Properties of [3H] ß-carboline-3-carboxylate ethyl ester binding to the benzodiazepine receptor

β-Carbolines are inhibitors of [³H] diazepam binding with the most potent inhibitor being β-carboline-3-carboxylate ethyl ester (β-CCE). In this report the binding of [³H] β-CCE to extensively washed rat forebrain membranes is characterized. [³H] ß-CCE binds with high affinity (K_D = 1.4 nM) to an apparently homogenous population of benzodiazepine receptor. The rank order of potency for inhibition of [³H] ß-CCE binding by different benzodiazepines is clonazepam > diazepam > chlordiazepoxide, which is similar to that observed for inhibition of [³H] diazepam binding. In marked contrast to [³H] diazepam, the binding of [³H] ß-CCE is not modulated by GABA since concentrations of GABA as high as 10^?3 M had no effect. [³H] ß-CCE is also less potent than [³H] diazepam in its interaction with the peripheral type kidney benzodiazepine receptor indicating that this ligand has a higher degree of specificity for the central brain type benzodiazepine receptor.     

Heterogeneity of Benzodiazepine Receptors: Experimental Differences Between [3H]Flunitrazepam and [3H]Ethyl-β-carboline-3-carboxylate Binding Sites in Rat Brain Membranes

Abstract: This study was designed to analyze possible differences in the binding of [³H]flunitrazepam ([³H]FNZP) and [³H]ethyl - β - carboline - 3 - carboxylate ([³H]β-CCE), to rat brain membranes, in various experimental conditions. In cerebral cortex, hippocampus, cerebellum, and orain stem the number of binding sites for [³H]β-CCE was higher than for [³H]FNZP; both were displaced by clonazepam. Until the 7th day of postnatal brain development the numbers of [³H]FNZP and [³H]β-CCE sites were equivalent; but later on, the β-carboline sites increased to a higher level. Noradrenergic denervation by 6-hydroxydopamine was followed in the hippocampal formation. Already after 2 days, there was a decrease in [³H]FNZP sites, which reached 70% of control after 14 days. Similar results were obtained with DSP-4 denervation. This change was only in B_max and not in K_D, In contrast, the [³H]β-CCE sites did not change with denervation. Neonatal injection of l - 2,4,5 - trihydroxyphenylalamine or DSP-4 produced in the adult a decrease in [³H]FNZP sites in the cerebral cortex, in parallel with the noradrenergic denervation. On the other hand, there was an increase in the cerebellum and brain stem, in correspondence with the hyperinnervation by sprouting. In these rats, the number of sites for [³H]β-CCE did not change in the different brain regions. With 0.1% Triton X-100, applied to synaptosomal membranes, [³H]FNZP binding was reduced by 35%, while that of [³H]β-CCE was not significantly changed. These results suggest that there is heterogeneity of binding sites for benzodiazepine receptors in rat brain. A tentative interpretation of the experiments involving noradrenergic denervation and hyperinnervation, as well as those with Triton X-100, is that [³H]FNZP binds to pre- and postsynaptic receptors, while [³H]β-CCE binds mainly to postsynaptic benzodiazepine receptors.     

[3H]Propyl β-Carboline-3-Carboxylate as a Selective Radioligand for the BZ1 Benzodiazepine Receptor Subclass

