18F]-N-Methylspiroperidol: the radioligand of choice for PETT studies of the dopamine receptor in human brain

N-Methylspiroperidol, the amide N-methyl analogue of the neuroleptic spiroperidol, was radiolabeled with fluorine-18, and its distribution in the baboon brain was studied using positron emission transaxial tomography. Stereospecific binding was demonstrated in the striatum (but not in the cerebellum) by pretreatment with (-)- or (+)-butaclamol. The kinetic distribution was similar to that of [18F]spiroperidol, but the absolute striatal uptake (in percent of administered dose) was at least two-fold higher. Analysis of baboon blood at 10 min after injection indicated that less than half of the radioactivity in the plasma was due to unchanged radioligand. Analysis of the metabolic stability of [18F]-N-methylspiroperidol in rat brain for 4 hr indicated that, like [18F]spiroperidol, it is very stable to metabolic transformation in the rat central nervous system. Striatal uptake and retention in the rat was five-fold higher for [18F]-N-methylspiroperidol than for [18F]spiroperidol. These results suggest that [18F]-N-methylspiroperidol is an ideal choice for studies of the dopamine receptor in humans.     

No-carrier-added (NCA) (±)-N-(3-[18F]fluoropropyl)-N-normetazocine-Synthesis and PET studies in a baboon

No-carrier-added (NCA) (±)-N-(3-[¹⁸F]Fluoropropyl)-N-normetazocine (2) was synthesized by N-alkylation of (±)-N-normetazocine (1) with NCA 1-[¹⁸F]fluoro-3-iodopropane in an overall radiochemical yield of 10% (EOB) with a mass of 3.5 nmol in a synthesis time of 90 min from end of bombardment (EOB). PET studies of 2 in a baboon did not indicate specificity for opiate receptor sites alone: The activity declined rapidly in the striatum the frontal cortex and the cerebellum. The baboon total arterial plasma radioactivity clearance was very rapid and the metabolism of compound 2 in plasma was also very rapid. These results suggest that compound 2 is not a suitable radioligand for imaging opiate receptors in the human brain by positron tomography.     

Comparison of Three 18F-Labeled Butyrophenone Neuroleptic Drugs in the Baboon Using Positron Emission Tomography

The butyrophenone neuroleptics spiroperidol, benperidol, and haloperidol were radiolabeled with fluorine-18 and studied in baboon brain using positron emission transaxial tomography (PETT). Pretreatment of the baboon with a high pharmacological dose of (+)-butaclamol reduced the specifically bound component of radioactivity distribution in the striatum to approximately the radioactivity distribution found in the cerebellum. Comparative studies of brain distribution kinetics over a 4-h period indicated that either [18F]spiroperidol or [18F]benperidol may be suitable for specific labeling of neuroleptic receptors. In an 8-h study with [18F]spiroperidol, striatal radioactivity did not decline, suggesting that spiroperidol either has a very slow dissociation rate or that it binds irreversibly to these receptors in vivo. [18F]Haloperidol may not be suitable for in vivo PETT studies, because of a relatively high component of nonspecific distribution and a faster dissociation from the receptor. Analysis of 18F in plasma after injection of [18F]spiroperidol indicated rapid metabolism to polar and acidic metabolites, with only 40% of the total radioactivity being present as unchanged drug after 30 min. Analysis of the metabolic stability of the radioactively labeled compound in rat striatum indicated that greater than 95% of [18F]spiroperidol remains unchanged after 4 h.     

