Abstract
To investigate the role of G-protein βγ subunits in δ-opioid signal transduction, we have transfected Chinese hamster ovary (CHO) cells stably expressing the human δ-opioid receptor (hDOR/CHO cells) with the Gα-subunit of transducin-1 (hDOR/T1/CHO). Inhibition of forskolin-stimulated adenylyl cyclase and phospholipase Cβ (PLCβ) activation was measured in each of these cell lines. Because PLCβ3 activation in CHO cells has been shown to be mediated by free Gβγ subunits derived from Gαi/o, the action of transducin was confirmed by measuring a significant attenuation of (+)-4-[(αR)-α-((2S,5R)-4-Allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N,N-diethylbenzamide (SNC80)-mediated maximal inositol-1,4,5-trisphosphate formation in transducin-expressing cells of 59 ± 12% compared with control cells. The acute inhibition of cAMP formation was unchanged between control and transducin-expressing cells. We show that cells stably expressing the human δ-opioid receptor exhibited a pertussis toxin-sensitive cAMP overshoot in response to chronic application of SNC80. After 4 h of pretreatment and washout with 100 nM SNC80, maximal forskolin-stimulated cAMP formation in hDOR/CHO cells increased by 229 ± 37% compared with buffer-treated cells. Expression of transducin in hDOR/CHO cells diminished this response: hDOR/T1/CHO cells showed no significant change in maximal forskolin-stimulated cAMP formation after pretreatment and washout. These data indicate that the expression of α-transducin scavenges free Gβγsubunits and, furthermore, that free Gβγ subunits play a role in opioid-mediated PLCβ activation and adenylyl cyclase superactivation, but not acute inhibition of forskolin-stimulated cAMP formation in hDOR/CHO cells.
Of the three distinct opioid receptors that have been identified (μ, κ, and δ), the δ-opioid receptor seems to have the most promise for mediating analgesia while minimizing such adverse side effects as addiction, respiratory depression, and constipation (Rapaka and Porreca, 1991; Quock et al., 1999). In 1994, the human δ-opioid receptor (hDOR) was cloned (Knapp et al., 1994; Simonin et al., 1994) and subsequently stably transfected into CHO cells for characterization (Malatynska et al., 1995). We have shown that the hDOR in this cell line exhibits a typical inhibition of forskolin-stimulated cAMP accumulation and a cAMP overshoot after chronic opioid agonist pretreatment. In this regard, Chinese hamster ovary cells stably expressing the human δ-opioid receptor (hDOR/CHO) have proven to be useful for studying adenylyl cyclase (AC) superactivation by δ-opioid-selective agonists (Malatynska et al., 1996).
The adenylyl cyclase superactivation phenomenon was first noted by Sharma et al. (1975). In their studies, NG108–15 cells, which express primarily mouse δ-opioid receptors, exhibited an inhibition of PGE1-stimulated cAMP formation in response to acute treatment with morphine, whereas chronic morphine treatment followed by removal resulted in an increased PGE1-stimulated cAMP accumulation. This opioid-mediated cAMP overshoot has since been demonstrated in a variety of systems as reviewed by Nestler (1993).
