Bidirectional Allosteric Effects of Agonists and GTP at α2A/D-Adrenoceptors1

  1. Wang-Ni Tian1,
  2. Duane D. Miller2 and
  3. Richard C. Deth1
  1. 1Department of Pharmaceutical Sciences, Northeastern University, Boston, Massachusetts (W.-T.T., R.C.D.); and 2Department of Pharmaceutical Sciences, University of Tennessee, Memphis, Tennessee (D.D.M.).
     
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    Abstract

    Agonists and GTP exert reciprocal effects on the stability of the G protein-coupled receptor/G protein complex, implying bidirectional control over the receptor/G protein interface. To investigate this relationship, we compared the ability of a series of hydroxyl-substituted phenethylamine and imidazoline agonists to stimulate [35S]guanosine 5′-O-(3-thio)triphosphate ([35S]GTPγS) binding in membranes from α2A/D-adrenergic receptor-transfected PC12 cells with the magnitude of the GTP-induced reduction in agonist affinity in [3H]rauwolscine-binding studies. Agents previously described as full and partial agonists in functional studies showed similar relative efficacies in promoting GTP binding (r = 0.97) as well as similar relative potencies (r = 0.94). Efficacy among agonists for promotion of [35S]GTPγS binding was closely correlated with the relative influence of GTPγS on agonist binding (r = 0.97), consistent with a bidirectional allosteric influence by agonists and GTP on receptor/G protein complexation. In an additional series of tolazoline derivatives, a range in efficacy from full agonism to strong inverse agonism was observed, depending on the presence or absence of hydroxyl substituents. Together these results suggest that agonist-induced repositioning of transmembrane helices via their hydroxyl interactions is a critical determinant of the stability of the receptor/G protein complex and therefore of agonist efficacy.

    The ability of adrenergic agonists to increase GTP binding to G proteins is well recognized as the basis of their efficacy. Increased GTP binding has been shown to result from increased dissociation of GDP as a consequence of binding of an active conformation of the receptor (R*) to the GDP-occupied form of the heterotrimeric G protein (Hilf et al., 1989). By facilitating GDP dissociation, the net effect of the agonist-activated receptor is to increase the apparent affinity of GTP. Specific helical segments of the α2A/D-adrenergic receptor have been identified that possess the ability to activate G proteins (Dalman and Neubig, 1991; Ikezu et al., 1992; Liu et al., 1995; Eason and Liggett, 1995) and agonist binding is thought to regulate the presentation of these regions as a part of a receptor/G protein interface. The relative efficacy of agonists may therefore be closely linked to the ability of ligands to effectively reposition these helices to allow for G protein complexation.

    For a number of receptors, including the α2A/D-adrenergic receptor, a sequence of 8 to 10 residues, comprising the cytoplasmic extension of transmembrane helix 6, has been shown to be critical for Giactivation (Liu et al., 1995). Conversely, a segment in the cytoplasmic extension of helix 5 may be involved in GSactivation (Eason and Liggett, 1995). Because more than one type of G protein can be activated, GTP-binding studies may provide a more complete measurement of agonist efficacy than functional responses reflecting only one pathway.

    The binding of phenethylamine agonists involves side chain interactions with residues of helices 5 and 6. Meta- andpara-hydroxyl substituents bind to serine (or cysteine in the case of the α2A/D-adrenergic receptor) residues on helix 5 (Strader et al., 1989), whereas the phenyl group is thought to bind to a highly conserved phenylalanine on helix 6 (Dixon et al., 1988). Because catecholamine binding to these residues might result in repositioning of helices 5 and 6, it is reasonable to propose that hydroxyl substituents on the phenyl ring might play a key role in determining the efficacy of phenethylamines, as has been confirmed in previous functional studies of α2-adrenergic receptors (Ruffolo and Waddell, 1983; Ruffolo, 1984).

    GTP binding to G proteins can affect agonist affinity (for review, seeIiri et al., 1998). Complexation of the agonist-occupied R* with the GDP-bound form of the G protein serves to stabilize the R* state, and delays agonist dissociation, reflected in a lowerKD value. This higher agonist affinity is presumably a result of the immobilization of receptor helices in the R* state caused by their binding to interfacial surfaces of the G protein. Stabilization of R* is maintained after GDP dissociation, however, the subsequent binding of GTP to the α-subunit initiates a conformational change in the heterotrimeric G protein that weakens the receptor complex, and initiates its dissociation. The released receptor can freely revert to its R state, and agonist affinity in the presence of GTP reverts to its higher KD value that is characteristic of the inactive R state.

