Constitutive activation of the mu opioid receptor by mutation of D3.49(164), but not D3.32(147): D3.49(164) is critical for stabilization of the inactive form of the receptor and for its expression

The roles of conserved aspartates in the third transmembrane domain of the rat mu opioid receptor (RMOR) were explored with mutations of D3.32(147) and D3.49(164). D3.49(164) in the highly conserved DRY motif was mutated to 13 amino acids. Except for the D3.49(164)E mutant, each mutant displayed little or no detectable [(3)H]diprenorphine binding, and pretreatment with naloxone greatly enhanced binding. D3.49(164)H, -Q, -Y, -M, and -E mutants were further studied. D3.32(147) was substituted with A or N. All seven mutants exhibited similar binding affinities for the antagonist [(3)H]diprenorphine as the wild-type. The D3.49(164)H, -Q, -Y, and -M mutants, but not the D3.49(164)E and D3.32(147) mutants, exhibited enhanced basal [(35)S]GTPgammaS binding which was comparable to the maximally activated level of the wild-type and was related to expression levels. Naloxone, naltrexone, and naloxone methiodide significantly inhibited the basal [(35)S]GTPgammaS binding of the D3.49(164) mutants, indicating inverse agonist activities. Treatment of the D3.49(164)Y mutant with pertussis toxin greatly reduced the basal [(35)S]GTPgammaS binding, demonstrating constitutive activation of Galpha(i)/Galpha(o). The D3.49(164)H, -Y, -M, and -Q mutants had higher affinities for DAMGO than the wild-type, which were not significantly lowered by GTPgammaS. Thus, mutation of D3.49(164) to H, Y, M, or Q in RMOR resulted in receptor assuming activated conformations. In contrast, the D3.49(164)E mutant displayed significantly lower basal [(35)S]GTPgammaS binding and reduced affinity for DAMGO. Upon incubation of membranes at 37 degrees C, the constitutively active D3.49(164)Y mutant was structurally less stable, whereas the inactivated D3.49(164)E mutant was more stable, than the wild-type. Computational simulations showed that the E3.49 side chain interacted strongly with the conserved R3.50 in the DRY motif and stabilized the inactive form of the receptor. Taken together, these results indicate that D3.49 plays an important role in constraining the receptor in inactive conformations.     

Receptor selectivity of Met-enkephalin-Arg6-Phe7, an endogenous opioid peptide, in cerebral cortex of human and rat

This study was undertaken to examine the receptor selectivity of Met-enkephalin-Arg6-Phe7 (MERF) employing radioreceptor binding assays in human cerebral cortex membranes, and to elucidate the responsible receptors that mediate the regulatory action of MERF on high (20 mM) K+-stimulated release of [3H]norepinephrine ([3H]-NE) in rat cortex slices. Specific binding of [3H]MERF was inhibited by DAMGO, Tyr-D-Arg-Phe-Sar(TAPS), bremazocine and ethylketocyclazocine (EKC), but not by U69,593 (U69) and DPDPE. MERF showed high affinity for specific binding sites of [3H]DAMGO. However, MERF had little influence on the specific binding of [3H]DPDPE, [3H]U69 and [3H]diprenorphine ([3H]DIP) in the presence of 1 microM each of DAMGO, DPDPE and U69. In [3H]NE release experiments using rat cortex slices, DAMGO, MERF and EKC, in order of their potency, inhibited K+-stimulated release of [3H]NE. The inhibitory effects of MERF and DAMGO were more sensitive than that of EKC to antagonism by CTAP, nor-binaltorphimine (nor-BNI) and naloxone. These results suggested that MERF possesses high affinity for mu-receptors, but not for delta-, kappa1-, and very low affinity for kappa2-receptors in human cerebral cortex membranes. Also, the inhibitory effect of MERF on the K+-stimulated release of [3H]NE appears to be mediated by mu-receptors in rat cerebral cortex slices.     

