The Dissociation Rate of Unlabelled Dopamine Antagonists and Agonists from the Dopamine-D2 Receptor,Application of an Original Filter Method

Abstract

A filtration technique was developed to measure the dissociation rate of unlabelled drugs from membrane receptors. Receptor preparations saturated with unlabelled drug were adsorbed to glass fibre filters positioned on a filtration apparatus. Dissociation of the drug from the receptor sites was achieved by repeatedly applying small buffer samples on the filter, this was followed by short incubation on the filter with a [³H]ligand. Rat striatal membrane preparations adsorbed on filters retained the same dopamine-D² receptor binding properties as the tissue in aqueous suspension. Stereospecific [³H]haloperidol binding was maximal with 20 mg tissue per filter and 5 min incubation, K_D = 2.8 nM and B_max = 24 fmoles/mg tissue was found. The dissociation from the dopamine-D₂ receptor for 18 dopamine antagonists and 3 agonists followed first order reaction kinetics. Half-lifes of dissociation ranged from 3.5 min for azaperone to 233 min for metitepine. There was no strict relationship between dissociation half-life and apparent equilibrium binding affinity or lipophilicity of the drugs. Half-life of receptor dissociation appeared neither to be a primary determining factor in the duration of pharmacological action of the drugs. The importance of the drug receptor dissociation rate for binding experiments in vitro as well as for chronic drug treatment is discussed.     

Opposite Regulation of Serotonin-S2 and Dopamine-D2 Receptors in Rat Brain Following Chronic Receptor Blockade

Abstract

Rats were chronically treated with setoperone, a mixed serotonin and dopamine antagonist. Alterations in serotonin-S₂ and dopamine-D₂ receptors in the brain and changes in behavioural responses to tryptamine and apomorphine were studied along with duration of treatment and drug withdrawal. As with neuroleptics, behavioural supersensitivity to apomorphine and increase in the number of striatal dopamine-D₂ receptor sites were apparent after 2 days setoperone treatment, both effects were maximal with 14 days treatment and were maintained over more than 20 days drug withdrawal. In contrast to the changes in the dopaminergic system, the rats showed a decreased response to tryptamine and serotonin-S₂ receptor sites in the frontal cortex were significantly reduced in numbers. Both effects developed in parallel over 14 days treatment and extinguished over 10 days drug withdrawal. K_D-values of radioligand binding to dopamine-D₂ and serotonin-S₂ receptor sites were unchanged by the setoperone treatment. The concomitant development and extinction of the in vivo and in vitro effects suggests a causal relationship between them. Chronic treatment with a selective histamine-H₁ antagonist (levocabastine) or the tranquilizer diazepam did not affect dopamine-D₂ or serotonin-S₂ receptor sites. These observations demonstrate that in contrast to the receptor regulation theory, serotonin-S₂ receptors are down regulated following persistent receptor blockade. Implications for the clinical use of serotonin antagonists and possible molecular mechanisms involved in the receptor regulation have been discussed.     

Comparison of filtration and equilibrium dialysis methods for [3H]imipramine binding to human platelets

Receptor binding of imipramine in human platelets was assessed by filtration through glassfiber filters and by equilibrium dialysis. Both methods yield drug-receptor dissociation constants of similar magnitude (10^?9m) to literature values. However, the density of binding sites (B_max) was fivefold lower by filtration (473 ± 92 fmol/mg protein) compared to equilibrium dialysis (2652 ± 765 fmol/mg protein). Dialysis allows direct assessment of free imipramine and avoids drug loss during the separation step of the filtration assay. Additional advantages were found for computer nonlinear regression analysis of untransformed data to eliminate errors owing to linear transformation in the Scatchard analysis and for simultaneous quantitation of nonspecific and total drug binding.     

Altered Muscarinic and Nicotinic Receptor Densities in Cortical and Subcortical Brain Regions in Parkinson's Disease

