Peripheral dopamine receptor identification: Properties of a specific dopamine receptor in the rat adrenal zona glomerulosa

Specific dopaminergic receptors were found in the rat adrenal zona glomerulosa. Specific binding as defined by the difference in [³H]-spiroperidol binding in the presence or absence of excess dopamine was saturable and of high affinity. Stereospecificity of binding to the dopaminergic receptor was demonstrated by the fact that (+)-butaclamol was 300-fold more active at displacing [³H]-spiroperidol from the binding site than (?)-butaclamol. A Scatchard analysis of the data revealed a K_D = 6.9 nM and a B_max = 173 pmol/gm for the binding of [³H]-spiroperidol to adrenal capsular homogenate binding site. Characteristics of this receptor place it in the recently defined D2 dopamine receptor subclass.     

Binding of [3H]SKF 38393 to Dopamine D-l Receptors in Rat Striatum In Vitro; Estimation of Receptor Molecular Size by Radiation Inactivation

[3H]SKF 38393 (2,3,4,5-tetrahydro-7,8-dihydroxy-1-phenyl-1H-3-benzazepine) binds with high affinity to 3,4-dihydroxyphenylethylamine (dopamine) D-1 receptors in rat striatum in vitro (KD = 7 and 14 nM in nonfrozen and frozen striatum, respectively). The number of binding sites (Bmax) was approximately 80.0 pmol/g of original tissue, a value similar to the Bmax for the dopamine D-1 antagonist SCH 23390. Nondisplaceable [3H]SKF 38393 binding was approximately 45% of total binding. Irradiation (0-4 Mrad) of frozen whole striata decreased the number of [3H]SKF 38393 binding sites monoexponentially without changing the binding affinity. The functional molecular mass for the agonist dopamine D-1 binding site was 132,800 daltons, which is higher than the functional molecular mass of the antagonist dopamine D-1 binding site (approximately 80,000 daltons).     

Characterization of a dopamine-sensitive [3H]LSD binding site in honeybee (Apis mellifera) brain

[³H]Lysergic acid diethylamide ([³H]LSD) binds on membrane homogenate of honeybee brain to both a dopamine-sensitive site (D-site) and a serotonin-sensitive site (S-site). Under suitable conditions the properties of the two sites can be studied separately. Specific binding of [³H]LSD to both the D-site and the S-site has high affinity and is saturable. The mean equilibrium dissociation constants (K_D) were 3.8 nM for the D- and 0.89 nM for the S-site. The densities (B_max values) of both binding sites were 1.7 pmol/mg protein for the D-site and 0.79 pmol/mg protein for the S-site. [³H]LSD binding to the D-site was reversible and reached equilibrium in about 30 min. Pharmacological displacement studies display a high binding affinity of the putative natural agonist dopamine to the D-site (K_i = 22 nM). The most potent displacers of D-site binding were lisuride, (+)-bromocriptine, chlorpromazine, S(+)-butaclamol, and 6,7-ADTN. The [³H]LSD labelled D-site seems to be G-protein coupled, since addition of the stable GTP analogue GTPγS or NaCl to the incubation medium evoked a decrease of specific [³H]LSD binding to the D-site.     

[3H]Dopamine Labeling of D3 Dopaminergic Sites in Human, Rat, and Calf Brain

Abstract: The binding of [³H]dopamine to brain regions of calf, rat, and human was investigated. The calf caudate contained the highest density of [³H]dopamine binding sites, with a B_max value of 185 fmol/mg protein, whereas rat and human striatum contained one-third this number of sites. The K_D values for [³H]dopamine in all tissues were 2–3 nM. Dopaminergic catecholamines (dopamine, apomorphine, 6,7-dihydroxy-2-aminotetralin, and N-propylnorapomorphine) inhibited the binding of [³H]dopamine in all three species, at low concentrations, with IC₅₀ values of 1.5 to 6 nM. Neuroleptics, in contrast, inhibited the binding at high concentrations (with IC₅₀ values of 200 to 40,000 nM). The [³H]dopamine binding sites were saturable, heat-labile, and detectable only in dopamine-rich brain regions; these sites differed from D₂ dopamine sites (labeled by [³H]butyrophenone neuroleptics), and from D_l dopamine sites (labeled by [³H]thioxanthene neuroleptics) associated with the dopamine-stimulated adenylate cyclase. We have, therefore, called these high-affinity [³H]dopamine binding sites D₃ sites. [³H]Apomorphine and [³H]ADTN also appeared to label D₃ sites. These ligands however, were less selective than [³H]dopamine, and labeled sites other than D₃ as well. Assay conditions were important in determining the parameters of [³H]dopamine binding. The optimum conditions for selective labeling of the D₃ dopaminergic sites, using [³H]dopamine, required the presence of EDTA and ascorbate.     