Although the original finding took place more than 25 years ago, the molecular mechanism of adenylyl cyclase superactivation has yet to be entirely elucidated. What has been shown is the involvement of specific adenylyl cyclase isoforms, G-protein α and βγ subunits, and kinases, depending on the system being studied (Avidor-Reiss et al., 1995; Ammer and Schulz, 1998; Chakrabarti et al., 1998a,b). In fact, the molecular mechanism of AC superactivation remains elusive and seems to be somewhat tissue-dependent: Ammer and Schulz (1998) have demonstrated the requirement for activated Gαsto show a cAMP overshoot in opioid-withdrawn NG108–15 cells (Ammer and Schulz, 1998). Chakrabarti et al. (1998a) have shown that in guinea pig ileum longitudinal muscle myenteric plexus preparations, chronic in vivo pretreatment with morphine results in a type of cAMP overshoot wherein a reversal from inhibition to stimulation of AC is observed (Chakrabarti et al., 1998a), and that activation of protein kinase C is required for ACII phosphorylation by the same pretreatment (Chakrabarti et al., 1998b). Furthermore, they were able to demonstrate an up-regulation of ACII (Chakrabarti et al., 1998b), which is an AC that has been shown to be conditionally stimulated by Gβγ and Gαs (Sunahara et al., 1996). It is likely that, in this system, these events contribute to the cAMP overshoot caused by chronic morphine. In contrast, a CHO cell line stably transfected with the rat μ-opioid receptor exhibits AC superactivation that is unaffected by cycloheximide pretreatment, indicating that no up-regulation of AC or Gαs occurs in this system (Avidor-Reiss et al., 1995). These results indicate that although the cAMP overshoot phenomenon first demonstrated by Sharma et al. (1975) is common, the series of events leading up to this response can be variable. Some aspects of the cAMP overshoot, however, seem to be consistent, such as signaling through Gβγ.
Chronic opioid agonist-mediated adenylyl cyclase superactivation and the resultant cAMP overshoot have long been considered in vitro models for studying opioid tolerance and withdrawal (Sharma et al., 1975,1977; Nestler, 1993; Malatynska et al., 1996; Ammer and Schulz, 1998). Although opioid-activated Gi/o-protein α subunits acutely inhibit cAMP formation, it has been hypothesized that the liberated Gβγ subunits play a role in the compensatory increase in forskolin-stimulated cAMP formation. One method for examining this hypothesis is to interrupt signaling through Gβγ.
It has been shown that pertussis toxin-sensitive Gi/o-coupled receptors can activate phospholipase Cβ2 (PLCβ2) and PLCβ3 via liberated Gβγ subunits in various cell lines including CHO cells, and that CHO cells express PLCβ3exclusively (Camps et al., 1992; Dickenson and Hill, 1998). Here, we are demonstrating a pertussis toxin-sensitive SNC80-mediated increase in IP1 formation in hDOR/CHO cells, indicating that δ-opioid receptor activation leads to PLCβ stimulation through Gβγ. Therefore, one would expect the SNC80-mediated increase in IP1 formation in hDOR/CHO cells to be attenuated by interfering with Gβγ signaling (Freund et al., 1994; Murthy and Makhlouf, 1996; Zhang et al., 1996).
A variety of in vitro methods has been employed to investigate the effects of signal transduction through Gβγsubunits, including antisense knockdown and scavenge of free Gβγ. Because of its established role in Gβγ scavenging by expression in a variety of systems (Federman et al., 1992; Avidor-Reiss et al., 1996; Yoshimura et al., 1996; Selbie et al., 1997; Olianas and Onali, 1999), we chose to use the cloned G-protein α subunit of retinal transducin-1 (α-transducin) to scavenge free Gβγsubunits. We are demonstrating the importance of free Gβγ subunits in mediating PLCβ3 activation and adenylyl cyclase superactivation by stably transfecting α-transducin, into CHO cells stably expressing the human δ-opioid receptor (thereby creating hDOR/T1/CHO cells). It was our hypothesis that because both PLCβ3 activation and adenylyl cyclase superactivation are dependent on Gβγ, the stable expression of α-transducin in hDOR/CHO cells will result in a decreased maximal SNC80-mediated IP1 formation and a loss of the cAMP overshoot after chronic opioid agonist pretreatment.
Materials and Methods
Preparation of hDOR/T1/CHO Cells and Cell Culture.
hDOR/CHO (Malatynska et al., 1995) were transfected with a pertussis toxin-insensitive mutant of the α-subunit of transducin-1 (hDOR/T1/CHO) as described previously (Varga et al., 2000). Both hDOR/CHO and hDOR/T1/CHO cells were plated in 24-well polystyrene plates (Costar, Cambridge, MA) at a density of 65,000 cells per well and grown in a humidified incubator at 37°C (5% CO2) for 48 h in Ham's F-12 medium (Invitrogen, Carlsbad, CA) with 10% fetal calf serum before assay.
