[(35)S]GTPγS binding and opioid tolerance and efficacy in mouse spinal cord

The present study examined efficacy of a series of opioid agonists and then using chronic in vivo treatment protocols, determined tolerance to opioid agonist stimulated [(35)S]GTPγS (guanosine 5'-O-(3-[(35)S] thio)triphosphate) binding in mouse spinal cord membranes and compared it directly to spinal analgesic tolerance. The [(35)S]GTPγS binding assay was used to estimate efficacy (E(max) and τ; Operational Model of Agonism) of a series of opioid agonists for G-protein activation in mouse spinal cord. The rank order of opioid agonist efficacy determined in the [(35)S]GTPγS assay using the Operational Model and E(max) was similar. These efficacy estimates correlated with historical analgesic efficacy estimates. For tolerance studies, mice were continuously treated s.c. for 7days with morphine, oxycodone, hydromorphone, etorphine or fentanyl and [(35)S]GTPγS studies were conducted in spinal cord membranes. Other mice were tested in i.t. analgesia dose response studies (tailflick). Tolerance to DAMGO ([D-Ala(2),N-MePhe(4),Gly-ol(5)]enkephalin) or morphine stimulated [(35)S]GTPγS binding (decrease in E(max)) was observed following etorphine and fentanyl treatment only. These treatment protocols downregulate μ-opioid receptor density whereas morphine, oxycodone and hydromorphone do not. Spinal analgesic tolerance was observed following all treatment protocols examined (morphine, oxycodone and etorphine). Opioid antagonist treatment that specifically upregulates (chronic naltrexone) or downregulates (clocinnamox) μ-opioid receptor density produced a corresponding change in opioid agonist stimulated [(35)S]GTPγS binding. Although receptor downregulation and G-protein uncoupling are among potential mechanisms of opioid tolerance, the present results suggest that uncoupling in mouse spinal cord plays a minor role and that the [(35)S]GTPγS assay is particularly responsive to changes in μ-opioid receptor density.

The role of opioid antagonist efficacy and constitutive opioid receptor activity in the opioid withdrawal syndrome in mice

On the basis of efficacy, opioid antagonists are classified as inverse opioid agonists (e.g. naltrexone) or neutral opioid antagonists (e.g. 6β-naltrexol). This study examined the interaction between naltrexone and 6β-naltrexol in the precipitated opioid withdrawal syndrome in morphine dependent mice. Furthermore, the possible contribution of constitutive opioid receptor activity to precipitated withdrawal was evaluated using increasing levels of morphine dependence. In the first experiment, low doses of 6β-naltrexol antagonized naltrexone precipitated withdrawal while high doses acted additively. All doses of naltrexone increased 6β-naltrexol's potency to precipitate withdrawal. The next experiment examined changes in antagonist potency to precipitate withdrawal with increasing morphine dependence. Mice were exposed to morphine for 1-6 days and then withdrawal was precipitated. Naltrexone was more potent than 6β-naltrexol at all the time points. The ED(50) of both drugs decreased at the same rate suggesting that increased dependence produced no change in constitutive opioid receptor activity. Taken together these results indicate that the functional efficacy of 6β-naltrexol is dose-dependent and that constitutive opioid receptor activity did not change as opioid dependence increased from 1 to 6 days.

The role of intermittent food in the induction of attack in pigeons

The present experiments evaluated whether transitions in reinforcer probability are necessary to induce attack in pigeons. In Experiment I, three of six pigeons exposed to response-contingent constant-probability food schedules and a photograph of a conspecific as a target exhibited sustained postreinforcement attack on the target. The postreinforcement pattern of attack developed over the course of the experiment and was accompanied by a reduction in the rate of postreinforcement key pecking and an increase in the postreinforcement pause in key pecking. These effects on key pecking resulted in unprogrammed variations in the probability of reinforcement which may have been responsible for the induction of attack. In Experiment II, the attack-inducing properties of a constant-probability response-independent food schedule were compared to a periodic food schedule matched for overall rate of food delivery and to a no-food condition. In addition to attack, the spatial location of the subjects was monitored during each interfood interval. The periodic and aperiodic food schedules generated very different patterns of spatial location. Postfood attack was induced by both food schedules, although the constant-probability schedule induced attack in fewer birds. The no-food condition was not effective in inducing attack in any birds. These experiments indicate that intermittent food schedules without reductions in reinforcer probability are sufficient to induce attack in some pigeons, although not as effective as schedules with transitions in reinforcer probability.

Dosing protocol and analgesic efficacy determine opioid tolerance in the mouse

RATIONALE

Analgesic efficacy of opioids and dosing protocol have been shown to influence analgesic tolerance.

OBJECTIVE

This study tested the hypothesis that there is an inverse relationship between analgesic efficacy and tolerance following continuous infusion of opioid analgesics. Furthermore, it was hypothesized that analgesic efficacy plays a minor role in determining the magnitude of tolerance following intermittent or acute administration, and that acute and intermittent administration of opioid agonists produces less tolerance than continuous infusion.

MATERIALS AND METHODS

Analgesic (tailflick) efficacy (tau) of etorphine, methadone, oxycodone, and hydrocodone was determined using the operational model of agonism. To induce tolerance, mice were injected with opioid agonists once (acute), once per day for 7 days (intermittent) or continuously infused for 7 days. Dose-response studies were conducted using morphine following treatment.

RESULTS

The order of analgesic efficacy was etorphine > methadone > oxycodone congruent with hydrocodone. Infusion of the higher analgesic efficacy drug etorphine produced significantly less tolerance than the lower analgesic efficacy drugs oxycodone, methadone, and hydrocodone at equi-effective doses. In general, intermittent and acute treatment produced less tolerance compared to continuous infusion even at similar daily doses.

CONCLUSION

Taken together, intermittent and acute opioid agonist administration produces minimal tolerance compared to continuous infusion. Furthermore, there is an inverse relationship between analgesic efficacy and tolerance following continuous infusion. These results suggest that opioid analgesic tolerance may be increased when sustained release dosing formulations or continuous infusions are employed clinically.

The relative potency of inverse opioid agonists and a neutral opioid antagonist in precipitated withdrawal and antagonism of analgesia and toxicity

Opioid antagonists can be classified as inverse agonists and neutral antagonists. In the opioid-dependent state, neutral antagonists are significantly less potent in precipitating withdrawal than inverse agonists. Consequently, neutral opioid antagonists may offer advantages over inverse agonists in the management of opioid overdose. In this study, the relative potency of three opioid antagonists to block opioid analgesia and toxicity and precipitate withdrawal was examined. First, the potency of two opioid inverse agonists (naltrexone and naloxone) and a neutral antagonist (6beta-naltrexol) to antagonize fentanyl-induced analgesia and lethality was determined. The order of potency to block analgesia was naltrexone > naloxone > 6beta-naltrexol (17, 4, 1), which was similar to that to block lethality (13, 2, 1). Next, the antagonists were compared using withdrawal jumping in fentanyl-dependent mice. The order of potency to precipitate withdrawal jumping was naltrexone > naloxone 6beta-naltrexol (1107, 415, 1). The relative potencies to precipitate withdrawal for the inverse agonists compared with the neutral antagonist were dramatically different from that for antagonism of analgesia and lethality. Finally, the effect of 6beta-naltrexol pretreatment on naloxone-precipitated jumping was determined in morphine and fentanyl-dependent mice. 6beta-Naltrexol pretreatment decreased naloxone precipitated withdrawal, indicating that 6beta-naltrexol is a neutral antagonist. These data demonstrate that inverse agonists and neutral antagonists have generally comparable potencies to block opioid analgesia and lethality, whereas the neutral opioid antagonist is substantially less potent in precipitating opioid withdrawal. These results support suggestions that neutral antagonists may have advantages over inverse agonists in the management of opioid overdose.