In Situ Molecular Size of Agonist Dopamine D-2 Binding Sites in Rat Striatum

Specific binding of [3H]N-propylnorapomorphine [( 3H]NPA) to 3,4-dihydroxyphenylethylamine (dopamine) D-2 receptors was investigated in rat striatum in vitro. For various dopamine receptor substances, the rank order of potency to inhibit [3H]NPA binding was spiroperidol greater than or equal to NPA greater than LY 171555 greater than SCH 23390 greater than SKF 38393. A single high-affinity binding site was found in membranes prepared in either Tris-citrate buffer or imidazole buffer; the affinity constants were 0.11 and 0.76 nM, respectively. The number of receptors (33 pmol/g wet weight) was independent of whether the membranes were prepared in Tris-citrate buffer or imidazole buffer and was similar to the number of receptors estimated by [3H]spiroperidol binding to dopamine receptors. Irradiation inactivation of frozen whole rat striata showed a monoexponential loss of [3H]NPA binding sites without a change in the binding affinity. The target size of the [3H]NPA binding site was 81,000 daltons, which shows that the functional molecular entity to bind the dopamine D-2 agonist was smaller than the molecular entity to bind the dopamine D-2 antagonist [3H]spiroperidol (target size, 137,000 daltons).     

Effects of the neoclerodane Hardwickiic acid on the presynaptic opioid receptors which modulate noradrenaline and dopamine release in mouse central nervous system

We have comparatively investigated the effects of Hardwickiic acid and Salvinorin A on the K⁺-evoked overflow of [³H]noradrenaline ([³H]NA) and [³H]dopamine ([³H]DA) from mouse hippocampal and striatal nerve terminals, respectively. The K⁺-evoked overflow of [³H]DA was inhibited in presence of Salvinorin A (100 nM) but not in presence of Hardwickiic acid (100 nM). Hardwickiic acid (100 nM) mimicked Salvinorin A (100 nM) in facilitating K⁺-evoked hippocampal [³H]NA overflow and the two compounds were almost equipotent. Facilitation of [³H]NA overflow caused by 100 nM Hardwickiic acid was prevented by the κ-opioid receptor (KOR) antagonist norbinaltorphimine (norBNI, 100 nM) and by the selective δ-opioid receptor (DOR) antagonist naltrindole (100 nM), but was not altered by 100 nM D-Phe-Cys-Tyr-D-Trp-Arg-Thr-Pen-Thr-NH2 (CTAP), a selective μ-opioid receptor (MOR) antagonist. We conclude that Hardwickiic acid modulates hippocampal [³H]NA overflow evoked by a mild depolarizing stimulus by acting at presynaptic opioid receptor subtypes.     