    Receptor/G protein coupling can thus be viewed as a cycle of forward and reverse allosteric events extending across their shared interface. In the forward direction the free energy of agonist binding produces an increase in GTP-binding affinity for the α-subunit, whereas GTP binding initiates a negative influence on agonist-binding affinity in the reverse direction. Quantitative differences in the ability of receptor ligands to promote the forward direction results in differences in agonist efficacy. These reflect the relative ability of ligands to improve (or in the case of inverse agonists impair) the native tendency of the receptor to achieve an R*state.

    In the current study we examined whether a quantitative relationship exists between the forward allosteric effect of hydroxy-substituted full and partial agonists on GTP binding and the reverse allosteric effect of GTP on agonist binding. [35S]guanosine 5′-O-(3-thio)triphosphate (GTPγS) binding was measured in membranes from stably transfected PC12 cells expressing α2D-adrenergic receptors (the rat homolog of the human α2A-adrenergic receptor). Receptor binding of agonists was measured in [3H]rauwolscine displacement studies in the absence or presence of GTPγS in the same membranes under otherwise identical conditions.

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    Experimental Procedures

    Materials.

    PC12 cells stably expressing the cloned α2A/D-adrenergic receptor at a density of 3 to 4 pmol/mg membrane protein were generously provided by Dr. Stephen M. Lanier (Medical University of South Carolina). [35S]GTPγS (1255 Ci/mmol) and [3H]rauwolscine (78 Ci/mmol) were purchased from DuPont-NEN (Boston, MA). UK14304 [5-bromo-N-(4,5-dihydro-1H-imidazol-2-yl)-6-quinoxalinamine] and clonidine were obtained from Research Biochemicals International (Natick, MA); R-(−)- andS-(+)-hydroxytolazoline, 3,4-dihydroxytolazoline, andR-(−)-OH-3,4-dihydroxytolazoline were synthesized as previously described (Miller et al., 1983; Sengupta et al., 1987). Other reagents were purchased from Sigma Chemical Co. (St. Louis, MO).

    Cell Culture and Membrane Preparation.

    Transfected PC12 cells were grown as monolayers in Dulbecco's modified Eagle's medium with high glucose supplemented with 10% fetal calf serum, 5% horse serum, penicillin, streptomycin, and fungizone as described previously (Tian et al., 1994). Cells were washed twice with PBS, harvested with a rubber policeman, and pelleted. The pellet was resuspended in 5 ml/dish of lysis buffer (5 mM Tris-HCl, pH 7.5, 5 mM EDTA, 5 mM EGTA, 0.1 mM phenylmethylsulfonyl fluoride) at 4oC and homogenized with a Dounce homogenizer. The lysate was then centrifuged at 34,000g for 15 min and the pellet was resuspended in membrane buffer (50 mM Tris-HCl, pH 7.5, 0.6 mM EDTA, 5 mM MgCl2, 0.1 mM phenylmethylsulfonyl fluoride). Aliquots were frozen in liquid nitrogen and stored at −80oC until used.

    [35S]GTPγS Binding.

    As described previously (Tian et al., 1994), binding was initiated by addition of reaction mixture (50 mM Tris-HCl, pH 7.5, 5 mM MgCl2, 1 mM EDTA, 1 mM dithiothreitol, 100 mM NaCl, 2 mM GDP, 1 mM propranolol, and 2 to 3 nM [35S]GTPγS) to 4 to 8 μg of membranes in a total volume of 0.1 ml. Most experiments were carried out in triplicate at 25°C for a 10-min incubation period. Filters were washed four times (with 4 ml of 50 mM Tris-HCl, pH 7.5, containing 5 mM MgCl2 and 100 mM NaCl) and then counted. Nonspecific binding was determined in the presence of 10 μM GTPγS and subtracted from total bound radioactivity.

    Radioligand Binding Assay.

