C. Two micrograms of protein from the samplewas then separated in 10% polyacrylamide gel and [³²P]ADP-ribosylated G_i/O proteins were revealed by 8 h exposureof the dried gel to Hyperfilm(Amersham).

Antiserum Treatment of CHO-hD₃ or -hD₂ Membranes. CHO-hD₃ and -hD₂ membranes (30-50 µg protein) were preincubated at 4°C for 5 h with 3.3 µg of antisera against different G $alpha$ proteins. [³⁵S]GTP $gamma$ S binding was then performed in absence and in presenceof dopamine (10 µM) as described above. The antisera used werethe same as described above and were chosen for their capabilityto recognize the COOH terminal part of G $alpha$ subunits involved inreceptor interactions. Another antiserum (C17) against c-Jun NH₂-terminalkinase (JNK1), a target unrelated to G proteins, was also testedas a control to exclude nonspecific antibodyeffects.

Compounds. (+)7-OH-DPAT was obtained from CNRS (Paris, France). PD 128,907 was purchased from RBI (Natick, MA); dopamine, haloperidol,EEDQ, and cholera and PTXs were purchased from Sigma. GR 218,231and S 14297 were synthesized by J.-L. Peglion,Servier.

	Results

Top Summary Introduction Materials and Methods Results Discussion References

Saturation Binding Experiments. The receptor expression level of hD₃ receptors, determined in [¹²⁵I]iodosulpride saturation binding experiments, was almost 11-foldhigher than that of hD₂ receptors (Table 1 and Fig. 1).

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TABLE 1
Densities of recombinant receptors and agonist-activated G proteins in CHO cells stably expressing hD₂ and hD₃ receptors
Receptor expression levels (B_max) of hD₃ and hD₂ receptors stably expressed in CHO cell membranes were determined by saturation binding experiments with [¹²⁵I]iodosulpride. Treatment of CHO-hD₃ membranes with EEDQ (33 µM) significantly reduced hD₃ receptor expression (p < 0.05, 2-tailed t test). Number of dopamine-activated G proteins was determined by [³⁵S]GTP $gamma$ S isotopic dilution saturation binding, as described in Materials and Methods. Apparent K_D for [³⁵S]GTP $gamma$ S saturation binding is denoted K_APP. EEDQ (33 µM) treatment of CHO-hD₃ membranes did not significantly alter B_max or K_APP for [³⁵S]GTP $gamma$ S saturation.

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Fig. 1. Saturation binding of [¹²⁵I]iodosulpride and [³⁵S]GTP $gamma$ S to CHO-hD3 and CHO-hD₂ cell membranes. A, representative saturation binding isotherms of [¹²⁵I]iodosulpride to CHO-hD₂ and CHO-hD₃ membranes. B, representative saturation binding isotherms of [³⁵S]GTP $gamma$ S to CHO-hD₂ and CHO-hD₃ membranes. Basal and dopamine (10 µM)-stimulated [³⁵S]GTP $gamma$ S binding were determined in the presence of increasing concentrations of GTP $gamma$ S. These data were transformed as described in Materials and Methods to generate a saturation binding isotherm for net agonist-dependent [³⁵S]GTP $gamma$ S binding. Points shown are means of duplicate determinations from representative experiments repeated on at least four occasions. B_max and K_D/apparent K_D (K_app) data from these experiments are shown in Table 1.

The number of dopamine-activated G proteins, determined in [³⁵S]GTP $gamma$ S isotopic dilution experiments with unlabeled GTP $gamma$ S, washigher in CHO-hD₃ membranes than in CHO-hD₂ membranes (Table 1).These different expression levels of receptors (R) and G proteins(G) corresponded to a 3-fold higher R/G ratio in CHO-hD₃ membranesthan in CHO-hD₂ membranes (4.6:1.5; Table 1). Treatment of CHO-hD₃membranes with EEDQ (33 µM) reduced hD₃ receptor density by abouthalf (Tables 1 and 2). The effect of EEDQ was specific to thereceptors: EEDQ did not significantly alter the number or affinityof [³⁵S]GTP $gamma$ S for dopamine-activated G proteins (Table 1).

hD₃ Receptor Alkylation with EEDQ. CHO-hD₃ membranes were sensitive to EEDQ treatment. Addition of EEDQ to ice-cold membranes and immediate centrifugation (15min, 4°C, 20,000g) was sufficient to reduce the number of hD₃binding sites in a concentration-dependent manner without a changein affinity of the radioligand (Table 2 and Fig. 2). EEDQ alsoconcentration dependently reduced the stimulation of [³⁵S]GTP $gamma$ S binding induced by dopamine (Table 2 and Fig. 3). Atthe maximal EEDQ concentration tested (300 µM), the density ofhD₃ receptors was reduced by over 80%, whereas dopamine-induced[³⁵S]GTP $gamma$ S binding was reduced by 64%. Subsequent experiments werecarried out with an EEDQ concentration of 33 µM, which reduceddopamine-induced [³⁵S]GTP $gamma$ S binding by about 50% (Tables 1 and 2). Under these conditions,the pEC₅₀ ( $-$ log EC₅₀) of dopamine was slightly reduced to 7.87± 0.09 (compared with 8.00 for control membranes, Table 4), withoutalteration of basal [³⁵S]GTP $gamma$ S binding. The K_A value determined by Furchgott analysiswas 53 ± 23 nM, which corresponded closely to the affinity ofdopamine at hD₃ receptors determined in competition binding experiments(54.9 nM, Table 3). The resulting K_A/EC₅₀ ratio for dopaminewas 5.3, indicating the presence of receptor reserve. This wasconfirmed in occupancy/response plots, which yielded hyperboliccurves, with the mean half-maximal response to dopamine beingobserved at 11.8 ± 2.3% occupation of hD₃ binding sites (Fig.3).

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TABLE 2
Concentration-dependent actions of EEDQ on receptor density and function in CHO-hD₃ membranes
CHO-hD₃ cell membranes were treated with different concentrations of EEDQ. Receptor density was determined in [¹²⁵I]iodosulpiride saturation binding experiments. Percentage of remaining hD₃ binding sites is calculated as a percentage of mean B_max determined in absence of EEDQ (15.43 pmol/mg, Table 1). [³⁵S]GTP $gamma$ S binding is expressed as percentage of dopamine (10 µM)-dependent binding observed under control conditions in parallel experiments.