Solubilization and Characterization of Striatal Dopamine Receptors

Abstract: Dopamine receptor binding proteins were sol-ubilized with the detergent 3–(3–cholamidopropyl) dimethylammonio - 2 - hydroxy - 1– propanesulfonate (CHAPSO) from bovine and rat striatal membranes. The binding of the dopamine antagonist [³H]spiroperidol ([³H]Spi) to the solubilized dopamine receptors was determined by the polyethyleneglycol method. The CHAPSO-solubilized dopamine receptor binding proteins remain in the supernatant fraction following centrifuga-tion at 100,000 ×g for 2 h. The CHAPSO-solubilized dopamine receptor proteins, as well as the prelabeled [³H]Spi-receptor protein complex, bind specifically to wheat germ agglutinin (WGA)-agarose columns, which is consistent with an identification as glycoproteins. HPLC analysis of the CHAPSO-solubilized, prelabeled [³H]Spi-receptor protein complex (CHAPSO preparation) reveals association with a high molecular weight form, indicating the formation of aggregates and/or micelles. Treatment of the WGA-agarose-bound [³H]Spi-receptor protein complex with digitonin (CHAPSO-digitonin preparation) results in dissociation of the high molecular weight form into lower molecular weight forms. The HPLC profile of the prelabeled [³H]Spi-receptor complex in the CHAPSO-digitonin preparation reveals two radioactive peaks. The major peak had a retention time of 16 min, corresponding to an apparent MW of 175,000, whereas the minor peak had a retention time of 21 min, corresponding to an apparent MW of 49,000. The CHAPSO-solubilized dopamine receptor binding proteins are sensitive to modulation by GTP, indicating that the association with the GTP binding component is preserved in the “soluble” state. The potencies of dopamine antagonists and agonists for inhibiting the binding of [³H]Spi to CHAPSO-solubilized dopamine receptor proteins are similar to those for membrane-bound proteins. Chronic treatment with haloperidol increases the B_max, and does not change the K_D for [³H]Spi in the CHAPSO-solubilized and in the membrane-bound preparations. Thus, the CHAPSO-solubilized dopamine receptor proteins retain the binding characteristics of the supersensitive membrane-bound dopamine receptors.     

Ontogenetic Development of the Striatal [3H]Spiperone Binding: Regulation by Sodium and Guanine Nucleotide in Rats

Ontogenetic development of specific [3H]spiperone binding to crude synaptic membranes and its regulation by Na+ and GTP was investigated in the rat striatum. (d)-Butaclamol more effectively inhibited [3H]spiperone binding than (l)-butaclamol. The ratio of inhibitory activity of (d)- and (l)-butaclamol for [3H]spiperone binding was not different between 1-, 7-, and 70-day-old animals but eight- to ninefold lower at 18 days of gestation than during the postnatal period. A Scatchard plot of specific binding indicated the presence of two types of binding: low-affinity (KD = 1.51 nM) and high-affinity (KD = 0.09 nM) binding on day 70. Only one component (KD = 0.075 nM) was observed on days 1 and 7 and both types of binding were found on day 15. Bmax gradually increased with age and reached a peak on day 30, followed by a decline on days 70 and 360. Na+, 100 mM, significantly increased specific binding on days 1, 7, 15, and 70. GTP, 50 microM, completely reversed the Na+-induced decrease in IC50 of apomorphine on both days 15 and 70, but not on day 7. It is suggested that receptors could recognize ligand stereospecificity on day 1. The density in dopamine receptors in the striatum reaches a peak on day 30, followed by a decrease on days 70 and 360. In addition, regulation by Na+ and GTP in agonist binding to dopamine receptors seems to become functional between 1 and 2 weeks after birth.     

Membranes with dopamine receptors coupled to G proteins: Purification from theLymnaea central nervous system

A membrane fraction, which contained dopamine receptors and heterotrimeric G proteins, was purified from homogenate of molluscan (Lymnaea) CNS tissues. Radioligand binding analysis with the use of [7.8-³H] dopamine detected the presence of a high-affinity binding site in this fraction. [7.8-³H] Dopamine was displaced in a dose-dependent manner by dopamine antagonists, S(-)-sulpiride, (±)-SKF83566, and fluphenazine. Radioligand binding analysis of purified membranes with the use of labelled GDP showed the presence of a high affinity binding site withB _max=92±5 pmol/mg of protein andK _d =64±10 nM. GDP, in contrast to GTP, markedly increased [7.8-³H] dopamine binding in the absence of metal cations (the maximum increase was 2.5-fold). Added separately, Na and Mg ions decreased the stimulatory influence of GDP. Jointly, these ions completely abolished this GDP influence on the [7.8-³H] dopamine binding. In the membrane fraction, GTPase activity in the presence of dopamine increased during an initial period and then decreased below the basal level. Therefore, we have demonstrated that in our experiments dopamine receptors in the purified membrane fraction are functionally coupled with heterotrimeric G proteins, but their interaction displays some specific features.     

