Identification of an opioid receptor subunit carrying the mu binding site

The enkephalin affinity reagent [3H]Tyr-D-Ala-Gly-Phe-Leu-CH2Cl [( 3H]DALECK) was synthesized. It exhibited high-affinity reversible binding, at pH 7.4, to both mu and delta opioid receptor sites in rat brain membranes. At pH 8.1, nanomolar levels of [3H]DALECK produced an irreversible labeling in synaptic membranes, essentially only in one subunit of 58 000 daltons. The irreversible phase of the reaction reduced the subsequent binding of a mu-selective enkephalin derivative but not that of a delta-selective one. It is concluded that a mu subunit of the opioid receptor exists, can be alkylated specifically, and is of Mr 58 000.     

Covalent labeling of opioid receptors with 3H-D-Ala2-Leu5-enkephalin chloromethyl ketone. I. Binding characteristics in rat brain membranes

The chloromethyl ketone derivative of D-Ala2-Leu5-enkephalin was synthesized in a radioactive form, and the resulting compound (3H-DALECK) was used to label opioid receptors. 3H-DALECK binds with high affinity, specificity and saturability to rat brain membranes. The number of sites labeled is 130 fmoles/mg protein. Unlabeled opioids inhibited the binding of 3H-DALECK; etorphine and DAGO being most potent. A 10-fold preference for mu sites over delta was seen in site-specific competition experiments; while DALECK displayed low affinity for kappa sites of rat brain. DALECK irreversibly blocked a certain population of sites. Approximately 40% of 3H-DALECK binding at 15 min, and 60% at 60 min association time did not dissociate in the presence of a large excess of unlabeled DALECK and was resistant to washing. Autoradiography performed after SDS-PAGE revealed specific alkylation of proteins with molecular weight of 74, 65, 56, 43 and 34 kD. These results demonstrate the applicability of using 3H-DALECK to covalently label opioid receptors.     

The identification and characteristics of subpopulations of alpha 1-adrenergic receptors

Rat liver and brain alpha 1-adrenergic receptors were purified 500 fold by successive chromatographic steps using heparin- and wheat germ agglutinin-agarose; an affinity matrix constructed by coupling CP85.224 (a derivative of prazosin) to affigel 102. It is shown that the existence in brain of an alpha 1-adrenergic receptor subpopulation, which is structurally distinct from that previously characterized. Chlorethylclonidine, irreversibly inactivates [3H] prazosin binding sites in partially purified membrane preparations of rat liver. Under identical conditions, only 50% of receptors are irreversibly inactivated. Computer modelling of data obtained from the competition by the alpha-antagonists, WB 4101 and phentolamine, for [3H] prazosin binding to partially purified preparations of rat liver is best fit by assuming a single low-affinity site for both ligands. However, the partially purified brain preparations indicates the presence of two affinity binding sites for these antagonists. Prior alkylation of brain receptors with chlorethylclonydyne results in the loss of the low-affinity phentolamine and WB4101 binding sites. These data provide evidence for the existence of a single receptor subpopulation (alpha 1b) in rat liver and for two subpopulations (alpha 1a and alpha 1b) in rat brain. The significance of these results in understanding the signal mechanisms which allow cellular responsiveness to alpha 1-adrenergic receptor agonists is discussed.     

Study of frog sartorius muscle acetylcholine receptor using the irreversible inhibitor TDF

Summary The response of normal and denervated frog sartorius muscles to several agonists differing in intrinsic activity was studied using the fluid electrode technique. The response to carbamylcholine could be irreversibly blocked by exposure of the muscles top-trimethylammoniumbenzenediazonium difluoroborate (TDF), but the response could be protected from blockage by agonists and antagonists indicating that both TDF and these ligands act at the acetylcholine binding site of the receptor. It is shown that specific reversible binding of the trimethylammonium group of TDF to the receptor plays little or no role in the irreversible reaction of TDF with the receptor, which accounts for the extremely low specificity of its reaction with the receptor.This work is taken from a thesis presented by J. M. Lindstrom in partial fulfillment of the requirements for the Ph. D. degree in Biology at the University of California, June 1971.     

EGF induces increased ligand binding affinity and dimerization of soluble epidermal growth factor (EGF) receptor extracellular domain.