Opioid receptors in human neuroblastoma SH-SY5Y cells: evidence for distinct morphine (mu) and enkephalin (delta) binding sites

Human neuroblastoma SH-SY5Y cells exhibited a heterogeneous population of mu and delta types of opioid binding sites. These specific binding sites displayed the characteristic saturability, stereospecificity and reversibility, expected of a receptor. Scatchard analysis of [3H]-D-Ala2-D-Leu5-enkephalin (DADLE) in the presence of 10(-5) M D-Pro4-morphiceptin (to block the mu receptors) and the competitive displacement by various highly selective ligands yielded the binding parameters of delta sites which closely resemble those of the delta receptors in brain and mouse neuroblastoma clones. Similarly, the high affinity binding of [3H]-dihydromorphine, together with the higher potency of morphine analogues to displace [3H]-naloxone binding established the presence of mu sites. Guanine nucleotides and NaCl significantly inhibited the association and increased the dissociation of [3H]-DADLE binding. The observed heterogeneity of opioid receptors in cultured SH-SY5Y cells would serve as an excellent model for the biochemical and pharmacological characterization of brain opiate receptors.     

Interaction of [3H](–)-SKF-10,047 with Brain σ Receptors: Characterization and Autoradiographic Visualization

The sigma opiates differ from other opiates in their stimulatory and psychotomimetic actions. The sigma opiate [3H](-)-SKF-10,047 has been used to characterize sigma receptors in rat nervous tissue. Binding of [3H](-)-SKF-10,047 to rat brain membranes was of high affinity, saturable, and reversible. Scatchard analysis revealed the apparent interaction of this drug with two distinct binding sites characterized by affinities of 0.03 and 75 nM (5 mM Tris-HCl buffer, pH 7.4, at 4 degrees C). Competition analyses involving rank order determinations for a series of opiates and other drugs indicate that the high-affinity binding site is the mu opiate receptor. The lower-affinity site (revealed after suppression of mu and delta receptor binding) has been identified as the sigma opiate/phencyclidine receptor. In vitro autoradiography has been used to visualize neuroanatomical patterns of receptors labeled using [3H](-)-SKF-10,047 in the presence of normorphine and [D-Ala2,D-Leu5]enkephalin to block mu and delta interactions, respectively. Labeling patterns differ markedly from those for mu, delta, or kappa receptors. The highest densities (determined by quantitative autoradiography) are found in the medial portion of the nucleus accumbens, amygdaloid nucleus, hippocampal formation, central gray, locus coeruleus, and the parabrachial nuclei. Receptors in these structures could account for the stimulatory, mood-altering, and analgesic properties of the sigma opiates. Although not the most selective sigma opiate ligand, [3H](-)-SKF-10,047 binds to sigma opiate receptors in brain, and this interaction can be readily distinguished from its interactions with other classes of brain opiate receptors.     

Synthesis and in vivo evaluation of [18F]N-(2-benzofuranylmethyl)-N'-[4-(2-fluoroethoxy)benzyl]piperazine, a novel σ1 receptor PET imaging agent

N-(2-Benzofuranylmethyl)-N'-[4-(2-fluoroethoxy)benzyl]piperazine (6, σ(1)K(i)=2.6 nM) was radiolabeled with fluorine-18 to provide a potential σ(1) receptor radioligand for use in positron emission tomography (PET). Radiofluorination of the appropriate tosylate precursor furnished [(18)F]6 with a specific activity of 45 GBq/μmol, in an average radiochemical yield of 18% and greater than 98% radiochemical purity. MicroPET imaging in Papio hamadryas baboon brain revealed [(18)F]6 uptake consistent with σ receptor distribution, and specificity for σ receptors was demonstrated in a haloperidol pre-treated animal. [(18)F]6 possesses suitable properties for PET imaging of σ(1) receptors, and further investigation of this σ(1) receptor tracer is warranted.     