Abstract: Ethyl β-carboline-β-carboxylate (β-CCE) is a mixed-type inhibitor of [³H]flunitrazepam ([³H]FNM) binding to benzodiazepine receptors in noncerebellar regions of rat brain. These findings may represent the presence of either receptor multiplicity or negative cooperativity among benzodiazepine receptors. [³H]Propyl β-carboline-3-carboxylate ([³H]PrCC) has previously been shown to bind specifically to benzodiazepine receptors of rat cerebellum. In the present study we found no indication of the presence of true negative cooperativity among benzodiazepine receptors when [³H]PrCC was used as radioligand. However, we observed that [³H]PrCC labelled only 57% of [³H]FNM binding sites in rat hippocampus (B_max values) and 71% in rat cerebral cortex, whereas the number of receptors labelled by both ligands was equal in the cerebellum. Hofstee analyses of the shallow inhibition curves seen in hippocampus and cerebral cortex when [³H]FNM binding was inhibited by β-CCE indicate that β-CCE and some other β-carboline-3-carboxylate derivatives interact preferentially with a subclass of receptors, and that the percentage of this subclass is equivalent to the number of receptors labelled by [³H]PrCC. We conclude that [³H]PrCC at low concentration (0.3–0.4 × 10^-9 M) labels a subclass of benzodiazepine receptors, BZ₁, while another class, BZ₂ receptors, are not labelled by [³H]PrCC when filtration assays are used. By parallel determinations of the proportion between [³H]FNM and [³H]PrCC binding we calculated the percentage of BZ₁ receptors in several regions of rat, guinea pig and calf brain and in mouse forebrain. The values ranged from approximately 50% in hippocampus to 90% in the guinea pig pons.     

Brain benzodiazepine receptors increase after chronic ethyl-β-carboline-3-carboxylate

Rats were treated with repeated intraventricular injections of ethyl-3-carboline-3-carboxylate (β-CCE) (10 ug/rat, twice daily for 8 days), 36 h after the last injection, the total number of H-diazepam binding sites was increased in the cerebral cortex, cerebellum and hippocampus by 63, 51 and 38%, respectively. On the other hand, there were no significant differences in the dissociation constants (K_D) between β-CCE and solvent treated rats. In contrast, chronic β-CCE administration failed to change the number of the apparent affinity of H-β-CCE binding sites in all the brain areas examined. The results suggest that β-CCE is an antagonist at the ³H- diazepam binding sites.     

Lack of specificity in cation effects on solubilized benzodiazepine receptor

Receptors for benzodiazepines (BZ) and -carboline-carboxylic acid ethyl ester (-CCE) has been solubilized with decanoly-N-methylglucamide (DMG), a new kind of nonionic detergent. The apparent dissociation constants of diazepam and -CCE for solubilized receptor were similar to those for synaptic membranes. Sucrose density gradient centrifugation of the solubilized receptor protein revealed that the binding profile of [³H]-CCE essentially parallels that of [³H]diazepam and that both sedimentation coefficients were 10.5S. Co²⁺ and Ni²⁺, which increase [³H]diazepam binding and decrease [³H]-CCE binding to synaptic membranes, remarkably increased the binding of both to the solubilized receptor. Mg²⁺ and Ca²⁺, which had no effect on membrane receptor binding, also enhanced [³H]diazepam and [³H]-CCE binding to the solubilized receptor. The increase in binding in the presence of these divalent cations was due to a change in the apparent number of binding sites, with no change in binding affinities. The relative lack of specificity in divalent cation effects on solubilized BZ receptor may be caused by separation or destruction of the cation recognition site or channel of the BZ receptor complex by solubilization of the synaptic membrane with DMG.     

Beta-adrenergic receptors: evidence for negative cooperativity.

The specific binding of [³H] (?)alprenolol to sites in frog erythrocyte membranes provides a tool for directly assessing ligand binding to adenylatecyclase coupled β-adrenergic receptors. Hill Plots of such binding data yield slopes (n_H=“Hill Coefficients”) less than 1.0, suggesting that negatively cooperative interactions among the β-adrenergic receptors may occur. The existence of such negative cooperativity was confirmed by a direct kinetic method. The dissociation of receptor bound [³H] (?)alprenolol was studied under two conditions: 1) with dilution of the ligand-receptor complex sufficient to prevent rebinding of the dissociated tracer and 2) with this same dilution in the presence of excess unlabeled (?)alprenolol. If the sites are independent, the dissociation rates must be the same in both cases. However, the presence of (?)alprenolol increases the rate of [³H] (?)alprenolol dissociation, indicating that negatively cooperative interactions among the β-adrenergic receptor binding sites do occur.     

Direct studies of beta-adrenergic receptors intact frog erythrocytes.