Continuous morphine produces more tolerance than intermittent or acute treatment

Dosing protocol and analgesic efficacy have been proposed to be important determinants of the magnitude of opioid tolerance. The present study examined the effect of acute, intermittent and continuous treatment with the low analgesic efficacy agonist morphine on analgesic tolerance. Mice were implanted s.c. with a 25 mg morphine pellet for 1-7 days. Other mice were implanted s.c. with two 25 mg, or one 75 mg morphine pellet for 7 days. The release of morphine from subcutaneous implanted pellets was quantitated using a spectrophotometric assay. In other studies, mice were injected with morphine once (18.5-185 mg/kg/day; approximately 10-100 times ED(50) for morphine analgesia) or once/day for 7 days. Controls were implanted with a placebo pellet or injected with saline. Analysis of drug release from a 25 mg pellet indicated that release was greatest during the first 24 h, declined and then remained relatively constant. The amount of morphine released over 7 days by a 75 mg pellet (23.9 mg) was more than that of a single 25 mg pellet (15.4 mg) but less than two 25 mg pellets (30.8 mg). Following treatment, morphine cumulative dose-response studies were conducted (tail flick). Continuous treatment with morphine using pellet implantation produced a dose-dependent shift in the morphine ED(50) by 3.3, 5.8 and 8.5 fold for one 25 mg pellet, one 75 mg pellet and two 25 mg pellets, respectively. Acute and intermittent morphine administration produced substantially less analgesic tolerance than continuous release of morphine by implant pellets. The maximum shift in the ED(50) was 1.6 for acute treatment and 2.7 for 7 day intermittent treatment; despite a larger total daily dose. The present results indicate that continuous treatment with morphine results in greater analgesic tolerance than acute or intermittent morphine treatment even at comparable daily doses. These results are consistent with the suggestion that intermittent dosing has reduced risk of producing opioid tolerance.

Hydromorphone efficacy and treatment protocol impact on tolerance and mu-opioid receptor regulation

This study examined the antinociceptive (analgesic) efficacy of hydromorphone and hydromorphone-induced tolerance and regulation of mu-opioid receptor density. Initially s.c. hydromorphone's time of peak analgesic (tail-flick) effect (45 min) and ED50 using standard and cumulative dosing protocols (0.22 mg/kg, 0.37 mg/kg, respectively) were determined. The apparent analgesic efficacy (tau) of hydromorphone was then estimated using the operational model of agonism and the irreversible mu-opioid receptor antagonist clocinnamox. Mice were injected with clocinnamox (0.32-25.6 mg/kg, i.p.) and 24 h later, the analgesic potency of hydromorphone was determined. The tau value for hydromorphone was 35, which suggested that hydromorphone is a lower analgesic efficacy opioid agonist. To examine hydromorphone-induced tolerance, mice were continuously infused s.c. with hydromorphone (2.1-31.5 mg/kg/day) for 7 days and then morphine cumulative dose response studies were performed. Other groups of mice were injected with hydromorphone (2.2-22 mg/kg/day) once, or intermittently every 24 h for 7 days. Twenty-four hours after the last injection, mice were tested using morphine cumulative dosing studies. There was more tolerance with infusion treatments compared to intermittent treatment. When compared to higher analgesic efficacy opioids, hydromorphone infusions induced substantially more tolerance. Finally, the effect of chronic infusion (31.5 mg/kg/day) and 7 day intermittent (22 mg/kg/day) hydromorphone treatment on spinal cord mu-opioid receptor density was determined. Hydromorphone did not produce any change in mu-opioid receptor density following either treatment. These results support suggestions that analgesic efficacy is correlated with tolerance magnitude and regulation of mu-opioid receptors when opioid agonists are continuously administered. Taken together, these studies indicate that analgesic efficacy and treatment protocol are important in determining tolerance and regulation of mu-opioid receptors.

The analgesic efficacy of fentanyl: relationship to tolerance and mu-opioid receptor regulation

This study determined if fentanyl analgesic efficacy predicts the magnitude of tolerance and mu-opioid receptor regulation. To estimate efficacy, mice were injected i.p. with saline or clocinnamox (CCAM), an irreversible mu-opioid receptor antagonist, (0.32-25.6 mg/kg) and 24 h later fentanyl cumulative dose-response studies were conducted. CCAM dose dependently shifted the fentanyl dose-response function to the right. The apparent efficacy (tau) of fentanyl, based on the operational model of agonism, was estimated as 58, indicating that fentanyl is a high analgesic efficacy agonist. Next, mice were infused with fentanyl (1, 2 or 4 mg/kg/day) for 7 days. Controls were implanted with placebo pellets. At the end of 7 days, morphine cumulative dose-response studies or mu-opioid receptor saturation binding studies were conducted. Fentanyl infusions dose dependently decreased morphine potency with the highest fentanyl dose reducing morphine potency by approximately 6 fold. Chronic infusion with fentanyl (4 mg/kg/day) significantly reduced mu-opioid receptor density by 28% without altering affinity, whereas lower infusion doses had no effect. Taken together, the present results strengthen the proposal that opioid analgesic efficacy predicts mu-opioid receptor regulation and the magnitude of tolerance.

Mu-opioid receptor up-regulation and functional supersensitivity are independent of antagonist efficacy

Chronic opioid antagonist treatment up-regulates opioid receptors and produces functional supersensitivity. Although opioid antagonists vary from neutral to inverse, the role of antagonist efficacy in mediating the chronic effects of opioid antagonists is not known. In this study, the effects of two putative inverse agonists (naltrexone, naloxone) and a putative neutral antagonist (6beta-naltrexol) were examined. Initially, peak effect (40 min, naltrexone and naloxone; 70 min, 6beta-naltrexol) and relative potency to antagonize morphine analgesia were determined (relative potencies = 1, 2, and 16, 6beta-naltrexol, naloxone, and naltrexone, respectively). Next, mice were infused for 7 days with naloxone (0.1-10 mg/kg/day), naltrexone (10 or 15 mg s.c. pellet), or 6beta-naltrexol (0.2-20 mg/kg/day), and spinal micro-opioid receptor density was examined, or morphine analgesia dose-response studies were conducted. All antagonists up-regulated mu-opioid receptors (60-122%) and induced supersensitivity (1.8-2.0-fold increase in morphine potency). There were no differences in antagonist potency to produce up-regulation or supersensitivity. These data suggest that opioid antagonist-induced mu-opioid receptor up-regulation and supersensitivity require occupancy of the receptor and that antagonist efficacy is not critical. Finally, the ED(50) to precipitate withdrawal jumping was examined in morphine-dependent mice. Naltrexone, naloxone, and 6beta-naltrexol produced withdrawal jumping, although potencies relative to 6beta-naltrexol were 211, 96, and 1, respectively. Thus, antagonist potency to precipitate opioid withdrawal was related to inverse agonist efficacy. Overall, the estimated relative potency of the opioid antagonists was a function of the outcome measured, and inverse agonist activity was not required for mu-opioid receptor up-regulation and supersensitivity.

Opioid agonist efficacy predicts the magnitude of tolerance and the regulation of mu-opioid receptors and dynamin-2

It has been proposed that opioid agonist efficacy may play a role in tolerance and the regulation of opioid receptor density. To address this issue, the present studies estimated the in vivo efficacy of three opioid agonists and then examined changes in spinal mu-opioid receptor density following chronic treatment in the mouse. In addition, tolerance and regulation of the trafficking protein dynamin-2 were determined. To evaluate efficacy, the method of irreversible receptor alkylation was employed and the efficacy parameter tau estimated. Mice were injected with the irreversible mu-opioid receptor antagonist clocinnamox (0.32-25.6 mg/kg, i.p), and 24 h later, the analgesic potency of s.c. morphine, oxycodone and etorphine were determined. Clocinnamox dose-dependently antagonized the analgesic effects of morphine, etorphine and oxycodone. The shift to the right of the dose-response curves was greater for morphine and oxycodone compared to etorphine and the highest dose of clocinnamox reduced the maximal effect of morphine and oxycodone, but not etorphine. The order of efficacy calculated from these results was etorphine>morphine>oxycodone. Other mice were infused for 7 days with oxycodone (10-150 mg/kg/day, s.c.) or etorphine (50-250 microg/kg/day, s.c.) and the analgesic potency of s.c. morphine determined. The low efficacy agonist (oxycodone) produced more tolerance than the high efficacy agonist (etorphine) at equi-effective infusion doses. In saturation binding experiments, the low efficacy opioid agonists (morphine, oxycodone) did not regulate the density of spinal mu-opioid receptors, while etorphine produced approximately 40% reduction in mu-opioid receptor density. Furthermore, etorphine increased spinal dynamin-2 abundance, while oxycodone did not produce any significant change in dynamin-2 abundance. Overall, these data indicate that high efficacy agonists produce less tolerance at equi-effective doses. Furthermore, increased efficacy was associated with mu-opioid receptor downregulation and dynamin-2 upregulation. Conversely, lower efficacy agonists produced more tolerance at equi-effective doses, but did not regulate mu-opioid receptor density or dynamin-2 abundance. Taken together, these studies indicate that agonist efficacy plays an important role in tolerance and regulation of receptors and trafficking proteins.