Pharmacological effects of naltriben as a ligand for opioid mu and kappa receptors in rat cerebral cortex

Naltriben (NTB) has been used to differentiate the subtypes of delta opioid receptors, delta1 and delta2. However, there is considerable evidence suggesting that NTB may act on other types of opioid receptors too. We examined the effects of NTB on the specific binding of radiolabeled ligands for opioid mu and kappa2 receptors, and the effects on the release of [3H]norepinephrine ([3H]NE) in rat cerebral cortex slices. NTB displaced the specific binding of [3H]DAMGO with Ki value of 19.79 +/- 1.12 nM in rat cortex membranes. Specific binding of [3H]diprenorphine ([3H]DIP) was inhibited by NTB with Ki value of 82.75 +/- 6.32 nM in the presence of DAMGO and DPDPE. High K+ (15 mM)-stimulated release of [3H]NE was attenuated by DAMGO in rat cerebral cortex slices. NTB (30 nM) shifted the dose-response curve of DAMGO to the right and attenuated the maximal effect. In the meantime, NTB inhibited high K+-stimulated [3H]NE release at concentrations above 100 nM. The inhibitory effect of NTB was not attenuated by CTAP (10 nM) and naloxone (3 nM) but by higher concentration of naloxone (30 nM), nor-BNI (300 nM) and bremazocine (3 nM). These results indicate that NTB, depending on the dosage, could acts not only as an antagonist at delta but also as a noncompetitive antagonist for mu receptors, and as an agonist for kappa2 receptors in rat cerebral cortex.     

Mutagenesis of a Single Amino Acid in the Rat μ-Opioid Receptor Discriminates Ligand Binding

Abstract: To investigate the role of Asp¹¹⁴ in the cloned rat μ-opioid receptor for ligand binding, the charged amino acid was mutated to an asparagine to generate the mutant μ receptor D114N. The wild-type μ receptor and the D114N mutant were then stably expressed in human embryonic kidney 293 cells, and the binding affinities of a series of opioids were investigated. The μ-selective agonists [ d -Ala²,MePhe⁴,Gly-ol⁵]enkephalin and morphine and the endogenous peptides Met-enkephalin and β-endorphin exhibited greatly reduced affinities for the D114N mutant compared with the wild-type μ receptor, as did the potent synthetic agonist etorphine. In contrast to the full agonists, the partial agonists buprenorphine and nalorphine and the antagonists diprenorphine and naloxone bound with similar affinities to the wild-type and D114N mutant μ receptors. The reduced affinities of the full agonists for the D114N mutant did not involve an uncoupling of the receptor from G proteins because methadone and etorphine stimulated the D114N μ receptors to inhibit adenylyl cyclase. Although the Asp¹¹⁴ to Asn¹¹⁴ mutation reduced full-agonist binding, mutation of His²⁹⁷ to Asn²⁹⁷ in the μ receptor did not but, in contrast, did reduce binding affinity of the partial agonist buprenorphine and the antagonist diprenorphine. These results indicate that some partial agonists and antagonists may have different determinants for binding to the μ receptor than do the prototypical full agonists.     

Activation of the mu opioid receptor involves conformational rearrangements of multiple transmembrane domains