Forskolin-Stimulated cAMP Formation.
This was done following a method modified from Gilman (1970). The growth medium was aspirated and replaced with serum-free Iscove's modified Dulbecco's medium (IMDM) (Invitrogen). In experiments involving opioid agonist pretreatment, either IMDM or 100 nM SNC80 (Tocris, Ballwin, MO) in IMDM was added to cells for 4 h. After this chronic treatment, the cells were washed three times with fresh IMDM, 15 min per wash. The IMDM was then aspirated and replaced with 5 mM 3-isobutyl-1-methylxanthine (IBMX; Sigma Chemical, St. Louis, MO) in IMDM. Adenylyl cyclase was stimulated with water-soluble forskolin [7-deacetyl-7-(O-N-methylpiperazino)-γ-butyryl, diHCl; Calbiochem, San Diego, CA]. Doses of SNC80 with 100 μM forskolin (agonist dose-response curve) or doses of forskolin alone (forskolin dose-response curve) were added to the wells, which were then placed in a humidified incubator at 37°C (5% CO2) for 20 min. The forskolin was then aspirated and replaced with 150 μl of ice-cold Tris/EDTA buffer (50 mM Tris HCl, 4 mM EDTA, pH 7.5) to terminate the reaction. Each well was scraped to dislodge the cells, and the contents of each well were transferred to Microfuge tubes (Beckman Coulter, Fullerton, CA) and boiled for 10 min to lyse the cells. Lysate was centrifuged and 50 μl of supernatant was incubated with 50 μl of [3H]cAMP (final concentration, 4 nM; PerkinElmer Life Sciences, Boston, MA) and 100 μl of protein kinase A (final concentration, 30 μg/ml; Sigma Chemical, St. Louis, MO) as a cAMP binding protein. cAMP standards were run in parallel. After a 2-h incubation at 4°C, activated charcoal (26 mg/ml) (NORIT, Amersfoort, The Netherlands) was added to adsorb free cAMP. The mixture was then centrifuged, and 200 μl of supernatant was counted in EcoLite (ICN Pharmaceuticals, Costa Mesa, CA) scintillation fluid.
Pertussis Toxin Pretreatment of Cells Assayed for cAMP.
hDOR/CHO and hDOR/T1/CHO cells were pretreated for 18 to 24 h with either serum-free IMDM or 50 to 75 ng/ml pertussis toxin (List Biological, Campbell, CA) in serum-free IMDM. For experiments involving the superactivation pretreatment protocol, either IMDM or 100 nM SNC80 in IMDM was added to the appropriate wells for the final 4 h of pertussis toxin pretreatment. Cells were then washed once with fresh IMDM before the cAMP formation assay as described above.
IP1 Formation.
This was performed following a method adapted from Berridge and Irvine (1984). In 24-well plates, growth medium was aspirated and replaced with serum-free IMDM containing 0.2 μM myo-[3H]inositol (PerkinElmer Life Sciences) for 18 h. The cells were washed in 1 ml fresh IMDM for 1 h. The medium was then replaced with IMDM containing 10 mM LiCl (Sigma Chemical, St. Louis, MO) for 10 min. Concentrations of SNC80 in IMDM were added for 1 h, then replaced with 0.5 ml of ice-cold methanol to terminate the reaction. The wells were scraped and the contents were transferred to a chloroform water mixture (1 ml and 0.5 ml, respectively) for inositol phosphate extraction. After centrifugation, the extracts were loaded onto AG1-X8 resin (formate form) (Bio-Rad) and washed three times with water followed by three washes with a solution of sodium tetraborate and formic acid (5 mM and 60 mM, respectively) to elute free inositol. IP1 was then eluted with a solution of formic acid and ammonium formate (0.1 M and 0.2 M, respectively). Eluent was counted in 16 ml of EcoLite scintillation fluid.