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Fig. 2. Concentration-dependent reduction of hD₃ receptor density by EEDQ. A, representative saturation binding isotherms of [¹²⁵I]iodosulpride to CHO-hD₃ membranes pretreated with different concentrations of EEDQ. B, Scatchard representation of data from A. Points shown are means of duplicate determinations from representative experiments repeated on at least three occasions. B_max and K_D data from these experiments are shown in Table 2.

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Fig. 3. hD₃ receptor inactivation with EEDQ reveals receptor reserve for dopamine-stimulated [³⁵S]GTP $gamma$ S binding to CHO-hD₃ membranes. A, concentration-dependent reduction of dopamine-stimulated [³⁵S]GTP $gamma$ S binding by pretreatment with EEDQ (0 to 300 µM). Columns represent mean ± S.E.M. from at least three experiments carried out in triplicate. B, stimulation by dopamine of [³⁵S]GTP $gamma$ S binding to control or EEDQ (33 µM)-pretreated CHO-hD₃ membranes. C, double-reciprocal plot of 1/[A] versus 1/[A'], where [A] and [A'] are equiactive concentrations for stimulation of [³⁵S]GTP $gamma$ S binding with and without EEDQ treatment, respectively. D, dopamine occupancy/response relationship, derived using the value of K_A from C. Hyperbolic isotherm indicates the presence of receptor reserve. For B, C, and D, points shown are means of triplicate determinations from a representative experiment repeated on at least three occasions. Mean K_A value was 53 ± 23 nM. Mean half-maximal response to dopamine was observed at at 11.8 ± 2.3% occupation of hD₃ binding sites.

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TABLE 3
Competition binding of dopaminergic ligands at hD₂ and hD₃ receptors
Affinities (pK_i values) at hD₃ and hD₂ receptors stably expressed in CHO cells were determined by competition binding experiments with [¹²⁵I]iodosulpride. Two-site analysis of isotherms at hD₂ receptors is shown if this was significantly superior to a one-site fit (P $<=$ 0.05, F test). Percentage of high-affinity binding sites is denoted % high. Isotherms at hD₃ receptors fitted best to a single binding site model. Results are means ± S.E. of mean of at least four independent experiments. K_i/H/L values were calculated from respective mean pK_i/H/L values. hD₂/hD₃ affinity ratio was obtained by dividing K_i/H/L value at hD₂ receptors by K_i value at hD₃: for agonist ligands ratios show a wide variation depending on whether K_i value at hD₃ is compared with K_H or K_L value at hD₂.

[¹²⁵I]Iodosulpride Competition Binding hD₂ and hD₃ At hD₃ receptors, agonist competition binding isotherms were monophasic, although in some experiments with dopamine a small(~10% of binding sites), high-affinity (pK_H, $-$ log K_H, ~9) component was apparent (data not shown). At hD₂ receptors,agonist competition isotherms were biphasic and fitted betterto a two-site model (p < .05, F test; Fig. 4), yielding estimatesof affinity for the high- and low-affinity components (Table 3),presumably reflecting binding to G protein-coupled and -uncoupledstates of the receptor, respectively. Selectivity ratios of affinityat hD₂/hD₃ receptors were calculated by comparing the K_i at hD₃receptors with the K_H and the K_L at hD₂ receptors. Competitionbinding curves with antagonist ligands, haloperidol, S 14297,and GR 218,231, were monophasic for both hD₂ and hD₃ sites (Table3).

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Fig. 4. Competition binding of dopaminergic agonists at hD₃ and hD₂ receptors. Representative [¹²⁵I]iodosulpride competition binding isotherms for dopamine, (+)-7-OH-DPAT and PD 128,907 at hD₂ and at hD₃ receptors. At hD₂ receptors the data fitted better to a two-site model (P < .05, F test). Points shown are means of triplicate determinations from representative experiments repeated on at least three occasions. pK_i, pK_H, and pK_L data from these experiments are shown in Table 3.

[³⁵S]GTP $gamma$ S Binding Conditions at CHO-hD₃ and CHO-hD₂ Cell Membranes. In preliminary experiments (not shown), conditions were defined that yielded optimal dopamine-induced stimulation of [³⁵S]GTP $gamma$ S binding. 1) Optimal stimulation was observed at NaCl concentrationsof 100 and 150 mM for hD₂ and hD₃ membranes, respectively. 2)GDP concentration dependently reduced basal binding of [³⁵S]GTP $gamma$ S to both hD₂ and hD₃ cell membranes. 3) MgCl₂ increaseddopamine-dependent [³⁵S]GTP $gamma$ S binding to a maximum at around 3 to 10 mM for both receptorsubtypes. 4) Stimulation of [³⁵S]GTP $gamma$ S binding was linear with time over the period of the incubations.In view of the lower stimulation of [³⁵S]GTP $gamma$ S binding by agonists at hD₃ receptors, a higher concentrationof [³⁵S]GTP $gamma$ S was used (1.0 nM) than with hD₂ (0.1 nM) to provide astronger signal. Typical binding of [³⁵S]GTP $gamma$ S (0.1 nM) to CHO-hD₂ membranes was 90 to 100 fmol/mg basaland 230 to 250 fmol/mg in the presence of dopamine (10 µM). Typicalbinding of [³⁵S]GTP $gamma$ S (1 nM) to CHO-hD₃ membranes was 1000 to 1100 fmol/mg basaland 1500 to 1600 fmol/mg with dopamine (10 µM). In control experimentsin which the concentration of [³⁵S]GTP $gamma$ S used for hD₃ receptors was 0.1 nM (as for hD₂ receptors),the pEC₅₀ for dopamine was 8.04 ± 0.03 (n = 3) nM, not significantlydifferent from the pEC₅₀ observed with a [³⁵S]GTP $gamma$ S concentration of 1 nM (8.00 ± 0.07, Table 4). Dopamine-inducedstimulation was 45.8 ± 2.8% (n = 3).

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TABLE 4
Stimulation of [³⁵S]GTP $gamma$ S binding by dopaminergic ligands at hD₂ and hD₃ receptors
Agonist efficacies were determined by [³⁵S]GTP $gamma$ S binding. Results are means ± S.E. of mean of at least three independent experiments. EC₅₀ values were calculated from mean pEC₅₀ values. Haloperidol and GR 218,231 did not induce any alteration of [³⁵S]GTP $gamma$ S binding to either hD₂ or hD₃ membranes. S 14297 did not alter [³⁵S]GTP $gamma$ S binding to hD₃ membranes.