(?) [³H]Dihydroalprenolol, a potent competitive β-adrenergic antagonist can be used to directly study β-adrenergic receptors by ligand binding techniques in an intact cell system, the frog erythrocyte. At 37°, binding reached equilibrium within 1 minute. Upon addition of excess unlabeled propranolol, complete dissociation of receptor bound ligand occurred within 1 minute. The characteristics of (?) [³Hdihydroalprenolol binding to β-adrenergic receptors in intact cells were quite similar to those previously demonstrated with isolated membrane fractions. The equilibrium dissociation constant for (?) [³H]dihydroalprenolol was 1.5 nM. Order of potency of agonists and antagonists in competing for the binding sites was appropriate for the β-adrenergic receptor as was the stereospecificity of binding ((?) isomers more potent than (+) isomers). Saturation studies with these intact cells indicated 1700 binding sites/cell in excellent agreement with the number previously estimated from membrane studies. Preincubation of cells with 10^?5M isoproterenol produced a 36% fall in number of β-adrenergic receptors. It is concluded that (?) [³H]dihydroalprenolol can be used to directly study the properties and regulation of β-adrenergic receptors in intact cell as well as broken cell preparations.     

[3H]-BIBP3226 and [3H]-NPY Binding to Intact SK-N-MC Cells and CHO Cells Expressing the Human Y1 Receptor

Abstract

We have studied the binding of [³H]-NPY and the newly developed non-peptide Y₁ receptor antagonist [³H]-BIBP3226 to intact SK-N-MC cells and CHO-K1 cells transfected with the human NPY Y₁ receptor gene i.e. CHO-Y1 cells. Whereas the association and dissociation of the specific [³H]-NPY binding was slow, the binding kinetics of [³H]-BIBP3226 binding was very rapid. Saturation binding of both radioligands reveal the presence of an apparently homogeneous population of high affinity binding sites in both cell lines. The corresponding equilibrium dissociation constants are similar for the two cell lines and are close to those obtained from previous competition binding experiments. The specific binding of both radioligands was completely and with high affinity displaced by BIBP3226 and its inactive (S)-enantiomer BIBP3435 was much less potent. Whilst the NPY Y₁ agonists NPY, PYY and [Leu³¹-Pro³⁴]-NPY completely and potently displaced [³H]-NPY binding, they could only displace 70 to 80 % of the [³H]-BIBP3226 binding sites in CHO-Y1 and SK-N-MC cells. A possible explanation can be that only part of the receptors are G-protein coupled. In agreement pertussis toxin was found to reduce high affinity [³H]-NPY binding sites in CHO-Y1 cells whereas [³H]-BIBP3226 binding parameters remained unchanged.     

[3H]Ketanserin Binding in Human Brain Postmortem

This study aimed at comparing the binding characteristics of [³H]ketanserin, a high-affinity serotonin 2A (5-HT_2A) receptor antagonist, in the prefrontal cortex, hippocampus and striatum of human brain post-mortem. The results indicated the presence of a single population of binding sites in all the regions investigated, with no statistical difference in maximum binding capacity (B_max) or dissociation constant (K_d) values. The pharmacological profile of [³H]ketanserin binding was consistent with the labeling of the 5-HT_2A receptor, since it revealed a competing drug potency ranking of ketanserin = spiperone > clozapine = haloperidol > methysergide > mesulergine > 5-HT. In conclusion, the 5-HT_2A receptor, as labeled by [³H]ketanserin, would seem to consist of a homogenous population of binding sites and to be equally distributed in human prefronto-cortical, limbic and extrapyramidal structures.     