Synthesis,tissue distribution in rats and PET studies in baboon brain of no-carrier-added [18F]RU 52461: in vivo evaluation as a brain glucocorticoid receptor radioligand

11,17β-Dihydroxy-6-methyl-17α -(3-[¹⁸F]fluoro-prop-1 -ynyl)androsta-1,4,6-trien-3-one ([¹⁸F]RU 52461), an ¹⁸F-analog of RU 28362, was synthesized by bromide displacement with [¹⁸F]fluoride in 12–30% overall radiochemical yield (decay-corrected) within 140 min from end of bombardment (EOB). The specific activity was 900–1500 mCi/μmol (33.3–55.5 GBq/μmol) at the end of synthesis (EOS). Biodistribution studies indicated high adrenal and pituitary retention, and uniformly low uptake of [¹⁸F]RU 52461 in all other brain regions of the rat. Except for the pituitary, no specific receptor-mediated uptake of [¹⁸F]RU 52461 could be demonstrated using saturating doses of unlabeled RU 52461 in rat brain. While no change was observed throughout the brain areas in adrenalectomized rats and in animals coinjected with dexamethasone, when compared to controls. PET studies revealed extremely low levels of radioactivity in baboon brain. Therefore, [¹⁸F]RU 52461 does not appear to cross the blood-brain barrier, suggesting that this radiopharmaceutical is not suitable to visualize the brain glucocorticoid binding sites by PET.     

Synthesis and in vivo evaluation of [18F]-4-[5-(4-methylphenyl)-3-(trifluoromethyl)-1H-pyrazol-1-yl]benzenesulfonamide as a PET imaging probe for COX-2 expression

Synthesis of [18F]4-[5-(4-methylphenyl)-3-(trifluoromethyl)-1H-pyrazol-1-yl]benzenesulfonamide ([18F]celecoxib), a selective COX-2 inhibitor, is achieved via a bromide to [18F]F- exchange reaction. Synthesis of the precursor for radiolabeling was achieved from 4'-methylacetophenone in four steps with 22% overall yield. Under non-radioactive conditions, fluorination was achieved using TBAF in DMSO at 135 degrees C in 80% yield. Synthesis of [18F]celecoxib was achieved using [18F]TBAF in DMSO at 135 degrees C in 10+/-2% yield (EOS) with >99% chemical and radiochemical purities. The specific activity was 120+/-40 mCi/micromol (EOB). [18F]celecoxib was found to be stable in ethanol, however, de[18F]fluorination (6.5%) was observed after 4 h in 10% ethanol-saline solution. Rodent PET studies show bone labeling indicating in vivo de[18F]fluorination of [18F]celecoxib. PET studies in baboon indicated a lower rate of de[18F]fluorination than rat and retention of radioactivity in brain regions consistent with the known distribution of COX-2. A radiolabeling method that can generate consistent high specific activity is needed for routine human use.     

pH Selectivity of N-Ethylmaleimide Reactions with Opiate Receptor Complexes in Rat Brain Membranes

N-Ethylmaleimide (NEM) decreases opiate agonist binding presumably by blocking crucial sulfhydryl (SH) groups at receptor binding sites. At physiological pH, NEM decreased GTP and manganese regulation but increased sodium effects on [3H]D-Ala2-Met5-enkephalinamide (D-Ala enk) binding to rat brain membranes. To determine the apparent pK values of putative SH groups in opiate receptors that react with NEM, rat brain membranes were incubated with 100-250 microM NEM in buffers ranging from pH 4.5 to 8.0. Results showed that lowering pH below 6.5 reduced the NEM effect on opiate receptor functions and that the apparent pK values of NEM-reacting SH groups in binding and regulatory sites ranged between 5.4 to 6.0. Most of the total SH groups in brain membranes continued to react with NEM at low pH, so that when nonspecific SH groups were blocked by incubating membranes at pH 4.5 with NEM, opiate receptors became sensitive to very low concentrations (1 microM) of NEM.     