Abstract: Muscarinic and nicotinic cholinergic receptors and choline acetyltransferase activity were studied in postmortem brain tissue from patients with histopathologically confirmed Parkinson's disease and matched control subjects. Using washed membrane homogenates from the frontal cortex, hippocampus, caudate nucleus, and putamen, saturation analysis of specific receptor binding was performed for the total number of muscarinic receptors with [³H]quinuclidinyl benzilate, for muscarinic M₁ receptors with [³H]pirenzepine, for muscarinic M₂ receptors with [³H]oxotremorine-M, and for nicotinic receptors with (–)-[³H]nicotine. In comparison with control tissues, choline acetyltransferase activity was reduced in the frontal cortex and hippocampus and unchanged in the caudate nucleus and putamen of parkinsonian patients. In Parkinson's disease the maximal binding site density for [³H]quinuclidinyl benzilate was increased in the frontal cortex and unaltered in the hippocampus, caudate nucleus, and putamen. Specific [³H]pirenzepine binding was increased in the frontal cortex, unaltered in the hippocampus, and decreased in the caudate nucleus and putamen. In parkinsonian patients B_max values for specific [³H]oxotremorine-M binding were reduced in the cortex and unchanged in the hippocampus and striatum compared with controls. Maximal (–)-[³H]nicotine binding was reduced in both the cortex and hippocampus and unaltered in both the caudate nucleus and putamen. Alterations of the equilibrium dissociation constant were not observed for any ligand in any of the brain areas examined. The present results suggest that both the innominatocortical and the septohippocampal cholinergic systems degenerate in Parkinson's disease. The reduction of cortical [³H]oxotremorine-M and (–)-[³H]nicotine binding is compatible with the concept that significant numbers of the binding sites labelled by these ligands are located on presynaptic cholinergic nerve terminals, whereas the increased [³H]pirenzepine binding in the cortex may reflect postsynaptic denervation supersensitivity.     

Investigation of Drug-Receptor Interactions by Means of Irreversible Receptor Inhibitors: Binding of Oxytocin and Angiotensin II to Their Receptors in Rat Uterus

Abstract

A stimulus-response coupling model in which individual steps follow hyperbolic or Hill-type laws has been employed to mimic phenomena associated with irreversible receptor inhibition (receptor reserve) in a responding biological system. Two methods for computation of ligand-receptor dissociation constant (K_A) have been derived from this model: 1) The relation between pD₂ and maximal attainable response allows a rough estimate of K_A; 2) A generalization of the earlier Furchgott-Bursztyn procedure employing equipotent doses for noninhibited and partially inhibited systems, has been achieved by introduction of Hill equation into the model. Applied to oxytocin and angiotensin II receptors in rat uterus, these pharmacological methods indicate rather low affinity of the two receptors for the respective peptides (around 2x10^?8 for angiotensin II and 2x10^?7 mol/1 for oxytocin), in case of oxytocin much lower than values reported from binding studies. Apparently, several binding sites are present on the target tissue cells from which the methods based on cellular response can pick up those corresponding to the receptors. Biophysical methods are lacking this ability. Single pD₂ values in noninhibited systems cannot themselves deliver any relevant information about receptor binding.     

Down-Regulation of Angiotensin II Receptor Subtypes and Desensitization of Cyclic GMP Production in Neuroblastoma N1E-115 Cells

Abstract: Murine neuroblastoma N1E-115 cells possess membranous receptors for the octapeptide angiotensin II (AngII) whose density is substantially increased by in vitro differentiation. Incubation of differentiated N1E-115 cells with AngII produced a rapid decrease in receptor density, but did not alter the affinity of these receptors for either ¹²⁵I-AngII or the high-affinity antagonist ¹²⁵I-[Sarc¹,Ile⁸]-AngII. This apparent down-regulation was dose related with an ED₅₀ of 1 nM, and maximal decreases of ～90% were obtained with 100 nM AngII. Receptor loss from differentiated cell membranes was unaffected by incubations of membranes obtained from agonist-exposed cells with non-hydrolyzable analogues of GTP for 60 min at 37°C to ensure dissociation of the ligand. Partial loss of AngII receptors was apparent within 5 min of agonist exposure, whereas maximal declines were not observed until 30 min. This temporal pattern resulted from a preferential decrease in the AT₁ receptor subtype during the first 5 min, followed by a decline in both AT₁ and AT₂ receptors with longer periods of agonist exposure. The loss of membranous receptors was reversible with partial recovery observed after 4 h, and with nearly full recovery observed 18 h after exposure of the cells to AngII. However, the long-term recovery of receptor density was blocked by the protein synthesis inhibitor, cycloheximide. The heptapeptide angiotensin III produced a similar down-regulation of receptors, and the high-affinity antagonist [Sarc¹, Thr⁸]-AngII blocked agonist-induced down-regulation. Finally, the apparent loss of cell surface Angll receptors decreased the ability of AngII to stimulate cyclic GMP production within intact N1E-115 cells. These results suggest that differentiated N1E-115 cells are an excellent cell line in which to examine the factors regulating the expression of AngII receptor subtypes in the nervous system.     