    Assays were performed in a total volume of 0.1 ml and contained 50 mM Tris-HCl (pH 7.5), 5 mM MgCl2, 1 mM EDTA, 1 mM dithiothreitol, 1 μM propranolol, 100 mM NaCl, and 20 to 50 μg of membrane fraction. Displacing ligands and GTPγS (10 μM) were added when indicated. Nonspecific binding was determined in presence of 0.1 mM phentolamine. Competition binding curves were analyzed with LIGAND (Munson and Rodbard, 1980) and GraphPad Prism. A model with two classes of binding sites was tested for its statistical superiority over a model with a single class of binding site with an F test based on the residual variance between the actual and predicted data points. The size of the GTPγS-induced shift in agonist affinity was quantitated by calculating the area between individual displacement curves and averaging the data.

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    Results

    In an earlier study (Tian et al., 1994), we described the ability of epinephrine (EPI) to stimulate [35S]GTPγS binding in membranes from PC12 cells expressing cloned α2A/D-receptors. EPI caused an increase of ∼3-fold in [35S]GTPγS binding when measured after a 10-min incubation period and exhibited an EC50 of 0.14 ± 0.01 μM (Fig.1A; Table1). EPI produced the largest increase of binding among all the phenethylamines or imidazolines tested and its activity was assigned a value of 1.0 for comparative purposes.

    Figure 1
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    Figure 1

    Stimulation of [35S]GTPγS binding in PC12/α2A/D-membranes by phenethylamine and imidazoline agonists. Binding was determined after a 10-min incubation in the presence of increasing concentrations of each agent. Results are expressed as a percentage of the unstimulated basal level of binding (average = 386 ± 33 fmol/mg protein). Data shown are the means of triplicate determinations from a representative of three separate experiments. Summary data are provided in Table 1.

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    Table 1

    Relative activity (RA) and EC50 of α2-adrenergic agonists in stimulating [35S]GTPγS binding to PC12/α2A/D-membranes

    Five additional phenethylamines, which differed in one or more of the potential binding features of EPI, as well as three imidazoline derivatives (UK14304, clonidine, and oxymetazoline; Fig.2) were evaluated for their effects on [35S]GTPγS binding. As shown in Fig. 1 and Table 1, the maximum stimulation caused by three of these agonists (norepinephrine, deoxyepinephrine, and UK14304) approached but did not equal the level of EPI response. The remaining five agonists produced considerably smaller increases of 40 to 60% above control levels. A rank order for efficacy of EPI > norepinephrine > deoxyepinephrine ≅ UK14304 ≫ synephrine > clonidine > oxymetazoline ≥ phenylephrine = norphenylephrine was determined. Differences in agonist potency were also evident with a potency order of oxymetazoline > clonidine ≥ UK14304 > EPI > norepinephrine = norphenylephrine > deoxyepinephrine = phenylephrine > synephrine. Clearly, the efficacy and potency orders are distinct from each other.

    Figure 2
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    Figure 2

    Chemical structures of the compounds evaluated in this study.

    A comparison of EC50 and relative maximal activity values from GTPγS-binding studies with values previously reported from intact tissue functional responses shows a high degree of correlation for both relative efficacy (r = 0.97) and relative potency, expressed as KAvalues (r = 0.94) (Fig.3). Thus, agonist-induced stimulation of [35S]GTPγS binding in this isolated membrane preparation is predictive of tissue response.

    Figure 3
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    Figure 3

    Correlation of [35S]GTPγS binding-derived agonist potency and relative activity with previously reported α2-receptor values (top). EC50values obtained from agonist dose-response curves for [35S]GTPγS binding in PC12/α2A/D-membranes are plotted versus previously reported agonist KA values from functional studies (Wikberg, 1978a,b; Hieble and Pendleton, 1979; Jarrott et al., 1979, 1980; Lasch and Jakobs, 1979; Rossi et al., 1979; Tanaka and Starke, 1979; Summers et al., 1980; DeJong and Soudijn, 1981; Kahn et al., 1982; Turner et al., 1985; Paris et al., 1989a). For those compounds with multiple determinations, the mean value was used (bottom). Maximal responses for [35S]GTPγS binding were normalized to the value for EPI and plotted versus previously reported relative activity values.

    In the absence of GTPγS, agonists competed for [3H]rauwolscine-binding sites in isolated membranes in a biphasic concentration-dependent manner (Fig.4), yielding computed estimatedKD values forKDH andKDL as well as their percentage contribution to total binding (Table 2). In the presence of 10 μM GTPγS, binding was monophasic, yielding an estimated KD that was generally, but not always, similar to KDL values. The net influence of GTPγS on agonist binding was quantitated by measuring the total area between displacement curves in its absence and presence and normalizing to the value for EPI. Notably, this approach includes contributions of both the amplitude of theKD change and the percentage of high- versus low-affinity sites.