Continuous opioid agonist treatment dose-dependently regulates mu-opioid receptors and dynamin-2 in mouse spinal cord

Continuous opioid agonist treatment produces tolerance and in some cases mu opioid receptor (muOR) down-regulation. Previous studies indicate that down-regulation of muOR is more likely with high-efficacy opioid agonists (e.g., etorphine), whereas lower efficacy agonists (e.g., morphine) do not regulate muOR density. It has been suggested that muOR down-regulation may depend upon increases in Dynamin-2 (DYN-2) proteins. Therefore, the present study examined the effect of various infusion doses of etorphine on muOR density, DYN-2 protein, and DYN-2 mRNA abundance in mouse spinal cord. Mice were implanted sc with an osmotic pump that infused etorphine (50-250 microg/kg/day). Controls were implanted with inert placebo pellets. At the end of 7 days, mice were sacrificed, spinal cord removed and processed for radioligand binding, quantitative Western blotting, or RT-PCR assay. Results indicate that etorphine induced dose-dependent regulation of muOR density, DYN-2 proteins, and mRNA abundance in mouse spinal cord. Higher infusion doses significantly down-regulated muOR density, increased DYN-2 protein abundance, and decreased DYN-2 mRNA. Analysis of these results indicated a significant correlation between muOR down-regulation and DYN-2 abundance in mouse spinal cord. Taken together, muOR regulation may depend on changes in DYN-2 abundance induced by high-efficacy opioid agonists in mouse spinal cord.

Opioid agonist and antagonist treatment differentially regulates immunoreactive mu-opioid receptors and dynamin-2 in vivo

Opioid agonists and antagonists can regulate the density of mu-opioid receptors in whole animal and in cell culture. High intrinsic efficacy agonists (e.g., etorphine), but not lower intrinsic efficacy agonists (e.g., morphine), produce mu-opioid receptor down-regulation and can alter the abundance of mu-opioid receptor mRNA. Conversely, opioid antagonists substantially increase the density of mu-opioid receptors without changing its mRNA. Mu-opioid receptor up-regulation has been associated with decreases in the trafficking protein dynamin-2, whereas mu-opioid receptor down-regulation produces an increase in dynamin-2 abundance. To probe the differences between opioid agonist and antagonist-induced mu-opioid receptor regulation, the current study determined changes in mu-opioid receptor density using a combined radioligand binding ([3H] DAMGO) and quantitative Western blotting approach in mouse spinal cord. Furthermore, the differences between intermittent and continuous dosing protocols were evaluated. Continuous (7-8 days) s.c. infusions of naloxone (5 mg/kg/day) or naltrexone (15 mg s.c. implant pellet) increased mu-opioid receptor density in radioligand binding assays (approximately +80%) in mouse spinal cord and down-regulated dynamin-2 abundance (approximately -30%), but had no effect on the abundance of immunoreactive mu-opioid receptor. Continuous (7 days) s.c. infusion of etorphine (200 microg/kg/day) decreased immunoreactive mu-opioid receptor (approximately -35%) and [3H] DAMGO binding (approximately -30%), and concurrently increased dynamin-2 abundance (approximately +40%). Continuous (7 days) morphine infusion (40 mg/kg/day plus 25 mg s.c. implant pellet) had no effect on any outcome measure. Delivery of the same daily dose of etorphine or naloxone using intermittent (every 24 h for 7 days) s.c. administration had no effect on immunoreactive mu-opioid receptor, [3H] DAMGO binding or dynamin-2 abundance. These data indicate that mu-opioid receptor density, determined in radioligand binding assays, and immunoreactive dynamin-2 abundance are regulated by continuous, but not intermittent, opioid ligand treatment. Furthermore, the differential regulation of mu-opioid receptor abundance by agonists and antagonists in immunoblotting assays contrasts with changes in [3H] DAMGO binding. Taken together, these results suggest that etorphine-induced down-regulation may depend upon mu-opioid receptor degradation and changes in dynamin-2-mediated receptor trafficking. Conversely, antagonist-induced up-regulation does not require an increase in mu-opioid receptor synthesis and may entail conversion of receptors to an appropriate conformation to bind ligand, as well as changes in receptor trafficking.

Chronic opioid antagonist treatment selectively regulates trafficking and signaling proteins in mouse spinal cord

Chronic opioid antagonist treatment produces functional supersensitivity and mu-opioid receptor (muOR) upregulation. Studies suggest a role for G-protein receptor kinases (GRKs) and dynamin (DYN), but not signaling proteins (e.g., G(ialpha2)), in regulation of muOR density following opioid treatment. Therefore, this study examined muOR density, agonist potency, and the abundance and gene expression of GRK-2, DYN-2, and G(ialpha2) in mouse spinal cord after opioid antagonist treatment. Mice were implanted with a 15 mg naltrexone (NTX) or placebo pellet and 8 days later pellets were removed. At 24 and 192 h following NTX treatment, mice were tested for spinal DAMGO analgesia. Other mice were sacrificed at 0 or 192 h following NTX treatment and G(ialpha2), GRK-2, and DYN-2 protein and mRNA levels determined. [(3)H] DAMGO binding studies were also conducted. Immediately following NTX treatment (0 h), muOR density was increased (+ approximately 135%), while 192 h following NTX treatment muOR density was unchanged. NTX increased DAMGO analgesic potency (3.1-fold) 24 h following NTX treatment, while there was no effect at 192 h. NTX decreased protein and mRNA abundance of GRK-2 (-32%; -48%) and DYN-2 (-25%; -29%) in spinal cord at 0 h. At 192 h following 8-day NTX treatment, GRK-2 protein and mRNA were at control levels, while DYN-2 protein remained decreased (-31%) even though DYN-2 mRNA had returned to control levels. G(ialpha2) was unaffected by NTX treatment. These data suggest that opioid antagonist-induced mu-receptor upregulation is mediated by changes in abundance and gene expression of proteins implicated in receptor trafficking, which may decrease constitutive receptor cycling.

Chronic opioid antagonist treatment dose-dependently regulates mu-opioid receptors and trafficking proteins in vivo

Chronic opioid antagonist treatment increases the density of mu-opioid receptors (muOR) in many model systems. In previous studies, naltrexone treatment produced an increase in muOR density accompanied by decreases in GRK-2 and DYN-2 protein abundance. To examine the relationship between changes in receptor density and proteins involved in receptor trafficking, the dose-dependent effect of chronic naloxone infusion was determined. Dose-dependent antagonism of morphine analgesia was also examined. Mice were infused with naloxone (0.1, 1.0, 5.0 mg/kg/day sc) for 7 days via osmotic pump. Controls were treated with placebo pellets. On the 7th day, morphine dose-response studies were determined using the tail flick. Other mice were sacrificed at the end of the treatment and spinal cords were collected for determination of muOR density and GRK-2 and DYN-2 protein abundance. Naloxone infusion dose-dependently increased spinal muOR density with no change in affinity. The increases in mu-receptor density were proportional to dose-dependent decreases in GRK-2 and DYN-2 protein levels. Furthermore, naloxone dose-dependently antagonized morphine. These data suggest that opioid antagonist-induced muOR up-regulation in mouse spinal cord is associated with regulation of proteins involved in receptor trafficking and support suggestions that opioid antagonist-induced receptor up-regulation is due to reduced constitutive internalization of opioid receptors.

Role of G(i)alpha2-protein in opioid tolerance and mu-opioid receptor downregulation in vivo

Although opioid receptors are G-protein coupled, the role that specific G-protein subunits play in the development of opioid tolerance and the regulation of opioid receptor number is not well understood. In the present study, we used a G((i)alpha2) antisense oligodeoxynucleotide (ODN) to examine the contribution of G((i)alpha2) proteins to mu-opioid tolerance and receptor downregulation in the mouse. Mice were injected intracerebroventricularly (ICV) and into the spinal intrathecal space (IT) for 4-5 consecutive days (30 microg/site/day), with an antisense ODN or a mismatch ODN directed at mRNA for the G((i)alpha2) subunit of G-proteins. Controls were treated with dH(2)O. On the second day of ODN treatment continuous subcutaneous (SC) infusion of etorphine (200 microg/kg/day) or morphine (40 mg/kg/day + 25 mg pellet) was begun. Control mice were implanted with inert placebo pellets. Three days later, pumps and pellets were removed and mice were tested for morphine analgesia or mu-opioid receptor density was determined in whole brain. Etorphine produced significant tolerance (ED(50) shift = approximately 11-fold) and downregulation of mu-opioid receptors (approximately 25%). Morphine treatment produced significant tolerance (ED(50) shift approximately 9-fold), but no mu-opioid receptor downregulation. Antisense treatment reduced G((i)alpha2) protein levels in striatum and spinal cord by approximately 25%. G((i)alpha2) antisense reduced the acute potency of morphine. G((i)alpha2) antisense blocked the development of tolerance to morphine treatment and reduced the development of tolerance to etorphine treatment. Antisense did not have any effect on etorphine-induced mu-opioid receptor downregulation. In another experiment, 7-day treatment with morphine or etorphine similarly increased G((i)alpha2) mRNA and protein abundance in spinal cord. Overall, these results support an important role for G((i)alpha2)-protein in the acute effects of opioids and opioid tolerance. However, G((i)alpha2) is not required for agonist-induced mu-opioid receptor density regulation in vivo.