[³⁵S]GTP $gamma$ S Binding at CHO-hD₃ and CHO-hD₂ Cell Membranes: Agonist Actions. Dopamine, PD 128,907, and (+)-7-OH-DPAT increased [³⁵S]GTP $gamma$ S binding to CHO-hD₃ and CHO-hD₂ membranes in a concentration-dependentmanner, with EC₅₀, E_max, and nH values shown in Table 4. S 14297exhibited slight agonist actions at hD₂ receptors (E_max = 20.6%)but no agonist activity was detected at hD₃ receptors (Fig. 5).PD 128,907 was almost twice as efficacious at hD₂ as at hD₃ receptors,whereas (+)-7-OH-DPAT was a partial agonist at both receptor subtypes.The ratios of EC₅₀ values at hD₂/hD₃ were intermediate betweenthe K_H(hD₂)/K_i(hD₃) and the K_L(hD₂)/K_i(hD₃) ratios in Table 3.In control experiments in which the concentrations of NaCl andMgCl₂ were inverted between hD₂ and hD₃, we did not observe markedchanges in EC₅₀ and E_max values of (+)-7-OH-DPAT and PD 128,907(data not shown), but a slight decrease in percentage of stimulationby agonists was noted.

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Fig. 5. Agonist stimulation of hD₃ and hD₂ receptor-mediated G protein activation. [³⁵S]GTP $gamma$ S binding is expressed as a percentage of maximal stimulation given by dopamine. A, fold stimulation of [³⁵S]GTP $gamma$ S binding by dopamine at hD₂ and hD₃ receptors. B, agonist concentration-response curves at hD₂ receptors. C, agonist concentration-response curves at hD₃ receptors ( $bullet$ dopamine; $black-diamond$ PD 128,907; $open circle$ (+)-7-OH-DPAT; and $black-triangle$ S 14297). Points shown are means of triplicate determinations from representative experiments repeated on at least three occasions. E_max, pEC₅₀, and nH data from these experiments are shown in Table 4.

[³⁵S]GTP $gamma$ S Binding at CHO-hD₃ and CHO-hD₂ Cell Membranes: Antagonist Actions. Haloperidol, GR 218,231, and S 14297 did not alter [³⁵S]GTP $gamma$ S binding from basal levels at hD₃ receptors or, except S 14297(as described above) at hD₂ receptors. The inhibition of dopamine-stimulated[³⁵S]GTP $gamma$ S binding (Table 5 and Fig. 6), yielded antagonist potencies(K_B values), which conserved the same order of potency as theK_i values shown for these compounds in Table 3. The novel ligandGR 218,231 was shown to behave as a competitive antagonist, inducinga rightward parallel shift of the dopamine stimulation curve withoutloss of maximal efficacy (Fig. 7), yielding a linear Schild plot(r = 0.96, slope = 1.06 ± 0.10) and a pA₂ value of 9.34 similarto its affinity calculated by competition binding (pK_i = 8.95,Table 3).

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TABLE 5
Antagonism of dopamine-stimulated [³⁵S]GTP $gamma$ S binding to CHO-hD₂ and -hD₃ membranes
Antagonist potencies (pK_B values) were calculated from IC₅₀ values for inhibition of dopamine (3 µM for hD₂, 1 µM for hD₃)-stimulated [³⁵S]GTP $gamma$ S binding. pK_B values are expressed as means ± S.E. of mean of at least three independent experiments. K_B values were calculated from mean pK_B values.

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Fig. 6. Antagonism of hD₃ and hD₂ receptor-mediated G protein activation. Antagonism of dopamine (3 µM)-stimulated [³⁵S]GTP $gamma$ S binding at hD₂ receptors and of dopamine (1 µM)-stimulated [³⁵S]GTP $gamma$ S binding at hD₃ receptors ( $open circle$ haloperidol, $bullet$ GR 218,231, and $black-diamond$ S 14297). Points shown are means of triplicate determinations from representative experiments repeated on at least three occasions. pIC₅₀ and pK_B data from these experiments are shown in Table 4.

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Fig. 7. Competitive antagonism of hD₃ receptor-mediated G protein activation by GR 218,231. A, concentration-response isotherms for stimulation of [³⁵S]GTP $gamma$ S binding by dopamine at hD₃ receptors in the presence of increasing concentrations of GR 218,231 ( $bullet$ 3 nM, $black-diamond$ 10 nM, $black-triangle$ 30 nM, and $black-square$ 100 nM). Points shown are means of triplicate determinations from representative experiments repeated on at least three occasions. B, Schild plot of the hD₃ dopamine concentration-response experiments. Points shown are mean values from at least three independent experiments performed in triplicate.

Effect of Pertussis and Cholera Toxins on hD₃ Receptor Coupling. Membranes were prepared from CHO-hD₃ cells treated with PTX (100 ng/ml) or cholera toxin (1 µg/ml) for 6 h. Pretreatment withPTX reduced, but did not totally suppress, dopamine-dependent[³⁵S]GTP $gamma$ S binding: it was attenuated by about 80% (81 ± 16 fmol/mgversus 430 ± 26 fmol/mg in control), without changes in basal[³⁵S]GTP $gamma$ S binding (Fig. 8). The incomplete suppression of dopamine-stimulated[³⁵S]GTP $gamma$ S binding was not due to an insufficiently long incubationof CHO-hD₃ cells with PTX. Indeed, when membranes were preparedfrom CHO-hD₃ cells after the 6-h incubation, no subsequent incorporationof [³²P]ADP-ribose was observed, indicating that all the G $alpha$ _i/o proteinspresent had already been ADP-ribosylated (Fig. 8).

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Fig. 8. Partial attenuation of dopamine-stimulated [³⁵S]GTP $gamma$ S binding by PTX, but not cholera toxin. A, [³²P]ADP-ribose incorporation catalyzed by PTX. ADP-ribosylation of CHO-hD₃ cell membranes preincubated with or without PTX or cholera toxin (CT) for 6 h was carried out as described in Materials and Methods. [³²P]ADP-ribosylated G_i/O proteins were revealed by a 8-h exposure to Hyperfilm. The data shows that PTX pretreatment abolished subsequent [³²P]ADP-ribose incorporation. The same result was obtained in a second, independent experiment. B, Effect of PTX and CT on dopamine-stimulated [³⁵S]GTP $gamma$ S binding. CHO-hD₃ cell were incubated for 6 h with PTX or CT and stimulation of [³⁵S]GTP $gamma$ S binding was determined with dopamine (10 µM). Bars represent mean ± S.E.M. values from at least three independent experiments performed in triplicate and are expressed in fentomoles per milligram of dopamine-induced [³⁵S]GTP $gamma$ S binding.