We previously demonstrated that D3.49(164)Y or T6.34(279)K mutation in the rat mu opioid receptor (MOPR) resulted in agonist-independent activation. Here, we identified the cysteine(s) within the transmembrane domains (TMs) of the D3.49(164)Y mutant that became accessible in the binding-site crevice by use of methanethiosulfonate ethylammonium (MTSEA) and inferred conformational changes associated with receptor activation. While the C7.38(321)S mutant was insensitive to MTSEA, the D3.49(164)Y/C7.38(321)S mutant showed similar sensitivity as the D3.49(164)Y, suggesting that, in the D3.49(164)Y mutant, C7.38(321) becomes inaccessible while other cysteines are accessible in the binding-site crevice. Each of the other seven cysteines in the TMs was mutated to serine on the background of D3.49(164)Y/C7.38(321)S, and the resulting triple mutants were evaluated for [3H]diprenorphine and [d-Ala2,NMe-Phe4,Gly5-ol]-enkephalin (DAMGO) binding and effect of MTSEA on [3H]diprenorphine binding. The D3.49(164)Y/C7.38(321)S mutant and the triple mutants, except the C6.47(292)S triple mutant, retained similar affinities for [3H]diprenorphine and DAMGO as the D3.49(164)Y mutant. The second-order rate constants for MTSEA reactions showed that C3.44(159)S, C4.48(190)S, C5.41(235)S, and C7.47(330)S significantly reduced sensitivity to MTSEA, compared with the D3.49(164)Y/C7.38(321)S. These results suggest that the four cysteines may be rotated and/or tilted to become accessible. While the D3.49(164)Y/C7.38(321)S was similarly sensitive to MTSEA as the D3.49(164)Y mutant, the T6.34(279)K/C7.38(321)S was much less sensitive to MTSEA than the T6.34(279)K mutant, suggesting that the two constitutively active mutants assume different conformations and/or possess different dynamic properties. Molecular models of the MOPR monomer and homodimer, using the crystal structures of rhodopsin, the beta2-adrenergic receptor, and the ligand-free opsin, which contains several features characteristic of the active state, were employed to analyze these experimental results in a structural context.     

Morphine-induced desensitization and down-regulation at mu-receptors in 7315C pituitary tumor cells

Pituitary 7315c tumor cells maintained in culture were treated with varying concentrations of morphine from 10 nM to 300 microM, for periods of five or forty-eight hours. The ability of the mu-opioid receptor agonist, DAMGO, to inhibit forskolin-stimulated adenylyl cyclase in washed membrane preparations from the treated cells was compared with its activity in membranes from cells incubated in the absence of added morphine. In the same membrane preparations, the number and affinity of mu-opioid receptors was estimated by measurements of [3H]diprenorphine binding. After 5 hr of treatment with morphine concentrations of 100 nM or higher, a significant reduction in inhibition of adenylyl cyclase by DAMGO was observed. Little further loss of agonist activity was observed when the incubations were extended to 48 hr. After 5 hr of morphine treatment, there was no change in either the number of receptors, or their affinity for [3H]diprenorphine. However, after 48 hr of morphine treatment, greater than 25% reductions in receptor number were apparent with morphine pretreatment concentrations of 10 microM or higher. These results suggest that opioid tolerance in this system is primarily associated with a reduced ability of agonist-occupied receptor to activate the effector system. Receptor down-regulation was not necessary for loss of agonist response, although a reduction in receptor number occurred after exposure to high concentrations of morphine for periods longer than 5 hr.     

Functional role of a conserved motif in TM6 of the rat mu opioid receptor: constitutively active and inactive receptors result from substitutions of Thr6.34(279) with Lys and Asp.