    Figure 4
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    Figure 4

    Influence of GTPγS (10 μM) on [3H]rauwolscine displacement curves for α2-adrenergic receptor agonists. Each curve is a representative of two to four experiments with data points derived from triplicate determinations. Values for KDH,KDL, and the area between curves are provided in Table 2.

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    Table 2

    Competition for [3H]rauwolscine-binding sites in PC12/α2A/D-membranes by α2-adrenergic ligands

    The relative ability of agonists to maximally stimulate [35S]GTPγS binding was compared with three different receptor-binding parameters to determine the extent of correlation. As shown in Fig. 5, plots of relative efficacy versus the percentage of high-affinity sites (Fig.5B) or versus the ratio ofKDH/KDL(Fig. 5C) each exhibited a low degree of correlation (r= 0.46 and 0.40, respectively). In contrast, the size of the GTPγS-induced shift in binding was highly correlated with efficacy (Fig. 5A; r = 0.97).

    Figure 5
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    Figure 5

    Correlation between relative agonist efficacy in stimulation of [35S]GTPγS binding with different receptor-binding parameters. The maximal stimulation of [35S]GTPγS binding for each agonist (agonist efficacy) is plotted against the size of GTPγS-induced rightward shift in [3H]rauwolscine displacement curves (A), the ratio of receptors exhibiting high versus low agonist affinity (B), and the ratio of KDL/KDH(C).. The GTPγS-induced rightward shift was measured as the total area between curves obtained in the absence or presence of GTPγS (10 μM) and relative efficacy values are those listed in Table 1. Dashed lines represent the 95% CI for the fitted line.

    From the perspective of structure-activity relationships, the above-mentioned pattern of graded agonism reveals the critical importance of catechol hydroxyl groups for efficacy at α2D-adrenergic receptors. Thus, the three phenethylamines that lack either a 3- (meta) or 4- (para) position hydroxyl group (phenylephrine, norphenylephrine, and synephrine) each exhibited less than half the efficacy of EPI (relative efficacies of 0.29, 0.28, and 0.47, respectively) and were also less potent. Absence of the β-hydroxyl group (deoxyepinephrine), however, resulted in a more modest decrease in efficacy (0.78) accompanied by a 14-fold lower potency.

    To further examine the importance of these hydroxyl groups, we measured the ability of the antagonist tolazoline and several of its hydroxyl-containing derivatives to alter [35S]GTPγS binding and to bind to α2A/D-adrenergic receptors. Tolazoline itself failed to either stimulate or inhibit GTP binding (Fig.6), thus behaving as a “null” antagonist, as defined by Costa et al. (1992), under these assay conditions. The addition of a β-hydroxyl group [R-(−)-OH-tolazoline] did not alter the activity of tolazoline. However, the addition of catechol 3,4-dihydroxy groups to tolazoline resulted in the remarkable expression of either agonist or inverse agonist activities, depending on whether an additional hydroxyl group was present on the benzylic carbon or not (Fig. 6). Thus, bothR-(−)-OH-3,4-dihydroxytolazoline andS-(+)-OH-3,4-dihydroxytolazoline increased [35S]GTPγS binding, with the former yielding a relative efficacy of 0.72 and the latter 0.31 at the highest concentrations tested. In marked contrast, 3,4-dihydroxytolazoline reduced basal [35S]GTPγS binding by 55% under standard experimental conditions, which included 100 mM NaCl.

    Figure 6
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    Figure 6

    Effects of tolazoline and its hydroxyl-substituted analogs on [35S]GTPγS binding to PC12/α2D-membranes. Data shown are means ± S.E. of triplicate determinations of a representative of at least three separate experiments.

    The inhibitory effect of 3,4-dihydroxytolazoline was further examined under Na+-free conditions that have been shown previously to favor spontaneous activity of the α2D-adrenergic receptor, thereby facilitating observation of inverse agonist properties (Tian et al., 1994). 3,4-Dihydroxytolazoline progressively reduced [35S]GTPγS binding up to a maximum of 68% at 1 mM, with an IC50 of 30 μM (Fig.7A), similar to its IC50 in the presence of 100 mM NaCl. When the concentration of NaCl was raised stepwise from 0 to 200 mM, the percentage of inhibition produced by 3,4-dihydroxytolazoline was gradually diminished from 55 to 24%, although inhibition remained significant (P < .05) in the presence of 200 mM NaCl (Fig. 7B).