Opioid agonists differentially regulate mu-opioid receptors and trafficking proteins in vivo

Chronic opioid agonist treatment produces tolerance and in some cases opioid receptor internalization and down-regulation. Both morphine and etorphine induce tolerance; however, only etorphine produces mu-opioid receptor (muOR) down-regulation. In vitro studies implicate dynamin-2 (DYN-2) and G-protein receptor kinase-2 (GRK-2) in these processes. Therefore, we examined etorphine and morphine effects on regulation of GRK-2 and DYN-2 in mouse spinal cord. Mice were treated for 7 days with etorphine (200 microg/kg/day infusion) or morphine (40 mg/kg/day infusion + one 25-mg implant pellet). Controls were implanted with a placebo pellet. On the 7th day after implantation mice were tested for i.t. [D-Ala(2),N-Me-Phe(4),Gly(5)-ol]-enkephalin (DAMGO) analgesia. In other mice, spinal cord was removed for [(3)H]DAMGO binding studies or GRK-2 and DYN-2 protein and mRNA abundance were determined. Both etorphine and morphine produced significant tolerance (ED(50) shift = 7.6- and 7.3-fold for morphine and etorphine, respectively). Etorphine decreased spinal muOR density by approximately 30%, whereas morphine did not change muOR density. Etorphine increased ( approximately 70%) DYN-2 protein abundance and decreased its mRNA (31%), whereas it had no effect on GRK-2 protein and mRNA abundance. Morphine had no effect on either DYN-2 or GRK-2 protein or mRNA abundance. These data raise the possibility that unequal receptor regulation by etorphine and morphine might be due to differential regulation of trafficking proteins. Overall, receptor down-regulation associated with chronic etorphine treatment may accelerate dynamin-related activity. Finally, the decrease in DYN-2 mRNA may be related to stabilization of DYN-2 protein abundance, which might inhibit transcription.

Antagonist-induced micro-opioid receptor up-regulation decreases G-protein receptor kinase-2 and dynamin-2 abundance in mouse spinal cord

Chronic treatment with opioid receptor antagonists has been shown to increase the density of micro-, delta- and kappa-opioid receptors in cell culture and in the intact animal. Although opioid receptor antagonist-induced up-regulation is a robust phenomenon, the mechanisms responsible for the increase in receptor density remain unclear. In the present study, changes in a kinase and a GTPase that have been implicated in G-protein-coupled receptor regulation were examined following opioid receptor antagonist treatment. Mice were implanted s.c. with a naltrexone pellet or placebo pellet. On the eighth day following implantation, spinal cord was removed and G-protein receptor kinase-2 (GRK-2) and dynamin-2 abundance were determined using a quantitative immunoblot approach. Changes in micro-opioid receptor density were also determined. Naltrexone treatment produced a significant (145%) increase in micro-opioid receptor density. Naltrexone treatment was associated with a significant 36% decrease in GRK-2 and 30% decrease in dynamin-2 abundance in spinal cord. These data raise the possibility that opioid receptor antagonist-induced micro-opioid receptor up-regulation in the intact animal may be due to a reduction in constitutive internalization of opioid receptors.

Mu-opioid receptor down-regulation and tolerance are not equally dependent upon G-protein signaling

In the present study, the contribution of pertussis toxin (PTX)-sensitive G(i/o)-proteins to opioid tolerance and mu-opioid receptor down-regulation in the mouse were examined. Mice were injected once intracerebroventricularly and intrathecally with PTX (0.1 microg/site). Controls were treated with saline. On the 10th day following PTX treatment, continuous subcutaneous infusion of etorphine (150 or 200 microg/kg/day) or morphine (40 mg/kg/day+25 mg slow-release pellet) was begun. Control mice were implanted with inert placebo pellets. Pumps and pellets were removed 3 days later, and mice were tested for morphine analgesia or mu-opioid receptor density was determined in the whole brain, spinal cord, and midbrain. Both infusion doses of etorphine produced significant tolerance (ED50 shift=approximately 4-6-fold) and down-regulation of mu-opioid receptors (approximately 20-35%). Morphine treatment also produced significant tolerance (ED50 shift= approximately 5-8-fold), but no mu-opioid receptor down-regulation. PTX dramatically reduced the acute potency of morphine and blocked the further development of tolerance by both etorphine and morphine treatments. However, PTX had no effect on etorphine-induced mu-opioid receptor down-regulation in brain, cord, or midbrain. These results suggest that PTX-sensitive G-proteins have a minimal role in agonist-induced mu-opioid receptor density regulation in vivo, but are critical in mediating acute and chronic functional effects of opioids such as analgesia and tolerance.

mu-Opioid receptor downregulation contributes to opioid tolerance in vivo

The present study examined the contribution of downregulation of mu-opioid receptors to opioid tolerance in an intact animal model. Mice were implanted subcutaneously with osmotic minipumps that infused etorphine (50-250 microg/kg/day) for 7 days. Other mice were implanted subcutaneously with a morphine pellet (25 mg) or a morphine pellet plus an osmotic minipump that infused morphine (5-40 mg/kg/day) for 7 days. Controls were implanted with an inert placebo pellet. At the end of treatment, pumps and pellets were removed, and saturation binding studies were conducted in whole brain ([3H]DAMGO) or morphine and etorphine analgesic ED(50)s were determined (tail-flick). Morphine tolerance increased linearly with the infusion dose of morphine (ED(50) shift at highest infusion dose, 4.76). No significant downregulation of mu-receptors in whole brain was observed at the highest morphine treatment dose. Etorphine produced dose-dependent downregulation of mu-opioid receptor density and tolerance (ED(50) shift at highest infusion dose, 6.97). Downregulation of mu-receptors only occurred at the higher etorphine infusion doses (> or =150 microg/kg/day). Unlike morphine tolerance, the magnitude of etorphine tolerance was a nonlinear function of the dose and increased markedly at infusion doses that produced downregulation. These results suggest that mu-opioid receptor downregulation contributes to opioid tolerance in vivo. Therefore, opioid tolerance appears to rely upon both "receptor density-dependent" and " receptor density-independent" mechanisms.

Role of cAMP-dependent protein kinase (PKA) in opioid agonist-induced mu-opioid receptor downregulation and tolerance in mice

Studies suggest that acute and chronic opioids can regulate the cAMP-dependent protein kinase (PKA) signaling pathway and that changes in this pathway may be involved in opioid tolerance. In the present study, we examined the role of cAMP-PKA on mu-opioid receptor downregulation and tolerance in mice. Mice were injected intracerebroventricular (i.c.v.) and intrathecal (i.t.) once a day with an antisense oligodeoxynucleotide directed at the mRNA for the alpha catalytic subunit of mouse PKA. Controls were treated with saline or a mismatch oligodeoxynucleotide. On day 2 of treatment, mice were implanted s.c. with a 25-mg morphine pellet and an osmotic minipump infusing morphine (40 mg/kg/day) for 3 days. Other mice were implanted with an osmotic minipump infusing etorphine (125, 250 microg/kg/day) for 2 days. Control mice were implanted s.c. with inert placebo pellets. At the end of treatment, pumps and pellets were removed and mice tested for morphine or etorphine analgesia. Other mice were sacrificed and mu-opioid receptor binding assays conducted in whole brain. Both infusion doses of etorphine produced significant tolerance (ED(50) shift = 3.6 and 6.3-fold). The higher etorphine infusion produced downregulation of mu-receptor density ( approximately 30%) while the lower infusion dose of etorphine did not. Morphine treatment also produced significant tolerance in mice (ED(50) shift = 4.5-fold), but no receptor downregulation. Antisense to PKA partially blocked tolerance induced by the higher dose of etorphine, but had no effect on receptor downregulation. On the other hand, antisense to PKA completely blocked tolerance induced by morphine and the lower infusion dose of etorphine. The mismatch oligodeoxynucleotide had no effect on any measure. These results suggest that PKA has a limited role in opioid agonist-induced receptor downregulation. However, the partial block of tolerance for the high infusion dose of etorphine and the complete block of tolerance for morphine and the low infusion dose of etorphine suggests that PKA may play a critical role in tolerance that is "receptor-regulation-independent."

