Properties of Opiate-Receptor Binding in Rat Brain (Naloxone/Opiate Antagonist)

Properties of Opiate-Receptor Binding in Rat Brain (Naloxone/Opiate Antagonist)

Proc. Nat. Acad. Sci. USA Vol. 70, No. 8, pp. 2243-2247, August 1973 Properties of Opiate-Receptor Binding in Rat Brain (naloxone/opiate antagonist) CANDACE B. PERT AND SOLOMON H. SNYDER* Departments of Pharmacology and Experimental Therapeutics, and Psychiatry and the Behavioral Sciences, Johns Hopkins University School of Medicine, Baltimore, Maryland 21205 Communicated by Julius Axelrod, May 2, 1973 ABSTRACT 3HJNaloxone, a potent opiate antagonist, at a counting efficiency of 28%. Protein was measured by binds stereospecifically to opiate-receptor sites in rat- the method of Lowry et al. (3), with bovine-serum albumin brain tissue. The binding is time, temperature, and pH dependent and saturable with respect to [3Hinaloxone and as a standard. tissue concentration. The ['Hinaloxone-receptor complex (-)-Naloxone was labeled by tritium exchange at the New formation is bimolecular with a dissociation constant of England Nuclear Corp. 50 mg of naloxone were dissolved 20 nM. 15 Opiate agonists and antagonists compete for the in 0.3 ml of trifluoroacetic acid with 50 mg of 5% Rh/A1203 same receptors, whose density is 30 pmol/g. Potencies of Ci of mixture opiates and their antagonists in displacing [3H1naloxone to which were added 25 3H20, and the was in- binding parallel their pharmacological potencies. cubated 18 hr at 800. In our laboratory, a 70-mCi portion of [3H]naloxone was evaporated twice to dryness, and purified by The elegant conceptualization of Goldstein et al. (1) that thin-layer chromatography on Silica gel G plates (MN- opiate-receptor binding should be stereospecific enabled us Kieselgel G/uv 254) of 0.25-mm thickness (n-butanol-glacial to demonstrate and quantify opiate-receptor binding (2). acetic acid-H20; 4:1:2). When the purified [3H]naloxone was Specific-receptor binding of opiates and their antagonists chromatographed in three additional solvent systems, the closely parallels their pharmacological potency and is con- resulting single peak of radioactivity coincided with authentic fined to nervous tissue. The present report describes the naloxone, which was chromatographed beside it. The specific kinetics of specific opiate-receptor binding and the influences activity of [3H]naloxone was 6.1 Ci/mmol of standard, as of temperature, pH, ionic concentrations, and several opiates determined by comparison with the ultraviolet absorption and their antagonists. of standard solutions of naloxone at 260 nm. Based upon this MATERIALS AND METHODS specific activity determination and a counting efficiency of 28%, 378 cpm is equivalent to 0.1 pmol of naloxone. Male Sprague-Dawley rats, 7-12 weeks old, were killed by Drugs were generously donated by the following companies: cervical dislocation and decapitated, and their brains were Endo (naloxone, oxycodone); Roche [levorphanol, dextror- rapidly removed. After the cerebellum, which is devoid of re- phan, levallorphan, (+)-3-hydroxy-N-allyl-morphinan]; Lilly ceptor activity (2), was excised, each brain was homogenized [(-)- and (+)-methadone, (+)-propoxyphene]; Winthrop in 10 ml of 0.05 M Tris HCl buffer, pH 7.4 at 350, by .10 (pentazocine cyclazocine, meperidine); Reckitt and Colman, strokes of a motor-driven ground-glass pestle, and the ho- American Cyanamid Agricultural Division and Dr. William mogenate was diluted to 110 volumes of tissue with cold Tris Martin, Lexington, Kentucky (etorphine); Knoll (hydro- buffer. morphone); Ciba-Geigy (etonitazene). In the standard binding assay, 1.9-ml aliquots of this freshly prepared homogenate were incubated for 5 min in triplicate with either levorphanol or dextrorphan (0.1 gM). After cool- RESULTS ing to 40, [3H]naloxone was added to a final concentration The time-course of [3H naloxone binding to whole rat-brain of 8 nM (65,000 cpm) and incubation at 350 in a final volume homogenates was studied at 350 in the presence of 0.1 uM of 2 ml was resumed for 15 min. Samples were cooled to 40 levorphanol or 0.1 uM dextrorphan (Fig. 1). For most opiates, in an ice bath and then filtered under reduced pressure analgesic activity is highly stereospecific with almost all through Whatman glass-fiber circles (GF-B) which were activity residing in isomers with a configuration analogous chosen because of their ability to hold relatively large quan- to that of D-(-)-morphine. Levorphanol is a potent opiate tities of tissue while maintaining an adequate flow rate. Filters with the D-configuration, while dextrophan is its enantiomer were washed twice with 8 ml of cold Tris buffer. The entire and is essentially devoid of analgesic activity. filtration cycle consumed only 20 sec for each sample. The Binding of [3H]naloxone occurred rapidly, was linear for filters were shaken with 1 ml of 10% sodium dodecyl sulfate no more than 