Binding of 3H-lisuride hydrogen maleate to striatal membranes of rat brain

Binding of ³H-lisuride hydrogen maleate (LHM), a dopaminergic agonist, to striatal membranes was inhibited by (+)-butaclamol, whereas (-)- butaclamol at a concentration of 10^?9-10^?7M was without effect. The difference in the amount of ³H-LHM bound to striatal membranes in the presence of 10^?7 M (-)-butaclamol and (+)-butaclamol was designated as the specific binding of ³H-LHM, and its properties were examined. The specific ³H-LHM binding to striatal membranes was saturated with an equilibrium amount of 490 fmol/mg protein and had an apparent dissociation constant (Kd) of 0.5 nM. The specific binding of ³H-LHM to striatal membranes was inhibited by LHM, haloperidol, apomorphine and methysergide with inhibitor association constants (Ki value) of 0.79, 7.1, 100 and 180 nM, respectively. Phentolamine, dopamine, (-)-norepinephrine and serotonin were weaker inhibitors of the specific binding of ³H-LHM to striatal membranes, with Ki values of 1,100, 3,500, 33,000 and 79,000 nM, respectively. No inhibition was observed with (±)-propranolol, dichloroisoproterenol or QNB. These results are discussed in connection with dopamine receptors.     

Selective labeling of alpha-noradrenergic receptors in rat brain with [3H]dihydroergokryptine.

Using concentrations of [³H] dihydroergokryptine between 0.1 and 5 nM, saturable binding can be demonstrated in rat cerebral cortical membranes with a dissociation constant (K_D) of about 0.8 nM. α-Noradrenergic agonists and antagonists compete for the sites labeled by these low concentrations of [³H] dihydroergokryptine with relative potencies characteristics of classical α-noradrenergic receptors. The very low potency of serotonin in competing for these binding sites indicates that, in contrast to findings with higher concentrations of [³H] DHE, low concentrations do not label serotonin receptors. Moreover, the low potency of dopamine in competing for [³H] dihydroergokryptine binding in both striatal and cortical membranes indicates that no detectable portion of binding is associated with postsynaptic dopamine receptors.     

ALTERATIONS IN THE BINDING OF [3H]LEUCINE-ENKEPHALIN TO STRIATAL MEMBRANES BY ENDOGENOUS FACTORS

—Saturation binding studies with [³H]leu-enk ([tyrosyl-3, 5-³H(N)]⁵leu-enkephalin) revealed the presence of high and low affinity binding sites in a paniculate fraction derived from rat striatum. The binding of [³H]leu-enk to the high affinity component (K_D= 2.0 ± 0.3 nM) was sensitive to morphine and levorphanol, while the binding to the low affinity component (K_D= 21 ± 2 nM) was not. Incubation of the membranes, prior to assay for 30 min at 37°C, followed by centrifugation at 27, 000 g for 20 min in order to pellet the membranes allowed the detection of a factor, present in the high speed supernatant, which caused a dose-dependent inhibition of the binding of [³H]leu-enk to the morphine-sensitive and insensitive binding components. Investigations into the nature of the morphine-insensitive binding component demonstrated that it was an artifact since it was not detectable when bound and free ligand were separated by centrifugation. Furthermore, [³H]leu-enk bound to Whatman glass fiber filters, used to collect bound ligand, in a morphine-insensitive manner, and under conditions where the binding of [³H]leu-enk to the morphine sensitive component diluted proportionally with serial dilutions of the membranes, the binding to the morphine-insensitive component did not. The factor present in the high speed supernatant did not dialyze and its effects were mimicked by either trypsin or soybean trypsin inhibitor, but not by bovine serum albumin. The apparent inhibition of the binding of [³H]leu-enk to these binding components is probably not of biological significance, but the fact that the artifactual morphine insensitive binding component of striatal membranes has been shown to decrease by 20–30% following lesions of the substantia nigra suggests that the influence of this endogenous factor must be controlled for.     