D2 Receptor Antagonists Do Not Modify Guanine Nucleotide-Sensitive Interactions Between Dopamine and D1 Dopamine Receptors Under In Vitro Conditions

Abstract: This study investigated possible D₁/D₂ interactions in rat and bovine striatal tissue by examining the effects of D₂ antagonists on the action of dopamine at D₁ dopamine receptors. In addition, the extent to which D₂ antagonists may induce an agonist low-affinity state of the D₁ receptor was evaluated in comparison with the effects of the guanine nucleotide analogue 5′-guanylylimidodiphosphate [Gpp(NH)p]. In saturation experiments dopamine caused a dose-dependent decrease in rat striatal and bovine caudate D₁ receptor density. This effect of dopamine, which has been shown to be sensitive to Gpp(NH)p, was not altered by pretreatment with either of the selective D₂ antagonists eticlopride (200 nM) or domperidone (200 nM). Results from displacement experiments show that the affinity of dopamine for D₁ receptors and the proportion of receptors in an agonist high-affinity state, are reduced by Gpp(NH)p (100 µM) but not by eticlopride. A molar excess of dopamine (100 µM) promotes the dissociation of (±)-8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-1H-3-benzazepine-7-ol ([³H]SCH 23390) from rat striatal D₁ receptors at a rate that is significantly slower than when dissociation is initiated using 1 µM piflutixol. After pretreatment with Gpp(NH)p, [³H]SCH 23390 dissociation induced by dopamine occurred at an even slower rate. Pretreatment with eticlopride had no effect on the dopamine-induced rate of [³H]SCH 23390 dissociation. These results indicate that all experimental approaches detected dopamine effects at D₁ receptors that are Gpp(NH)p sensitive and D₂ antagonist insensitive and provide no evidence to support a D₁/D₂ link operating at the receptor level.     

Different kinetic properties of neuroleptic receptor binding in the rat striatum and frontal cortex.

³H-spiperone binding in the striatum is 80% stereospecific and 6 % non-stereospecific. In the frontal cortex stereospecific sites account for 60 % of the total binding and non-stereospecific sites for 25 %. Stereospecific sites are of different nature in both brain regions : dopaminergic in the striatum and serotonergic in the frontal cortex. The non-stereospecific sites are saturable and can only be detected by the use of appropriate blanks.Release experiments demonstrate the occurrence of positive coöperative effects in the dissociation of spiperone from striatal receptors while this is not detectable in the frontal cortex. In both brain regions a rapidly and a slowly dissociating component have been observed. In the frontal cortex the rapid component is ascribed to the dissociation of spiperone from the stereospecific sites and the slow component to the dissociation from non-stereospecific sites. The nature of these sites is yet to be identified.     

Guanine nucleotides modulate the function of chemotactic cyclic AMP receptors inDictyostelium discoideum

Summary Guanosine di- and triphosphates specifically decrease the affinity of chemotactic cAMP receptors in isolatedDictyostelium discoideum membranes. The K_0.5 was increased from 50 nM to 150 nM. Receptors were shown to be heterogeneous in dissociation kinetics. In the absence of guanine nucleotides three dissociation processes could be resolved, having first order rate constants of 8.7 x 10⁻⁴, 1.3 X 10⁻², and higher than 0.1 s⁻¹. Guanine nucleotides decreased the affinity for cAMP by transforming the slowest dissociating receptor form (K_D is 8 nM) to forms dissociating more rapidly. Our data indicate that a guanine nucleotide binding protein (G-protein) is involved in the transduction of the cAMP signal inD. discoideum.     

Improved high-affinity binding of 3H-apomorphine with a subcellular membrane fraction of mammalian brain tissue

The binding of low concentrations of [³H](?)apomorphine to preparations of calf and rat forebrain tissue was evaluated. Fractionation of crude homogenates to prepare a membrane fraction (P₄) of striatal or caudate homogenates increased the proportion of saturable to total binding from 33% to over 80%, and increased the apparent density of binding sites from 94 to 681 fmol/mg protein. Binding in calf caudate P₄ tissue was protein-dependent and optimal at pH = 7.0 to 7.5, and T = 20 to 25°C; at higher temperatures tissue binding sites appeared to degrade. The half-time of association and dissociation at 22°C were, respectively, 14.0 and 18.5 min; equilibration was complete in 60 min. Kinetic characteristics of high-affinity binding obtained from association and dissociation constants and from saturation isotherms were similar (K_d = 2.1 to 3.4 nM). The pharmacology of competition for ³H-APO suggests selectivity for dopamine-agonist interactions. These results indicate that the P₄ membrane preparation may be useful for the evaluation of dopamine-agonist binding sites or “receptors.”     

