[3H] sertraline binding to rat brain membranes

Tritiated sertraline, a radiolabeled form of a potent and selective inhibitor of serotonin uptake, was found to bind with high affinity to rat whole brain membranes. Characterization studies showed that [³H] sertraline binding occurred at a single site with the following parameters:K _d 0.57 nM,B _max 821 fmol/mg protein,n _h 1.06. This binding was reversible; the dissociation constant calculated from kinetic measurements (K _d 0.81 nM) agreed with that determined by saturation binding experiments. [³H] Sertraline binding in the presence of serotonin, paroxetine, fluoxetine or imipramine suggested competitive inhibition of binding (large increase inK _d with little change inB _max). The rank order of potency of inhibition of [³H] sertraline binding was similar to that of inhibition of serotonin uptake for known uptake inhibitors and the 1-amino-4-phenyltetralin uptake blockers. A marked decrease in ex vivo [³H] sertraline binding in the brain of rats 7 days after treatment withp-chloroamphetamine was consistent with the loss of serotonin uptake sites induced by this agent. The results of our study indicated that [³H] sertraline labels serotonin uptake sites in rat brain.     

Characterization of [3H]tryptamine binding sites in brain

[3H]Tryptamine binds with high affinity to sites on rat brain membranes. The sites have the characteristics of tryptamine receptor recognition sites. These sites are widely distributed among rat brain regions with the highest density occurring in the cerebral cortex, striatum and hippocampus. The site is also found in human cerebral cortex. The binding site is localized mainly to the synaptosomal fraction. Drug competition studies indicate that the [3H]tryptamine binding site is distinct from serotonin receptors. Drugs that are potent inhibitors of [3H]tryptamine binding include tetrahydro-beta-carboline, quipazine, phenylethylamine, amphetamine, p-chloroamphetamine and methamphetamine.     

Purine inhibition of [3H]-γ-aminobutyric acid receptor binding to rat brain membranes

Several purines, including inosine and hypoxanthine, inhibit the binding of [^3H]-γ-amino-butyric acid (GABA) and [^3H]diazepam to freeze-thawed and extensively washed rat brain membranes. While purines have been reported to inhibit diazepam binding competitively, their interactions with GABA receptors in both mitochondrial and mitochondrial plus microsomal fractions are noncompetitive. The possibility that purines may bind at one site and affect the GABA receptor-ionophore-benzodi-azepine complex is discussed.     

毛地黄黄酮和玄参黄酮抑制[~3H]地西泮和体外大鼠脑膜的结合(英文)

从阿拉伯艾蒿提取到两种苯并二氮杂受体的配基,毛地黄黄酮和玄参黄酮。两种化合物在体外可抑制[~3H]地西泮和大鼠皮层细胞膜的结合,IC_(50)值分别为1.3μmol·L~(-1)和23μmol·L~(-1)。两种化合物GABA比分别为1.1和1.2,都可少量增加[~(35)S]TBPS的结合,提示这种化合物是苯并二氮杂受体的拮抗剂或部分激动剂。     

Characterization of [3H]-imidazenil binding to rat brain membranes.

1. The binding of [3H]-imidazenil, an imidazobenzodiazepine carboxamide, to rat cerebellar membranes was characterized at different temperatures. 2. Specific binding was linear with tissue concentrations and reached maximum after 90, 30 and 5 min incubation at 0, 21 and 37 degrees C, respectively. The binding was of high affinity, specific and saturable; non linear regression and Scatchard analysis of the data was compatible with the presence of a single population of receptor sites with Bmax of 0.74 +/- 0.020, 0.90 +/- 0.011 and 1.0 +/- 0.036 pmol mg-1 protein at 0, 21 and 27 degrees C, respectively. Binding affinity decreased with increasing temperature: Kd were 0.29 +/- 0.051 nM (0 degrees C), 1.0 +/- 0.080 nM (21 degrees C) and 2.4 +/- 0.38 nM (37 degrees C). 3. At all tested temperatures, [3H]-imidazenil binding was reversible and the Kd calculated from the dissociation and association rate constants approximated the equilibrium Kd. 4. In the presence of gamma-aminobutyric acid (GABA), Kd increased 4 fold at 0 degrees C, whereas Bmax increased, albeit slightly, at all temperatures. 5. Benzodiazepines (BZDs), imidazopyridines and methyl-beta-carboline-3-carboxylate (beta CCM) were effective inhibitors of [3H]-imidazenil binding. Conversely, GABAA antagonists, barbiturates, picrotoxin and peripheral BZD receptor ligands were devoid of any activity. 6. Comparing [3H]-imidazenil to [3H]-flumazenil binding in various brain areas, similar densities of recognition sites as well as like regional differences in the distribution of binding sites for both radioligands were observed (cortex = striatum > cerebellum > spinal cord).(ABSTRACT TRUNCATED AT 250 WORDS)     

