Coexpression of -Opioid Receptors with µ Receptors in GH3 Cells Changes the Functional Response to µ Agonists from Inhibitory to Excitatory 2003年第63卷第1期 | 39康复网

Departments of Neurology (A.C., N.M., K.A.) and Psychiatry (C.E.), UCLA School of Medicine, Los Angeles, California; and Department of Pharmacology, the George Washington University, Washington, DC (M.L.D., T.G.H.)

Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

GH₃ cells show spontaneous activity characterized by bursts of action potentials and oscillations in [Ca²⁺]_i. This activity is modulated by the activation of exogenouslyexpressed opioid receptors. In GH₃ cells expressing only µ receptors(GH₃MOR cells), the µ receptor-specific ligand [D-Ala²,N-Me-Phe⁴,Gly⁵-ol]-enkephalin (DAMGO) inhibited spontaneous Ca²⁺ signaling by the inhibition of voltage-gated Ca²⁺ channels, activation of inward-rectifying K⁺ channels, and inhibition of adenylyl cyclase. In contrast, incells expressing both µ and receptors (GH₃MORDOR cells), DAMGOhad an excitatory effect on Ca²⁺ signaling that was mediated by phospholipase C and release ofCa²⁺ from intracellular stores. The excitatory effect of DAMGO wasalso inhibited by pretreatment with pertussis toxin. Despite theexcitatory effect on Ca²⁺ signaling, DAMGO inhibited Ca²⁺ channels and activated inward-rectifying K⁺ channels in GH₃MORDOR cells, although to a lesser extent thanin GH₃MOR cells. Long-term treatment with the receptor-specificligand [D-Pen²,D-Pen⁵]-enkephalin reduced the excitatory effect of DAMGO in the majorityof GH₃MORDOR cells and restored the inhibitory response to DAMGOin some cells. The inhibitory effect of somatostatin on Ca²⁺ signaling was not different in GH₃MORDOR versus GH₃MOR cells.These results indicate that interaction between µ- and -opioidreceptors causes a change in the functional response to µ ligands,possibly by the formation of a µ/ heterodimer with distinct functionalproperties.

Introduction

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Abstract
Introduction
Materials and Methods
Results
Discussion
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There is growing evidence that different types of opioid receptors, as well as other G protein-coupled receptors, may interactwithin individual cells to alter their pharmacological properties(Maggio et al., 1993; Traynor and Elliott, 1993; Quitterer andLohse, 1999; George et al., 2000; Gomes et al., 2000, 2001; Jordanet al., 2000; Yeo et al., 2001). Interaction between µ- and -opioidreceptor subtypes has been suggested by a variety of in vitroand in vivo evidence. In vivo evidence for µ/ receptor interactionsincludes observations that treatment with receptor-specificantagonists reduces tolerance and dependence in response to morphine(Abdelhamid et al., 1991). Morphine dependence is also alteredin -receptor knockout mice (Zhu et al., 1999) and in animalswhose receptors are selectively decreased with antisense oligonucleotides(Sanchez-Blazquez et al., 1997).

At present, it is not known whether these in vivo phenomena are caused by interactions between µ- and -opioid receptors inindividual cells, or whether different cell populations are involved.However, in vitro studies clearly show that µ- and -opioid receptorinteraction within individual cells results in significant alterationsin their pharmacology. Ligand-binding studies show that µ-specificligands alter the binding properties of -specific ligands andvice versa (George et al., 2000; Gomes et al., 2000). µ-Specificagonists and antagonists also potentiate mitogen-activated proteinkinase activity evoked by agonists in cells expressing bothµ and receptors, and -specific ligands potentiate mitogen-activatedprotein kinase activity evoked by µ agonists. These pharmacologicalproperties may be mediated by heterodimers of different opioidreceptor subtypes (Jordan and Devi, 1999; George et al., 2000;Gomes et al., 2000). Other evidence for µ/ receptor interactionincludes observations of a pertussis toxin-resistant inhibitionof adenylyl cyclase by the µ-receptor agonist DAMGO applied tocells expressing both µ and receptors but not µ or receptorsalone (George et al., 2000). In other studies, the interactionof µ and receptors stably expressed together in GH₃ cells produceda synergistic inhibition of adenylyl cyclase activity by µ- and-receptor agonists (Martin and Prather, 2001).