Dopamine stimulated [³⁵S]GTP $gamma$ S binding to membranes of CHO-hD₃ cells treated with cholera toxin with an pEC₅₀ of 8.04 ± 0.08(n = 4), similar to that observed in control membranes (pEC₅₀= 8.00, Table 4), but basal [³⁵S]GTP $gamma$ S binding in cholera toxin-treated cell membranes was increased(1230 ± 80 fmol/mg versus 1030 ± 36 fmol/mg for control membranes).However, the amount of dopaminedependent [³⁵S]GTP $gamma$ S binding was unchanged (407 ± 61 fmol/mg versus 430 ± 26fmol/mg in control membranes) (Fig. 8).

Effect of Antibodies on hD₃ and hD₂ Receptor Coupling. The presence of G $alpha$ _i/o, G $alpha$ _S, and G $alpha$ _q/11 in both CHO-hD₃ and CHO-hD₂ cell membranes was demonstrated by immunodetection withspecific antibodies (Fig. 9). Preincubation of hD3 and hD₂ cellmembranes with anti-G $alpha$ _i/ $alpha$ _o subunit antiserum significantly (P< .05, Student's paired t test) attenuated dopamine-dependent[³⁵S]GTP $gamma$ S binding, at both hD₃ and hD₂ receptors (Fig. 9). Anti-G $alpha$ _q/ $alpha$ ₁₁antiserum significantly attenuated dopamine-dependent [³⁵S]GTP $gamma$ S binding to CHO-hD₃ but not CHO-hD₂ membranes (P < .05,Student's paired t test). Antisera directed against G $alpha$ _S and anunrelated target, JNK1, did not affect [³⁵S]GTP $gamma$ S binding at either receptor (data not shown).

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Fig. 9. Inhibition by anti-G protein antibodies of dopamine-stimulated [³⁵S]GTP $gamma$ S binding to CHO-hD₃ and CHO-hD₂ cell membranes. A, immunodetection of G $alpha$ _i/o, G $alpha$ _S, and G $alpha$ _q/11 subunits in both CHO-hD₃ and CHO-hD₂ cell membranes was performed as described in Materials and Methods. B, CHO-hD₂ and CHO-hD₃ cell membranes were incubated for 5 h at 4°C in the presence of antibodies used in A. Stimulation of [³⁵S]GTP $gamma$ S binding was determined with dopamine (10 µM). Bars represent mean ± S.E.M. values from at least three independent experiments performed in triplicate and are expressed as percentage of dopamine-dependent [³⁵S]GTP $gamma$ S binding observed in control (untreated) samples. *P < .05; **P < .01 versus control (2-tailed, paired t test).

	Discussion

Top Summary Introduction Materials and Methods Results Discussion References

The primary purpose of the present study was to investigate the G protein coupling of dopamine hD₃ receptors. The resultsdemonstrate that hD₃ (and hD₂) receptors mediate stimulation of[³⁵S]GTP $gamma$ S binding when expressed in mammalian CHO cells, indicatingthat they are capable of activating intracellular G proteins.A robust degree of stimulation was observed (Fig. 5), enablinga detailed investigation of the coupling of these receptor subtypesand the identification of some marked differences between hD₃and hD₂sites.

First, despite the 11-fold higher hD₃ receptor expression level (15 pmol/mg), the dopamine-elicited increase in [³⁵S]GTP $gamma$ S binding (up to 1.6-fold) was less than that at hD₂ receptors.Partial inactivation of hD₃ receptors using the alkylating agentEEDQ showed that high hD₃ receptor expression levels are necessaryfor stimulation of G protein activation, because EEDQ treatmentreduced the stimulation of [³⁵S]GTP $gamma$ S binding induced by dopamine (Table 2). Nevertheless,Furchgott analysis yielded a hyperbolic occupancy/response plot(Fig. 3), indicating the presence of marked receptor reserve forhalf-maximal stimulation of [³⁵S]GTP $gamma$ S binding by dopamine and is consistent with the 5-foldK_A/EC₅₀ ratio for activation of hD₃ receptors (see Results). Thusthe limited stimulation of [³⁵S]GTP $gamma$ S binding to CHO-hD₃ membranes appears to be a propertyof hD₃ receptors themselves and not due to insufficient intrinsicefficacy of dopamine. It should be noted that the modest stimulationat hD₃ receptors is not a consequence of augmented basal [³⁵S]GTP $gamma$ S binding, because basal [³⁵S]GTP $gamma$ S binding was unaffected by receptor inactivation (not shown).Furthermore, the low-fold stimulation in CHO-hD₃ membranes isunlikely to be due to a global lack of activatable G proteins:the amount (B_max) of dopamine-activated G proteins in CHO-hD₃cell membranes is about 3-fold higher than that in CHO-hD₂ cellmembranes (Table 1 and Fig. 1). Taken together, the present datasuggest that stimulation of hD₃ receptors less effectively inducesthe conformational changes necessary for G protein activationthan at hD₂ receptors (Chio et al., 1994), perhaps due to a slowerrate of G protein coupling/uncoupling at hD₃ receptors or, alternatively,to interaction with different G protein subtypes at hD₃ versushD₂ receptors, a possibility discussedbelow.

Second, agonist efficacy varied between hD₂ and hD₃ receptors. S 14297, previously characterized as a D₃ receptor antagonistin vivo (Millan et al., 1995a,b) exhibited residual intrinsicactivity at hD₂ receptors (Table 4) but no detectable agonistactivity at hD₃ receptors. In the present high-expressing CHO-hD₃cell membranes, it might have been expected that partial agonistactions at hD₃ receptors would be "amplified" to yield maximalactivation of [³⁵S]GTP $gamma$ S binding, like dopamine. Nevertheless, both (+)-7-OH-DPATand PD 128,907 behaved as partial agonists at hD₃ receptors (Table4 and Fig. 5). It therefore appears that despite the high levelsof hD₃ receptors, the high R/G ratio in CHO-hD₃ membranes, and,as discussed above, receptor reserve for activation by dopamine,the present [³⁵S]GTP $gamma$ S binding methodology more readily differentiates partialagonist efficacies at hD₃ receptors than certain downstream modelsof hD₃ (or hD₂) receptor activation, such as mitogenesis (Sautelet al., 1995), where dopamine, (+)-7-OH-DPAT and PD 128,907 allbehaved as full agonists. Furthermore, in the present study, thedegree of selectivity of (+)-7-OH-DPAT and PD 128,907 for activationof hD₃ versus hD₂ receptors was greater than previously reported(Levant, 1997). (+)-7-OH-DPAT displayed an hD₃/hD₂ EC₅₀ ratioof 77 (Table 4) compared with 14 and 7 for inhibition of adenylylcyclase and mitogenesis experiments respectively (Chio et al.,1994; Sautel et al., 1995). PD 128,907 was 382-fold as selectivein this study compared with only 6-fold as selective in mitogenesisexperiments (Pugsley et al., 1995). The source of these differencesis unclear but probably relates to the fact that mitogenesis andextracellular acidification measure responses that are distalto agonist-induced receptor/G protein conformational changes.In contrast, [³⁵S]GTP $gamma$ S binding measures G protein activation, which providesa more proximal indication of agonist/antagonist actions at thereceptoritself.