Interaction of D-Ala2-[Tyr-3,5-3H]enkephalin(5-D-Leu) with opiate receptors of rat brain

Some kinetic features of D-Ala2-[Tyr-3.5-3H]enkephalin (5-D-Leu) binding to opiate receptors of rat brain were studied. It was shown that the Leu-enkephalin D analog interacts with the high and low affinity binding sites of opiate receptors, the equilibrium constants being equal to 0.71 and 8.4 nM, respectively. The rate constant for the label association with the high affinity binding sites in 2 . 10(8) M-1 min-1; those for the label dissociation from the opiate receptor binding sites with high and low affinities are 7.2 . 10(-3) and 0.16 min-1, respectively. Hence, the half-life time of these complexes is 95.7 and 4.3 min, respectively. Na+, K+ and Li+ markedly decrease the specific finding of the label, while Mg2+, Mn2+ and Ca2+ at the concentrations studied markedly increase its specific binding. It is concluded that the Leu-enkephalin D-analog under study acts as a morphine agonist and reveals a much higher affinity for rat brain opiate receptors than does Leu- or Met-enkephalin. This makes it a useful tool for study of the enkephalin reception under normal and pathological conditions.     

Autoradiographic reevaluation of the binding properties of 125I-[Leu31,Pro34]peptide YY and 125I-peptide YY3-36 to neuropeptide Y receptor subtypes in rat forebrain

125I-[Leu31,Pro34]peptide YY (PYY) and 125I-PYY3-36, initially described as selective neuropeptide Y Y1 and Y2 receptor ligands, respectively, were recently shown to label also Y4 and Y5 receptors. We used receptor autoradiography to assess whether these ligands can be reliably used to investigate the various neuropeptide Y receptors in rat forebrain. In most of the brain regions examined (in coronal sections at the level of dorsal hippocampus), specific 125I-[Leu31,Pro34]PYY binding was completely inhibited by 1 microM BIBP-3226, a selective Y1 receptor ligand, but unaffected by 10 nM rat pancreatic polypeptide, selectively inhibiting Y4 receptors, suggesting that Y4 receptors are present in negligible numbers compared with Y1 receptors in the areas examined. Significant numbers of BIBP-3226-insensitive 125I-[Leu31,Pro34]PYY binding sites were measured in the CA3 subfield of the hippocampus only, possibly representing Y5 receptors. 125I-PYY3-36 binding was unchanged by 1 microM BIBP-3226, whereas a population of 125I-PYY3-36 binding sites was sensitive to 100 nM [Leu31,Pro34]neuropeptide Y, likely representing Y5 receptors. The possibility of distinguishing between Y2 and Y5 receptors using 125I-PYY3-36 as radioligand was validated by their different regional distribution and their distinct changes 24 h after kainate seizures, i.e., binding to Y5 receptors was selectively decreased in the outer cortex, whereas binding to Y2 receptors was enhanced in the hippocampus. Thus, the use of selective unlabeled compounds is required for distinguishing the various receptor subtypes labeled by 125I-[Leu31,Pro34]PYY and 125I-PYY3-36 in rat brain tissue.     

Synthesis and evaluation of (S)-[18F]-fluoroethylcarazolol for in vivo beta-adrenoceptor imaging in the brain

The beta-adrenergic receptor ligand (S)-4-(3-(2'-[18F]-fluoroethylamino)-2-hydroxypropoxy)-carbazol ((S)-[18F]-fluoroethylcarazolol) was prepared by reaction of [18F]-fluoroethylamine with the corresponding (S)-epoxide and was evaluated in rats by studying its pharmacokinetics and its binding profile both in vitro and in vivo. In vitro, (S)-fluoroethylcarazolol binds preferentially to beta-adrenoceptors (pK(i)=9.3 for beta(1) and 9.4 for beta(2)) and has less affinity to 5HT(1A) and 5HT(1D) receptors (pK(i)=6.7 and 5.2). In vivo, standard uptake values (SUVs) up to 0.63+/-0.07 in cortical regions were found after 60 min. Metabolites (90%) appeared within 10 min in plasma, whereas, in brain 70-75% parent compound was found after 60 min. Clearance from plasma occurred within 5 min. Cerebral uptake could be blocked by 'cold' fluoroethylcarazolol in every region, except medulla. Uptake was also blocked by propranolol and pindolol, but not by WAY 100635. ICI 89406 hardly lowered [18F] levels in brain. ICI 118551 reduced uptake of [18F] in cerebellum (mainly beta(2)) by 30%. Specific binding (tissue minus medulla values) in various brain regions corresponded with those observed for [18F]-fluorocarazolol (r(2)=0.95) and with in vitro beta-adrenoceptor densities (r(2)=0.76). Autoradiography using phosphor images of (S)-[18F]-fluoroethylcarazolol in rat brain showed the characteristic binding pattern of beta-antagonists, while propranolol treatment resulted in low and homogenous uptake. Regional tissue minus medulla values corresponded with in vitro beta-adrenoceptor densities (r(2)=0.77). We conclude that (S)-[18F]-fluoroethylcarazolol is a high affinity ligand that binds specifically to cerebral beta-adrenoceptors in vivo and may be of use for beta-adrenoceptor imaging in the brain with PET.     