Role of cAMP-dependent protein kinase (PKA) in opioid agonist-induced mu-opioid receptor downregulation and tolerance in mice

Studies suggest that acute and chronic opioids can regulate the cAMP-dependent protein kinase (PKA) signaling pathway and that changes in this pathway may be involved in opioid tolerance. In the present study, we examined the role of cAMP-PKA on mu-opioid receptor downregulation and tolerance in mice. Mice were injected intracerebroventricular (i.c.v.) and intrathecal (i.t.) once a day with an antisense oligodeoxynucleotide directed at the mRNA for the alpha catalytic subunit of mouse PKA. Controls were treated with saline or a mismatch oligodeoxynucleotide. On day 2 of treatment, mice were implanted s.c. with a 25-mg morphine pellet and an osmotic minipump infusing morphine (40 mg/kg/day) for 3 days. Other mice were implanted with an osmotic minipump infusing etorphine (125, 250 microg/kg/day) for 2 days. Control mice were implanted s.c. with inert placebo pellets. At the end of treatment, pumps and pellets were removed and mice tested for morphine or etorphine analgesia. Other mice were sacrificed and mu-opioid receptor binding assays conducted in whole brain. Both infusion doses of etorphine produced significant tolerance (ED(50) shift = 3.6 and 6.3-fold). The higher etorphine infusion produced downregulation of mu-receptor density ( approximately 30%) while the lower infusion dose of etorphine did not. Morphine treatment also produced significant tolerance in mice (ED(50) shift = 4.5-fold), but no receptor downregulation. Antisense to PKA partially blocked tolerance induced by the higher dose of etorphine, but had no effect on receptor downregulation. On the other hand, antisense to PKA completely blocked tolerance induced by morphine and the lower infusion dose of etorphine. The mismatch oligodeoxynucleotide had no effect on any measure. These results suggest that PKA has a limited role in opioid agonist-induced receptor downregulation. However, the partial block of tolerance for the high infusion dose of etorphine and the complete block of tolerance for morphine and the low infusion dose of etorphine suggests that PKA may play a critical role in tolerance that is "receptor-regulation-independent."

In vivo regulation of mu-opioid receptor density and gene expression in CXBK and outbred Swiss Webster mice

Chronic in vivo treatment with the opioid agonist etorphine downregulates mu-opioid receptor density, produces tolerance, and regulates gene expression in the mouse. After cessation of treatment, there is an increase in mu-opioid receptor mRNA level associated with the recovery of mu-opioid receptors. However, the effect of etorphine on the regulation of mRNA during treatment is currently not known. In this study, etorphine-induced changes in mu-opioid receptor density, mRNA, and opioid analgesic potency were determined in two mouse strains that differ in basal mu-opioid receptor density in brain. CXBK mice (mu-opioid receptor deficient) and outbred Swiss Webster mice were implanted s.c. with placebo pellets (controls) or etorphine minipumps (250 microg/kg/day) for 1-7 days and mu-opioid receptor density or mRNA levels in whole brain were assessed or mice were tested for etorphine analgesia following 7 days of treatment. In control CXBK mice, mu-receptor density was approximately 40% less than that for the Swiss Webster, although mRNA abundance was similar in both strains. Etorphine's potency was 4-fold greater in control Swiss Webster compared to CXBK mice. Etorphine treatment decreased ( approximately 25-40%) mu-receptor density similarly in both strains throughout treatment. The magnitude of analgesic tolerance to etorphine was 8-fold in both mouse strains. Etorphine produced a biphasic effect on receptor mRNA in both strains with levels decreased (25%) by 3 days and increased (30-40%) at 7 days. mRNA levels remained elevated (55%) 16 h following the end of the 7 day etorphine treatment. Taken together, these data suggest that in vivo etorphine treatment that produces mu-opioid receptor downregulation and tolerance, can regulate mu-opioid receptor mRNA abundance. Receptor downregulation may initially induce decreases in mRNA levels since downregulation preceded a decrease in gene expression. Prolonged (>3 days) receptor downregulation may be responsible for increasing message levels and may be important in recovery of receptors following treatment. In addition, the magnitude of changes in receptor density, mRNA, and tolerance were similar in both CXBK and Swiss Webster mice, indicating that the mechanisms required for receptor regulation and its functional consequences are independent of basal mu-opioid receptor density.

The effect of nimodipine on opioid antagonist-induced upregulation and supersensitivity

Regulation of calcium flux has been suggested to play a role in acute and chronic effects of opioids. Previous studies have shown calcium channel blockers can inhibit opioid agonist-induced downregulation of mu-opioid receptors and may reduce the magnitude of tolerance. In the present study, we determined if calcium channel blockade would affect increases in opioid receptor density and functional supersensitivity produced by chronic opioid antagonist treatment in the mouse. Mice were implanted subcutaneously with a 15-mg naltrexone (NTX) or placebo pellet. Mice also were implanted with an osmotic minipump that infused nimodipine (100 microg/kg/day) or a second placebo pellet. This protocol yielded four groups: nimodipine-NTX; nimodipine-placebo; placebo-NTX; placebo-placebo. On the seventh day, pumps and pellets were removed. Twenty-four hours later, a morphine dose-response study was conducted (tail flick); or mice were sacrificed and saturation binding studies ([3H]DAMGO) were performed in whole brain. NTX treatment significantly increased the analgesic potency of morphine by approximately 60%. Nimodipine increased the potency of morphine by approximately 50%. For mice treated with both nimodipine and NTX, there was an additive effect on morphine potency ( approximately 120% increase). In binding studies, NTX increased the density of mu-opioid receptors similarly ( approximately 60-70%) in the presence and absence of nimodipine treatment, with no change in affinity. No effect of chronic nimodipine alone on mu-opioid receptor binding was observed. These data indicate that NTX-induced upregulation and supersensitivity are independent of calcium channel blockade by nimodipine. These results contrast with those from tolerance and downregulation studies, and confirm suggestions that different substrates mediate chronic opioid agonist and antagonist-induced effects in vivo. Finally, in a separate study, morphine potency was unaffected by acute nimodiopine (100 microg/kg; SC), suggesting that prolonged exposure to this calcium channel blocker is required to increase morphine potency.

Opioid receptor upregulation in mu-opioid receptor deficient CXBK and outbred Swiss Webster mice

Chronic in vivo treatment with opioid antagonists increases opioid receptor density and the potency of opioid agonists without altering receptor mRNA levels. To determine if basal receptor density affects opioid receptor upregulation, we examined the effect of chronic naltrexone treatment on mu-opioid receptor density and mRNA in two mice strains that differ in mu-opioid receptor density. CXBK mice (mu-opioid receptor deficient) and outbred Swiss Webster mice were implanted s.c. with a placebo or 15 mg naltrexone pellet for 8 days, the pellets removed and 24 hr later opioid receptor density (mu, delta) and receptor mRNA level (mu) determined in whole brain; or morphine dose-response studies conducted. In placebo-treated CXBK mice, mu-opioid receptor density was approximately 40% less than in Swiss Webster mice, although mu-opioid receptor mRNA abundance was similar in both strains. In placebo-treated CXBK mice, morphine potency was approximately 6-fold less than Swiss Webster mice. Naltrexone treatment increased morphine potency (1.7-fold) and mu- (approximately 90%) and delta- (approximately 20-40%) opioid receptor density in CXBK and Swiss Webster mouse brain similarly. Mu-opioid receptor mRNA was unchanged by naltrexone treatment in either strain. There was no difference in the basal or naltrexone-treated whole brain G(i alpha2) protein levels in CXBK or Swiss Webster mouse. These data indicate that a deficiency in mu-opioid receptors does not alter the regulation of opioid receptors by opioid antagonists in vivo, and suggest that adaptive responses to chronic opioid antagonist treatment are independent of opioid receptor density.

Preproenkephalin mRNA and enkephalin levels in the adult Syrian hamster: the influence from glucocorticoids

Proenkephalin (Penk) gene structure in hamsters and humans are similar but they differ from rats. In this study hamster Penk gene expression was examined after hypophysectomy+/-glucocorticoid receptor blockade with RU 486 (mifepristone). In contrast to rats, basal Penk gene expression in hamster adrenals did not change after treatments that reduced both the influence from glucocorticoids and phenylethanolamine-N-methyltransferase mRNA levels. Meanwhile, striatal preproenkephalin mRNA levels increased under these conditions.