The binding of epidermal growth factor (EGF) to its cell surface receptor (EGF-R) results in a number of intracellular responses including the activation of the receptor intracellular tyrosine kinase. Receptor oligomerization induced by ligand binding has been suggested to play an important role in signal transduction. However, the mechanisms involved in oligomerization and signal transduction are poorly understood. We have produced and purified several milligrams of recombinant extracellular domain of the EGF receptor (EGF-Rx) using the baculovirus/insect cell expression system. The baculovirus-generated EGF-Rx is glycosylated, has had its signal peptide correctly cleaved, and exhibits a dissociation constant for EGF similar to that for solubilized full-length receptor, of about 100 nM. The binding of EGF to EGF-Rx leads to the formation of receptor dimers and higher oligomerization states which are irreversibly captured using the covalent cross-linking agent disuccinimidyl suberate. Interestingly, purified receptor monomers and dimers, stabilized by the cross-linker in the presence of EGF, exhibit increased binding affinity toward EGF as compared with receptor monomers which have not been exposed to EGF. It appears that the high affinity state of receptor can be maintained by the covalent cross-linking agent. These results indicate that in addition to ligand binding, the extracellular domain of EGF receptor possesses the inherent ability to undergo ligand-induced dimerization and that the low affinity state is converted to a high affinity state by EGF.     

Reconstitution of active acetylcholine receptor by hybridisation of binding site-blocked with ion channel-blocked acetylcholine receptor protein

The nicotinic acetylcholine receptor regulates the ion permeability of the postsynaptic membrane. This report presents evidence that the transmitter binding site and the ion channel may be located on distinct subunits. By hybridisation of receptor complexes, in which the transmitter binding site was blocked with complexes in which the ion channel was irreversibly inhibited, we reconstituted active acetylcholine receptor complexes. The reconstituted system was similar to the native receptor in its ability to regulate the ion permeability of lipid vesicles in response to nicotinic cholinergic effectors.     

N-Bromoacetyl-amino-cyanopindolol: a highly potent beta-adrenergic affinity label blocks irreversibly a non-protein component tightly associated with the receptor

A new chemical affinity label for the beta-adrenergic receptor, based on the structure of pindolol, has been synthesized and iodinated with 125I. The compound, N-bromoacetylamino-cyanopindolol (BAM-CYP), has an apparent dissociation constant of 44 +/- 7 pM towards the turkey erythrocyte membranes. This compound blocks irreversibly both the ability of beta-adrenergic receptors to bind 125I-cyanopindolol and the ability of beta-receptors to activate adenylate cyclase in the presence of beta-agonists. Furthermore, the irreversible binding of BAM-CYP to half of the beta-receptor sites abolishes the ligand binding activity of all the sites. These findings suggest that the beta-receptor is oligomeric in its native state. Although 125I-BAM-CYP blocks irreversibly and specifically the beta-adrenergic receptor, it does so by labeling a non-protein component, most probably a water-soluble lipid. The labeling is stereospecific since it is prevented by l-propranolol and not by d-propranolol. It is suggested that this lipid is tightly associated with the receptor in close proximity to the binding site. It is also suggested that this water-soluble lipid fraction may prove crucial for the optimal interaction between the beta-adrenergic receptor and the components of adenylate cyclase.     

The actions of naloxazone on the binding and analgesic properties of morphiceptin (NH2Tyr-Pro-Phe-Pro-CONH2), a selective mu-receptor ligand

Active in both binding and biological assays, morphiceptin (NH₂ Tyr-Pro-Phe-Pro-CONH₂), a potent opioid peptide derivative of β-casamorphine, binds specifically and selectively to mu or morphine-type receptors with little affinity for delta sites. Displacement studies of a variety of ³H-labeled opiates and enkephalins show biphasic curves. Naloxazone, which blocks irreversibly and selectively high affinity opiate and enkephalin binding, abolishes morphiceptin's inhibition of binding at low concentrations, suggesting that the high affinity binding of enkephalins and opiates represents a mu or morphine-type receptor. Unlike the reversible antagonist naloxone, naloxazone treatment $\text{in}$$\text{vivo}$ inhibits for over 24 hours the analgesic activity of morphiceptin like it inhibits morphine, β-endorphin and enkephalin analgesia. Together, these studies imply that opiates and enkephalins bind with highest affinity to a mu receptor which mediates their analgesic activity. The ³H-D-ala²-D-leu⁵-enkephalin binding remaining after naloxazone treatment, representing a lower affinity site (K_D 4 nM), is quite insensitive to morphiceptin inhibition and has the characteristics of a delta receptor. However, the ³H-dihydromorphine binding present after naloxazone treatment, which also represents a lower affinity site (K_D 6 nM), is far more sensitive to both morphine and morphiceptin and may represent a second morphine-like, or mu, receptor.     