A novel analogue of clonidine with opiate-receptor agonist activity

A new analogue of the α₂-adrenergic receptor ligand clonidine, N-(4-hydroxphenacetyl)-4-aminoclonidine, was synthesized. The analogue possesses opiate-receptor agonist activity in addition to α-adrenergic partial agonist activity. The analogue elicits inhibition of adenylate cyclase of NG108-15 neuroblastoma × glioma hybrid cells; most of the inhibition is reversed by the opiate-receptor antagonist naloxone. The analogue also inhibits the binding of [³H]D-Ala²-Met⁵-enkephalinamide and [³H]dihydromorphine to rat brain opiate receptors. The structure of the analogue suggests common elements in the ligand binding sites of α- and opiate receptors and may lead to a new class of opiate analgesics.     

A differential interaction of putative μ-selective agonists with opiate binding sites in rat brain

The availability of tritium-labelled sufentanil ([³H]SUF) allowed for a further radioligand analysis of opiate binding sites in rat brain. A comparison of the binding characteristics of [³H]SUF and [³H]dihydromorphine ([³H]DHM) revealed a very similar potency in their mutual displacement by unlabelled analogues. Furthermore, a series of putative μ-opiate agonists displayed equal potencies in displacing either [³H]SUF and [³H]DHM, the only striking exception being the highly μ-selective opioid peptide morphiceptin which was 33 times less potent in inhibiting [³H]SUF as compared to [³H]DHM binding. Additional experiments revealed further pronounced differences in [³H]SUF and [³H]DHM binding characteristics: the total amount of binding sites for [³H]SUF was 4 times higher than that for [³H]DHM and the regional distribution within particular brain areas displayed considerable differences. Furthermore, the binding of [³H]SUF was differentially modulated by sodium and GTP as compared to [³H]DHM binding. These data suggest that in rat brain, [³H]SUF interacts both with μ-opiate sites recognizing [³H]DHM and another type of opiate site, which cannot be equated with any of the, as yet, described δ- or κ-binding sites, and rather, represents a subclass of μ-opiate receptor sites. These experiments, thus, support the notion of subclasses (isoreceptors) for different types of opiate receptors.     

Dopamine receptor-mediated regulation of striatal cholinergic activity: positron emission tomography studies with norchloro[18F]fluoroepibatidine