Gallamine binding to muscarinic M1 and M2 receptors, studied by inhibition of [3H]pirenzepine and [3H]quinuclidinylbenzilate binding to rat brain membranes

Whereas classic muscarinic antagonist ligands appear to recognize only a single class of muscarinic receptor sites, the recently discovered antagonist pirenzepine appears to distinguish at least two classes of sites. Its unique binding properties, demonstrated in both indirect and direct binding studies, have led to an emerging concept of high affinity (M1) and low affinity (M2) sites. This concept has been supported by pharmacologic studies of functional muscarinic responses, as well as by data suggesting different effector relationships for the two sites. Gallamine possesses muscarinic antagonist properties, and it also recognizes heterogeneity among muscarinic receptors. The purpose of this study was to define gallamine-recognized heterogeneity in terms of the pirenzepine-defined M1, M2 concept. This has been done by studying the ability of gallamine to inhibit [3H]pirenzepine binding to the M1 site, and to inhibit [3H]quinuclidinylbenzilate ([3H]QNB) binding in cerebellar membrane preparations, which contain almost exclusively the M2 site. The results show that gallamine binds with high affinity to the M2 site, with Ki = 2.4 nM, and lower affinity to the M1 site with Ki = 24 nM. Within these classes gallamine does not recognize heterogeneity. The ability of gallamine to inhibit [3H]QNB binding to cortex is best described by a two-site model comprised of 77% low affinity gallamine sites (M1) and 23% high affinity gallamine sites (M2). Thus, the heterogeneity among muscarinic receptors which is recognized by gallamine within the receptor binding paradigms of this study can be attributed to the M1, M2 subtypes as defined by pirenzepine binding. In addition, gallamine at low concentrations appears to bind as a pure competitive antagonist at these two sites, indicated by linear Schild plots with slopes of 1.0, the lack of an effect on dissociation of radioligands, and the ability to protect [3H]pirenzepine and [3H]QNB-binding sites from alkylation by propylbenzylcholine mustard. These studies do not exclude the possibility of a non-competitive interaction of gallamine with the muscarinic receptor observed by other investigators at high gallamine concentrations, and postulated to occur at a site adjacent to the primary muscarinic site. It is proposed that gallamine is capable of interacting with both the primary muscarinic site and an allosteric site. These results support the emerging concept of M1 and M2 muscarinic subclasses and suggest that gallamine and related compounds may be useful in defining muscarinic receptor subclasses, given their higher affinity for the M2 site.     

Differential inhibition of [3H]-oxotremorine-M and [3H]-quinuclinidyl benzilate binding to muscarinic receptors in rat brain membranes with acetylcholinesterase inhibitors

The potential interaction of acetylcholinesterase inhibitors with cholinergic receptors may play a significant role in the therapeutic and/or side-effects associated with this class of compound. In the present study, the capacity of acetylcholinesterase inhibitors to interact with muscarinic receptors was assessed by their ability to displace both [3H]-oxotremorine-M and [3H]-quinuclinidyl benzilate binding in rat brain membranes. The [3H]-quinuclinidyl benzilate/[3H]-oxotremorine-M affinity ratios permitted predictions to be made of either the antagonist or agonist properties of the different compounds. A series of compounds, representative of the principal classes of acetylcholinesterase inhibitors, displaced [3H]-oxotremorine-M binding with high-to-moderate potency (ambenonium>neostigmine=pyridostigmine=tacrine>physostigmine> edrophonium=galanthamine>desoxypeganine) whereas only ambenonium and tacrine displaced [3H]-quinuclinidyl benzilate binding. Inhibitors such as desoxypeganine, parathion and gramine demonstrated negligible inhibition of the binding of both radioligands. Scatchard plots constructed from the inhibition of [3H]-oxotremorine-M binding in the absence and presence of different inhibitors showed an unaltered Bmax and a reduced affinity constant, indicative of potential competitive or allosteric mechanisms. The capacity of acetylcholinesterase inhibitors, with the exception of tacrine and ambenonium, to displace bound [3H]-oxotremorine-M in preference to [3H]quinuclinidyl benzilate predicts that the former compounds could act as potential agonists at muscarinic receptors. Moreover, the rank order for potency in inhibiting acetylcholinesterase (ambenonium>neostigmine=physostigmine =tacrine>pyridostigmine=edrophonium=galanthamine >desoxypeganine>parathion>gramine) indicated that the most effective inhibitors of acetylcholinesterase also displaced [3H]-oxotremorine-M to the greatest extent. The capacity of these inhibitors to displace [3H]-oxotremorine-M binding preclude their utilisation for the prevention of acetylcholine catabolism in rat brain membranes, the latter being required to estimate the binding of acetylcholine to [3H]-oxotremorine-M-labelled muscarinic receptors. However, fasciculin-2, a potent peptide inhibitor of acetylcholinesterase (IC50 24 nM), did prevent catabolism of acetylcholine in rat brain membranes with an atypical inhibition isotherm of [3H]-oxotremorine-M binding, thus permitting an estimation of the "global affinity" of acetylcholine (Ki 85 nM) for [3H]-oxotremorine-M-labelled muscarinic receptors in rat brain.     