The effects of antisense to Gialpha2 on opioid agonist potency and Gialpha2 protein and mRNA abundance in the mouse

In this study, mice received a single intracerebroventricular (i.c.v. ) injection of an antisense oligodeoxynucleotide (ODN) directed towards the mRNA of Gialpha2. Controls received a saline or a nonsense ODN injection. The subsequent effects on protein levels and mRNA of Gialpha2 were determined in mouse striatum, as well as, the effect on opioid ([d-Ala2, d-Leu5]-enkephalin; DADLE) inhibition of cyclic AMP (cAMP) formation in striatum and morphine analgesic potency. At 48 h after treatment, maximal inhibition (Emax) of cAMP formation was significantly reduced for the antisense group compared to controls. Antisense ODN treatment only changed the Emax and did not significantly alter the IC50s of the dose-effect curves for inhibition of cAMP formation. Antisense ODN, but not nonsense ODN, significantly reduced morphine's analgesic potency by >2-fold, 48 h following treatment. Using a quantitative immunoblotting procedure, antisense treatment was shown to decrease striatal Gialpha2 protein 48 h after antisense injection, while there were no changes in protein levels at 2, 12 and 24 h. In contrast, no changes in Gialpha2 mRNA in mouse striatum were noted at any time after antisense treatment. Taken together, these data suggest that Gialpha2 mediates opioid-induced analgesia and opioid inhibition of cAMP production in the mouse. These data also suggest that antisense reduces target protein by a mechanism independent of changes in mRNA abundance.

Acute ethanol exposure decreases the analgesic potency of morphine in mice

Chronic (7 days), forced ethanol drinking can decrease the analgesic potency of opioid agonists in mice. In the present study, the effect of short-term ethanol treatment was examined using forced ethanol access and ethanol injection protocols. Mice were given forced access to 1, 3 or 7% (v/v) ethanol for 24 hr and then tested for s.c. morphine analgesia using the tailflick assay. Controls had access to water. Another group of mice was injected i.p. with 2.5 g/kg ethanol or water 4 times over a 21 hr period and tested 3 hr after the final injection for morphine analgesia. Other mice were injected once i.p. with 1, 2 or 3 g/kg ethanol or water and tested 24 hr later using the tailflick. In the forced access study, ethanol dose-dependently decreased morphine's analgesic potency with the highest dose (7%) producing a 1.6-fold shift in the ED50. This decrease in morphine potency was similar to that found in a related study using 7% ethanol for 7 days (1.8-fold shift). Repeated ethanol injections significantly reduced the analgesic potency of morphine (1.9-fold shift), whereas, a single injection of 1, 2 or 3 g/kg ethanol did not alter the potency of morphine. Control studies indicated that neither 24 hr water nor food deprivation affected morphine potency. Overall, these data show that sustained exposure to ethanol over a 24 hr period will dose-dependently decrease morphine's analgesic potency.

In vivo homologous regulation of mu-opioid receptor gene expression in the mouse

Regulation of the mu-opioid receptor gene by opioid analgesic drugs has not been observed in rats and mice following in vivo treatments that produce tolerance. Although in vivo heterologous regulation of mu-opioid receptor mRNA by non-opioid compounds has been reported, the failure to observe changes in mu-opioid receptor mRNA levels in vivo after treatment with opioid agonists raised the possibility that in vivo homologous regulation by agonists may not occur. Therefore, in the present study, the effect of a high intrinsic efficacy opioid receptor agonist on opioid receptor density, gene expression and tolerance was determined. Mice were infused with etorphine for 7 days using an osmotic minipump, then the pump was removed and studies conducted 16-168 h later. Etorphine (50-250 microg/kg/day) infusion produced significant dose-dependent tolerance to the analgesic (tailflick) effects of etorphine, as well as dose-dependent mu-opioid receptor downregulation in brain at 16 h following the end of the infusion. Mu-opioid receptor density returned to control levels over a 168 h period following the end of etorphine (250 microg/kg/day) infusion. Similarly, the magnitude of tolerance decreased over the same period. Evaluation of changes in brain mu-opioid receptor mRNA 16 h following etorphine infusion indicated that there was dose-dependent increase in steady-state levels, with no significant change in GAPDH mRNA. The increase in mu-opioid receptor mRNA was approximately 55-65% over control at the highest etorphine infusion dose. Mu-opioid receptor mRNA returned to control levels over a 168 h period following the end of etorphine (250 microg/kg/day) infusion. These data suggest that the increase in mu-opioid receptor mRNA following the termination of etorphine treatment may drive the recovery of mu-opioid receptors. These data are the first demonstration of in vivo homologous regulation of mu-opioid receptor gene expression in the mouse by an opioid receptor agonist that produces tolerance and receptor downregulation.

The effect of in vivo ethanol consumption on cyclic AMP and delta-opioid receptors in mouse striatum

In this study the effect of in vivo ethanol consumption on cyclic AMP (cAMP) and [D-Ala2,D-Leu5]enkephalin (DADLE) inhibition of forskolin-stimulated cAMP production was examined in mouse striatum. Effects of ethanol on striatal delta-opioid receptor (DOR) density and mRNA were also examined. Mice had unlimited access to 7% (v/v) ethanol alone or water for 1 or 7 days and were then sacrificed and striatum removed for analysis. There was no difference in basal cAMP formation between water and ethanol-treated mouse striatum following 7 day treatment, and a small, but statistically significant increase in basal cAMP in the ethanol group following 1 day treatment. Both 1 day and 7 day ethanol treatment did not significantly alter the percentage increase in cAMP following treatment with 10 microM forskolin. There was a significant effect of ethanol treatment on the maximum inhibitory effect of DADLE on forskolin-stimulated cAMP formation following both 1 and 7 day ethanol treatment. The DADLE IC50 was unaffected by ethanol treatment. Saturation binding studies ([3H]Deltorphin II) indicated no effect of ethanol on Bmax or Kd in striatum. Similarly, no difference between water and ethanol-treated was observed for DOR mRNA in striatum. These data indicate that ethanol consumption can alter opioid regulation of cAMP formation. However, this effect is not related to changes in any delta-opioid receptor parameters that were examined.

The effect of cumulative dosing on the analgesic potency of morphine in mice

Opioid analgesic potency can be evaluated using cumulative dosing, in which subjects are repeatedly administered a drug and tested after each dose until a criterion effect is reached. Although many laboratories use cumulative dosing, the effects of varying the starting dose and the magnitude of the increment dose on morphine analgesia (tail flick) in mice have not been evaluated. In experiment 1. mice were injected with the same starting dose [0.5 mg/kg subcutaneously (SC)] and 30 min later were tested for analgesia. Mice that were not analgesic were administered an increment dose (0.5, 1.0, 2.0, 2.5, or 3.0 mg/kg) and retested. The process was continued until all mice were analgesic. There was a significant effect of increment dose on morphine potency, with the relative potency increasing as the increment dose was increased. In experiment 2, different starting doses (0.5, 1.0, 2.0, or 3.0 mg/kg) were used with a constant increment dose of 1.0 mg/kg. There was a significant effect of starting dose on the potency of morphine, with the relative potency increasing as the starting dose increased. To determine if increment and starting dose affect tolerance estimates, mice were implanted SC with a 25- or 75-mg morphine or placebo pellet for 7 days and then tested using cumulative dose-response. Changes in the increment dose significantly affected the degree of tolerance for mice implanted with a 25-mg morphine pellet but not for mice implanted with a 75-mg morphine pellet. Changes in the starting dose did not significantly alter estimates of tolerance. Overall, these data indicate that the starting dose and increment dose can impact on morphine's potency determined by cumulative dosing protocols. Furthermore, estimates of tolerance can be affected by dosing parameters in the cumulative dosing protocol. These results suggest that cumulative dosing procedures should be standardized across experiments.

Synthesis and antinociceptive activity of [D-Met2, Pro5] enkephalin [N1,5-beta-D-2,3,4,6-O-tetraacetylglycosyl]--amide and [D-Met2, Pro5] enkephalinamide

Tetra-O-acetylgalactopyranosylamine and tetra-O-acetylglucopyranosylamine of D-Met2, Pro5 enkephalin were designed and synthesized to enhance their membrane penetration, biological activity and resistance to proteolytic hydrolysis. Three approaches to the synthesis were attempted, which lead to a new synthetic scheme with a higher yield and enhanced ease of purification. The improved procedure involved attaching the tetra-O-acetylglycopyranosylamine to a t-Boc-Gly-Phe-Pro-OH peptide, removing the t-Boc, and condensing it with t-Boc-Tyr-D-Met-OH. Biological evaluation in vivo showed that these acetylglycopyranosylamine derivatives bind to mu and delta opioid receptors in homogenate binding assays and possess analgesic activity. The analgesic potency was less than that of the parent compound D-Met2, Pro5 enkephalin. These acetylglycopyranosylamine derivatives showed enhanced lipophilicity compared to their parent compound by a partition coefficient study and they also showed greater membrane permeability, using the rabbit cornea as a model system. These derivatives also are resistant to hydrolytic enzymes as compared to the endogenous met-enkephalin when evaluated in homogenized iris-ciliary body and aqueous humor from rabbit eyes.