Metaphit inhibits dopamine transport and binding of [3H]methylphenidate, a proposed marker for the dopamine transport complex

Metaphit, an acylating derivative of phencyclidine, was shown to interact with components of the dopamine nerve terminal in rat striatal tissue. This compound, previously demonstrated to be an irreversible inhibitor at the phencyclidine receptor, was shown in these experiments to irreversibly inhibit synaptosomal [3H]dopamine uptake. It also inhibited binding of [3H]methylphenidate to its recognition site, which is thought to be a subunit of the dopamine transporter. Although the inhibition was due primarily to a reduction in the binding and transport capacity of the systems studied, increases in the apparent KD of [3H]methylphenidate and the Km of [3H]dopamine were also observed. Differences in the behavior of Metaphit and phencyclidine in these dopaminergic systems compared to their effects on the NMDA receptor-linked phencyclidine receptor suggest that Metaphit may be interacting with two distinct molecular sites in the rat striatum.     

Covalent labeling of opioid receptors with 3H-D-Ala2-Leu5-enkephalin chloromethyl ketone. II. Binding characteristics in frog brain membranes

3H-D-Ala2-Leu5-enkephalin chloromethyl ketone (3H-DALECK) was used to label opioid receptors of frog brain membranes. We have previously shown (15) that 70% of the opioid receptors are of kappa type in this preparation. The binding of 3H-DALECK was of high affinity, half maximal binding being achieved by 0.9 nM of the radioligand. The number of sites labeled was calculated to be 108 fmol/mg protein. Opioid ligands, incubated with the membranes prior to the label, inhibited 3H-DALECK binding with the following rank order:etorphine greater than EKC greater than DAGO greater than DALECK greater than DADLE. Dissociation experiments showed that 70% of the binding is irreversible. Fluorography performed after SDS-PAGE revealed specific covalent labeling of protein subunits of 90, 58 and 20 kD molecular weights. Results will be compared to those obtained in rat brain (13). Our two studies demonstrate that 3H-DALECK is a useful probe for investigation the subunit structure of opioid receptors.     

Studies on opioid receptor selectivity of beta-endorphin antagonists

Opioid receptor selectivity of several beta-endorphin (beta-EP) analogs which antagonize beta-EP-induced analgesia has been assessed using partially selective binding assays. Although the apparent affinity dissociation constant of beta-EP in these assays varies from 0.2 to 360 nm, the potency of beta-EP antagonists relative to beta-EP remains largely unchanged. It is unlikely that differences in receptor affinities can account for the antagonist properties of these analogs in vivo.     

Fluorescent and photoactivatable fluorescent derivatives of tetrodotoxin to probe the sodium channel of excitable membranes

Fluorescent and photoactivatable fluorescent derivatives of tetrodotoxin (TTX) have been synthesized. N-Methylanthraniloylglycine hydrazide, anthraniloyl hydrazide, and 2-azidoanthraniloylglycine hydrazide were coupled to the carbonyl at C6 of oxidized tetrodotoxin to form stable fluorescent hydrazones. The C6 ketone can be reductively aminated with either ammonium or methylammonium acetate to form 6-amino- or 6-(methylamino)tetrodotoxin, which can then be acylated by a variety of fluorescent reagents. The biological activity, competitive binding with [3H]tetrodotoxin for the receptor on rat axonal membranes, and equilibrium binding isotherms obtained by fluorescence enhancement or anisotropy indicate that the derivatives are only about 2-5 times less active then tetrodotoxin itself. The 2-azidoanthraniloylglycine hydrazone of oxidized tetrodotoxin, when activated by light, generates a reactive nitrene which is capable of covalent insertion into the toxin receptor. The product of the photolysis is a highly fluorescent tetrodotoxin derivative which is irreversibly linked to the receptor site. The excitation and emission spectra of the fluorescent tetrodotoxin derivatives vary with solvent polarity, and this sensitivity has been used to determine the immediate environmental characteristics of the toxin binding site of the sodium channel. It is concluded that the toxin binding site is highly polar. Emission and excitation spectra reveal that radiationless energy is transferred from tryptophan residues of the receptor to the anthraniloyl group of the TTX derivatives.     