Competitive Interaction of Agonists and Antagonists with 5-HT3-Recognition Sites in Membranes of Neuroblastoma Cells Labelled with [3H] ICS 205–930

Abstract

[3H]ICS 205–930 labelled 5-HT₃ recognition sites in membranes prepared from murine neuroblastoma N1E-115 cells. Binding was rapid, reversible, saturable and stereoselective to an apparently homogeneous population of sites. Kinetic studies revealed that agonists and antagonists produced a monophasic dissociation reaction of [3H]ICS 205–930 from its recognition sites. The dissociation rate constant of the radioligand was similar whether the dissociation was induced by an agonist or an antagonist. Competition studies carried out with agonists and antagonists also suggested the presence of a homogeneous population of [3H]ICS 205–930 recognition sites. Competition curves were best fit for a 1 site model. [3H]ICS 205–930 binding sites displayed the pharmacological profile of a 5-HT₃ receptor. The interactions of agonists and antagonists with [3H]ICS 205–930 recognition sites were apparently competitive in nature, as demonstrated in kinetic and equilibrium experiments. In saturation experiments carried out with [3H]ICS 205–930 in the presence and the absence of unlabelled agonists and antagonists, apparent Bmax values were not reduced whereas apparent Kd values were increased in the presence of competing ligands. There was a good agreement between apparent pK_B values calculated for the competing ligands in saturation experiments and pKd values calculated from competition experiments. The present data demonstrate that [3H]ICS 205–930 labels a homogeneous population of sites at which agonists and antagonists interact competitively.     

Multiple benzodiazepine receptors and their regulation by gamma-aminobutyric acid

The interaction of propyl β-carboline-3-carboxylate (PCC) with benzodiazepine receptors in the cerebral cortex of the rat was investigated by direct measurements of [³H]PCC binding and by competitive inhibition of [³H]flunitrazepam (FLU) binding. Initial experiments showed that [³H]PCC binding exhibited characteristics of saturability, stereospecificity and a pharmacological specificity remarkably similar to that of [³H]FLU binding. Analysis of [³H]PCC binding isotherms and PCC/[³H]PCC competition curves revealed the presence of a small population of super high affinity PCC binding sites (K_SH = 30–100 pM) which represents approximately 3–6% of the total sites. When measured by competitive inhibition of [³H]FLU binding, receptor occupancy by PCC was generally consistent with that determined by direct measurements of [³H]PCC binding. Analysis of the PCC/[³H]FLU competition curve revealed the presence of two major populations of high and low affinity PCC binding sites with dissociation constants of 0.54 and 10 nM and relative abundances of 52 and 45%, respectively. Collectively, the results of the [³H]PCC binding isotherm, PCC/[³H]PCC competition curve and PCC/[³H]FLU competition curve are internally consistent when rationalized in terms of three populations of benzodiazepine receptors - super high, high, and low affinity - each having different affinities for PCC and equal affinity for FLU. The effects of γ-aminobutyric acid (GABA) on PCC and FLU binding were investigated, and it was observed that GABA enhanced the binding of FLU to the various receptor subtypes whereas no significant effect of GABA on the binding of PCC was detected.     

Muscarinic receptor binding in rat brain using the agonist, [3H]cis methyldioxolane

Muscarinic receptor binding was measured in rat forebrain preparations using the muscarinic agonist, [³H]cis methyldioxolane ([³H]CD). The results of equilibrium binding studies using [³H]CD concentrations between 0.5–64 nM showed that [³H]CD binding did not saturate in this concentration range, although the binding isotherm was concave downward. Nonlinear regression analysis of the binding data revealed the presence of two populations of muscarinic receptors having dissociation constants of 1.83 and 123 nM and binding capacities of 85 and 1320 fmol/mg protein, respectively. Competitive inhibition experiments showed that [³H]CD binding was readily displaced by several muscarinic agonists and antagonists. The stereospecificity of [³H]CD binding was demonstrated in competitive inhibition experiments using the stereoisomers of benzetimide and acetyl-β-methylcholine. Dexetimide was 10,000 times more potent than levetimide and l-acetyl-β-methylcholine was 520 times more potent than d-acetyl-β-methylcholine. A variety of nonmuscarinic cholinergic drugs were not effective at inhibiting [³H]CD binding at a concentration of 10 μM.     