HETEROGENEITY OF HISTAMINE Hi-RECEPTORS: SPECIES VARIATIONS IN [3H]MEPYRAMINE BINDING OF BRAIN MEMBRANES

[³H]Mepyramine binds with high affinity to membranes from brain of human, rat, guinea-pig, rabbit and mouse with drug specificity indicating an association with histamine H₁receptors. Considerable species differences occur in the affinity of [³H]mepyramine, with guinea-pig and human having 34 times greater affinity than rat, mouse or rabbit. The greater affinity of [³H]mepyramine in guinea-pig than in rat is attributable both to faster association and slower dissociation rates in guinea-pig. Species differences in affinity for H₁ receptor sites occur for some antihistamines but not for others. Some tricyclic antidepressant and neuroleptic drugs are extremely potent inhibitors of [³H]mepyramine binding, exceeding in potency any H₁ antihistamines examined. The tricyclic antidepressant doxepin and the neuroleptic clozapine are the most potent of all drugs examined in competing for [³H]mepyramine binding. The regional distribution of specific [³H]mepyramine binding differs considerably in the various species examined.     

Analytical method for simultaneously measuring ex vivo drug receptor occupancy and dissociation rate: Application to (R)-dimethindene occupancy of central histamine H1 receptors

We introduce a novel experimental method to determine both the extent of ex vivo receptor occupancy of administered compound and its dissociation rate constant (k₄). [Here, we reference k₄ as the rate of offset of unlabeled ligand in convention with Motulsky and Mahan ()]. We derived a kinetic rate equation based on the dissociation rate constant for an unlabeled compound competing for the same site as a labeled compound and describe a model to simulate fractional occupancy. To validate our model, we performed in vitro kinetics and ex vivo occupancy experiments in rat cortex with varying concentrations of (R)-dimethindene, a sedating antihistamine. Brain tissue was removed at various times post oral administration, and histamine H1 receptor ligand [³H]-doxepin binding to homogenates from drug-treated or vehicle-treated rats was measured at multiple time points at room temperature. Fractional occupancy and k₄ for (R)-dimethindene binding to H1 receptors were calculated by using our proposed model. Rats dosed with 30 and 60?mg/kg (R)-dimethindene showed 42% and 67% occupancy of central H1 receptors, respectively. These results were comparable to occupancy data determined by equilibrium radioligand binding. In addition, drug k₄ rate determined by using our ex vivo method was equivalent to k₄determined by in vitro competition kinetics (dissociation half-life t_1/2 ~ 30?min). The outlined method can be used to assess, by simulation and experiment, occupancy for compounds based on dissociation rate constants and contributes to current efforts in drug optimization to profile antagonist efficacy in terms of its kinetic drug-target binding parameters. Data described by the method may be analyzed with commercially available software. Suggested fitting procedures are given in the appendix.     

Retention pharmacokinetic and pharmacodynamic parameter relationships of antihistamine drugs using biopartitioning micellar chromatography

Antihistamines are drugs which act by competitive inhibition of the H₁ or H₂ histamine receptors. Little has been known about their clinical pharmacokinetics and biological responses until the last few years. In this paper, we propose quantitative retention–activity relationship, QRAR, models based on the retention data of antihistamines in a biopartitioning micellar chromatography (BMC) system using a Brij35 mobile phase for describing pharmacokinetic parameters such as half-life and volume of distribution, or the pharmacodynamic parameters, therapeutic plasma levels, lethal doses and drug-receptor dissociation constant. The predictive ability of these models is statistically validated. These results are compared to traditional quantitative structure–activity relationship, QSAR, models using lipophilicity data. The adequacy of QRAR models can be explained taking into account the fact that the retention of compounds in BMC depends on their hydrophobic, electronic and steric characteristics which are of great importance in pharmacokinetic and pharmacodynamic behavior.     