Third, the antagonist rank order of potency of haloperidol, S 14297, and the novel selective antagonist, GR 218,231 (Murrayet al., 1996; Figs. 6 and 7) at hD₃ and hD₂ receptors correspondedto the order of affinity determined in competition binding experiments,although a reduced preference for hD₃ sites was observed in functionaltests (Table 5). It is noteworthy that, whereas the pK_B valuesof the antagonists resembled their respective pK_i values, theantagonists did not exhibit negative efficacy at either hD₃ orhD₂ receptors at concentrations up to 10⁵ M. At higher concentrations, [³⁵S]GTP $gamma$ S binding was somewhat reduced below basal levels in someexperiments but this was taken to be a nonspecific effect, becauseit occurred at concentrations >1000-fold greater than their bindingaffinity, the effects did not show a discernible correlation withthe order of potency, and a similar trend was observed in untransfectedCHO cell membranes (D. Cussac, unpublished observations). A recentstudy using hD₃ receptors expressed in CHO cells (Malmberg etal., 1998) reported that basal [³⁵S]GTP $gamma$ S binding could be increased by dopaminergic agonists anddecreased by antagonists. However, in that study dopamine-inducedstimulation was very low (only ~1.2-fold), negative efficacy wasonly observed at very high drug concentrations ( $>=$ 10⁶ M), and control untransfected CHO cells were not examined. Nevertheless,further investigation of the issue of negative efficacy is desirable,because the conditions used for [³⁵S]GTP $gamma$ S binding both in the present study and that of Malmberget al. (1998) (high concentrations of GDP and NaCl) favor suppressionof constitutive hD₃ and hD₂ receptor activation (Gardner et al.,1996). Indeed, some studies reported that haloperidol shows negativeefficacy in models of D₃ and D₂ receptor activation (mitogenesis,Griffon et al., 1996; prolactin secretion, Nilsson et al., 1996).

Fourth, G protein activation by dopamine at hD₃ receptors is PTX sensitive (Fig. 8), implicating G_i/o G proteins. This isanalogous to the known PTX sensitivity of D₂ receptors (Neve etal., 1989; Lajiness et al., 1993; Seabrook et al., 1994; Swarzenskiet al., 1996; Hall and Strange, 1997). However, marked differenceswere observed between hD₃ and hD₂ receptors in antibody tests.In the present study, dopamine-stimulated [³⁵S]GTP $gamma$ S binding at hD₃ and hD₂ receptors was inhibited by an antiserumthat recognizes the three $alpha$ _i subunits ( $alpha$ _i1/i2/i3) and, more weakly, $alpha$ _O subunits (Cussac et al., 1996). This antiserum inhibited dopamine-stimulated[³⁵S]GTP $gamma$ S binding to CHO-hD₃ membranes more strongly than to CHO-hD₂membranes (67% versus 40% inhibition, Fig. 9). The greater effectat hD₃ receptors may be due to a coupling by hD₃ to both G_i andG_O proteins, whereas hD₂ receptors may couple only to membersof the G_i protein family. This would be consistent with a studythat found that an attenuation of D₂ receptor-mediated inhibitionof adenylyl cyclase activity was achieved by pretreatment withanti-G $alpha$ _i1/i2 but not by anti-G $alpha$ _O antibodies (Izenwasser and Côté,1995). Alternatively, hD₃ receptor functional coupling to G proteinsmay be more labile than that at hD₂ receptors. Thus, the hD₃ receptor/Gprotein interaction may be more susceptible to the steric hindranceof antibody binding to G $alpha$ subunits, in accordance with the apparentlyless "efficient" G protein coupling of hD₃ receptors discussedabove.

Fifth, an interaction of hD₃ receptors with a G protein other than G_i or G_O is suggested by the observation that, when CHO-hD₃cells were treated with PTX, there remained a residual capacityof dopamine to stimulate [³⁵S]GTP $gamma$ S binding. This was not due to an insufficient incubationperiod with PTX, because control experiments (Fig. 8) indicatedthat 6 h were sufficient to completely ADP-ribosylate G_i/o proteinsin CHO-hD₃ cells, in agreement with previous studies in pituitarycells (Cussac et al., 1996). Thus, a component of dopamine-dependent[³⁵S]GTP $gamma$ S binding at hD₃ receptors may be mediated by a G proteinthat is not PTX sensitive. This possibility is supported by theinhibition of dopamine-dependent [³⁵S]GTP $gamma$ S binding at hD₃ receptors by anti-G $alpha$ _q/11 antibodies (Fig.9). Such an effect was not observed at hD₂ receptors, although $alpha$ _q/11 (as well as $alpha$ _i/O and $alpha$ _S) subunits are expressed in bothcell lines (Fig. 9). Furthermore, the inhibition by anti-G $alpha$ _q/11antibodies is not simply due to nonspecific Ig interactions, becausethe same concentration of antisera against an unrelated target(JNK1) did not affect dopamine-dependent [³⁵S]GTP $gamma$ S binding (not shown). Thus, these data suggest that hD₃receptors in the present CHO-hD₃ cell line may interact with G $alpha$ _q/11and, potentially, modulate phosphatidyl inositol turnover. Althougha previous study of hD₃ receptors expressed in CHO cells did notfind such an effect (Freedman et al., 1994), that may have beendue to a 50-fold lower hD₃ expression level (0.3 versus 15 pmol/mgin the cells used in thisstudy).