P2y(12), a new platelet ADP receptor, target of clopidogrel

The binding characteristics of (33)P-2MeS-ADP, a stable analogue of ADP, were determined on CHO cells transfected with the human P2Y(12) receptor, a novel purinergic receptor. These transfected CHO cells displayed a strong affinity for (33)P-2MeS-ADP, the binding characteristics of which corresponded in all points to those observed on platelets. In particular, this receptor recognised purines with the following order of potency: 2MeS-ADP = 2MeS-ATP > ADP = ATPgammaS = ATP > UTP, a binding profile which is similar to that obtained in platelets. The binding of (33)P-2MeS-ADP was antagonised by pCMPS but not by MRS2179 and FSBA, antagonists of P2Y(1) and aggregin, respectively. Moreover, the binding of (33)P-2MeS-ADP to these cells was strongly and irreversibly inhibited by the active metabolite of clopidogrel with a potency which was consistent with that observed for this compound on platelets. Like in platelets, 2MeS-ADP induced adenylyl cyclase down-regulation in these P2Y(12) transfected CHO cells, an effect which was absent in the corresponding non-transfected cells. As already shown in platelets, the active metabolite of clopidogrel antagonised 2MeS-ADP-induced inhibition of adenylyl cyclase on transfected cells. Our results confirm that P2Y(12) is the previously called "platelet P2t(AC)" receptor and show that this receptor is antagonised by the active metabolite of clopidogrel.     

Temperature-dependent interaction of the bovine hippocampal serotonin(1A) receptor with G-proteins

The ligand binding and G-protein coupling of the bovine hippocampal 5-HT1A receptor as a function of temperature was monitored. There is an almost complete and irreversible loss in agonist binding at 50 degrees C. However, the antagonist binding is reduced only by 50%, and this could be reversed if the temperature is lowered to 25 degrees C. Interestingly, the agonist binding of the 5-HT1A receptor in membranes exposed to 50 degrees C is inhibited to a much lesser extent by GTP-gamma-S, a non-hydrolysable analogue of GTP, indicating uncoupling of the 5-HT1A receptor to G-proteins at 50 degrees C. We propose that high temperature selectively and irreversibly inactivates G-proteins thereby affecting G-protein-receptor interaction and agonist binding of the 5-HT1A receptor.     

Analysis of the adrenal angiotensin II receptor with the photoaffinity labeling method

The angiotensin II (Asp-Arg-Val-Tyr-Ile-His-Pro-Phe, AT) receptor of bovine adrenocortex has been investigated with photosensitive analogues of AT. In a first series of experiments, we have shown that isolated cortical cells secrete aldosterone in a permanent and specific manner if they have been photolyzed in the presence of the photolabel [Sar1,(4'-N3)Phe8]AT. This permanent stimulation is in contrast to the smooth muscle assays where under similar conditions a permanent and specific block was always observed. It is assumed that the irreversible occupation of the AT receptor produces this effect. In a second type of experiment, we have shown that the AT binding site on adrenocortical membranes can be specifically and irreversibly occupied under similar conditions and that this occupation can be prevented in a competitive manner by the presence of nonphotosensitive hormone. Using a radioactive label, [Sar1,(3'-125I)Tyr4,(4'-N3)Phe8]AT, we have identified the AT receptor as a 300-kDa protein by means of gel filtration under nonreducing and nondenaturating conditions. Under reducing and denaturing conditions, a subunit of 60 kDs was found by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration. The AT receptor is proposed to be a 300-kDa protein with one binding subunit of 60 kDa.     