Mutations within the "X1BBX2X3B" motif or its variants in the junction of the third intracellular (i3) loop and the sixth transmembrane domain (TM6) have been shown to lead to constitutive activation of several G protein-coupled receptors (GPCRs). In this study, T6.34(279) at the X3 locus of the rat mu opioid receptor was mutated to Lys and Asp, and the mutants were examined for binding and signaling properties. The T6.34(279)K mutant was poorly expressed, and pretreatment with naloxone greatly enhanced its expression. This construct exhibited properties identified previously with constitutive activation: (1) compared with the wild type, it produced much higher agonist-independent [35S]GTPgammaS binding, which was abolished by pertussis toxin treatment; (2) it displayed an enhanced affinity for the agonist DAMGO similar to that of the high-affinity state of the wild type, which was not altered by GTPgammaS, while having unchanged affinity for the antagonist diprenorphine. The T6.34(279)K mutant displayed a higher intracellular receptor pool than the wild type. Naloxone inhibited the basal [35S]GTPgammaS binding of the T6.34(279)K mutant, demonstrating inverse agonist activity at this mutant receptor. In contrast, the T6.34(279)D substitution did not increase basal [35S]GTPgammaS binding, greatly reduced agonist-promoted [35S]GTPgammaS binding, and markedly decreased affinity for DAMGO. Thus, the T6.34(279)D mutant adopts conformations corresponding to inactive states of the receptor. The results were interpreted in the structural context of a model for the mu opioid receptor that incorporates the information from the crystal structure of rhodopsin. The interaction of T6.34(279) with R3.50(165) in the mu opioid receptor is considered to stabilize the inactive conformations. The T6.34(279)K substitution would then disrupt this interaction and support agonist-free activation, while T6.34(279)D mutation should strengthen this interaction which keeps the receptor in inactive states. T6.34(279) may, in addition, interact with the neighboring R6.35(280) to help constrain the receptor in inactive states, and T6.34(279)K and T6.34(279)D mutations would affect this interaction by disrupting or strengthening it, respectively. To the best of our knowledge, the results presented here represent the first structurally rationalized demonstration that mutations of this locus can lead to dramatically different properties of a GPCR.     

Coupling efficacy and selectivity of the human mu-opioid receptor expressed as receptor-Galpha fusion proteins in Escherichia coli

Two constructs encoding the human micro-opioid receptor (hMOR) fused at its C terminus to either one of two Galpha subunits, Galpha(o1) (hMOR-Galpha(o1)) and Galpha(i2) (hMOR-Galpha(i2)), were expressed in Escherichia coli at levels suitable for pharmacological studies (0.4-0.5 pmol/mg). Receptors fused to Galpha(o1) or to Galpha(i2) maintained high-affinity binding of the antagonist diprenorphine. Affinities of the micro-selective agonists morphine, [D-Ala(2),N-Me-Phe(4),Gly(5)-ol]enkephalin (DAMGO), and endomorphins as well as their potencies and intrinsic activities in stimulating guanosine 5'-O-(3-[(35)S]thiotriphosphate) ([(35)S]GTPgammaS) binding were assessed in the presence of added purified Gbetagamma subunits. Both fusion proteins displayed high-affinity agonist binding and agonist-stimulated [(35)S]GTPgammaS binding. In the presence of Gbetagamma dimers, the affinities of DAMGO and endomorphin-1 and -2 were higher at hMOR-Galpha(i2) than at hMOR-Galpha(o1), whereas morphine displayed similar affinities at the two chimeras. Potencies of the four agonists in stimulating [(35)S]GTPgammaS binding at hMOR-Galpha(o1) were similar, whereas at hMOR-Galpha(i2), endomorphin-1 and morphine were more potent than DAMGO and endomorphin-2. The intrinsic activities of the four agonists at the two fusion constructs were similar. The results confirm hMOR coupling to Galpha(o1) and Galpha(i2) and support the hypothesis of the existence of multiple receptor conformational states, depending on the nature of the G protein to which it is coupled.     

14 beta-(Bromoacetamido)morphine irreversibly labels mu opioid receptors in rat brain membranes

The binding properties of 14 beta-(bromoacetamido)morphine (BAM) and the ability of BAM to irreversibly inhibit opioid binding to rat brain membranes were examined to characterize the affinity and selectivity of BAM as an irreversible affinity ligand for opioid receptors. BAM had the same receptor selectivity as morphine, with a 3-5-fold decrease in affinity for the different types of opioid receptors. When brain membranes were incubated with BAM, followed by extensive washing, opioid binding was restored to control levels. However, when membranes were incubated with dithiothreitol (DTT), followed by BAM, and subsequently washed, 90% of the 0.25 nM [3H] [D-Ala2,(Me)Phe4,Gly(ol)5]enkephalin (DAGO) binding was irreversibly inhibited as a result of the specific alkylation of a sulfhydryl group at the mu binding site. This inhibition was dependent on the concentrations of both DTT and BAM. The mu receptor specificity of BAM alkylation was demonstrated by the ability of BAM alkylated membranes to still bind the delta-selective peptide [3H] [D-penicillamine2,D-penicillamine5]enkephalin (DPDPE) and (-)-[3H]bremazocine in the presence of mu and delta blockers, selective for kappa binding sites. Under conditions where 90% of the 0.25 nM [3H]DAGO binding sites were blocked, 80% of the 0.8 nM [3H]naloxone binding and 50% of the 0.25 nM 125I-labeled beta h-endorphin binding were inhibited by BAM alkylation. Morphine and naloxone partially protected the binding site from alkylation with BAM, while ligands that did not bind to the mu site did not afford protection.2+hese studies have demonstrated that when a disulfide bond     