    Figure 7
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    Figure 7

    Inverse agonist effect of 3,4-dihydroxytolazoline in PC12/α2A/D-membranes. Binding of [35S]GTPγS was determined in the absence of Na+ at increasing concentrations of 3,4-dihydroxytolazoline (A), and in the presence of 100 μM 3,4-dihydroxytolazoline at increasing concentrations of NaCl (B). Data shown are means ± S.E. of triplicate determinations of a representative of two separate experiments.

    Receptor binding of R-(−)-OH-tolazoline,R-(−)-OH-3,4-dihydroxytolazoline, and 3,4-dihydroxytolazoline was examined in [3H]rauwolscine displacement studies. As shown in Fig. 8 and Table 2, only the agonistR-(−)-OH-3,4-dihydroxytolazoline showed a biphasic displacement pattern. Tolazoline itself had a significantly higher affinity than any of its hydroxyl-substituted derivatives. Notably, the estimated KD for 3,4-dihydroxytolazoline (3 μM) was 10-fold lower than its IC50 for inhibition of basal [35S]GTPγS binding.

    Figure 8
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    Figure 8

    Competition by tolazoline and its hydroxyl-substituted analogs for [3H]rauwolscine-binding sites in PC12/α2A/D-membranes. Membranes were incubated with 12 nM [3H]rauwolscine in the presence of 100 mM NaCl and increasing concentrations of drugs at 25°C for 50 min. Data shown are from triplicate determinations of a representative of two or three experiments. Binding parameters are shown in Table 2.

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    Discussion

    Adrenergic receptor agonists provide efficacy by allosterically modifying receptor conformation such that interaction with cognate G proteins is more fruitful than is the case for the unoccupied receptor. Because unoccupied α2-adrenergic receptors can activate G proteins (Tian et al., 1994), antagonists can either interfere with agonist binding (null antagonists) or can additionally act to reduce the extent of basal receptor activity (inverse agonists), according to the predictions of a ternary complex model (Costa et al., 1992). In the current study, we have used the combination of radioligand binding and G protein activation studies to examine the relationship between receptor binding and agonist efficacy. Our results indicate that for both phenethylamine and imidazoline agonists, differences in relative efficacy are highly correlated with the extent to which GTP alters their own receptor binding. This implies the bidirectional transmission of allosteric effects by agonists and GTP across the receptor/G protein interface.

    Measurement of agonist efficacy at the level of G protein activation rather than at subsequent coupling steps has several theoretical advantages and the use of a cloned receptor expression system in a native membrane environment also provides practical advantages. Thus, a single receptor may couple simultaneously to several different G proteins, initiating multiple response pathways. For example, agonist stimulation of α2-adrenergic receptors in certain intact cells, including PC12 cells, has been shown to activate both Gi and GS (Jones et al., 1991; Duzic and Lanier, 1992; Eason et al., 1994), although in isolated PC12/α2D-membranes EPI stimulation of [35S]GTPγS binding is completely blocked by pertussis toxin pretreatment (Tian et al., 1994). Indeed, immunoprecipitation studies with PC12/α2D-membranes used in the current studies indicated that both Gi and Go are activated (data not shown). Because we currently know of no adrenergic pathway that does not operate via G protein activation, measurement of [35S]GTPγS binding should capture all avenues of agonist efficacy in a quantitatively reliable manner.

    The relationship between binding of agonist to adrenergic receptors and their ability to provide efficacy has been the subject of a number of previous studies, yielding conflicting results (Kahn et al., 1982;Hoffman et al., 1988; Paris et al., 1989). Several studies have reported a positive correlation between agonist efficacy (measured as regulation of adenylate cyclase activity) and the percentage of high-affinity binding for both β- (Hoffman et al., 1988) and α2-adrenergic receptors (Paris et al., 1989). However, Hoffman et al. (1988) failed to find such a correlation for α2-adrenergic receptors in platelet membranes but did find a correlation between efficacy and the ratio of low- to high-affinity KD values. Similarly,Galitsky et al. (1989) found a higher value ofKDL/KDHfor the full agonist UK14304 versus the partial agonist clonidine at α2-receptors in adipocytes. Minneman and Abel (1987) did not find a good correlation for either the percentage of high-affinity sites orKDL/KDHand agonist efficacy at α1-adrenergic receptors.