Characteristics of β-adrenergic-agonist binding to rat adipocyte membranes: Evidence that (±)-[3H]hydroxybenzylisoproterenol interacts selectively with the adipocyte β-adrenergic receptors

The binding characteristics of the β-adrenergic agonist $\text{(±)-[}{}^3\text{H]hydroxybenzylisoproterenol}$ to rat adipocyte membranes were studied. Binding was rapid, reaching equilibrium within 10 min at 37°C (second order rate constant k₁=1.37·10⁷·M^?1·min^?1). Dissociation of specific binding by 0.5 mM (?)-isoproterenol suggested dissociation from two different sites with respective dissociation rate constants k₂ of 0.106·min^?1 and 0.011·min^?1.[³H]Hydroxybenzylisoproterenol binding was saturable (B_max=690±107 fmol/mg protein), yielding curvilinear Scatchard plots. Computer modeling of these data were consistent with the existence of two classes of [³H]hydroxybenzylisoproterenol binding sites, one having high affinity (K_D=3.5±0.7 nM) but low binding capacity (10% of the total sites) and one haveing low affinity (K_D=101±20 nM) but high binding capacity (90% of the sites). Adrenergic ligands competed with [³H]hydroxybenzylisoproterenol binding with the following order of potency=(?)-propranolol>(?)-isoproterenol>(?)-norepinephrine≈ (?)-epinephrine>>(+)-isoproterenol=(+)-propranolo, which is consistent with binding to β₁-adrenergic receptors. Competition curves of [³H]hydroxybenzylisoproterenol binding by the β-agonist (?)-isoproterenol were shallow and modeled to two affinity states of binding, whereas, competition curves by β-antagonist (?)-propranolol were steeper with Hill number near to one. Gpp[NH]p severely reduced [³H]hydroxybenzyl-isoproterenol binding, an effect which apparently resulted from the reduction of the number of both the high and low affinity sites. In membranes which had been previously exposed to (?)-isoproterenol, then number of [³H]hydroxybenzylisoproterenol binding sites was reduced by 50%, an effect which apparently resulted from the loss of part of both the high and low affinity state binding sites. Finally, the ability of (?)-isoproterenol to stimulate adenylate cyclase correlate closely with the ability of (?)-isoproterenol to displace [³H]hydroxybenzylisoproterenol binding. Comparison of these findings with the binding characteristics of the β-antagonist [³H]dihydroalprenolol to rat adipocyte membranes, led to conclude that [³H]hydroxybenzylisoproterenol can be successfully used to label the β-adrenergic receptors of rat fat cells and suggests that it might be a better ligand than [³H]dihydroalprenolol in these cells.     

A unique regulatory profile and regional distribution of [3H]pirenzepine binding in the rat provide evidence for distinct M1 and M2 muscarinic receptor subtypes

We recently demonstrated that the non-classical muscarinic receptor antagonist [³H]pirenzepine ([³H]PZ) identifies a high affinity population of muscarinic sites in the rat cerebral cortex. We now report that cortical muscarinic sites to which [³H]PZ binds with high affinity are modulated by ions but not guanine nucleotides. We also have examined equilibrium [³H]PZ binding in homogenates of various rat tissues using a new rapid filtration assay. All regional saturation isotherms yielded a similar high affinity dissociation constant (K_d = 2 ? 8 nM) in 10 mM sodium-potassium phosphate buffer. Receptor density (B_max in fmol/mg tissue) varied as follows: corpus striatum = 154.5, cerebral cortex = 94.6, hippocampus = 94.3, ileum = 1.3, cerebellum = 1.0, and heart = 0.45. The cerebral cortex and hippocampus possess 61 percent of striatal binding sites, while the ileum, cerebellum and heart contain only 0.84 percent, 0.65 percent and 0.29 percent of striatal sites respectively. The [³H]PZ sites in heart, ileum, and cerebellum represent 3.1 percent, 9.6 percent, and 10.4 percent of the sites obtained by using [³H](?)quinuclidinyl benzilate. Thus, [³H]PZ labels high affinity muscarinic receptor binding sites with a tissue distribution compatible with the concept of distinct M₁ and M₂ receptor subtypes. Accordingly, regions such as heart, cerebellum, and ileum would be termed M₂, though each have an extremely small population of the M₁ high affinity [³H]PZ site. [³H]PZ therefore appears to be a useful ligand for M₁ receptor identification. Furthermore, the inability to demonstrate a significant effect of guanine nucleotides upon high affinity [³H]PZ binding to putative M₁ receptors suggests that M₁ sites may be independent of a guanine regulatory protein.     