Pertussis Toxin Pretreatment of Cells Assayed for IP1.
In IP1 formation experiments utilizing pertussis toxin, hDOR/CHO cells were pretreated with either 0.2 μM myo-[3H]inositol in serum-free IMDM or 0.2 μM myo-[3H]inositol with 50 ng/ml pertussis toxin in IMDM for the 18-h loading phase. Cells were then washed once and assayed for IP1formation as described above.
Data Analysis.
Data were analyzed using Prism v3.02 (GraphPad, San Diego, CA) and are represented as mean ± S.E. To fit the data to a sigmoidal dose-response relationship, the following equation was used: Y = Bottom + (Top-Bottom) / (1 + 10[(LogEC50 − X) × Hillslope)], where X is the logarithm of the drug concentration and Y is the response. Statistical differences were ascertained by the Student'st test on the regression variables (top, bottom, logEC50) as determined by a nonlinear regression analysis where the Hill coefficient was fixed to unity. In the inhibition of forskolin-stimulated cAMP formation experiments, results are normalized to 100% in the absence of SNC80 (top of the curve). In the adenylyl cyclase superactivation experiments, the overshoot in each cell line (comparison of the two curves representing each cell line pretreated with IMDM or SNC80) is normalized to 100% of maximal cAMP formation in the IMDM-pretreated cells (top of the curve for IMDM-pretreated cells). The basal adenylyl cyclase activities for the hDOR/CHO and hDOR/T1/CHO are close to 0 pmol of cAMP/million cells. The 10−4 M forskolin-stimulated value for hDOR/CHO is 307 ± 72 pmol of cAMP/million cells and 374 ± 180 pmol of cAMP/million cells for hDOR/T1/CHO cells. Using the Student'st test to compare these figures, a value of 0.67 is obtained, indicating no significant difference. Results of the IP1 formation experiments are normalized to 100% of basal IP1 formation. The basal IP1 formation values for the two cell lines are 589 ± 460 cpm for the hDOR/CHO cells, and 1012 ± 90 cpm for the hDOR/T1/CHO cells. Using the Student's t test to compare these values, a value of 0.41 is obtained, indicating no statistically significant difference.
Results
The Effect of Pertussis Toxin on SNC80-Mediated IP1Formation in hDOR/CHO Cells.
In hDOR/CHO cells, SNC80-mediated stimulation of IP1 formation was sensitive to pertussis toxin (Fig. 1). SNC80 stimulated IP1 formation with an EC50 value of 21 ± 13 nM and anE max value of 311 ± 12%. After 18 h of pretreatment with 50 ng/ml pertussis toxin, hDOR/CHO cells showed no significant stimulation of IP1formation; consequently, no further statistics were analyzed on this data set.
The Effect of α-Transducin Expression in hDOR/CHO cells on SNC80-Mediated IP1 Formation.
Stable α-transducin expression in these cells resulted in a significant attenuation of maximal SNC80-mediated IP1 formation. hDOR/CHO cells displayed an E max value of 361 ± 17% of basal and hDOR/T1/CHO cells showed a maximum of 206 ± 9% of basal (n = 3; p < 0.001) This represents a significant attenuation of theE max value by 59 ± 12% by the expression of α-transducin (Fig. 2).
The Effect of Pertussis Toxin Pretreatment on SNC80-Mediated Inhibition of Forskolin-Stimulated cAMP Formation in hDOR/CHO Cells.
Pertussis toxin abated SNC80-mediated inhibition of forskolin-stimulated cAMP formation. SNC80 inhibited cAMP formation in untreated hDOR/CHO cells by 96 ± 9% with an EC50 value of 1.7 ± 1 nM, whereas there was no measurable inhibition after 50 to 75 ng/ml pertussis toxin pretreatment (n = 3; p < 0.001) (Fig.3).