Despite the strong evidence for interaction between µ and receptors in individual cells, functional roles for this interactionhave not been clearly defined. We have used GH₃ cells, a prolactin-and growth hormone-secreting pituitary cell line, as a model forthe study of opioid-receptor function. These cells express multiplefunctional neurotransmitter receptors and voltage-gated ion channelsand have robust spontaneous activity characterized by bursts ofaction potentials, influx of Ca²⁺ through voltage-gated Ca²⁺ channels, and oscillations in intracellular Ca²⁺ concentration ([Ca²⁺]_i) (Charles et al., 1999). The spontaneous Ca²⁺ signaling of GH₃ cells provides a sensitive detection systemfor the effects of exogenously expressed opioid receptors (Piroset al., 2000). In this study, we used patch-clamp techniques andvideo imaging of [Ca²⁺]_i to show that the functional response to µ-receptor activationis altered by coexpression of receptors.

Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Cell Cultures. GH₃, GH₃MOR, and GH₃MORDOR cells were maintained in culture in Dulbecco's modified Eagle's medium/Ham's F12 media supplementedwith 5% fetal bovine serum, 5% horse serum, 100 IU/ml penicillin,and 100 µg/ml streptomycin in 25-mm² flasks. GH₃MOR cells stably transfected with the µ-opioid receptorwere selected by inclusion of 1 mg/ml geneticin (Piros et al.,1995). Inclusion of geneticin (1 mg/ml) and hygromycin (200 µg/ml)stably selected for GH₃MOR cells that were stably transfectedwith the receptor (Piros et al., 1996). Cells were passagedor transferred onto 35-mm dishes for use in electrophysiologicalexperiments or poly(D-lysine)-coated glass coverslips for fluorescenceimaging, on which they were grown for 1 to 5 days to a confluenceof approximately 60 to 80% beforeexperimentation.

Measurement of [Ca²⁺]. [Ca²⁺]_i was measured in 50 to 1000 individual cells in a microscopic field, depending on the magnification, with a time resolutionof 33 ms. Cells on glass coverslips were loaded with fura-2AMby incubation in 5 to 10 µM dye for 40 to 60 min. Cells were thenwashed and maintained in normal medium for 30 min before experimentation.Coverslips were excited with a mercury lamp through 340- or 380-nmbandpass filters, and fluorescence at 510 nm was recorded througha 20× objective with an silicon intensified tube or charge-coupleddevice camera to VHS videotape, optical memory disc recorder,or computer hard drive. Images were then digitized and subjectedto background subtraction and shading correction, after whichchange in fluorescence or [Ca²⁺]_i was calculated on a pixel-by-pixel basis, as described previously,by a frame grabber and image-analysis board (Data Translationor Axon Image Lightning board) using Axon Imaging Workbench software(Axon Instruments, Inc., Union City, CA) (Charles et al., 1999).

Calcium Signaling Analysis. The frequency of Ca²⁺ oscillations was quantified for each individual cell by counting the number of Ca²⁺ peaks over a 3-min interval using the Mini Analysis Program (Synaptosoft,Decatur, GA). An excitatory response, compared with an inhibitoryresponse, was defined as a greater than 50% increase or decreasein the frequency of Ca²⁺ oscillations for an individual cell. The percentages of cellsshowing excitatory or inhibitory responses in each experimentwere averaged, and p values for differences in the averages weredetermined using a Student's ttest.