Effect of some potent adenosine uptake inhibitors on benzodiazepine binding in the CNS

A series of nucleoside transport inhibitors has been tested for their ability to displace [³H]diazepam binding to CNS membranes. No correlation between their potency as [³H]adenosine uptake blockers and as inhibitors of [³H]diazepam binding was found, either in rat or guinea-pig brain tissue. Dipyridamole, a potent adenosine transport inhibitor interacted strongly (K_i = 54 nM) with peripheral-type benzodiazepine binding sites (“acceptor sites”) and was 4–5 fold weaker in displacing [³H]methylclonazepam and [³H]Ro15-1788, ligands selective for the specific central benzodiazepine “receptor”. Unlike the benzodiazepines, dipyridamole had no anticonvulsant action against metrazole-induced convulsions in mice. Ro5-4864, a benzodiazepine which selectively interacts with the peripheral-type benzodiazepine binding site, was approximately equipotent with diazepam in inhibiting [³H]adenosine uptake in brain tissue. These results do not support the idea of a very close link between high-affinity central binding sites for clinically-active benzodiazepines and the adenosine uptake site. The possibility of a connection between benzodiazepine “acceptor” sites and the membrane nucleoside transporter is discussed.     

Hydrocortisone binding receptor in the rat pituitary GH3 cell line.

A receptor with specificity and high affinity for hydrocortisone (HC) has been found in the cytosol of GH₃ cells, a growth hormone (GH) producing culture. Scatchard analysis indicated that the interaction of [³H]HC with the receptor has an apparent dissociation constant (K_d) of about 6.0 × 10^?9M and a concentration of binding sites of approx. 1 × 10^?13 mol/mg cytosol protein. The second order association rate constant was determined to be 1.5 × 10⁶ M^?1 min^?1. The receptor activity is stable at 2°C for several hours, but is destroyed completely by heating at 37°C for 1 hour, or by treatment with pronase, only partially by RNase, but not by DNase. The binding of [³H]HC to the cytosol receptor is inhibited by unlabeled progesterone (PR) or dexamethasone to the same extent as the inhibition by unlabeled HC. However, it is only partially inhibited by testosterone, 17-methyl-testosterone, 17α and 17β-estradiol, and 4-pregnen-20β-ol-3-one, and is unaffected by 5α-pregnan-3β,20β-diol. The biological role for these receptors in the regulation of GH synthesis is supported by the observations that the HC-stimulated production of GH is antagonized by PR, which competes with the binding of HC to the receptor.     

[3H]Aniracetam Binds to Specific Recognition Sites in Brain Membranes

Abstract: [³H]Aniracetam bound to specific and saturable recognition sites in membranes prepared from discrete regions of rat brain. In crude membrane preparation from rat cerebral cortex, specific binding was Na⁺ independent, was still largely detectable at low temperature (4°C), and underwent rapid dissociation. Scatchard analysis of [³H]aniracetam binding revealed a single population of sites with an apparent K_D value of ～70 nM and a maximal density of 3.5 pmol/mg of protein. Specifically bound [³H]aniracetam was not displaced by various metabolites of aniracetam, nor by other pyrrolidinone-containing nootropic drugs such as piracetam or oxiracetam. Subcellular distribution studies showed that a high percentage of specific [³H]aniracetam binding was present in purified synaptosomes or mitochondria, whereas specific binding was low in the myelin fraction. The possibility that at least some [³H]aniracetam binding sites are associated with glutamate receptors is supported by the evidence that specific binding was abolished when membranes were preincubated at 37°C under fast shaking (a procedure that substantially reduced the amount of glutamate trapped in the membranes) and could be restored after addition of either glutamate or α-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) but not kainate. The action of AMPA was antagonized by DNQX, which also reduced specific [³H]aniracetam binding in unwashed membranes. High levels of [³H]aniracetam binding were detected in hippocampal, cortical, or cerebellar membranes, which contain a high density of excitatory amino acid receptors. Although synaptosomal aniracetam binding sites may well be associated with AMPA-sensitive glutamate receptors, specifically bound [³H]aniracetam could not be displaced by cyclothiazide or GYKI 52466, which act as a positive and negative modulator of AMPA receptors, respectively.     