The dissociation of insulin from human insulin antibodies

The dissociation of insulin from human insulin antibodies has been investigated using a technique that is rapid and does not require addition of excess unlabelled insulin. A slow (k₁ = 2·1^?3 min^?1 and a fast (k₂ = 4·10^?2 min^?1) dissociating antibody component were identified in all studies. These have been shown to correspond, respectively, to the high and low affinity antibody components of equilibrium binding studies. The range of k₁ and k₂ values and their response to temperature change is small. Insulin resistance and stability of diabetes are not related to properties of antibody dissociation. Dissociation is faster in the presence of high (6–850 nM) insulin concentration due to increased binding to the fast dissociating component without change in the dissociation rate constants. When incubation time is increased beyond achivement of maximal binding there is a time-dependent rise in binding to the slow dissociating component, with a concomitant fall in k₁. The traditional concept that equilibrium is established at maximum binding requires further examination.     

The Serotonin 5-HT2C Receptor Is a Prominent Serotonin Receptor in Basal Ganglia: Evidence from Functional Studies on Serotonin-Mediated Phosphoinositide Hydrolysis

Abstract: Serotonin (5-hydroxytryptamine; 5-HT) 5-HT_2A and 5-HT_2C receptors belong to the class of phosphoinositide-specific phospholipase C (PLC)-linked receptors. Conditions were established for measuring 5-HT_2A-linked and 5-HT_2C-linked PLC activity in membranes prepared from previously frozen rat frontal cortex and caudate. In the presence of Ca²⁺ (300 nM) and GTPγS (1 µM), 5-HT increased PLC activity in caudate membranes. Pharmacological analysis using the selective 5-HT_2A antagonist, spiperone, and the nonselective 5-HT_2A/2C antagonist, mianserin, demonstrated that over half of the 5-HT-stimulated PLC activity was due to stimulation of 5-HT_2C receptors as opposed to 5-HT_2A receptors. Radioligand binding assays with [³H]RP 62203 and [³H]-mesulergine were used to quantify 5-HT_2A and 5-HT_2C sites, respectively, in caudate. From these data, the B_max for caudate 5-HT_2A sites and 5-HT_2C sites was 165.4 ± 9.7 fmol/mg of protein and 49.7 ± 3.3 fmol/mg of protein, respectively. In contrast to that in caudate, PLC activity in frontal cortex was stimulated by 5-HT in a manner that was inhibited by the 5-HT_2A-selective antagonists, spiperone and ketanserin. Taken together, the results indicate that 5-HT_2A- and 5-HT_2C-linked PLC activity can be discerned in brain regions possessing both receptor subtypes using membranes prepared from previously frozen tissue. More importantly, significant 5-HT_2C-mediated phosphoinositide hydrolysis was observed in caudate, despite the relatively low density of 5-HT_2C sites. The significance of these observations with respect to the physiological function of 5-HT_2C receptors is discussed.     

Discrimination of Multiple [3H]5-Hydroxytryptamine Binding Sites by the Neuroleptic Spiperone in Rat Brain

Certain neuroleptic drugs, such as spiperone and (+) butaclamol, can discriminate between two populations of [³H]5-hydroxytryptamine ([³H]5-HT) binding sites in rat brain. The butyrophenone neuroleptic spiperone shows the greatest selectivity for these two binding sites, having at least a 3000-fold difference between its dissociation constants (2-12 nM versus 35,000 nM) for the high- and low-affinity sites, respectively. Inhibition of [³H]5-HT binding by spiperone in rat frontal cortex and corpus striatum yields distinctly biphasic inhibition curves with Hill slopes significantly less than unity. Results from nonlinear regression analysis of these inhibition studies were consistent with a two-site model in each brain region. In the frontal cortex the high-affinity neuroleptic sites comprised about 60% of the total [^3/H]5-HT binding sites whereas in the corpus striatum they accounted for only 20% of the sites. Furthermore, saturation studies of [³H]5-HT binding assayed in the absence or presence of 1 μM-spiperone (a concentration that completely blocks the high-affinity site while having minimal activity at the low-affinity site) reveal a parallel shift in the Scatchard plot with no change in the dissociation constant of [³H]5-HT, but a significant decrease (64% in frontal cortex or 28% in corpus striatum) in the number of specific binding sites. These observations are consistent with the existence of at least two populations of [³H]5-HT binding sites having a differential regional distribution in rat brain.     