Dopamine Receptors in Subcellular Fractions from Bovine Caudate: Enrichment of [3H]Spiperone Binding in a Postsynaptic Membrane Fraction

Abstract: Specific binding of tritiated dopamine, spiperone, and N-propylnorapomorphine was examined in subcellular fractions from bovine caudate nucleus. All fractions contained at least two sets of specific binding sites for [³H]spiperone (K_{D 1}^aPP= 0.2 nM, K_{D 2}^aPP= 2.2 nM), the higher affinity sites accounting for one-third to one-eighth of the total. [³H]Spiperone binding was slightly enriched over the total particulate fraction in P₂, P₃, SPM, and a crude fraction of synaptic mitochondria. A microsomal subfraction (P₃B₂) exhibited the highest specific binding capacity obtained, representing a fourfold enrichment over the total particulate fraction. [³H]Dopamine exhibited apparent binding to a single class of high-affinity sites in all fractions examined (K_D^aPP= 4.0 nM). A greater than twofold enrichment was observed in all fractions except myelin and P₃, with a fivefold enrichment in SPM and P₃B₂. At least two classes of receptors were labeled by [³H]-N-propylnorapomorphine (K_{D 1}^aPP= 0.55 nM, K_{D 2}^aPP= 20 nM), using 50 nM-spiperone together with 100 nM-dopamine to define nonspecific binding. Although binding to the higher affinity site was displaced by spiperone, and lower affinity binding by dopamine, comparison of receptor densities with values obtained by using [³H]spiperone and [³H]dopamine directly suggested that [³H]-N-propylnorapomorphine labeled additional sites. We have also examined a postsynaptic membrane (PSM) fraction obtained from SPM by successive extraction with salt and EGTA followed by sonication and separation on a density gradient. [³H]Spiperone binding in PSM was enriched two- to threefold over unfractionated SPM with a concomitant decrease in [³H]dopamine binding. The enrichment in spiperone receptors was almost entirely due to an increase in the number of lower affinity binding sites, suggesting that these sites may be associated with the postsynaptic membrane.     

Optimal Conditions for [3H]Apomorphine Binding and Anomalous Equilibrium Binding of [3H]Apomorphine and [3H]Spiperone to Rat Striatal Membranes: Involvement of Surface Phenomena Versus Multiple Binding Sites

I. Binding of [³H]apomorphine to dopaminergic receptors in rat striatum was most reproducible and clearly detectable when incubations were run at 25°C in Tris-HCl buffer, pH 7.5, containing 1 mM-EDTA and 0.01% ascorbic acid, using a washed total-membrane fraction. The receptor binding was stereospecifically inhibited by (+)-butaclamol, and dopamine agonists and antagonists showed high binding affinity for these sites. Unlabelled apomorphine inhibited an additional nonstereospecific binding site, which was unrelated to dopamine receptors. EDTA in the incubation mixture considerably lowered nonstereospecific [³H]apomorphine binding, apparently by preventing the complexation of the catechol moiety with metal ions which were demonstrated in membrane preparations. Stereospecific [³H]apomorphine binding was not detectable in the frontal cortex, whereas in the absence of EDTA much saturable nonstereospecific binding occurred. II. Kinetic patterns of stereospecific [³H]spiperone and [³H] apomorphine binding to rat striatal membranes and the inhibition patterns of a dopamine antagonist and an agonist were evaluated at different temperatures in high-ionic-strength Tris buffer with salts added and low-ionic-strength Tris buffer with EDTA. Apparent K_D, values of spiperone decreased with decreasing tissue concentrations. K_D, values of both spiperone and apomorphine were little influenced by temperature changes. Scatchard plots of the stereospecific binding changed from linear to curved; the amount of nonstereospecific binding of the ³H ligands varied considerably, but in opposite directions for spiperone and apomorphine in the different buffers. In various assay conditions, interactions between agonists, and between antagonists, appeared fully competitive, but agonist-antagonist interactions were of mixed type. The anomalous binding patterns are interpreted in terms of surface phenomena occurring upon reactions of a ligand with complex physicochemical properties and nonsolubilized sites on membranes suspended in a buffered aqueous solution. It is concluded that anomalous binding patterns are not necessarily an indication of binding to multiple sites or involvement of distinct receptors for high-affinity agonist and antagonist binding.     