1 min, and plateaued between 10 and 30 min in counting vials for 30 min. After the addition of 12 ml of so that equilibrium was reached by 15 min (Fig. 1). After 30 PCS (Amersham-Searle; Phase Combining System), radio- min, [3H]naloxone binding gradually decreased by about activity was determined by liquid-scintillation spectrometry, 25% and then remained constant up to 70 min. 0.1 ,uM dex- trorphan did not reduce [3H]naloxone binding at any time. * To whom reprint requests should be sent at the Department of By contrast, 0.1 uM levorphanol greatly reduced the binding Pharmacology. of [3H]naloxone at all time intervals examined. Increasing 2243 Downloaded by guest on October 1, 2021 2244 Physiology: Pert and Snyder Proc. Nat. Acad. Sci. USA 70 (1973) binding" will refer to the binding of [3H]naloxone in the _ Ovvu presence of 0.1 MAM dextrorphan minus its binding in the E of 0.1 CL presence ,M levorphanol. 0 Specific [3Hjnaloxone binding was linear with brain-tissue protein over the range 0.2-2.0 mg of protein (Fig. 2). Specific co binding displayed a sharp pH optimum at 7.4 (Fig. 2), with zw o 1600 a steep decline at more acid pH values and a gradual decline 0 at more alkaline pH values. In some experiments, the fall in z binding at slightly acid pH was less sharp, presumably be- I 800 cause of variable tissue aggregation. The thermal stability of the opiate receptor was examined by prior incubation of the tissue for 10 min at various tem-' 10 30 50 70 INCUBATION TIME (MINUTES) peratures and then conducting the standard binding assay FIG. 1. Time-course of stereospecific [3Hlnaloxone binding to at 35°. Binding was not affected by prior incubation at tem- rat-brain homogenate. After 5 min preincubation in the presence peratures from 20 to 400, but was reduced by heating at of 0.1 M levorphanol (c), 0.1MuM dextrorphan (0), or no drug (0), higher temperatures. Heating for 10 min at temperatures in homogenates were incubated at 350 in the standard binding assay excess of 500 reduced specific naloxone binding by 90% or from 1 to 75 min with [3H]naloxone. After samples were cooled to more (Fig. 2). 40 they were filtered rapidly and the radioactive content of the Specific binding was temperature dependent with maximal tissue-laden filter was determined by liquid scintillation spectro- metry. In some experiments binding declined continuously be- binding at 35° and a Qio value of 1.5 when measured between tween 30 and 70 min. 25 and 350 and 1.3 when measured between 150 and 25° after 15 min of incubation. At 4° binding was reduced to 25% the levorphanol concentration to 0.1 mM did not further of values at 35°. diminish naloxone binding. Specific [3H ]naloxone binding could be altered by various In all subsequent experiments, incubations with 0.1 ,M ionic manipulations (Fig. 3). The divalent cations calcium concentrations each of levorphanol and dextrorphan were and magnesium lowered binding by about 40% at concen- included and the radioactivity in the presence of levorphanol trations of 3 mM and further lowered binding to 30% of con- was subtracted as a "blank" value representing nonspecific trol values at 10 mM. In the absence of added sodium and binding, while the failure of dextrorphan to reduce binding potassium, specific binding was the same as in. the presence ensured that the effect of levophanol was related to its affinity of physiological concentrations of these ions. At concentra- for the specific opiate receptor. In a typical experiment in tions in excess of 500 mM both lithium and sodium produced which 65,000 cpm of [3H]naloxone (8 nM) were incubated a gradual decrease of binding. Potassium, which at physio- in 2 ml with brain homogenate (18 mg wet weight equal to logical concentrations of 5 mM did not affect binding, re- 1.8 mg of protein) 2000 cpm and 800 cpm were bound, re- duced specific binding 20% at 10 mM and 50% at 30 mM. spectively, in the absence and presence of 0.1 MM levorphanol. Sodium, lithium, magnesium, and calcium did not alter the In the absence of tissue about 300 cpm were bound to the nonspecific binding of [3HInaloxone in the presence of non- filters. Accordingly, only about 500 cpm were bound non- radioactive levorphanol. specifically to brain tissue in the presence of levorphanol so Naloxone binding was demonstrated to be saturable by that the ratio of specific to nonspecific binding in typical two techniques (Fig. 4). In one approach, we measured the experiments would be about 3. Henceforth, "specific receptor binding of increasing amounts of [3H]naloxone, while in other 0 0 C 00 o a0~~~~~~~~~~~~~~>] 0100 w z 0° 800 z 0.0 ED~~~~~~~~~~~~ 2 26 3 6 45 5 06 0 _j ItI0 s_ << 0~~~~~~~~~~~~~~~~~~~~~~~~u z 0lF < 200 0) 2 3 pH a, 2 3 BRAIN HOMOGENATE PROTEIN (mg) FIG. 2. Thermal sensitivity, pH dependence, and tissue linearity of stereospecific [3H]naloxone binding to rat-brain homogenate.

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