Electrophysiology. The whole-cell patch-clamp (Axopatch 200A amplifier, Axon Instruments) technique was used to record currents from voltage-clampedGH₃, GH₃MOR, and GH₃MORDOR cells. Ca²⁺-channel activity was recorded with Ba²⁺ as the charge carrier. Cells were initially bathed in a solutioncontaining 140 mM NaCl, 2.8 mM KCl, 1 mM MgCl₂, 1 mM CaCl₂, and10 mM HEPES, pH 7.2. After the whole-cell configuration was established,the bath solution was replaced by one composed of 125 mM NaCl,5.4 mM CsCl, 10.8 mM BaCl₂, 1 mM MgCl₂, and 10 mM HEPES. Electrodescontained 120 mM CsCl, 10 mM EGTA, 1 mM MgCl₂, 3 mM Mg-ATP, and10 mM HEPES, pH 7.2 with CsOH. The potential difference betweenthe open electrode and the bath ground was zeroed before establishinga 1-Gohm resistance seal. Voltage-activated Ba²⁺ currents were recorded from cells depolarized from the holdingpotential of 80 to 0 mV for 80 ms at 10-s intervals. Whole-cellinwardly rectifying K⁺ (K_ir) channel current recordings were performed using an extracellularsolution containing 140 mM KCl, 4 mM MgCl₂, 1 mM CaCl₂, 10 mMHEPES, 7 mM glucose, and 5 × 10⁴ mM tetrodotoxin, pH 7.2 with KOH. Recording electrodes containeda solution composed of 140 mM KCl, 10 mM EGTA, 2 mM MgCl₂, 10mM HEPES, and 3 mM Mg-ATP, pH 7.2 with KOH. Opioid agonists orsomatostatin were bath-applied to cells clamped at 60 mV. Currentswere low-pass-filtered at 2 KHz and digitized (Digidata; AxonInstruments) at 10 KHz for storage on the hard drive of a Pentiumpersonal computer, after which analysis was performed using pCLAMP8software (AxonInstruments).

Electrophysiological Analysis. The significance of inhibition of Ba²⁺ currents by opioid ligands or somatostatin was determined using the Student's t testto compare the average of four current amplitudes averaged immediatelybefore drug application with those averaged immediately beforewashout. Differences were considered significant when p < 0.05.A similar approach was used to determine whether K_ir current activationby opioid ligands or somatostatin was significant. In many cases,there was a steady run-down of Ba²⁺ current amplitude or a run-up of inward current amplitude duringK_ir current recording. When this occurred, four points were usedimmediately before drug application and after complete drug washoutto carry out a linear extrapolation. Activation of K_ir currentsor inhibition of Ba²⁺ currents was considered significant if the average of four pointsimmediately before drug washout was significantly different fromthe equivalent values from the extrapolation (p < 0.05). Whensignificance was achieved, the amplitudes of Ba²⁺ current inhibition and K_ir current activation were calculatedrelative to the corresponding current amplitudes from thefit.

[³H]Diprenorphine Binding Assay. Binding assays were performed as described previously (Von Zastrow et al., 1993). Approximately 200,000 cells (determinedby counting in a hemocytometer) were placed in polyvinyl chloridemicrotiter plates (BD Biosciences, San Jose, CA) with 100 nM [³H]diprenorphine (21 Ci/mmol; Amersham Biosciences Inc., Piscataway,NJ) in a total volume of 100 µl. After incubation on ice for 60min, the mixture was harvested quickly in an M24RS harvester (BrandelInc., Gaithersburg, MD) using GT100 GF/B glass filters and washedwith ice-cold phosphate-buffered saline. After drying, the filterswere counted in a Beckman LS1600 scintillation counter using CytoScint(ICN Biomedicals, Inc Costa Mesa, CA). Nonspecific binding wasdetermined by performing radioligand binding in the presence of10 µM diprenorphine. DPDPE-specific [³H]diprenorphine binding was determined by incubation in [³H]diprenorphine in the presence of 10 µM DPDPE.

Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

DAMGO Inhibits Spontaneous Ca²⁺ Oscillations in GH₃MOR Cells. GH₃ cells show spontaneous Ca²⁺ oscillations that are generated by spontaneous depolarization resulting in the influx of Ca²⁺ through voltage-gated channels (Charles et al., 1999). The patternof Ca²⁺ signaling in individual cells is heterogeneous, as is their responseto the activation of membrane receptors. In GH₃ cells expressingonly the µ-opioid receptor (GH₃MOR cells), the µ-receptor agonistDAMGO inhibited spontaneous Ca²⁺ signaling (Fig. 1). DAMGO (100 nM) abolished Ca²⁺ oscillations in the majority of cells and reduced the frequencyof Ca²⁺ signaling in others Spontaneous Ca²⁺ signaling resumed in most cells 1 to 3 min after washout DAMGO.

fig.ommitted

DAMGO inhibits Ca²⁺ signaling in GH₃ cells expressing µ-opioid receptors. Raster plot of [Ca²⁺] versus time in a microscopic field of GH₃MOR cells. Each row represents an individual cell and [Ca²⁺]_i for each cell is indicated by grayscale (bar). The top tracing is a line trace of a representative individual cell. Individual cells show a heterogeneous pattern of spontaneous Ca²⁺ oscillations. Bath application of DAMGO inhibits Ca²⁺ oscillations in the majority of cells.

fig.ommitted

DAMGO has excitatory effects on Ca²⁺ signaling in GH₃ cells expressing both µ and receptors. Raster plot of F (~[Ca²⁺]_i) versus time in a microscopic field of GH₃MORDOR cells. Each row represents an individual cell: the top trace shows a representative individual cell. DAMGO evokes a concentration-dependent increase in the frequency of Ca²⁺ oscillations in GH₃MORDOR cells, whereas DPDPE reversibly inhibits Ca²⁺ oscillations.

fig.ommitted

Effects of somatostatin and opioids on Ca²⁺and K_ir channel activity are similar in GH₃MOR and GH₃MORDOR cells. A, percentage of cells responding with a reduction in Ba²⁺ current amplitude to somatostatin (SST; 1 µM, n = 18, 14, and 7 for GH₃, GH₃MOR, and GH₃MORDOR, respectively), DAMGO (1 µM, n = 5, 49, and 24, respectively), or DPDPE (1 µM, n = 14, 5, and 24, respectively). B, percentage of cells responding with an increase in inward K⁺ current to somatostatin (1 µM, n = 17, 25, and 16 for GH₃, GH₃MOR, and GH₃MORDOR, respectively), DAMGO (1 µM, n = 3, 20, and 9, respectively), or DPDPE (1 µM, n = 13, 23, and 29, respectively). C, the amplitude of Ba²⁺ current inhibition by somatostatin, DAMGO, or DPDPE is expressed as a percentage of the control Ba²⁺ current amplitude. Bars represent average data from at least four separate recordings. Error bars, ± S.E.M. There was a slight decrease in the Ba²⁺ current inhibition by DAMGO in GH₃MORDOR cells compared with GH₃MOR cells, but this decrease was not statistically significant. The difference between the effects of DAMGO and DPDPE on GH₃MORDOR cells were not statistically significant. D, the amplitude of inward K⁺ currents activated by somatostatin, DAMGO, or DPDPE is expressed in picoamperes (pA). Bars represent the average data from at least four separate recordings. Error bars, ± S.E.M. There was a significant (p < 0.05) reduction in the activation of K_ir currents in GH₃MORDOR cells compared with GH₃MOR cells. The difference between the effect of DAMGO and DPDPE on GH₃MORDOR cells was not statistically significant.