Effects of stress on [3H]cyclohexyladenosine binding to rat brain membranes

The investigation of stress-induced changes in neuronal functioning is important to our understanding of mental disorders, stress-induced psychological impairment, and the emotional reactions of fear and anxiety. Data from previous animal studies have demonstrated various pituitary-adrenal responses to stress and also changes in brain neurotransmitters. We are investigating whether stress-induced neuroendocrine and brain monoamine changes are accompanied by concomitant changes in brain neurotransmitter and/or neuromodulator receptors. We have developed a behavioral paradigm of chronic stress which incorporates sustained stress, continuous performance, and disruption of sleep. Animals which are habituated to press a lever to receive food are trained in an active shock escape task. A matched set of animals housed in identical operant chambers but not exposed to footshock are used as comparative controls. [3H]Cyclohexyladenosine ([3H]CHA) (5-7 nM) binding to A1 adenosine receptors in hypothalamic membrane preparations from rats stressed for three days was fifteen percent higher than in matched controls. However, no differences in [3H]CHA binding were found in tissue preparations from frontal cortex, hippocampus, or striatum, when comparing stressed and matched control rats. Plasma corticosterone levels were higher in stressed rats than in matched controls.     

Inhibition of [3H]GABA binding to rat brain synaptic membranes by bicuculline related alkaloids

The binding of 45 bicuculline related phthalideisoquinoline alkaloids to the GABAA receptor was studied using rat brain synaptic membranes prepared both in Tris-HCl and in Tyrode buffers. The IC50 values determined in Tyrode for phthalideisoquinolines are lower (by about one order of magnitude) than and correlate well (r2 = 0.95) with the IC50 data obtained by [3H]GABA displacement in Tris-HCl. Applying Tyrode, the activities of GABA agonists relative to Tris-HCl are decreased. It can be recognized that activities in receptor binding are dependent on the conformations phthalideisoquinolines prefer in solution. On the basis of systematic alterations in the phthalideisoquinoline molecule the main structural elements involved in the binding of phthalideisoquinoline alkaloids appear to be identical with those of GABA agonists, suggesting that the same binding conformation of the GABAA receptor may be implicated for both agonists and antagonists. The opposite shift in relative potencies of agonists and antagonists may be the consequence of an alteration in the "ionic status" rather than that in the conformation of the GABAA receptor.     

Binding of [3H]naloxonazine to rat brain membranes

[3H]Naloxonazine binds to opioid-binding sites in rat brain homogenates. Prior administration of either morphine or D-Ala2-D-Leu5-enkephalin to the homogenates inhibits in a concentration-dependent manner the specific binding of [3H]naloxonazine. Most important, all the binding competed by unlabeled naloxonazine at 1 microM is also competed by morphine and D-Ala2-D-Leu5-enkephalin. [3H]Naloxonazine binding is linear with tissue up to 10 mg/ml wet weight of tissue, is temperature dependent, and has a pH maximum of approximately 7.7. Maximal binding is reached within 90 min at 25 degrees. The affinity of [3H]naloxonazine for its binding sites is quite high with half-maximal binding obtained at a concentration of approximately 2 nM. Approximately 40% of the total specific binding of [3H]naloxonazine is resistant to multiple washes and to displacement by levallorphan (1 microM) added 60 min after the [3H]naloxonazine, suggesting that a portion of [3H]naloxonazine binding is not freely reversible. The percentage of total [3H] naloxonazine binding which is not freely reversible varies 3-fold between regions, with the hypothalamus (60%) being the highest and the brainstem (18%) the lowest.     