A single nucleotide polymorphic mutation in the human mu-opioid receptor severely impairs receptor signaling

Large scale sequencing of the human mu-opioid receptor (hMOR) gene has revealed polymorphic mutations that occur within the coding region. We have investigated whether the mutations N40D in the extracellular N-terminal region, N152D in the third transmembrane domain, and R265H and S268P in the third intracellular loop alter functional properties of the receptor expressed in mammalian cells. The N152D receptor was produced at low densities. Binding affinities of structurally diverse opioids (morphine, diprenorphine, DAMGO and CTOP) and the main endogenous opioid peptides (beta-endorphin, [Met]enkephalin, and dynorphin A) were not markedly changed in mutant receptors (<3-fold). Receptor signaling was strongly impaired in the S268P mutant, with a reduction of efficacy and potency of several agonists (DAMGO, beta-endorphin, and morphine) in two distinct functional assays. Signaling at N40D and R265H mutants was highly similar to wild type, and none of the mutations induced detectable constitutive activity. DAMGO-induced down-regulation of receptor-binding sites, following 20 h of treatment, was identical in wild-type and mutant receptors. Our data show that natural sequence variations in hMOR gene have little influence on ligand binding or receptor down-regulation but could otherwise modify receptor density and signaling. Importantly, the S268P mutation represents a loss-of-function mutation for the human mu-opioid receptor, which may have an incidence on opioid-regulated behaviors or drug addiction in vivo.     

Solubilization of High-Affinity,Guanine Nucleotide-Sensitive μ-Opioid Receptors from Rat Brain Membranes

Abstract: High-affinity μ-opioid receptors have been solubilized from rat brain membranes. In most experiments, rats were treated for 14 days with naltrexone to increase the density of opioid receptors in brain membranes. Occupancy of the membrane-associated receptors with morphine during solubilization in the detergent 3-[(3-cholamidopropyl)dimethyl]-1-propane sulfonate appeared to stabilize the μ-opioid receptor. After removal of free morphine by Sephadex G50 chromatography and adjustment of the 3-[(3-cholamidopropyl)dimethyl]-1-propane sulfonate concentration to 3 mM, the solubilized opioid receptor bound [³H][d -Ala²,N-Me-Phe⁴,Gly-ol⁵]-enkephalin ([³H]DAMGO), a μ-selective opioid agonist, with high affinity (K_D = 1.90 ± 0.93 nM; B_max = 629 ± 162 fmol/mg of protein). Of the membrane-associated [³H]-DAMGO binding sites, 29 ± 7% were recovered in the solubilized fraction. Specific [³H]DAMGO binding was completely abolished in the presence of 10 µM guanosine 5′-O-(3-thiotriphosphate). The solubilized receptor also bound [³H]diprenorphine, a nonselective opioid antagonist, with high affinity (K_D = 1.4 ± 0.39 nM, B_max = 920 ± 154 fmol/mg of protein). Guanosine 5′-O-(3-thiotriphosphate) did not diminish [³H]diprenorphine binding. DAMGO at concentrations between 1 nM and 1 µM competed with [³H]diprenorphine for the solubilized binding sites; in contrast, [d -Pen²,d -Pen⁵]-enkephalin, a δ-selective opioid agonist, and U50488H, a κ-selective opioid agonist, failed to compete with [³H]diprenorphine for the solubilized binding sites at concentrations of <1 µM. In the absence of guanine nucleotides, the DAMGO displacement curve for [³H]diprenorphine binding sites better fit a two-site than a one-site model with K_Dhigh = 2.17 ± 1.5 nM, B_max = 648 ± 110 fmol/mg of protein and K_Dlow = 468 ± 63 nM, B_max = 253 ± 84 fmol/mg of protein. In the presence of 10 µM guanosine 5′-O-(3-thiotriphosphate), the DAMGO displacement curve better fit a one- than a two-site model with K_D = 815 ± 33 nM, B_max = 965 ± 124 fmol/mg of protein.     