DAMGO Has an Excitatory Effect on Ca²⁺ Signaling in GH₃MORDOR Cells. GH₃MORDOR cells express both receptors and µ receptors with a ratio of approximately 11:1 (B_max for [³H]DPDPE binding = 3.45 pmol/mg of protein compared with B_max for[³H]DAMGO binding = 0.3 pmol/mg of protein) (Piros et al., 1996).We reported previously that the -specific ligand DPDPE inhibitsspontaneous Ca²⁺ signaling in cells expressing both the µ- and -opioid receptors(Piros et al., 2000). However, in contrast to the inhibition ofCa²⁺ signaling observed in GH₃MOR cells, DAMGO increased both baseline[Ca²⁺]_i and the frequency of Ca²⁺ oscillations in GH₃MORDOR cells This effectwas concentration-dependent, with a maximal response observedat 1 µM DAMGO.

fig.ommitted

Average percentage of cells showing excitatory versus inhibitory responses to DAMGO in GH₃MOR and GH₃MORDOR cells. An excitatory versus inhibitory response was defined as a greater than 50% increase or decrease in the frequency of Ca²⁺ oscillations for each individual cell. The number of cells showing each type of response was averaged over all experiments for a given condition (error bars represent standard deviation). In GH₃MOR cells, DAMGO had an inhibitory response in the majority of cells (n = 300 cells, 10 experiments), whereas in GH₃MORDOR cells, the response to DAMGO was predominantly excitatory (n = 360 cells, 12 experiments; p < 10⁸ for difference in either the percentage of inhibitory or excitatory response in GH₃MOR versus GH₃MORDOR cells). The excitatory response to DAMGO was inhibited by pretreatment with either thapsigargin (1 µM, n = 100 cells, three experiments; p < 10⁷) or U73122 (1 µM, n = 100 cells, three experiments; p < 0.001), and a greater percentage of cells showed an inhibitory response (p < 0.001 for thapsigargin, p < 0.005 for U73122). The excitatory response to DAMGO was also inhibited by pretreatment for 24 h with pertussis toxin (200 ng/ml, n = 120 cells, four experiments; p < 10⁸). Treatment of cells for 24 h with 10 µM DPDPE also inhibited the excitatory response to DAMGO (n = 150 cells in five experiments; p < 10⁶) and increased the percentage of cells showing an inhibitory response (p < 10⁴).

DAMGO Inhibits Ba²⁺ Currents and Activates K_ir Currents in GH₃MORDOR cells. We reported previously that µ receptors that are stably expressed in GH₃ cells inhibit L-type Ca²⁺ channels and adenylyl cyclase activity and activate K_ir channels(Piros et al., 1995, 1996, 2000). Despite its differential effecton Ca²⁺ signaling in GH₃MORDOR compared with GH₃MOR cells, DAMGO inhibitedBa²⁺ currents and activated K⁺ currents recorded from both GH₃MOR and GH₃MORDOR cells. The averageBa²⁺ current inhibition in response to DAMGO was reduced in GH₃MORDORcells compared with GH₃MOR cells, but this difference was notstatistically significant. The average K_ir current amplitude evokedby DAMGO was reduced to a statistically significant (p < 0.05)degree in GH₃MORDOR versus GH₃MOR cells. DAMGO had no effect oncurrents recorded from untransfected GH₃ cells that lack opioidreceptors but contain endogenous somatostatin receptors that coupledto Ca²⁺ and K_ir channels. Despite the fact that thereare more than 10-fold more than µ receptors in GH₃MORDOR cells(Piros et al., 1996), the degree of Ba²⁺ current inhibition and K_ir channel activation by the DAMGO (1µM) and DPDPE (1 µM) was not significantly different . Furthermore, the activation of K_ir currents by the twoagonists was not additive, suggesting the involvement of similarsignaling mechanisms (data not shown). These data indicate thatalthough DAMGO retains some inhibitory effect via Ca²⁺ and K_ir channels in cells expressing both µ and receptors,this inhibitory effect is overcome by a simultaneous excitatoryeffect to result in an increase in baseline [Ca²⁺]_i and in the frequency of Ca²⁺oscillations.