In conclusion, the [³⁵S]GTP $gamma$ S binding strategy employed in this study enabled the characterization of G protein coupling athD₃ receptors. The data suggest that the coupling of hD₃ receptorsto G proteins is less efficacious than that at hD₂ receptors,yielding a less pronounced stimulation of [³⁵S]GTP $gamma$ S binding despite the high expression levels of receptorsand G proteins, and the presence of receptor reserve for dopamine.In addition, unlike hD₂ receptors, hD₃ receptors may couple toG proteins other than G_i, such as G_O and/or G_q/11 proteins. Theprecise G protein subtypes involved in hD₃ receptor coupling andtheir relevance to physiological actions require furtherinvestigation.

	Acknowledgment

We thank Lucy Sezguin for quality technicalassistance.

	Footnotes

Received July 8, 1998; Accepted December 16, 1998

¹ These two authors made equivalent contributions to thiswork.

Send reprint requests to: Adrian Newman-Tancredi, Ph.D., Department of Psychopharmacology, Institut de Recherches Servier, 125, Chemin de Ronde, 78290 Croissy-sur-Seine Paris, France. E-mail: newman_tancredi{at}hotmail.com

	Abbreviations

EEDQ, N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline; GR 218, 231, 2(R,S)-(dipropylamino)-6-(4-methoxyphenylsulfonylmethyl)-1,2,3,4- tetrahydronaphtalene; [³⁵S]GTP $gamma$ S, guanosine-5'-O-(3-[³⁵S]thio)-triphosphate; (+)7-OH-DPAT, 7-hydroxy-2-(di-n-propylamino)tetralin; PD 128, 907, (+)-(4aR,10bR)-3,4,4a,10b-tetrahydro-4-propyl-2H,5H-[1]benzopyrano[4,3-b]-1,4-oxazin-9-ol; S 14297, (+)-[7-(N, N-dipropylamino)-5,6,7,8-tetrahydro-naphtho(2,3b)dihydro-2,3-furane].