Molecular basis for the interaction of histamine with the histamine H2 receptor.

We undertook these studies to characterize the molecular basis of the interaction of histamine with the H2 receptor. Key areas of homology in the structures of the histamine H2 and beta 2 adrenergic receptor suggested specific transmembrane amino acids that might be important for binding of histamine. A third transmembrane aspartic acid of the histamine receptor (Asp98), thought to serve as a counter anion that interacts with the cationic amine moiety of histamine, was mutated to Asn98, and the mutated receptor was expressed in Hepa cells. Removal of the negatively charged amino acid abolished both binding of the H2 receptor antagonist [methyl-3H]tiotidine and histamine stimulated increases in cellular cAMP content. Mutation of a fifth transmembrane aspartic acid (Asp186) to Ala186 or Asn186 by itself or in conjunction with mutation of another fifth transmembrane amino acid (Thr190 to Ala190) resulted in a loss of [methyl-3H] tiotidine binding, although the generation of cAMP in response to histamine was maintained. The histamine receptor with only a Thr190 to Ala190 or Cys190 mutation retained the ability to bind [methyl-3H]tiotidine, but both the affinity and efficacy of binding were reduced. These data lead us to propose a model for histamine binding in which Asp98 is essential for histamine binding and action, Asp186 defines H2 selectivity, and Thr190 is important in establishing the kinetics of histamine binding, but is not essential for H2 selectivity.     

Role of Asp187 and Gln190 in the Na+/proline symporter (PutP) of Escherichia coli

Asp187 and Gln190 were predicted as conserved and closely located at the Na(+) binding site in a topology and homology model structure of Na(+)/proline symporter (PutP) of Escherichia coli. The replacement of Asp187 with Ala or Leu did not affect proline transport activity; whereas, change to Gln abolished the active transport. The binding affinity for Na(+) or proline of these mutants was similar to that of wild-type (WT) PutP. This result indicates Asp187 to be responsible for active transport of proline without affecting the binding. Replacement of Gln190 with Ala, Asn, Asp, Leu and Glu had no effect on transport or binding, suggesting that it may not have a role in the transport. However, in the negative D187Q mutant, a second mutation, of Gln190 to Glu or Leu, restored 46 or 7% of the transport activity of WT, respectively, while mutation to Ala, Asn or Asp had no effect. Thus, side chain at position 190 has a crucial role in suppressing the functional defect of the D187Q mutant. We conclude that Asp187 is responsible for transport activity instead of coupling-ion binding by constituting the translocation pathway of the ion and Gln190 provides a suppressing mutation site to regain PutP functional activity.     

Binding sites of opiates and endogenous opioids in the oocytes of the toad Bufo viridis