    Rauwolscine is an inverse agonist at α2-adrenergic receptors (Tian et al., 1994), and this property may have facilitated our observation of a correlation between agonist efficacy and GTP-induced shifts in [3H]rauwolscine displacement. Inverse agonists exhibit a strong preference for the inactive R conformation of the receptor, whereas agonists, even weaker partial agonists, preferentially bind to the active R* state. The effect of GTP to convert all receptors to the R state should therefore be more critical for an inverse agonist radioligand such as rauwolscine.

    In the current studies, the relative efficacy of agonists in promoting [35S]GTPγS binding was well correlated with values reported from functional assays, such as inhibition of neurotransmitter release or platelet aggregation (Fig. 3B). This indicates that despite the potential caveats, these systems do provide useful indications of the extent of G protein activation by full and partial agonists. If the G protein involved in the functional response is the dominant contributor to [35S]GTPγS binding (e.g., Gi), this would be the case. The close correlation between agonist potency andKA values (Fig. 3A) may seem unexpected because numerous studies have found that agonist potency in functional assays does not correlate with eitherKDH orKDL values. However,KA values, commonly determined via the “Furchgott Method” of partial receptor inactivation, typically are intermediate between KDH andKDL values and thus represent a functional composite of high- and low-affinity receptor states.

    The tight correlation between relative agonist efficacy and GTP-dependent decrease in agonist affinity that we found is consistent with bidirectional transfer of allosteric effects between two interacting regulatory proteins. Thus, α2-receptor binding of agonists promotes formation of a productive complex with cognate G proteins, whereas GTP binding promotes dissociation of this complex. The critical surface of the receptor for complexation with Gi includes a segment at the cytoplasmic terminus of transmembrane helix 6 (Liu et al., 1995). In spin label studies with bovine rhodopsin, this region was shown to exhibit helical structure and its orientation was highly responsive to receptor activation (Farrens et al., 1996). By analogy, conformational changes induced by agonist binding may reposition this segment so that it can participate in G protein complexation and activation in the R* state. At the same time, complexation with the G protein also would serve to stabilize this region of the receptor in the high-affinity R*, mediated in particular by constraint of helix 6. In short, the ability of agonists to reposition helix 6 may be a critical aspect of their efficacy, and G proteins may stabilize the repositioned helix in the R* state of the receptor.

    Crystallographic studies of G proteins have identified critical “switch” regions in α-subunits that differentially respond to the presence of guanyl nucleotides and are thought to participate in receptor complexation and transmission of allosteric influences to the nucleotide-binding pocket (Coleman et al., 1994; Mixon et al., 1995). Specifically, the surface formed by carboxyl and amino termini has been proposed to be critical for receptor interaction (Sullivan et al., 1987). Binding of GTP introduces disorder in this region (Mixon et al., 1995) that could serve to destabilize the ternary complex with the agonist-occupied receptor, accounting for loss of the high-affinity agonist binding state. Because the same structural features are involved in both antegrade (AR*G formation) and retrograde (AR*G dissociation) events, a close correlation between stimulated GTP binding and GTP-dependent loss of affinity would therefore be expected.

    Based on the above-mentioned analysis, differences in agonist efficacy may be related to a differential ability to reposition transmembrane helix 6. In the catecholamine ligand-binding pocket, agonists are thought to bind to helix 6 via pi electron bonding interactions with a phenylalanine residue (Phe-391 in the α2D-adrenergic receptor) (Dixon et al., 1988). Being small, diffusable molecules, agonists are intrinsically limited in their ability to effect the movement of a protein motif, such as a helical element. However, once they are initially bound to the receptor in its R state, further bonding opportunities provided by the now immobile ligand can be much more effective. In the case of phenylethylamines (and imidazolines), initial ionic and hydrogen bond interactions can serve the role of immobilizing the phenyl moiety. Variations in both the strength of these interactions and in their spatial outcomes (i.e., positioning of the phenyl ring) will determine the effectiveness of immobilization on receptor activation.