	References

Top Summary Introduction Materials and Methods Results Discussion References

Adham N, Ellerbrock B, Hartig P, Weinshank RL and Branchek T (1993) Receptor reserve masks partial agonist activity of drugs in a cloned rat 5-hydroxytryptamine1B receptor expression system. Mol Pharmacol 43: 427-433[Abstract].
Atkinson BN and Minneman KP (1992) Occupancy-response relationships for $beta$ - and $alpha$ ₂-adrenergic receptors exerting opposing effects on cAMP production. Receptor 2: 195-206[Medline].
Boundy VA, Lu L and Molinoff PB (1996) Differential coupling of rat D₂ dopamine receptor isoforms expressed in Spodoptera frugiperda insect cells. J Pharmacol Exp Ther 276: 784-794[Abstract/Free Full Text].
Burris KD, Pacheco MA, Filtz TM, Kung MP, Kung HF and Molinoff PB (1995) Lack of discrimination by agonists for D₂ and D₃ dopamine receptors. Neuropsychopharmacology 12: 335-345[Medline].
Chio CL, Lajiness ME and Huff RM (1994) Activation of heterologously expressed D₃ dopamine receptors: Comparison with D₂ dopamine receptors. Mol Pharmacol 45: 51-60[Abstract].
Cox BA, Rosser MP, Kozlowski MR, Duwe KM, Neve RL and Neve KA (1995) Regulation and functional characterization of a rat recombinant dopamine D₃ receptor. Synapse 21: 1-9[Medline].
Cussac D, Kordon C, Enjalbert A and Saltarelli D (1996) ADP-ribosylation of G $alpha$ _i and G $alpha$ _O in pituitary cells enhances their recognition by antibodies directed against their carboxyl termini. J Receptor Signal Transduction Res 16: 169-190[Medline].
Fishburn CS, Elazar Z and Fuchs S (1995) Different glycosylation and intracellular trafficking for the long and short isoforms of the D₂ dopamine receptor. J Biol Chem 270: 29819-29824[Abstract/Free Full Text].
Freedman SB, Patel S, Marwood R, Emms F, Seabrook GR, Knowles MR and McAllister G (1994) Expression and pharmacological characterization of the human D₃ dopamine receptor. J Pharmacol Exp Ther 268: 417-426[Abstract/Free Full Text].
Gardner BR, Hall DA and Strange PG (1996) Pharmacological analysis of dopamine stimulation of [³⁵S]-GTP $gamma$ S binding via human D_2SHORT and D_2LONG dopamine receptors expressed in recombinant cells. Br J Pharmacol 118: 1544-1550[Medline].
Griffon N, Pilon C, Sautel F, Schwartz JC and Sokoloff P (1996) Antipsychotics with inverse agonist activity at the dopamine D₃ receptor. J Neural Transm 103: 1163-1175.
Griffon N, Pilon C, Sautel F, Schwartz JC and Sokoloff P (1997) Two intracellular signaling pathways for the dopamine D₃ receptor: Opposite and synergistic interactions with cyclic AMP. J Neurochem 68: 1-9[Medline].
Hall DA and Strange PG (1997) Evidence that antipsychotic drugs are inverse agonists at D₂ dopamine receptors. Br J Pharmacol 121: 731-736[Medline].
Hall H, Halldin C, Dijkstra D, Wikström H, Wise LD, Pugsley TA, Sokoloff P, Pauli S, Farde L and Sedvall G (1996) Autoradiographic localisation of D₃ dopamine receptors in the human brain using the selective D₃ dopamine receptor agonist (+)-[³H]-PD 128907. Psychopharmacology 128: 240-247[Medline].
Izenwasser S. and Côté TE (1995) Inhibition of adenylyl cyclase activity by a homogeneous population of dopamine receptors: Selective blockade by antisera directed against G_i1 and/or G_i2. J Neurochem 64: 1614-1621[Medline].
Lajiness ME, Chio CL and Huff RM (1993) D₂ dopamine receptor stimulation of mitogenesis in transfected Chinese hamster ovary cells: Relationship to dopamine stimulation of tyrosine phosphorylations. J Pharmacol Exp Ther 267: 1573-1581[Abstract/Free Full Text].
Lazareno S and Birdsall NJM (1993) Estimation of antagonist K_B from inhibition curves in functional experiments: Alternatives to the Cheng-Prusoff equation. Trends Pharmacol Sci 14: 237-239[Medline].
Levant B (1997) The D₃ dopamine receptor: Neurobiology and potential clinical relevance. Pharmacol Rev 49: 231-252[Abstract/Free Full Text].
Liu LX, Monsma FJ, Sibley DR and Chiodo LA (1996) D_2L, D_2S, and D₃ dopamine receptors stably transfected into NG108-15 cells couple to a voltage-dependent potassium current via distinct G protein mechanisms. Synapse 24: 156-164[Medline].
Lledo PM, Homburger V, Bockaert J and Vincent JD (1992) Differential G protein mediated coupling of D₂ dopamine receptors to K⁺ and Ca²⁺ currents in rat anterior pituitary cells. Neuron 8: 455-463[Medline].
MacKenzie RG, VanLeeuwen D, Pugsley TA, Shih YH, Demattos S, Tang L, Todd RD and O'Malley KL (1994) Characterization of the human dopamine D₃ receptor expressed in transfected cell lines. Eur J Pharmacol 266: 79-85[Medline].
Malmberg A, Mikaels A and Mohell N (1998) Agonist and inverse agonist activity at the dopamine D₃ receptor measured by guanosine 5'-[ $gamma$ -thio]triphosphate-[³⁵S] binding. J Pharmacol Exp Ther 285: 119-126[Abstract/Free Full Text].
Millan MJ, Gressier H and Brocco M (1995a) The dopamine D₃ receptor antagonist, (+)-S 14297, blocks the cataleptic properties of haloperidol in rats. Eur J Pharmacol 321: R7-R9.
Millan MJ, Peglion JL, Vian J, Rivet JM, Brocco M, Gobert A, Newman-Tancredi A, Dacquet C, Bervoets K, Girardon S, Jacques V, Chaput C and Audinot V (1995b) Functional correlates of dopamine D₃ receptor activation in the rat in vivo and their modulation by the selective antagonist, (+)-S 14297: 1. Activation of post-synaptic D₃ receptors mediates hypothermia, whereas blockade of D₂ receptors elicits prolactin secretion and catalepsy. J Pharmacol Exp Ther 275: 885-898[Abstract/Free Full Text].
Missale C, Nash SR, Robinson SW, Jaber M and Caron MG (1998) Dopamine receptors: From structure to function. Physiol Rev 78: 189-225[Abstract/Free Full Text].
Morris BJ, Newman-Tancredi A, Audinot V, Simpson CS and Millan MJ (1997) Induction of c-fos expression in cultured rat striatal neurones by activation of dopamine D₃ receptors. Br J Pharmacol 122: 279P.
Murray PJ, Helden RM, Johnson MR, Robertson GM, Scopes DIC, Stokes M, Wadman S, Whitehead JWF, Hayes AG, Kilpatrick GJ, Large C, Stubbs CM and Turpin MP (1996) Novel 6-substituted 2-aminotetralins with potent and selective affinity for the dopamine D₃ receptor. Bioorg Med Chem Lett 6: 403-408.
Neve KA, Henningsen RA, Bunzow JR and Civelli O (1989) Functional characterization of a rat dopamine D₂ receptor cDNA expressed in a mammalian cell line. Mol Pharmacol 36: 446-451[Abstract].
Newman-Tancredi A, Conte C, Chaput C, Verrièle L and Millan MJ (1997) Agonist and inverse agonist efficacy at human recombinant serotonin 5-HT_1A receptors as a function of receptor: G-protein stoichiometry. Neuropharmacology 36: 451-459[Medline].
Nilsson CL, Ekman A, Hellstrand M and Eriksson E (1996) Inverse agonism at dopamine D₂ receptors: Haloperidol-induced prolactin release from GH4C1 cells transfected with the human D₂ receptor is antagonized by R( $-$ )-n-propylnorapomorphine, raclopride, and phenoxybenzamine. Neuropsychopharmacology 15: 53-61[Medline].
Pilon C, Lévesque D, Dimitriadou V, Griffon N, Martres MP, Schwartz JC and Sokoloff P (1994) Functional coupling of the human dopamine D₃ receptor in a transfected NG108-15 neuroblastoma-glioma hybrid cell line. Eur J Pharmacol 268: 129-139[Medline].
Pregenzer JF, Alberts GL and Im WB (1997) Agonist-induced [³⁵S]-GTP $gamma$ S binding in the membranes of Spodoptera frugiperda insect cells expressing the human D₃ dopamine receptor. Neuroscience Lett 226: 91-94[Medline].
Pugsley TA, Davis MD, Akunne HC, MacKenzie RG, Shih YH, Damsma G, Wikstrom H, Whetzel SZ, Georgic LM, Cooke LW, Bemattos SB, Corbin AE, Glase SA, Wise LD, Dijkstra D and Heffner TG (1995) Neurochemical and functional characterization of the preferentially selective dopamine D₃ agonist PD 128,907. J Pharmacol Exp Ther 275: 1355-1366[Abstract/Free Full Text].
Robinson S and Caron MG (1997) Selective inhibition of adenylyl cyclase type V by the dopamine D₃ receptor. Mol Pharmacol 52: 508-514[Abstract/Free Full Text].
Sautel F, Griffon N, Lévesque D, Pilon C, Schwartz JC and Sokoloff P (1995) A functional test identifies dopamine agonists selective for D₃ versus D₂ receptors. NeuroReport 6: 329-332[Medline].
Seabrook GR, Kemp JA, Freedman SB, Patel S, Sinclair HA and McAllister G (1994) Functional expression of human D₃ dopamine receptors in differentiated neuroblastoma x glioma NG108-15 cells. Br J Pharmacol 111: 391-393[Medline].
Simon MI, Strathmann MP and Gautam N (1991) Diversity of G proteins in signal transduction. Science 252: 802-808[Abstract/Free Full Text].
Sokoloff P, Andrieux M, Besançon R, Pilon C, Martres MP, Giros B and Schwartz JC (1992) Pharmacology of human dopamine D₃ receptor expressed in a mammalian cell line: Comparison with D₂ receptor. Eur J Pharmacol 225: 331-337[Medline].
Starr MS and Starr BS (1995) Motor actions of 7-OH-DPAT in normal and reserpine-treated mice suggest involvement of both dopamine D₂ and D₃ receptors. Eur J Pharmacol 277: 151-158[Medline].
Svensson K, Carlsson A, Huff RM, Kling-Petersen T and Waters N (1994) Behavioral and neurochemical data suggest functional differences between dopamine D₂ and D₃ receptors. Eur J Pharmacol 263: 235-243[Medline].
Swarzenski BC, O'Malley KL and Todd RD (1996) PTX-sensitive regulation of neurite outgrowth by the dopamine D₃ receptor. NeuroReport 7: 573-576[Medline].
Tang L, Todd RD, Heller A and O'Malley KL (1994) Pharmacological and functional characterization of D₂, D₃ and D₄ dopamine receptors in fibroblast and dopaminergic cell lines. J Pharmacol Exp Ther 268: 495-502[Abstract/Free Full Text].
Watts VJ and Neve KA (1997) Activation of type II adenylate cyclase by D₂ and D₄ but not D₃ dopamine receptors. Mol Pharmacol 52: 181-186[Abstract/Free Full Text].