The binding of labelled naloxone, morphine and (D-Ala2,D-Leu5)enkephalin (DADL) to oocyte membranes of the toad Bufo viridis was investigated. The opiate antagonist naloxone binds to the membranes much more effectively than morphine or DADL. The binding of [3H]naloxone is reversible and saturating. The bound [3H]naloxone is readily replaced by unlabelled naloxone or bremazocine (kappa-agonist), far less effectively by morphine (mu-agonist) and SKF 10.047 (sigma-agonist) and is not practically replaced by DADL (delta-agonist), beta-endorphin (epsilon-agonist) and other neuropeptides. Analysis of experimental results in Scatchard plots revealed two types of binding sites with a high (Kd = 15 nM) and low (Kd = 10(3) nM) affinity for naloxone. The number of sites responsible for the binding of naloxone possessing a high affinity is 16 pmol-/mg of oocyte homogenate protein, i.e., 20-50 times as great as in the toad or rat brain. Trypsin and p-chloromercurybenzoate decrease the binding of [3H]naloxone. The oocyte extract is capable of replacing the membrane-bound [3H]naloxone, on the one hand, and of inhibiting the smooth muscle contracture of the rabbit vas deferens, on the other. This inhibition is reversed by naloxone and can also be induced by bremazocine, but not by morphine, DADL and SKF 10.047. In all probability oocytes contain compounds that are similar to opiate kappa-agonists. It may also be possible that these compounds mediate their effects via specific receptors and are involved in the control over maturation of oocytes and early development of toad eggs.     

Differential Effects of Mg2+ and Other Divalent Cations on the Binding of Tritiated Opioid Ligands

The effects of MgCl2 on the binding of tritiated ligands to opioid binding sites in homogenates of guinea-pig brain in HEPES buffer have been studied. The binding of tritiated mu-, delta-, and kappa-opioid agonists was promoted in a concentration-dependent manner over a range of MgCl2 concentrations from 0.1 mM to 10 mM, as was binding of the nonselective antagonists [3H]diprenorphine and [3H]naloxone. At concentrations of MgCl2 above 10 mM reversal of this effect was observed. The effects of MgCl2 on binding parameters differed at each site. The promoting effects of MgCl2 were mimicked by MnCl2, CaCl2, and MgSO4, but CoCl2 and ZnCl2 were inhibitory. Following treatment of guinea-pig brain synaptosomes at pH 11.5 to eliminate G proteins, the binding of the mu-opioid agonist [3H][D-Ala2, MePhe4, Gly-ol5]enkephalin and [3H]naloxone was much reduced but binding of [3H]diprenorphine was unaffected. Under these conditions MgCl2 still promoted binding of [3H]diprenorphine. The results suggest that Mg2+ ions promote binding by an action at the opioid receptor, even in the absence of G protein, and that opioid antagonists may differ in their recognition of opioid receptor binding sites.     

ASP147 in the third transmembrane helix of the rat mu opioid receptor forms ion-pairing with morphine and naltrexone.

We tested the hypotheses that the carboxylate side chain of Asp147 of the mu opioid receptor interacts with the protonated nitrogen of naltrexone and morphine and that this interaction is important for pharmacological properties of the two compounds. Mutation of Asp147 to Ala or Asn substantially reduced the affinity of naltrexone and the affinity, potency and efficacy of morphine, while the Glu mutant had similar properties as the wildtype, indicating the significant role of the carboxylate group of Asp147 in receptor binding and activation. This role could be due to its direct interaction with ligands or involvement in interhelical interactions. The unprotonated analogs of naltrexone and morphine, cyclopropylcarbonyl noroxymorphone (CPCNOM) and N-formylnormorphine (NFNM), respectively, were used to discriminate between these mechanisms. CPCNOM was much less potent as an antagonist and had substantially lower affinity for the mu receptor than naltrexone. Similarly, NFNM was unable to activate the mu receptor and had much lower affinity than morphine. These results indicate the importance of the protonated nitrogen. Notably, the D147A and D147N mutations did not appreciably affect the binding affinities of CPCNOM and NFNM. In addition, the D147E mutant had similar affinities for CPCNOM and NFNM as the D147A and D147N mu receptors. Thus, the carboxylate group of Asp147 is not important for binding of the two unprotonated compounds. These results indicate that the carboxylate group of Asp147 of the mu receptor interacts directly with the protonated nitrogen of naltrexone and morphine and this interaction is important for binding and receptor activation.     