    We therefore propose that differences in agonist efficacy observed among hydroxyl-substituted phenethylamines at α2D-adrenergic receptors may reflect variations in their ability to immobilize their phenyl ring for binding to Phe-391. Among the compounds we examined, the β-hydroxyl group was less critical for efficacy than either of the catechol hydroxyl groups, suggesting that the latter may be more important for determining phenyl ring orientation, as might be expected. However, the same was not true for binding potency. Such a differential contribution of hydroxyl substituents to agonist efficacy versus potency is well established (Ruffolo et al., 1979; Ruffolo, 1984), and phenolic hydroxyls have previously been shown to be critical for efficacy at α2-receptors, whereas primarily affecting agonist potency at α1-receptors (Ruffolo et al., 1984).

    UK14304 is a full agonist at α2D-adrenergic receptors but lacks hydroxyl groups, suggesting the possibility that its phenyl ring may be stably positioned by alternative means. As illustrated in Fig. 2, UK14304 possesses two aromatic nitrogens in a quinoxaline ring with positions equivalent to catechol hydroxyl groups. In their ring-stabilized position, these nitrogens may afford H-bonding or van der Waals bonding to residues in helix 5, thereby serving a role analogous to hydroxyl substituents.

    Our studies with hydroxyl-substituted tolazoline derivatives also suggest that hydroxyl groups on the phenyl ring may be important in determining its orientation and presentation for binding to Phe-391. Thus, in the absence of both catechol hydroxyls no agonism was detected [tolazoline and R-(−)-hydroxytolazoline], whereas 3,4-dihydroxytolazoline was a strong inverse agonist (Figs. 6 and 7) and R-(−)-OH-3,4-dihydroxytolazoline was a full agonist (Fig. 6). This is consistent with a specific positioning of the phenyl ring in the latter compounds, leading to either a negative or positive influence on receptor/G protein complex formation. Moreover,R-(−)-OH-3,4-dihydroxytolazoline binding was biphasic (Table 2) whereas 3,4-dihydroxytolazoline binding was not, indicative of the presence and absence of G protein complexation, respectively.

    The remarkable inverse agonism of 3,4-dihydroxytolazoline suggests that it induces a receptor conformation that is less capable of activating G proteins than the unoccupied receptor. Its maximum reduction in GTP binding of 68% is approximately twice that produced by rauwolscine under the same conditions (Tian et al., 1994). Thus, either 3,4-dihydroxytolazoline is a more efficacious inverse agonist at α2D-adrenergic receptors, or it acts on additional receptors. The bound position of the inverse agonist may physically block helix 6 from even its basal probability of moving to an active R* location. Because the addition of anR-(−)-hydroxyl group to the benzylic carbon converts 3,4-dihydroxytolazoline to a full agonist, the difference between producing a highly favorable versus a highly unfavorable influence on receptor/G protein interaction clearly can be subtle.

    Although our results indicate that hydroxyl group-dependent repositioning of helix 6 may be an important aspect of agonist-induced α2-adrenergic receptor activation, overall conformational events are likely to be more complex, involving additional regions of the receptor. This is especially true in light of the ability of Gi-coupled receptors such as the α2-receptor to also couple to GS in certain cellular environments (Duzic and Lanier, 1992; Jones et al., 1991; Eason et al., 1994). Thus, it appears that α2-receptors may exist in multiple agonist-induced active conformations that display unique G protein selectivity. Additional studies will be needed to determine how the structural features of agonist ligands can direct receptor signaling among these alternative G protein pathways.

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    Footnotes

    • Send reprint requests to: Dr. Richard C. Deth, Department of Pharmaceutical Sciences, 312 Mugar Hall, Northeastern University, 360 Huntington Ave., Boston, MA 02115. E-mail: r.deth{at}nunet.neu.edu

    • 1 This work was supported by U.S. Public Health Service Research Grant NIH-HL29847 (to R.C.D.).

    • Abbreviations:
      R*
      active conformation of the receptor
      GTPγS
      guanosine-5′-O-(3-thio)triphosphate
      EPI
      epinephrine
      UK14304
      5-bromo-N-(4,5-dihydro-1H-imidazol-2-yl)-6-quinoxalinamine
      BHT-933
      2-amino-6-ethyl-4,5,7,8-tetrahydro-6H-oxalo[5,4-d]azepin dihydrochloride
      • Received May 28, 1999.
      • Accepted October 26, 1999.
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