Acetylcholinesterase potentiates [3H]fluorowillardiine and [3H]AMPA binding to rat cortical membranes

In addition to its action at cholinergic synapses acetylcholinesterase (AChE) has been proposed to modulate neuronal activity by mechanisms unrelated to the hydrolysis of acetylcholine. We have investigated the effects of AChE on the binding of the specific AMPA receptor agonists (S)-[3H]5-fluorowillardiine ([3H]FW) and [3H]AMPA to rat cortical membranes. Pretreatment of membranes with AChE causes a dose-dependent increase in the binding of both radiolabelled agonists with a maximal increase to approximately 60% above control. This increase is completely blocked by the specific AChE inhibitors propidium, physostigmine, DFP and BW 284C51. AChE pretreatment had no effect on [3H]kainate binding. [3H]FW binding to membranes from young (15-day-old) rats is four orders of magnitude more sensitive to AChE modulation than membranes from adult rats (EC50 values of 4x10(-5) and 0.1 unit/ml, respectively) although the total percentage increase in binding is similar. Furthermore, the AChE-induced potentiation of [3H]FW binding is Ca2+ - and temperature-dependent suggesting an enzymatic action for AChE in this system. Saturation binding experiments with [3H]FW to adult membranes reveal high and low affinity binding sites and demonstrate that the main action of AChE is to increase the Bmax of both sites. These findings suggest that modulation of AMPA receptors could provide a molecular mechanism of action for the previously reported effects of AChE in synapse formation, synaptic plasticity and neurodegeneration.     

Characteristics of [3H]sultopride binding to rat brain

The binding of [3H]sultopride, a benzamide drug, to rat brain was investigated in vitro. Specific [3H]sultopride binding was observed in dopaminergic regions: striatum, nucleus accumbens, olfactory tubercle, substantia nigra, frontal cortex and anterior pituitary. Specific [3H]sultopride binding to striatum was saturable and had one high affinity binding site with a KD of 5.8 nM and a total density of receptors 25.7 pmol/g. [3H]Sultopride binding was stereoselectively displaced by (-)- and (+)-sultopride. Inhibition studies indicated that all neuroleptic drugs and dopamine were capable of displacing sultopride from its binding sites. A highly significant correlation was observed between IC50 values against [3H]sultopride and those against [3H]spiperone binding. Specific [3H]sultopride binding was highly dependent on the presence of sodium ions. The results suggest that the characteristics of sultopride binding sites seem to be similar to those of the D2-receptor labeled by spiperone and haloperidol. The sultopride binding site was highly dependent on the presence of sodium ions and may thus be characterized as a sodium-dependent D2-receptor.     

Characterization of [3H]zetidoline binding to rat striatal membranes

The binding of [3H]zetidoline, a novel neuroleptic agent, to rat brain striatal membranes was investigated in-vitro. The optimal binding conditions for [3H]zetidoline differed from those for [3H]spiperone in pH, temperature and time. [3H]Zetidoline has high affinity for striatal dopamine receptors. Its binding is saturable, stereo-specific, has a low non-specific component and is reversible and tissue specific. The Scatchard analysis gave a biphasic curve, indicating that [3H]zetidoline interacts with more than one population of receptor sites (B'max = 67 fmol mg-1 protein, K'd = 0.11 nM; B"max = 500 fmol mg-1 protein, K'd = 2.49 nM). Kinetic analysis of rates of association and dissociation yielded a Kd value in agreement with that measured at equilibrium. Inhibition studies indicated that only dopamine and dopaminergic agents are able to displace [3H]zetidoline from its binding sites, and in a different rank order from that for displacement of [3H]spiperone. (-)-Sulpiride was especially effective in inhibiting [3H]zetidoline specific binding. Furthermore, like that of [3H]benzamides, [3H]zetidoline binding appears to be highly Na+-dependent and Li+ only partially substitutes Na+.     

Characterization of [3H]paroxetine binding to rat cortical membranes

Paroxetine is a selective and potent inhibitor of 5-hydroxytryptamine uptake into serotonergic neurons. The specific binding of [3H]paroxetine to rat cortical membranes at 22 degrees C was examined in this study. Our results indicate the presence of a single saturable high affinity binding component for [3H]paroxetine. Scatchard analysis revealed a Kd of 0.15 +/- 0.01 nM, and a Bmax of 549 +/- 36 fmol/mg protein. The kinetically derived dissociation constant was 0.034 +/- 0.008 nM. [3H]Paroxetine binding was inhibited selectively by 5-HT uptake blockers, and a good correlation was demonstrated between the potency of various drugs to inhibit [3H]paroxetine binding and [3H]5-hydroxytryptamine uptake. Also, lesions performed with the neurotoxin, 5,7-dihydroxytryptamine resulted in a 94% decrease in endogenous 5-hydroxytryptamine levels and concomitantly, a 90% reduction in [3H]paroxetine binding when compared to sham controls. These results indicate that the binding site labelled by [3H]paroxetine is associated with the neuronal 5-hydroxytryptamine transporter complex.