The Excitatory Effect of DAMGO on Ca²⁺ Signaling in GH₃MORDOR Cells Is Abolished by Pretreatment with Thapsigargin or U73122. To determine the mechanism of the excitatory effect of DAMGO on GH₃MORDOR cells, we used the endoplasmic reticulum Ca²⁺ pump-inhibitor thapsigargin to deplete releasable intracellularCa²⁺ stores. Pretreatment with thapsigargin (1 µM) for 5 min abolishedthe excitatory effect of DAMGO on Ca²⁺ signaling in the majority of GH₃MORDOR cells and revealed a smallbut significant inhibitory effect . A similar effect wasobserved in cells pretreated with the phospholipase C inhibitorU73122 . These results indicate that the excitatoryeffect of DAMGO is mediated by the activation of phospholipaseC and subsequent release of Ca²⁺ from intracellular Ca²⁺ stores. The inhibitory response to DAMGO after U73122 or thapsigarginpretreatment is consistent with unveiling of a G_i/o-mediated inhibitionof Ca²⁺ signaling when the excitatory response to DAMGO isblocked.

The Excitatory Effect of DAMGO on Ca²⁺ Signaling in GH₃MORDOR Cells Is Abolished by Pretreatment with Pertussis Toxin. To investigate the role of G_i/G_o in the excitatory response to DAMGO in GH₃MORDOR cells, we treated cells for 24 h with pertussistoxin (200 ng/ml) before the application of DAMGO. A significantlyreduced percentage of cells pretreated with pertussis toxin showedan excitatory response to DAMGO compared with untreated cells

Somatostatin Inhibits Ca²⁺ Signaling in a Similar Fashion in GH₃, GH₃MOR, and GH₃MORDOR Cells. GH₃ cells express somatostatin receptors, and activation of these receptors inhibits Ca²⁺ channels and adenylyl cyclase via G_i/o-coupled mechanisms (Piroset al., 1995, 1996, 2000). Somatostatin (10 nM-1 µM) significantlyinhibited or abolished spontaneous Ca²⁺ oscillations in GH₃ cells. To determine whether the expressionof opioid receptors individually or in combination altered thefunctional response to a different G protein-coupled receptor,we investigated the response to somatostatin in GH₃, GH₃MOR, andGH₃MORDOR cells. We found that the inhibitory effect of somatostatin(100 nM) was not significantly different in any of these cells(n = 4 coverslips for each cell type, data not shown). These resultsindicate that the Ca²⁺-signaling response to at least one other G_i/o-coupled receptoris not significantly altered by the expression of µ- and -opioidreceptors in GH₃cells.

Long-Term Treatment with DPDPE Restores the Inhibitory Response of Some GH₃MORDOR Cells to DAMGO. Long-term treatment with DPDPE may reduce the numbers of receptors by multiple mechanisms, including increased internalizationand decreased expression (Prather et al., 1994b; Jordan and Devi,1999). We found that long-term treatment of GH₃MORDOR cells for24 h with 1 µM DPDPE resulted in an 86 ± 6% reduction (n = 4)in DPDPE-specific [³H]diprenorphine binding. Short-term treatment with DPDPE for 2min had no significant effect on DPDPE-specific [³H]diprenorphine binding. We also found that after treatment with1 µM DPDPE for 24 h, exposure to DAMGO had an excitatory effectin only a minority of cells and, in fact, either abolished spontaneousCa²⁺ oscillations or reduced their frequency in 20 to 30% of GH₃MORDORcells. In contrast, less than 5% of untreatedGH₃MORDOR cells showed an inhibitory response to DAMGO.

fig.ommitted

. Long-term treatment with DPDPE modulates the excitatory response to DAMGO. In cells treated with 10 µM DPDPE for 24 h, DAMGO does not evoke an excitatory response as in untreated GH₃MORDOR cells but instead has an inhibitory effect in approximately 20% of cells

Discussion

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Abstract
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Materials and Methods
Results
Discussion
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Our results show that coexpression of receptors with µ receptors changes the response to DAMGO from an inhibition to a stimulationof Ca²⁺ signaling. The excitatory response to DAMGO in GH₃MORDOR cellswas inhibited by the inhibition of phospholipase C with U73122or by the depletion of intracellular Ca²⁺ stores with thapsigargin, consistent with a Gq-mediated activationof PLC as the pathway for the excitatory response. The changein the response to DAMGO induced by -receptor expression thereforeseems to involve differential coupling to different Gproteins.