Large numbers of in vitro studies and microdialysis studies suggest that dopaminergic regulation of striatal acetylcholine (ACh) output is via inhibitory dopamine D2 receptors and stimulatory dopamine D1 receptors. Questions remain as to the relative predominance of dopamine D2 versus D1 receptor modulation of striatal ACh output under physiological conditions. Using positron emission tomography, we first demonstrate that norchloro[18F]fluoroepibatidine ([18F]NFEP), a selective nicotinic ACh receptor (nAChR) ligand, was sensitive to changes of striatal ACh concentration. We then examined the effect of quinpirole (D2 agonist), raclopride (D2 antagonist), SKF38393 (D1 agonist), and SCH23390 (D1 antagonist) on striatal binding of [18F]NFEP in the baboon. Pretreatment with quinpirole increased the striatum (ST) to cerebellum (CB) ratio by 26+/-6%, whereas pretreatment with raclopride decreased the ST/CB ratio by 22+/-2%. The ratio of the distribution volume of [18F]NFEP in striatum to that in cerebellum, which corresponds to (Bmax/K(D)) + 1 (index for nAChR availability), also showed a significant increase (29 and 20%; n = 2) and decrease (20+/-3%; n = 3) after pretreatment with quinpirole and raclopride, respectively. However, both the D1 agonist and antagonist had no significant effect. This suggests that under physiological conditions the predominant influence of endogenous dopamine on striatal ACh output is dopamine D2, not D1, receptor-mediated.     

Evaluation of [18F]VUF 5000 as a potential PET ligand for brain imaging of the histamine H3 receptor.

[18F]VUF 5000 was evaluated as a potential PET ligand for the histamine H3 receptor. In the rat a high uptake of [18F]VUF 5000 was observed in liver, lung and kidney and a low uptake in the brain. In order to explain these findings we determined the LogD(oct,7.2) of [18F]VUF 5000, studied the biodistribution in the presence of carrier VUF 5000, modified [18F]VUF 5000 chemically and studied the binding of [18F]VUF 5000 to human serum albumin. From the results of these experiments it was concluded that [18F]VUF 5000 is not suitable as a PET ligand for brain imaging of the histamine H3 receptor, since [18F]VUF 5000 hardly penetrates into the brain.     

Affinity of beta-carbolines on rat brain benzodiazepine and opiate binding sites

The affinity of beta-carbolines, which may be formed in the body, to benzodiazepine and opiate receptors was studied by measuring their ability to inhibit the binding of [3H]-flunitrazepam and [3H]-dihydromorphine on rat brain synaptosomal membranes. All "aromatized" beta-carbolines studied (norharmane, harmane and 6-methoxyharmane) inhibited the specific binding of [3H]-flunitrazepam in micromolar concentrations, dihydro-beta-carbolines (6-methoxyharmalan, harmalol) were less potent, while all tetrahydro-beta-carbolines showed very low affinity. 6-Hydroxytetrahydroharmane, which is formed by condensation 5HT with acetaldehyde, inhibited [3H]-dihydromorphine binding in micromolar concentration, while norharmane and tetrahydro-beta-carbolines without OH-group showed little affinity. beta-Carbolines are the most potent known natural benzodiazepine receptor ligands. Because they are formed after alcohol drinking, their effects on benzodiazepine and opiate receptors may be connected with alcohol dependence although some beta-carbolines may inhibit 5HT uptake in still lower concentrations.     

Unsulfated C-terminal 7-peptide of cholecystokinin: a new ligand of the opiate receptor.

On the basis of structural and conformational similarities between the C-terminal 7-peptide of cholecystokinin (pancreozymin) (CCK-(27–33)) and the active enkephalin analog [Trp⁴,Met⁵]-enkephalin, the affinity of CCK-(27–33) for the opiate receptor was determined. With unsulfated CCK-(27–33) half-maximal inhibition of stereospecific binding of [³H]-naloxone in a rat brain membrane preparation was observed at a 200 times higher concentration than that required with [Met⁵]-enkephalin. Sulfated CCK-(27–33) did not bind at concentrations up to 4 × 10^?5M. In the bioassay based on inhibition of electrically evoked contractions of guinea pig ileum similar potency ratios were observed and the effect of CCK-(27–33) was shown to be naloxone-reversible. These findings are of interest in view of the recently demonstrated presence of CCK-fragments in the brain.     