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				M. J. Millan, C. M. la Cour, F. Novi, R. Maggio, V. Audinot, A. Newman-Tancredi, D. Cussac, V. Pasteau, J.-A. Boutin, T. Dubuffet, et al. S33138 [N-[4-[2-[(3aS,9bR)-8-cyano-1,3a,4,9b-tetrahydro[1]-benzopyrano[3,4-c]pyrrol-2(3H)-yl)-ethyl]phenylacetamide], A Preferential Dopamine D3 versus D2 Receptor Antagonist and Potential Antipsychotic Agent: I. Receptor-Binding Profile and Functional Actions at G-Protein-Coupled Receptors J. Pharmacol. Exp. Ther., February 1, 2008; 324(2): 587 - 599. [Abstract] [Full Text] [PDF]

				C. A. Johnston and D. P. Siderovski Structural basis for nucleotide exchange on G{alpha}i subunits and receptor coupling specificity PNAS, February 6, 2007; 104(6): 2001 - 2006. [Abstract] [Full Text] [PDF]

				E. S. Burstein, J. Ma, S. Wong, Y. Gao, E. Pham, A. E. Knapp, N. R. Nash, R. Olsson, R. E. Davis, U. Hacksell, et al. Intrinsic Efficacy of Antipsychotics at Human D2, D3, and D4 Dopamine Receptors: Identification of the Clozapine Metabolite N-Desmethylclozapine as a D2/D3 Partial Agonist J. Pharmacol. Exp. Ther., December 1, 2005; 315(3): 1278 - 1287. [Abstract] [Full Text] [PDF]

				M. J. Millan, D. Cussac, A. Gobert, F. Lejeune, J.-M. Rivet, C. M. La Cour, A. Newman-Tancredi, and J.-L. Peglion S32504, a Novel Naphtoxazine Agonist at Dopamine D3/D2 Receptors: I. Cellular, Electrophysiological, and Neurochemical Profile in Comparison with Ropinirole J. Pharmacol. Exp. Ther., June 1, 2004; 309(3): 903 - 920. [Abstract] [Full Text] [PDF]

				M. A. Shaqura, C. Zollner, S. A. Mousa, C. Stein, and M. Schafer Characterization of {micro} Opioid Receptor Binding and G Protein Coupling in Rat Hypothalamus, Spinal Cord, and Primary Afferent Neurons during Inflammatory Pain J. Pharmacol. Exp. Ther., February 1, 2004; 308(2): 712 - 718. [Abstract] [Full Text] [PDF]

				C. Zollner, M. A. Shaqura, C. P. Bopaiah, S. Mousa, C. Stein, and M. Schafer Painful Inflammation-Induced Increase in {micro}-Opioid Receptor Binding and G-Protein Coupling in Primary Afferent Neurons Mol. Pharmacol., August 1, 2003; 64(2): 202 - 210. [Abstract] [Full Text] [PDF]

				A. Newman-Tancredi, D. Cussac, V. Audinot, J.-P. Nicolas, F. De Ceuninck, J.-A. Boutin, and M. J. Millan Differential Actions of Antiparkinson Agents at Multiple Classes of Monoaminergic Receptor. II. Agonist and Antagonist Properties at Subtypes of Dopamine D2-Like Receptor and alpha 1/alpha 2-Adrenoceptor J. Pharmacol. Exp. Ther., November 1, 2002; 303(2): 805 - 814. [Abstract] [Full Text] [PDF]

				S. K. Gupta, K. Pillarisetti, and N. Aiyar CXCR4 undergoes complex lineage and inducing agent-dependent dissociation of expression and functional responsiveness to SDF-1{alpha} during myeloid differentiation J. Leukoc. Biol., September 1, 2001; 70(3): 431 - 438. [Abstract] [Full Text] [PDF]

				A. Newman-Tancredi, V. Audinot, C. Moreira, L. Verrièle, and M. J. Millan Inverse Agonism and Constitutive Activity as Functional Correlates of Serotonin h5-HT1B Receptor/G-Protein Stoichiometry Mol. Pharmacol., November 1, 2000; 58(5): 1042 - 1049. [Abstract] [Full Text]

				M. J. Millan, A. Gobert, A. Newman-Tancredi, F. Lejeune, D. Cussac, J.-M. Rivet, V. Audinot, T. Dubuffet, and G. Lavielle S33084, a Novel, Potent, Selective, and Competitive Antagonist at Dopamine D3-Receptors: I. Receptorial, Electrophysiological and Neurochemical Profile Compared with GR218,231 and L741,626 J. Pharmacol. Exp. Ther., June 1, 2000; 293(3): 1048 - 1062. [Abstract] [Full Text]

				M. L. Bayewitch, I. Nevo, T. Avidor-Reiss, R. Levy, W. F. Simonds, and Z. Vogel Alterations in Detergent Solubility of Heterotrimeric G Proteins after Chronic Activation of Gi/o-Coupled Receptors: Changes in Detergent Solubility Are in Correlation with Onset of Adenylyl Cyclase Superactivation Mol. Pharmacol., April 1, 2000; 57(4): 820 - 825. [Abstract] [Full Text]

				M. J. Millan, F. Lejeune, and A. Gobert Reciprocal autoreceptor and heteroreceptor control of serotonergic, dopaminergic and noradrenergic transmission in the frontal cortex: relevance to the actions of antidepressant agents J Psychopharmacol, March 1, 2000; 14(2): 114 - 138. [Abstract] [PDF]

				D. Cussac, A. Newman-Tancredi, V. Pasteau, and M. J. Millan Human Dopamine D3 Receptors Mediate Mitogen-Activated Protein Kinase Activation Via a Phosphatidylinositol 3-Kinase and an Atypical Protein Kinase C-Dependent Mechanism Mol. Pharmacol., November 1, 1999; 56(5): 1025 - 1030. [Abstract] [Full Text]