The effect of ethanol drinking on opioid analgesia and receptors in mice

Recent studies suggest substantial interactions between opioids and ethanol (EtOH). Both in vivo and in vitro experiments indicate that EtOH can regulate opioid systems and that opioids can modify EtOH consumption. In the present studies, we examined if EtOH consumption altered opioid receptors and the potency of opioid analgesics. Mice were given unlimited access to 6-7% EtOH alone for 7 days or were allowed to drink increasing concentrations (3-6%) of EtOH over 13-14 days. Controls had access to water. The EtOH groups drank significantly less volume than controls, although there were no significant differences in body weight or baseline nociception. The analgesic (tail flick) potency of SC morphine was decreased by approximately 1.6-2.0-fold in EtOH-treated mice. A single acute dose of EtOH (1 g/kg) that produced blood alcohol levels in excess of that for 7 day exposure to EtOH, did not change morphine's analgesic ED50, suggesting that chronic exposure to EtOH was necessary for the reduction in potency. The change in morphine potency was not due to pharmacokinetic differences because EtOH consumption did not modify the concentration of morphine in brain and spinal cord. The analgesic potency of a delta-opioid receptor agonist (ICV DSLET) was also decreased by approximately 2-fold. Saturation binding studies indicated no changes in the density or affinity of brain and spinal cord delta-opioid ([3H]DPDPE, [3H]DSLET, [3H]DeltorphinII) and mu-opioid ([3H]DAMGO) receptors. Similarly, there was no significant effect of EtOH on delta-opioid receptor mRNA in either brain or spinal cord preparations. Taken together, these data suggest that EtOH consumption decreases the analgesic potency of opioids in mice through a mechanism that is unrelated to pharmacokinetics or opioid receptor changes in brain and cord.

Time-dependent effects of in vivo pertussis toxin on morphine analgesia and G-proteins in mice

Previous studies have indicated a long-duration of effect of in vivo pertussis toxin (PTX) on morphine analgesia in the mouse. However, the time-course of potency changes in morphine analgesia as determined in dose-response studies and biochemical correlates of PTX treatment have not been reported to date. Therefore, in the present studies the effects of in vivo PTX on morphine analgesia ED50 and PTX-catalyzed incorporation of [32P]-ADP-ribose and synapsin content in mouse spinal cord were examined. Mice were injected IT & ICV with saline or PTX (total dose = 0.2 microg) and tested for systemic morphine analgesia (tail-flick) 1, 10, 16 & 40 days later. There was no significant decrease in morphine potency 1 day following PTX treatment, whereas PTX produced a significant decrease in morphine potency at 10, 16 & 40 days. Concurrent decreases in the incorporation of [32P]-ADP-ribose in spinal cord by PTX were observed on days 10, 16 & 40. No changes were observed in synapsin content which suggests that the effect was not nonspecific. This study indicates that in vivo PTX produces co-ordinate long-lasting effects in both functional (analgesia) and biochemical (Gi/o-proteins) assays.

Magnitude of tolerance to fentanyl is independent of mu-opioid receptor density

The effect of a mu-opioid receptor irreversible antagonist on the development of tolerance to fentanyl was determined in mice. Mice were injected with saline or clocinnamox (3.2 mg/kg, i.p.) and 4 h later mice implanted s.c. with a placebo pellet or an osmotic minipump that infused fentanyl (0.165 mg/kg per day) for 3 days. Fentanyl pumps and placebo pellets were removed on the third day following implantation and 4 h later mu-opioid receptor saturation binding studies in whole brain ([3H][D-Ala2,MePhe4,Gly-ol5]enkephalin: DAMGO) or fentanyl analgesic dose-response studies (tailflick assay) were conducted. Fentanyl infusions and clocinnamox both significantly reduced the potency of fentanyl by 2.8- and 2.4-fold, respectively. When fentanyl and clocinnamox were administered together, a significant 5.0-fold reduction in fentanyl potency relative to the saline-placebo group was observed, which represents an additive effect of clocinnamox and fentanyl. The ED50 of fentanyl in clocinnamox-treated mice was shifted 2.1-fold by fentanyl infusion relative to the clocinnamox-placebo group. This is comparable to the 2.8-fold shift in the ED50 produced by fentanyl infusion in saline-treated mice. In binding studies, fentanyl produced a small (-9%) reduction in Bmax, while clocinnamox significantly reduced (-41%) mu-opioid receptor density without altering affinity (Kd). In the clocinnamox-fentanyl group, there was a 50% reduction in Bmax, which is similar to the additive effect observed in analgesia studies. These data indicate that changes in mu-opioid receptor density prior to the development of tolerance to fentanyl do not impact on the magnitude of tolerance.

The effect of mu-opioid receptor antisense on morphine potency and antagonist-induced supersensitivity and receptor upregulation

The present study examined the effect of in vivo antisense oligodeoxynucleotide treatment on naltrexone (NTX)-induced functional supersensitivity and mu-opioid receptor up-regulation in mice. On day 1 mice were implanted S.C. with a NTX or placebo pellet and injected I.T. and I.C.V. with dH2O or oligodeoxynucleotides. The oligodeoxynucleotides were designed so that they were either perfectly complementary to the first 18 bases of the coding region of mouse mu-opioid receptor mRNA, or had one (Mismatch-1) or four (Mismatch-4) mismatches. On days 3, 5, 7, and 9, mice were again injected I.T. and I.C.V. with dH2O or one of the oligodeoxynucleotides. After the final injections on day 9, placebo and NTX pellets were removed, and 24 h later mice were tested for morphine analgesia or sacrificed for saturation binding studies ([3H]DAMGO). Naltrexone increased the analgesic potency of morphine in dH2O treated mice by approximately 70%. In binding studies, NTX significantly increased density of brain (approximately 60%) and spinal cord (approximately 140%) mu-opioid receptors without affecting affinity. The mu-opioid antisense and the oligodeoxynucleotide with one mismatch (Mismatch-1) significantly reduced the potency of morphine by approximately twofold in placebo-treated mice. The oligodeoxynucleotide with four mismatches (Mismatch-4) did not significantly alter morphine potency. When placebo-treated mice were treated with either the antisense to the mouse mu-opioid receptor, Mismatch-4 or Mismatch-1 there were no significant changes in the density of mu-opioid receptors. Thus, mu-opioid antisense significantly reduced morphine potency without changing mu-opioid receptor density. When NTX and oligodeoxynucleotide treatments were combined, there was no change in NTX-induced supersensitivity and mu-opioid receptor upregulation. These data suggest that opioid antagonist-induced supersensitivity and upregulation of mu-opioid receptors does not involve changes in gene expression.

The effect of the irreversible mu-opioid receptor antagonist clocinnamox on morphine potency, receptor binding and receptor mRNA

In these experiments, the effect of the irreversible mu-opioid receptor antagonist clocinnamox on the potency of morphine, opioid receptor binding and mu-opioid receptor mRNA was examined. Mice were injected with clocinnamox (0.32-12.8 mg/kg) and the analgesic potency of morphine was examined 24 h later. Clocinnamox produced a dose-dependent decrease in the potency of morphine; and at the higher dose of clocinnamox the maximal analgesic effect was not observed following doses of morphine in excess of 500 mg/kg s.c. In saturation binding studies in brain, clocinnamox (0.32-25.6 mg/kg) dose-dependently decreased mu-opioid ([3H][D-Ala2,MePhe4,Gly-ol5]enkephalin; DAMGO) receptor Bmax with relatively minimal effects on Kd. Binding to delta-opioid receptor ([3H][D-Pen2,D-Pen5]enkephalin; DPDPE) and kappa-opioid receptor ([3H](5,7,8)-(-)-N-methyl-N-(7-(1-pyrrolidinyl)-1-oxaspiro(4,5)dec -8-yl) benzeneacetamide; U69,593) was not affected by clocinnamox. The effect of clocinnamox was time-dependent in that the greatest changes in morphine potency and mu-opioid receptor density were observed within 24 h of administration and decreased with time (336 h). Although mu-opioid receptor density was decreased to less than 30% of control 24 h following clocinnamox (12.8 mg/kg) and had increased to 80% by 5 days, a solution hybridization assay for mu-opioid receptor mRNA transcript revealed no changes in the steady-state levels of this mRNA. These studies indicate that clocinnamox is an irreversible antagonist at the mu-opioid receptor since it appears to selectively affect receptor density with minimal effects on affinity. Furthermore, clocinnamox produces time- and dose-dependent changes in Bmax and these changes appear to be unrelated to changes in mu-opioid receptor mRNA. It is possible that the repopulation of brain by mu-opioid receptors following clocinnamox is mediated by an existing pool of receptors that are activated following treatment.