Synthesis of a fluorine-18 labeled derivative of epibatidine for in vivo nicotinic acetylcholine receptor PET imaging

Epibatidine (exo-2-(2'-chloro-5'-pyridyl)-7-azabicyclo[2.2.1]heptane), a natural compound isolated from the skin of the Ecuadorian poison frog Epipedobates tricolor, is the most potent nicotinic acetylcholine receptor (nAChR) agonist reported to date. In order to visualize and quantify in vivo these receptors in human brain using Positron Emission Tomography (PET), [18F]norchlorofluoroepibatidine (exo-2-(2'-[18F]fluoro-5'-pyridyl)-7-azabicyclo[2.2.1]heptane), a fluorine-18 (t(1/2): 110 min) radiolabeled derivative of epibatidine has been designed. The corresponding 2'-bromo-, 2'-iodo- and 2'-nitro exo-2-(5'-pyridyl)-7-azabicyclo[2.2.1]heptane analogues as labeling precursors, as well as norchlorofluoroepibatidine as a reference compound have been synthesized by reductive, stereoselective, palladium-catalyzed Heck-type coupling between an N-Boc protected azanorbornene and the corresponding halopyridine. [18F]Norchlorofluoroepibatidine has been radiolabeled with fluorine-18 by nucleophilic aromatic substitution from the corresponding Boc-protected halo- and nitro precursors using [18F]FK-K222 complex in DMSO by conventional heating (at 150-180 degrees C for 10 min) or microwave activations (at 100 Watt, for 1 to 2.5 min), followed by TFA-removal of the protective group. Typically, using the microwave activation procedure, 60-80 mCi (2.22-2.96 GBq) of pure [18F]norchlorofluoroepibatidine could be obtained in less than 2 h (110-115 min) from the bromo labeling precursor, with specific radioactivities of 1.5-2.5 Ci/micromol (55.5-92.5 GBq/micromol) calculated for End of Bombardment. The preliminary PET experiments in baboon (Papio papio) with [18F]norchlorofluoroepibatidine show a high uptake and a rapid accumulation of the radiotracer into the brain within 30 min. In the thalamus, a nAChR rich area, uptake of radioactivity reached a maximum at 40 min (10% I.D./100 mL tissue). The ratio of radioactivity thalamus/cerebellum (the latter being a nAChR poor area) was 2 at 40 min and increased with time, up to 4.3 at 160 min. Its specific regiodistribution and its high ratio of specific-to-nonspecific binding confirm the ideal profile of [18F]norchlorofluoroepibatidine as a suitable radioligand for PET imaging of nAChRs in the brain.     

Visualization and solubilization of rat brain opiate receptors with a “κ” ligand selectivity pattern

1. Specific binding of [3H]ethylketocyclazocine (EkappaC), a prototype kappa-opiate agonist, to slide-mounted rat striatal sections is increased in the presence of 100 mM NaCl at 4 degrees C. 2. Under similar incubation conditions, binding of mu and delta prototype opiates is reduced to almost undetectable levels. 3. Correlation (P less than 0.01) of the ligand selectivity pattern of [3H]EKC displacement with the potencies of various opiate drugs in inhibiting the contractions of the rabbit vas deferens, a kappa-opiate receptor bioassay, suggests that the binding site under study represents the pharmacologically relevant kappa-opiate receptor. 4. Visualization of these kappa-opiate receptors with tritium-sensitive film reveals a striking, highly discrete brain distribution pattern (e.g., striatal patches, habenular stripe) which is similar to that of [3H]dihydromorphine and [3H]naloxone. 5. Soluble [3H]EKC binding sites obtained from rat membranes also possess a kappa-like ligand selectivity pattern, with bremazocine being a potent displacer while mu and delta ligands are almost inactive. 6. A possible explanation of these data is that the "kappa"-opiate binding site in rat brain is one transitional state of an opiate receptor capable of assuming distinct conformations with characteristic ligand selectivity patterns. Other possibilities such as pre and post-synaptic locations should also be considered.