Affinities of methylphenidate derivatives for dopamine,norepinephrine and serotonin transporters

We have synthesized several derivatives of dl-threo-methylphenidate (Ritalin) bearing substituents on the phenyl ring. IC₅₀ values for binding of these compounds to rat brain monoamine transporters were assessed using [³H]WIN 35,428 (striatal membranes, dopamine transporters, DAT), [³H]nisoxetine (frontal cortex membranes, norepinephrine transporters, NET) and [³H]paroxetine (brain stem membranes, 5HT transporters, 5HTT). Affinities (1/Ki) decreased in the order: DAT > NET ⪢ 5HTT. Substitution at the para position of dl-threo-methylphenidate generally led to retained or increased affinity for the dopamine transporter (bromo > iodo > methoxy > hydroxy). Substitution at the meta position also increased affinity for the DAT (m-bromo > methylphenidate; m-iodo-p-hydroxy > p-hydroxy). Substitution at the ortho position with bromine considerably decreased affinity. Similar IC₅₀ values for binding of o-bromomethylphenidate to the dopamine transporter were measured at 0, 22 and 37 degrees. N-Methylation of the piperidine ring of methylphenidate also considerably reduced affinity. The dl-erythro isomer of obromomethylphenidate did not bind to the DAT (IC₅₀ > 50,000 nM). Affinities at the dopamine and norepinephrine transporters for substituted methylphenidate derivatives were well correlated (r² = 0.90). Abilities of several methylphenidate derivatives to inhibit [³H]dopamine uptake in striatal synaptosomes corresponded well with inhibition of [³H]WIN 35, 428 binding. None of the compounds examined exhibited significant affinity to dopamine D1 or D2 receptors (IC₅₀ > 500 or 5,000 nM, respectively), as assessed by inhibition of binding of [³H]SCH 23390 or [¹²³I]epidepride, respectively, to striatal membranes.     

[3H]Spiroxatrine labels a serotonin1A-like site in the rat hippocampus

[³H]Spiroxatrine was examined as a potential ligand for the labeling of 5-HT_1A sites in the rat hippocampus. Analysis of the binding of [³H]spiroxatrine in the absence and presence of varying concentrations of three monoamine neurotransmitters revealed that serotonin (5-HT) had high affinity (IC₅₀= 20.7 nM for the [³H]spiroxatrine binding sites, consistent with the labeling of 5-HT₁ sites, while dopamine and norepinephrine had very low affinity (IC₅₀=57600 nM and >10⁻⁴ M respectively). Saturation studies of the binding of [³H]spiroxatrine revealed a single population of sites with a K_d=2.21 nM. Further pharmacologic characterization with the 5-HT_1A ligands 8-hydroxy-2-(di-n-propylamino) tetralin, ipsapirone, and WB4101 and the butyrophenone compounds spiperone and haloperidol gave results that were consistent with [³H]spiroxatrine labeling 5-HT_1A sites. This ligand produced stable, reproducible binding with a good ratio of specific to nonspecific binding. The binding of [³H]spiroxatrine was sensitive to GTP, suggesting that this ligand may act as an agonist. This was supported by the finding that spiroxatrine inhibits forskolin-stimulated adenylate cyclase activity (a proposed 5-HT_1A receptor model) in the rat hippocampus. Since [³H]spiroxatrine is structurally distinct from other currently available radioligands for the 5-HT_1A site, it should provide new information about the properties of this putative serotonergic receptor.     

Effects of neuroleptics on 3H-haloperidol and 3H-cis(Z)-flupenthixol binding and on adenylate cyclase activity in vitro.

The subcellular localization of dopamine-sensitive adenylate cyclase was studied in rat brain striatum and compared to the distribution of dopamine binding sites. The highest specific activity of adenylate cyclase activities sensitive to dopamine was associated almost exclusively with synaptic membranes (mithchondrial fraction; P₂). Using [³H] haloperidol and [³H] apomorphine as markers for the dopamine receptor, specific binding was observed in both the mitochondrial (P₂) and microsomal (P₃) fractions. Data for the mitochondrial fraction revealed a heterogeneity of binding sites. Two saturable sites for [³H] haloperidol were observed with K_d values of 2.5nM and 12.5nM respectively. Overall, the localization of multiple binding sites in the crude synaptosomal fraction correlates well with the localization of dopamine-sensitive adenylate cyclase in this fraction.     