Interaction of leucine enkephalin with (3H)naloxone binding in rat brain: Evidence for an opioid receptor complex

We recently presented evidence that distinct morphine and enkephalin receptors coexist in an opioid receptor complex (Mol. Pharmacol. 21:548-557, 1982). In this paper, we present data which demonstrate that in the presence of sodium leucine enkephalin noncompetitively inhibits the binding of [3H]naloxone to a crude particulate fraction of rat brain. Since the binding site labeled by [3H]naloxone in the presence of sodium may be an alternate conformation of the morphine receptor, these data provide further evidence that morphine and enkephalin receptors are allosterically coupled.     

Key Residues Defining the μ-Opioid Receptor Binding Pocket: A Site-Directed Mutagenesis Study

Abstract: Structural elements of the rat μ-opioid receptor important in ligand receptor binding and selectivity were examined using a site-directed mutagenesis approach. Five single amino acid mutations were made, three that altered conserved residues in the μ, δ, and κ receptors (Asn¹⁵⁰ to Ala, His²⁹⁷ to Ala, and Tyr³²⁶ to Phe) and two designed to test for μ/δ selectivity (Ile¹⁹⁸ to Val and Val²⁰² to Ile). Mutation of His²⁹⁷ in transmembrane domain 6 (TM6) resulted in no detectable binding with [³H]DAMGO (³H-labeled d -Ala², N -Me-Phe⁴,Gly-ol⁵-enkephalin), [³H]bremazocine, or [³H]ethylketocyclazocine. Mutation of Asn¹⁵⁰ in TM3 produces a three- to 20-fold increase in affinity for the opioid agonists morphine, DAMGO, fentanyl, β-endorphin_1–31, JOM-13, deltorphin II, dynorphin_1–13, and U50,488, with no change in the binding of antagonists such as naloxone, naltrexone, naltrindole, and nor-binaltorphamine. In contrast, the Tyr³²⁶ mutation in TM7 resulted in a decreased affinity for a wide spectrum of μ, δ, and κ agonists and antagonists. Altering Val²⁰² to Ile in TM4 produced no change on ligand affinity, but Ile¹⁹⁸ to Val resulted in a four- to fivefold decreased affinity for the μ agonists morphine and DAMGO, with no change in the binding affinities of κ and δ ligands.     

Studies on the effects of glucose in vitro and of the glycaemic state in vivo on the binding characteristics of mu, delta and kappa opiate receptors in mouse brain.

The effect of glucose on the binding characteristics of opiate receptor subtypes was investigated in brain membranes from normoglycaemic lean Aston (C57BL/6J) mice using [3H][D-Ala2,MePhe4,Gly5-ol]enkephalin (DAMGO), [3H][D-Pen2,D-Pen5]enkephalin (DPDPE) and [3H]U69,593 as selective ligands for mu, delta and kappa opiate receptors respectively. The equilibrium dissociation constants (Kd) and maximal binding capacities (Bmax) of [3H]DAMGO and [3H]DPDPE were unaltered by 20mM glucose in vitro. Similarly, [3H]U69,593 binding was not modified by increasing the concentration of glucose from 0 to 20mM (P between 0.10 and 0.05), or by the presence of 20mM fructose and of 20mM 3-O-me-glucose, a non-metabolisable sugar, in the incubation medium. The nonselective opiate ligand, [3H]diprenorphine, bound with similar affinity and binding capacity to brain membranes prepared from control and streptozotocin-diabetic Swiss (CD1) mice. The addition of 20mM glucose or of 20mM fructose in vitro induced no changes in their binding parameters. The affinity and binding capacity of [3H]U69,593 to STZ-diabetic Swiss mouse brain membranes was not significantly different to that of normoglycaemic controls; 20mM glucose in vitro had no effect on ligand binding to kappa sites in STZ-diabetic mouse brain membranes. We conclude that glucose does not interact directly with the opiate receptor to modfy it in such as way as could explain the altered sensitivity to different opioid agonists seen in obese and hyperglycaemic animal models in vivo.