It is possible that the expression of multiple opioid-receptor subtypes, in combination with a limited pool of G proteins,causes the "switching" of specific receptors from one G proteinto another (Prather et al., 1994a; Quitterer and Lohse, 1999;Sanchez-Blazquez et al., 2001; Yeo et al., 2001). Because GH₃MORDORcells express receptors and µ receptors at an 11:1 ratio (Piroset al., 1996; Prather et al., 2000), it is possible that the receptors occupy the majority of G_i/o proteins, causing µ receptorsto "switch" to G_q. However, evidence against this mechanism isthe observation that the response to somatostatin does not seemto be altered by the level of expression of different opioid receptors,suggesting that the function of other G_i-coupled receptors isnot altered by the coexpression of opioid receptors. Furthermore,the pattern of µ-receptor coupling to G_i/o protein subtypes isnot changed in GH₃MORDOR cells compared with GH₃MOR cells, despitethe presence of receptors in the former (Martin and Prather,2001). Coupling of µ receptors to Ca²⁺ channels and K_ir channels is also retained in the GH₃MORDORcells.

Another potential mechanism for this phenomenon is the formation of hetero-oligomeric complexes that have unique functionalproperties. Opioid receptor heterodimers have been reported incells either endogenously or exogenously expressing differenttypes of opioid receptors (Jordan and Devi, 1999; George et al.,2000; Gomes et al., 2000). Our results could be explained by theformation of µ/ heterodimers with functional properties distinctfrom those of either homomeric µ or receptors. In this scenario,µ receptors would exist primarily (but not exclusively) in a heterodimerconfiguration because of the preponderance of receptors in GH₃MORDORcells. DAMGO would therefore primarily activate heterodimers thatare coupled to G_q, leading to an excitatory response. DPDPE wouldprimarily activate monomeric receptors or homodimers, explainingthe inhibitory response. Also, DPDPE may not activate heterodimersbecause of structural specificity of this configuration, as suggestedby Gomes et al. (2000).

The pertussis toxin sensitivity of the excitatory response to DAMGO suggests an interaction between G_i/o and G_q Similar interactions between G_i/o- and G_q-coupled receptors withinindividual cells have been reported for a variety of receptortypes (Quitterer and Lohse, 1999). In cases in which G_i/o-coupledreceptors evoke an increase in [Ca²⁺]_i, the majority of studies support a mechanism by which subunitsreleased by G_i/o activation subsequently activate phospholipaseC (Quitterer and Lohse, 1999; Yoon et al., 1999), although onestudy suggested that subunits may act downstream from PLC (Yeoet al., 2001). Possible pathways for the effects of the subunitsinclude a direct activation of PLC (Camps et al., 1992), or anactivation of PLC that requires interaction with G_q (Quittererand Lohse, 1999; Chan et al., 2000). Direct activation of PLCby subunits seems less likely given that in most cells, theG_i/o-mediated release of Ca²⁺ only occurs if there is coactivation of G_q-coupled receptors.We propose that in GH₃MORDOR cells, DAMGO-evoked activation ofPLC via G_q requires subunits contributed by activation of G_i/o, as has been proposed for other cell types (Quittererand Lohse, 1999; Chan et al., 2000). Simultaneous activation ofboth G_q and G_i/o could be achieved by the binding of DAMGO toµ receptors in both heteromeric and homomeric configurations.

fig.ommitted

Schematic diagram of proposed signaling mechanisms involved in response to DAMGO and DPDPE in GH₃ cells expressing opioid receptors. The excitatory response to DAMGO in GH₃MORDOR cells is sensitive to pertussis toxin (PTX) as well as to U73122 and thapsigargin (TG). The diagram (adapted from Quitterer and Lohse, 1999) indicates signaling mechanisms that are consistent with these results.