Characterization of Curaremimetic Neurotoxin Binding Sites on Cellular Membrane Fragments Derived from the Rat Pheochromocytoma PC 12

Studies were conducted on the properties of 125I-labeled alpha-bungarotoxin binding sites on cellular membrane fragments derived from the PC12 rat pheochromocytoma. Two classes of specific toxin binding sites are present at approximately equal densities (50 fmol/mg of membrane protein) and are characterized by apparent dissociation constants of 3 and 60 nM. Nicotine and d-tubocurarine are among the most potent inhibitors of high-affinity toxin binding. The affinity of high-affinity toxin binding sites for nicotinic cholinergic agonists is reversibly or irreversibly decreased, respectively, on treatment with dithiothreitol or dithiothreitol and N-ethylmaleimide. The nicotinic receptor affinity reagent bromoacetylcholine irreversibly blocks high-affinity toxin binding to PC12 cell membranes that have been treated with dithiothreitol. Two polyclonal antisera raised against the nicotinic acetylcholine receptor from Electrophorus electricus inhibit high-affinity toxin binding. These detailed studies confirm that curaremimetic neurotoxin binding sites on the PC12 cell line are comparable to toxin binding sites from neural tissues and to nicotinic acetylcholine receptors from the periphery. Because toxin binding sites are recognized by anti-nicotinic receptor antibodies, the possibility remains that they are functionally analogous to nicotinic receptors.     

Photochemistry as a tool in investigating ionic channels: Photoaffinity probes

TPMP is a noncompetitive inhibitor of the nicotinic acetycholine receptor which blocks agonist-induced ion flux by directly interacting with the receptor's ion channel. By activation with UV light it can be made to react covalently with its binding site in the receptor protein. Here a method is described to perform this photolabeling with a time resolution comparable to the physiological event of channel opening and closing. By this technique structural transitions within the receptor can be visualized and transient conformational states can be labeled covalently and irreversibly.     

Photoaffinity labeling of A1-adenosine receptors

The ligand-binding subunit of the A1-adenosine receptor has been identified by photoaffinity labeling. A photolabile derivative of R-N6-phenylisopropyladenosine, R-2-azido-N6-p-hydroxyphenylisopropyladenosine (R-AHPIA), has been synthesized as a covalent specific ligand for A1-adenosine receptors. In adenylate cyclase studies with membranes of rat fat cells and human platelets, R-AHPIA has adenosine receptor agonist activity with a more than 60-fold selectivity for the A1-subtype. It competes for [3H]N6-phenylisopropyladenosine binding to A1-receptors of rat brain membranes with a Ki value of 1.6 nM. After UV irradiation, R-AHPIA binds irreversibly to the receptor, as indicated by a loss of [3H]N6-phenylisopropyladenosine binding after extensive washing; the Ki value for this photoinactivation is 1.3 nM. The p-hydroxyphenyl substituent of R-AHPIA can be directly radioiodinated to give a photoaffinity label of high specific radioactivity (125I-AHPIA). This compound has a KD value of about 1.5 nM as assessed from saturation and kinetic experiments. Adenosine analogues compete for 125I-AHPIA binding to rat brain membranes with an order of potency characteristic for A1-adenosine receptors. Dissociation curves following UV irradiation at equilibrium demonstrate 30-40% irreversible specific binding. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates that the probe is photoincorporated into a single peptide of Mr = 35,000. Labeling of this peptide can be blocked specifically and stereoselectively by adenosine receptor agonists and antagonists in a manner which is typical for the A1-subtype. The results indicate that 125I-AHPIA identifies the ligand-binding subunit of the A1-adenosine receptor, which is a peptide with Mr = 35,000.     

The galactose-recognizing system of rat peritoneal macrophages. Receptor-mediated binding and uptake of glycoproteins

Binding and phagocytosis of sialidase-treated cells by peritoneal macrophages is mediated by a galactose-specific receptor. So far, only cells or particles exposing terminal galactose residues were demonstrated to be ligands. We present results obtained with a newly developed radio-receptor assay, which proves both binding and uptake of glycoproteins mediated by the galactose-recognizing receptor of peritoneal macrophages. Requirement of Ca2+ for binding is used to distinguish between reversibly surface-bound and irreversibly internalized ligands. By using this approach, the uptake of the ligand is followed and its inhibition with phenylglyoxal and N-ethylmaleimide is demonstrated. Evidence was also obtained that internalization is followed by degradation of the ligand. Studies on the specificity show that only galactose is recognized but that the binding strength depends on the arrangement of galactose residues presented by the ligand.