Detailed analysis of heterogeneity of [3H]naloxone binding sites in rat brain synaptosomes

The experiments reported in this paper address the question of heterogeneity of [³H]naloxone binding sites in rat brainstem synaptosomal preparations at 23°C in the presence of 100 mM sodium chloride. Kinetic analysis in the presence of 0.4, 4 and 10 nM [³H]naloxone gave pseudo-first order association rate of 0.9±0.04, 1.23±0.08 and 1.06±0.08 min^–1, respectively. The dissociation of a 1 nM [³H]naloxone receptor complex was biphasic with dissociation rate constants of 1.8 and 0.4 min^–1. On the other hand, dissociation of 10 nM [³H]naloxone was monophasic with ak _d of 1.1 min^–1. Two subpopulations of binding sites were also observed by steady state binding studies, with Kd values of 0.5 and 3.4 nM and a ratio of high to low affinity sites of 1:9. Heterogeneity of [³H]naloxone binding sites could be seen by displacement studies performed with opioid eptides and alkaloids. We suggest that our data best fits a model with two independent naloxone binding sites wherein either one or both undergo a multi-step interaction with ligand.     

Polyamines Modulate the Binding of [3H]MK-801 to the Solubilized N-Methyl-D-Aspartate Receptor

Spermine and spermidine enhance the binding of [³H](+)-5-methyl-10,11-dihydro-5H-dibenzo[a, d]cyclohepten-5,10-imine ([³H]MK-801) to N-methyl-D-aspartate (NMDA) receptors in membranes prepared from rat brain. These polyamines also enhance binding of [³H]MK-801 to NMDA receptors that have been solubilized with deoxycholate. Other polyamines selectively antagonize this effect, a finding indicating that the polyamine recognition site retains pharmacological and structural specificity after solubilization. In the presence of spermidine, an increase in the affinity of the solubilized NMDA receptor for [³H]MK-801 is observed. However, the rates of both association and dissociation of [³H]MK-801 binding to solubilized NMDA receptors are accelerated when assays are carried out in the presence of spermidine. When kinetic data are transformed, pseudo-first-order association and first-order dissociation plots are nonlinear in the presence of spermidine, an observation indicating a complex binding mechanism. Effects of spermidine on solubilized NMDA receptors are similar to effects previously described in studies of membrane-bound receptors. The data indicate that polyamines interact with a specific recognition site that remains associated with other components of the NMDA receptor complex after detergent solubilization.     

Benzodiazepine receptors: temperature dependence of [3H]flunitrazepam binding.

The characteristics of [³H]flunitrazepam binding to brain specific benzodiazepine receptors were determined at varying temperatures. The rates at which [³H]flunitrazepam associated with and dissociated from benzodiazepine receptors increased with increasing temperatures. The dissociation constant (K_D) also increased with increases in temperature. The (K_D) determined by Scatchard analyses of saturation isotherms showed a similar change with changes in temperature. The maximal binding capacity (Bmax) did not change with changes in temperature. The inhibitory constants of several benzodiazepines to inhibit [³H]flunitrazepam binding to brain were also higher at 37°C than at 0°C, suggesting that the binding affinity of all benzodiazepines to brain benzodiazepine receptors is lower at 37°C than at 0°C. Van't Hoff analysis of [³H]flunitrazepam binding to brain at different temperatures reveals two linear components to this relationship.