The Effect of α-Transducin Expression in hDOR/CHO Cells on SNC80-Mediated Inhibition of Forskolin-Stimulated cAMP Formation.
Expression of α-transducin in hDOR/CHO cells (hDOR/T1/CHO cells) did not affect acute SNC80-mediated inhibition of forskolin-stimulated cAMP formation (Fig. 4). hDOR/CHO cells were inhibited 98 ± 11% and hDOR/T1/CHO cells were inhibited 97 ± 15%. The EC50 value for SNC80 was 1.6 ± 1 nM in hDOR/CHO cells and 1.6 ± 2 nM in hDOR/T1/CHO cells. There was no significant difference in these curves.
The Effect of Pertussis Toxin Pretreatment on Adenylyl Cyclase Superactivation in hDOR/CHO Cells.
The cAMP overshoot is sensitive to pertussis toxin. In the absence of pertussis toxin, SNC80-pretreated cells displayed a significant cAMP overshoot of 355 ± 165%, which was abolished by pertussis toxin pretreatment (n= 10; p < 0.05) (Fig.5).
The Effect of α-Transducin Expression in hDOR/CHO Cells on Adenylyl Cyclase Superactivation.
hDOR/CHO cells that were pretreated for 4 h with 100 nM SNC80, then washed three times, exhibited greater forskolin-stimulated cAMP formation than IMDM-treated control cells (Fig. 6). Forskolin-stimulated cAMP formation (10−4 M) in IMDM-pretreated cells was normalized to 100%. IMDM-pretreated cells exhibited an E max value of 164 ± 8% (n = 24). SNC80-pretreated cells were significantly stimulated 376 ± 12% of IMDM-pretreated control, representing a cAMP overshoot of 229 ± 37% (n = 22;p < 0.001). The maximal forskolin-stimulated cAMP formation of CHO cells coexpressing the human δ-opioid receptor and α-transducin (hDOR/T1/CHO) was likewise normalized to 100% of 10−4 M forskolin-stimulated, IMDM-pretreated control cells. The E max value of IMDM-pretreated hDOR/T1/CHO cells was 166 ± 14% and SNC80 pretreated hDOR/T1/CHO cells showed 163 ± 8% maximal stimulation (n = 4) (Fig. 6). The cAMP overshoot in the presence of α-transducin was not statistically significant.
Discussion
The human δ-opioid receptor stably expressed in CHO cells couples to inhibition of forskolin-stimulated adenylyl cyclase through Gαi/o, and to activation of PLCβ, presumably through Gβγ. These Gβγ subunits are derived from Gαi/o proteins, as evidenced by the complete block of the PLCβ response by pertussis toxin pretreatment. In addition, α-transducin expression in hDOR/CHO cells results in a decreased SNC80-stimulated IP1 formation, which is evidence for scavenge of Gβγ in this system. Concomitant with the attenuation of PLCβ3 activation, a reduction in the cAMP overshoot is observed, without any change in SNC80-mediated acute inhibition of adenylyl cyclase. This indicates that α-transducin selectively interferes with signaling through Gβγ in hDOR/T1/CHO cells and that Gβγ is required for AC superactivation.
The transfection of hDOR/CHO cells with α-transducin was successful (hDOR/T1/CHO), as evidenced by an increase in the intensity of a 41-kDa band over that found in untransfected hDOR/CHO cells and by functional studies demonstrating a novel coupling of α-transducin to the human δ-opioid receptor (using guanosine-5′-O-(3-[35S]thio)triphosphate binding; Varga et al., 2000). When the human δ-opioid receptor is stimulated by an agonist, Gi/o proteins are activated, releasing activated Gαi/o, and free Gβγ subunits. Acute SNC80 fully inhibits forskolin-stimulated adenylyl cyclase via activated Gαi/o subunits, as this response is blocked by pretreatment with pertussis toxin (Fig. 3). Because no difference is observed in the acute inhibition of AC by SNC80 in the presence or absence of α-transducin (Fig. 4), α-transducin does not seem to interfere with δ-opioid receptor coupling to or signal transduction through Gαi/o.