Direct binding of 3H-lisuride to adrenergic and serotonergic receptors

The characteristics of the specific binding of ³H-lisuride hydrogen maleate (³H-LHM) to homogenates of rat striatum and bovine frontal cortex tissue were investigated. In rat striatum 50% of ³H-LHM binding was inhibited potently by spiperone and haloperidol indicating a component of ³H-LHM binding to D₂ dopamine receptors. Specific ³H-LHM binding was detected in rat striatum after selective blockade of the D₂ dopamine component indicating specific ³H-LHM binding to other striatal sites. In bovine frontal cortex clonidine and serotonin competition curves for specific ³H-LHM binding included high affinity phases indicating alpha₂ adrenergic and high affinity serotonergic components of binding. Blockade of the adrenergic component by 10^?7M clonidine resulted in the specific ³H-LHM binding exhibiting distinctly serotonergic characteristics. Conversely, blockade of the serotonergic component by 2 × 10^?7M serotonin resulted in the specific ³H-LHM binding exhibiting distinct alpha₂ receptor characteristics. These data demonstrate the specific binding of ³H-LHM to alpha₂ adrenergic receptors, to a high affinity serotonin site, and to D₂ dopamine receptors.     

Acetaminophen-induced antinociception via central 5-HT2A receptors

Acetaminophen is one of the most widely used analgesic drugs. Although the mechanism of analgesic action of acetaminophen is still not known, the involvement of the central serotonin (5-hydroxytryptamine: 5-HT) system is one possibility. In the present study, we examined the antinociceptive effect of acute and chronic intraperitoneally (i.p.) administered acetaminophen by tail flick latency measurements in the rat. A significantly increased tail flick latency was observed in acute and 15-day acetaminophen-treated rats, but not in 30-day acetaminophen-treated rats, at a dose of 400 mg/kg/day. To investigate the plasticity of receptors at postsynaptic membrane, we conducted a series of experiments by radioligand binding method on frontal cortex and brainstem membrane. The technique involved radioligand binding with [phenyl-4-³H]spiperone and ketanserin for studying 5-HT_2A receptor characteristics. A significant decrease in the maximum number of 5-HT_2A binding sites (B_max) was demonstrated in all treatment groups with acetaminophen 300 and 400 mg/kg on frontal cortex membrane, whereas the value of the dissociation equilibrium constant (K_d) remained unchanged. The down-regulation of 5-HT_2A binding sites in frontal cortex was of a lesser magnitude after 30 days of treatment and the tail flick latency was as in the control animals. These results suggest that down-regulation of 5-HT_2A receptor in response to 5-HT release is a major step in the mechanism underlying analgesia produced by this agent. On the contrary, chronic use of acetaminophen may result in 5-HT depletion, which in turn produces re-adaptation of postsynaptic 5-HT_2A receptors. These data provide further evidence for a central 5-HT-dependent antinociceptive effect of acetaminophen.     

Impact of protein binding on receptor occupancy: A two-compartment model

In this paper we analyse the impact of protein-, lipid- and receptor-binding on receptor occupancy in a two-compartment system, with proteins in both compartments and lipids and receptors in the peripheral compartment only. We do this for two manners of drug administration: a bolus administration and a constant rate infusion, both into the central compartment. We derive explicit approximations for the time-curves of the different compounds valid for a wide range of realistic values of rate constants and initial concentrations of proteins, lipids, receptors and the drug. These approximations are used to obtain both qualitative and quantitative insight into such critical properties as the distribution of the drug over the two compartments, the maximum receptor occupancy and the area under the drug-receptor complex curve. In particular we focus on assessing the impact of the dissociation constants, K_P, K_L and K_R of the drug with, respectively, the proteins, the lipids and the receptors, the permeability and the surface area of the membrane between compartments, and the rate the drug is eliminated from the system.     

Receptor binding of pancreatic spasmolytic polypeptide in intestinal mucosal cells and membranes

Rat intestinal mucosal cells contain receptors for pancreatic spasmolytic polypeptide (PSP). The binding of 125I-PSP was rapid, saturable, reversible and specific. PSP competed with 125I-PSP for binding to the receptors and 10(-7) M of PSP half-maximally inhibited 125I-PSP binding. The normalized PSP dose-response graphs in intact cells and crude membranes were superimposable. Scatchard plots of PSP binding to membranes were curvilinear, indicating multiple classes of binding sites, negative cooperative interaction between sites or a combination of both. PSP increased the rate of dissociation of the 125I-PSP-receptor complex compared to the rate observed by dilution only, thus giving evidence that negative cooperative interaction may occur between PSP binding sites. The half-life of the fast dissociating complex was about 1.5 min and that of the slow dissociating complex 38 min. These values were independent of the receptor occupancy. The increased rate of dissociation at high receptor occupancy stemmed from a shift in the ratio of the pool sizes of fast and slow dissociating receptor complexes.