Supersensitivity to opioid analgesics following chronic opioid antagonist treatment: relationship to receptor selectivity

The effect of chronic opioid antagonist treatment on the analgesic potency of six opioid agonists was compared to changes in opioid receptor density and the selectivity of each agonist for mu (DAMGO), delta (DPDPE) and kappa (U69,593) opioid receptors. Mice were implanted SC with a 15-mg naltrexone or placebo pellet for 8 days. The pellets were removed and 24 h later, mice were sacrificed and binding studies were conducted, or mice were tested in analgesia (tail-flick) dose-response studies. All six analgesics acted as full agonists for both placebo and naltrexone-treated mice. Naltrexone increased the analgesic potency of methadone, etorphine, fentanyl, meperidine, and oxycodone by 1.9-3.2-fold. The analgesic potency of propoxyphene was not increased significantly (1.3-fold). In saturation binding studies in brain homogenate, naltrexone increased the Bmax of mu, delta, and kappa opioid receptors by 86, 43, and 33%, respectively, without altering Kd. Competition binding studies for each receptor type were conducted in brains from untreated mice, and KIs were determined for each agonist. All agonists had greatest selectivity toward mu compared with delta and kappa receptors. There did not appear to be an obvious relationship between receptor selectivity and the magnitude of supersensitivity. These studies indicate that supersensitivity occurs for a broad range of opioid analgesics following chronic opioid antagonist treatment in the mouse. However, the selectivity of these agonists for mu, delta, and kappa receptors does not appear to correlate with differences in supersensitivity.

The effect of intrinsic efficacy on opioid tolerance

BACKGROUND

The intrinsic efficacy of opioid analgesics has been suggested to play a role in the development of tolerance to these agents. However, the effect of differences in dosing protocol on tolerance to opioid analgesics of high or low efficacy has not been addressed. Therefore, the effect of opioid intrinsic efficacy on tolerance in mice was determined in protocols of continuous and intermittent administration of equieffective doses of opioid agonists.

METHODS

Initial antinociceptive median effective doses (ED50s) for five opioid agonists that vary in intrinsic efficacy were estimated in untreated mice. Groups of mice received continuous infusions of morphine, fentanyl, or etorphine for 72 h or 7 days from osmotic minipumps implanted subcutaneously. The infusion doses were calculated as multiples of the initial antinociceptive ED50. An inert placebo was implanted subcutaneously in controls. At the end of treatment, the pumps and placebos were removed, and 4-24 h later, mice were tested in dose-response studies (tail flick) using the same drug that had been chronically administered. In another study using intermittent dosing, mice received subcutaneous injections every 24 h for 3 days of saline or morphine, etorphine, fentanyl, oxycodone, or meperidine, or received subcutaneous injections every 24 h for 7 days of saline or morphine, etorphine, or fentanyl. Daily doses were calculated as multiples of the initial antinociceptive ED50. Twenty-four hours after the last injection, mice were tested in dose-response studies.

RESULTS

High-intrinsic-efficacy compounds (e.g., etorphine and fentanyl) produced less tolerance than a lower-intrinsic-efficacy drug (morphine) in 72-h and 7-day infusion studies. Tolerance for all compounds after intermittent treatment with equieffective doses was similar, and intrinsic efficacy had no effect on the magnitude of tolerance after intermittent dosing.

CONCLUSIONS

These results indicate that the intrinsic efficacy of opioid analgesics is inversely related to the degree of tolerance after continuous infusion, but that intrinsic efficacy does not significantly affect tolerance after once-daily intermittent administration of these agents. These findings may be of clinical utility in understanding the development of tolerance to the antinociceptive effects of opioids.

Spinal and supraspinal effects of pertussis toxin on opioid analgesia

The effects of in vivo pertussis toxin (PTX) treatment on the functional effects of opioid agonists were examined in the mouse. Mice were injected intracerebroventricularly (ICV), or intrathecally (IT), or IT and ICV with PTX, and dose-response studies of the antinociceptive action of systemic (SC) morphine, fentanyl, and etorphine were conducted 10 days later. IT PTX decreased the potency (approximately 4.5-fold) of morphine more than ICV administration (approximately 1.5-fold), whereas the combination of IT and ICV administration produced an additive effect. When PTX was administered spinally and supraspinally, the potency of morphine, fentanyl, and etorphine was reduced similarly (approximately 5-7-fold), indicating that the effect of PTX does does not vary considerably among agonists of different intrinsic efficacies. These studies indicate that in vivo PTX can reduce the potency of opioid agonists with different intrinsic efficacies, and that spinal mechanisms appear to be more sensitive to PTX treatment.

A simple procedure for assaying cAMP

A step-by-step protocol for assaying cAMP is presented. This method is based on the standard binding protein assay that is available commercially. However, using the present procedure, the per tube cost is dramatically reduced. In the current protocol, four different binding proteins are compared for their ability to bind cAMP. The source of all reagents is noted as well as necessary precautions for insuring reliable assays. A simple tissue preparation method is outlined for assaying cAMP in brain. The utility of the assay is illustrated by demonstrating the effect of forskolin on cAMP in mouse striatal tissue.

The effect of naltrindole on spinal and supraspinal delta opioid receptors and analgesia

The relationship between changes in binding for delta 1 (DPDPE) and delta 2 (DSLET) selective ligands were compared to potency changes for these ligands following naltrindole (NTI) in mice. Mice were injected s.c. with NTI (1 or 20 mg/kg) or saline and 1 hr later sacrificed for binding studies ([3H]DSLET, [3H]DPDPE) using whole brain or spinal cord. Other mice were injected s.c. with NTI (1 or 20 mg/kg) or saline and then injected IT or ICV with DSLET or DPDPE and were tested for analgesia using the tailflick test. In saturation binding studies, NTI decreased specific binding of [3H]DPDPE and [3H]DSLET in brain and spinal cord, but had no selective effect on either ligand. In contrast, in functional studies, NTI decreased analgesic potency of spinally and supraspinally administered DSLET more than DPDPE. Thus in functional studies NTI produced a selective effect on the delta 2 agonist DSLET; but in binding studies, NTI had no selective effect on the binding of [3H]DSLET and [3H]DPDPE.

Opioid antagonist-induced receptor upregulation: effects of concurrent agonist administration

The present study examined whether opioid antagonist-induced receptor upregulation could be antagonized by simultaneous treatment with opioid agonists. Mice were treated concurrently with opioid agonists (morphine, fentanyl, etorphine) and antagonists (naloxone, naltrexone) over a period of 7-8 days. Concurrent morphine (1 or 4, 75 mg SC implanted pellets), fentanyl (5.0 mg/kg/day, infusion) or etorphine (0.25 mg/kg/day, infusion) administration were unable to inhibit upregulation of mu opioid (DAMGO) receptors by either naloxone (1 mg/kg/day, infusion) or naltrexone (15 mg or 2 mg SC implanted pellet). Only a very high infusion dose of etorphine (10 mg/kg/day) inhibited upregulation by naltrexone (2mg SC implanted pellet). These results indicate that antagonist-induced upregulation is a robust, receptor-mediated phenomenon.

Opioid receptor regulation in mice

The effect of chronic treatment with opioid agonists and antagonists on mu opioid receptor density and opioid potency was examined in mice. Mice were implanted s.c. with osmotic mini-pumps that infused etorphine (50-500 micrograms/kg/day), fentanyl (0.03-5.0 mg/kg/day) or naloxone (0.1-10.0 mg/kg/day) for 7 to 8 days. Other mice were implanted s.c. with a morphine pellet (75 mg) for 3 or 7 days or were injected s.c. once daily for 7 days with fentanyl (0.3 mg/kg). At the end of treatment, saturation binding studies were conducted ([3H]DAMGO) or antinociceptive tolerance was evaluated using the tail-flick assay. Etorphine produced dose-dependent tolerance as well as down-regulation of mu receptor density. Fentanyl infusions produced upregulation of opioid receptors at lower (0.03 and 1.00 mg/kg/day) doses and down-regulation at the highest dose (5.00 mg/kg/day). The lowest fentanyl infusion dose also produced tolerance. Daily s.c. administration of fentanyl (0.30 mg/kg) increased receptor density and produced tolerance to fentanyl. Morphine pellets increased (3 day) and then had no effect (7 day) on receptor density, although tolerance to morphine was observed at 7 days. Naloxone dose-dependently increased mu opioid receptor density. Receptor affinity was not systematically altered by the drug treatments. Control binding studies indicated that acute etorphine interfered with binding at mu receptors 15 min after administration, but that all drug was eliminated by 16 hr. Thus, binding and tolerance studies using etorphine were conducted 16 hr after the end of infusion, when all drug had been eliminated.(ABSTRACT TRUNCATED AT 250 WORDS)