α-Transducin presumably acts as a free Gβγscavenger and has been used as such on numerous occasions (Federman et al., 1992; Avidor-Reiss et al., 1996; Yoshimura et al., 1996; Selbie et al., 1997; Olianas and Onali, 1999). One method for measuring the Gβγ scavenging ability of α-transducin is to determine the loss of coupling between Gβγand a known effector, such as the PLCβ1 or PLCβ3 enzyme, in the presence of α-transducin. Fortuitously, CHO cells have been shown to exclusively express the Gβγ-sensitive PLCβ3: Dickenson and Hill (1998) demonstrated that of PLCβ isoforms 1 to 4, only the PLCβ3isoform is expressed in CHO cells (Dickenson and Hill, 1998). Evidence for the coupling of this enzyme to Gβγ was provided by the observation that the pertussis toxin-sensitive [3H]inositol phosphate accumulation byN 6-cyclopentyladenosine in CHO cells transfected with the adenosine A1 receptor was attenuated in the presence of the Gβγscavenger, the C-terminal peptide of the β-adrenergic receptor kinase-1 (495–689). Furthermore, [d-Pen2,d-Pen5] enkephalin, a δ-opioid-selective agonist, has been shown to selectively activate PLCβ3 (over PLCβ1,2,4) in a pertussis toxin-sensitive manner in intestinal smooth muscle via Gβγusing anti-Gβ and various anti-PLCβ antibodies to interrupt signaling (Murthy and Makhlouf, 1996). In our hDOR/T1/CHO cells, Gβγ scavenge was demonstrated by the observed decrease in the maximal SNC80-mediated IP1 formation in the presence of α-transducin (Fig. 2). The above observations substantiate the validity of the coupling of the human δ-opioid receptor to PLCβ3 via Gβγ in the heterologous CHO expression system used here and indicate that the hDOR/CHO system actually mirrors what is observed in a naturally occurring intact system.
Four-hour pretreatment with a maximally stimulating concentration of the full agonist, 100 nM SNC80, followed by removal of the agonist by repeated washes results in an increased AC activity. This response can be blocked by pretreatment with pertussis toxin (Fig. 5). These data indicate that Gαi/o subunits are required for AC superactivation. However, the Gαi/o subunits do not necessarily mediate the AC superactivation.
The significant attenuation of adenylyl cyclase (AC) superactivation by α-transducin expression clearly demonstrates the requirement for Gβγ in this process (Fig. 6). Because both PLCβ3 and AC superactivation are mediated by Gβγ, one possibility is that in the hDOR/CHO system, PLCβ3 activation is upstream of the modification that results in the AC superactivation. This could occur through a number of pathways, but we have found that SNC80-induced ACVI [32P] incorporation (Varga et al., 1999) follows a time course similar to that of AC superactivation. This suggests that AC phosphorylation in this system may be the cause of the superactivation. It is conceivable, therefore, that the IP3 generated as a result of PLCβ3 activation increases intracellular calcium through release from internal stores to activate calmodulin and calcium calmodulin-dependent kinase or that the diacyl glycerol generated activates protein kinase C. Further studies are required to identify a potential kinase and its role in AC superactivation.