Opioid receptors generally have inhibitory effects mediated by their coupling through pertussis toxin-sensitive G_i/o proteinsto adenylyl cyclase, Ca²⁺ channels, and K⁺ channels (Piros et al., 1995, 2000; Williams et al., 2001). However,in some cells, opioids may have direct stimulatory effects, viaeither the rlease of Ca²⁺ from inositol phosphate-3-sensitive stores or the stimulationof Ca²⁺ entry (Jin et al., 1992; Smart et al., 1995; Smart and Lambert,1996; Spencer et al., 1997; Yoon et al., 1999; Chen et al., 2000).In other cells, opioid-receptor activation does not evoke an increasein [Ca²⁺]_i on its own , but it does potentiate Ca²⁺ signaling stimulated by other G_q-coupled receptors (Chen et al.,2000; Yeo et al., 2001). Each of the cell types in which opioidshave been reported to evoke an increase in [Ca²⁺]_i express both µ and receptors. This correlation suggests thatµ/ receptor interactions may be involved in an excitatory responsetoopioids.

An involvement of G_q and PLC in the antinociceptive effects of -2 agonists in mice has been reported (Sanchez-Blazquez andGarzon, 1998). This result is particularly interesting in lightof the conclusion of Gomes et al. (2000), stating that -2 agonistsactivate µ/ heterodimers. Additional evidence of a role for PLCin opioid-induced analgesia comes from PLC B3 knockout mice, inwhich a markedly increased sensitivity to antinociceptive effectsof morphine has been observed (Xie et al., 1999). An alterationof opioid-receptor levels that leads to activation of PLC couldtherefore result in both short- and long-term changes in the responseto opioidligands.

Regardless of the exact mechanisms involved, the observations that opioids are capable of both inhibitory and excitatory actionson cells and that these actions depend on the level of receptorexpression within cells have multiple significant implications.First, ligands or ligand combinations that differentially activateµ versus receptors may have different analgesic effects determinedfrom the µ/ receptor interactions and excitatory versus inhibitoryactions. Similarly, the development of tolerance and dependencemay be a function of relative µ- versus -receptor activation.We found that long-term exposure of GH₃MORDOR cells to DPDPE causeda decline in the excitatory response to DAMGO. One explanationfor this result is that long-term exposure to the -receptor agonistreduces the numbers of receptors in the membrane, thereby reducingthe excitatory µ/ receptor interaction. Long-term treatment withopioid agonists has been reported to reduce receptor the numberby multiple mechanisms, including increased internalization anddecreased expression (Prather et al., 1994b; Jordan and Devi,1999). Consistent with these previous reports, we found that long-termtreatment with DPDPE resulted in a significant reduction in DPDPE-specific[³H]diprenorphine binding in GH₃MORDOR cells. Long-term exposureto opioids that alter the ratio of µ- versus -receptor expressioncould therefore have dramatic effects on the function of opioidreceptors, both via their response to opioid ligands and alsopotentially via constitutive activation of these receptors (Wanget al., 1994; Liu et al., 2001). An increased understanding ofthese mechanisms and the identification of individual ligandsor ligand combinations that preferentially activate differentsignaling pathways as a result of µ/ interaction could lead tothe development of more effective pharmacological approaches toanalgesia with reduced levels of tolerance anddependence.

Abbreviations

DAMGO, [D-Ala²,N-Me-Phe⁴,Gly⁵-ol]-enkephalin; DPDPE, [D-Pen²,D-Pen⁵]-enkephalin; [Ca²⁺]_i, intracellular Ca²⁺ concentration; K_ir, inwardly rectifying K⁺; PLC, phospholipase C; U73122, 1-(6-[[17-3-methoxyestra-1,3.5(10)-trien-17-yl]amino]hexyl)-¹H-pyrrole-2,5-dione.

References

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Abstract
Introduction
Materials and Methods
Results
Discussion
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作者： Andrew C. Charles, Natalya Mostovskaya, Kathleen A 2007-5-15