Photoaffinity labeling of serotonin-binding proteins

A photosensitive arylazide derivative of serotonin (nitroaryl-azidophenyl serotonin, NAP-serotonin) has been synthesized for use in studying the biochemical nature of serotonin binding sites. [³H]-NAP-serotonin possesses a similar ability to bind to the crude membranes of rat brains does [³H]-serotonin and therefore seems suitable for use as a photoaffinity labeling probe for serotonin binding sites. Upon irradiation with ultraviolet light, [³H]-NAP-serotonin covalently attaches to protein components of the brain homogenate. Several distinct radioactively labeled proteins have been separated by sodium dodecyl sulfate polyacrylamide gel electro-phoresis. Their apparent molecular weights were 80,000, 49,000, and 38,000 (±5%). When 1 μM of unlabeled serotonin or d-lysergic acid diethylamide (d-LSD) was added prior to photolysis, the incorporation of [³H]-NAP-serotonin into these proteins was inhibited significantly. No inhibitory effect was observed when dopamine was used. These observations suggest that the photoaffinity labeled proteins are specific for serotonin binding.     

Allopregnanolone increase in striatal N-methyl-D-aspartic acid evoked [3H]dopamine release is estrogen and progesterone dependent

1. The neurosteroids are compounds derived from steroid hormones and synthesized in the nervous system. They can modulate different neurotransmitter pathways. In previous work we demonstrated that progesterone modulates dopamine release induced by the glutamatergic agonist N-methyl-D-aspartic acid (NMDA).2. The aim of this work was to evaluate a possible modulatory role of the progesterone metabolite allopregnanolone on NMDA-evoked [³H]dopamine release from corpus striatum slices obtained from cycling and ovariectomized female rats.3. We used a dynamic superfusion method to evaluate the release of [³H]dopamine. Allopregnanolone at 50–600 nM was added to the superfusion buffer (Krebs–Ringer–bicarbonate–glucose, pH 7.4, with constant O₂/CO₂ gassing). The results are expressed as a percentage over basal [³H]dopamine loaded by the tissue.4. Allopregnanolone (50 and 100 nM) increased the NMDA-evoked[³H]dopamine release from estrus rats. The remaining doses did not show significant changes in the pattern of release. This effect was not observed in diestrus rats. The ovariectomy abolished the facilitatory effect of allopregnanolone on NMDA-evoked 2 [³H]dopamine release.5. Subcutaneous administration of exogenous estrogen (25 mg/rat) and progesterone (1 mg/rat) restored the facilitatory effect on dopaminergic input.6. These results suggest that allopregnanolone is a neurosteroid able to modulate dopamine release in an ovarian-hormone-fluctuation-dependent manner and provide further support for a role of allopregnanolone as a modulator of glutamatergic–dopaminergic interaction in the corpus striatum.     

Characterization of [3H]cholecystokinin octapeptide binding to mouse brain synaptosomes: Effects of neuroleptics

The presence of high concentrations of both dopamine and cholecystokinin (CCK) in the striatum and in various limbic structures suggests that the CCK may not only influence dopaminergic transmission, but it also may be relevant to the psychopathology of schizophrenia and to the therapeutic effects of neuroleptics. By using a synaptosomal fraction isolated from the mouse cerebral cortex and [propionyl-³H]CCK8-sulphate ([³H]CCK8S) as a ligand, a single binding site for [³H]CCK8 with aK _d value of 1.04 nM and aB _max value of 42.9 fmol/mg protein was identified. The competitive inhibition of [³H]CCK8S binding by related peptides produced an order of potency of CCK8-sulphated (IC50=5.4 nM)>CCK8-unsulfated (IC50=40 nM) and >CCK4 (IC50=125 nM). The regional distribution of [³H]CCK8S binding in the mouse brain was highest in the olfactory bulb (34.3±5.6 fmol/mg protein) > cerebral cortex > cerebellum > olfactory tubercle > striatum > pons-medulla > mid brain > hippocampus > hypothalamus (12.4±2.1 fmol/mg protein). The repeated administration of haloperidol (2.5 mg/kg/tid) increased the binding of [³H]CCK8S in cerebral cortex from 31.8±1.7 to 38.9±5.2 fmol/mg protein. The varied distribution of CCK8S receptors may signify nonuniform functions for the octapeptide in the brain.