Another possibility is that the requirement for Gβγ in PLCβ3activation is independent of its requirement in AC superactivation. No consistent link between AC phosphorylation and AC superactivation has yet been found, which is in contradiction with the hypothesis in the preceding paragraph. Bayewitch et al. (1998) have demonstrated that ACVI, the only isoform of AC expressed in CHO cells (Varga et al., 1998) that has been shown to superactivate (Nevo et al., 1998), is directly inhibited by Gβγ (Bayewitch et al., 1998), and that chronic treatment with agonist leads to modifications in either the structure of the Gαiβγproteins or their compartmentalization (Bayewitch et al., 2000). Under these circumstances, the prediction is that there is constitutive Gβγ inhibitory tone on AC, which is reversed upon chronic treatment with agonist, and leads to the aforementioned observed increase in the activity of AC and the cAMP overshoot (Vogel et al., 2000). Therefore, it would be useful to determine which site in the ACVI molecule interacts with Gβγsubunits to inhibit its activity.
There is a subtle difference in the EC50 values for SNC80 between the stimulation of IP1formation (Figs. 1 and 2) and inhibition of forskolin-stimulated cAMP formation (Figs. 3 and 4). SNC80 seems to be about 10-fold less potent in stimulating PLCβ3 than in inhibiting AC. One explanation for this is that the interaction of Gαi/o with AC is of higher potency than the interaction of Gβγ with PLCβ3 or that more Gβγ is required to activate PLCβ than Gαi/o to inhibit AC.
In a previous study, we noted that the pertussis toxin-insensitive version of α-transducin used here was able to couple to the human δ-opioid receptor in hDOR/T1/CHO cells, as measured by an increased guanosine-5′-O-(3-[35S]thio)triphosphate binding (Varga et al., 2000). One consequence of such an interaction could be competition by α-transducin with endogenous G-proteins, thereby preventing any downstream effects mediated by endogenous G-proteins. This would serve to reduce PLCβ3activation and AC superactivation in much the same manner as a competitive antagonist at the receptor would. But at nanomolar potency, an acute inhibition of forskolin-stimulated AC activity is observed in the presence of α-transducin, which is identical to the inhibition seen in cells devoid of the scavenger (Fig. 4), which indicates that α-transducin is not interfering with signaling through endogenous Gαi/o. Therefore, the results of the acute inhibition experiments suggest that α-transducin selectively interferes with Gβγ signaling but has no effect on Gαi/o coupling.
We have demonstrated that coexpression of α-transducin with the human δ-opioid receptor diminishes the pertussis toxin-sensitive PLCβ activation by SNC80. This observation probably confirms the intended G-protein βγ scavenging property of α-transducin. Furthermore, although α-transducin does not seem to have any affect on acute SNC80-mediated inhibition of AC, its expression prevents chronic SNC80-induced AC superactivation. This indicates that Gβγ subunits are necessary for AC superactivation. By demonstrating the importance of Gβγ in AC superactivation, we are providing greater insight into the molecular mechanism of what is understood to be a model for tolerance to and withdrawal from opioids and potentially other agonists acting at Gi/o-coupled receptors.
Acknowledgments
We thank Sue Waite for her help in the preparation of this manuscript and Michelle Thatcher and Carol Haussler for their extensive assistance with maintenance of the cell cultures.
Footnotes
- Received April 9, 2001.
- Accepted August 13, 2001.
-
This work was supported in part by a grant from the Arizona Disease Control Research Commission and a training grant from the National Institute on Drug Abuse.
Abbreviations
- hDOR
- human δ-opioid receptor
- CHO
- Chinese hamster ovary
- AC
- adenylyl cyclase
- PLCβ
- phospholipase Cβ
- IP1
- inositol-1,4,5-trisphosphate
- SNC80
- (+)-4-[(αR)-α-((2S,5R)-4-Allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N,N-diethylbenzamide
- hDOR/CHO
- Chinese hamster ovary cells stably expressing the human δ-opioid receptor
- α-transducin
- Gα-protein subunit of transducin-1
- hDOR/T1/CHO
- Chinese hamster ovary cells stably expressing both the human δ-opioid receptor and α-transducin
- IMDM
- Iscove's modified Dulbecco's medium
- The American Society for Pharmacology and Experimental Therapeutics