Effect of aging on the interaction of quinuclidinyl benzilate,N-methylscopolamine,pirenzepine, and gallamine with brain muscarinic receptors

The objective of the present study was to investigate the effects of senescence on the binding characteristics of muscarinic receptors by using [³H]quinuclidinyl benzilate ([³H]QNB) and [³H]N-methylscopolamine ([³H]NMS) as ligands in young (3months), middle-age (10months) and old (24 months) male Fischer 344 rats. Muscarinic receptor density was found to decrease significantly with aging in certain brain regions, depending on the ligand employed. Moreover, the relative proportions of M₁ and M₂ muscarinic receptor subtypes was not significantly altered by aging, except in the aged striatum. Furthermore, the dissociation kinetics of [³H]NMS in the cerebral cortex and their allosteric modulation by gallamine were only slightly influenced by age.     

Differential modulation of organophosphate-sensitive muscarinic receptors in rat brain by parathion and chlorpyrifos

We previously reported similar levels of brain cholinesterase inhibition but marked differences in toxicity following acute maximum tolerated doses of the organophosphate pesticides parathion and chlorpyrifos. Because extensive acetylcholinesterase inhibition often induces compensatory changes in cholinergic receptor populations, we compared the effects of parathion and chlorpyrifos on brain muscarinic receptors. Adult male rats were treated with vehicle or the maximum tolerated dose of parathion (18 mg/kg, sc) or chlorpyrifos (279 mg/kg, sc) and observed for signs of acute toxicity. Similarly treated animals were sacrificed at 2, 7, or 14 days after treatment for measurement of cholinesterase activity and binding to the nonselective muscarinic antagonist [³H]quinuclidinyl benzilate, the M2-preferential antagonist [³H]AFDX-384, and the high-affinity agonist [³H]cis-methyldioxolane. More acute toxicity was noted after parathion treatment. Both insecticides caused similar levels (> 85%) of maximal cholinesterase inhibition and reductions (up to 55%) in atropine-sensitive quinuclidinyl benzilate binding (i.e., total muscarinic receptors) and [³H]AFDX-384 binding in cortex and striatum. Parathion also reduced, whereas chlorpyrifos increased, total muscarinic receptor binding and [³H]AFDX-384 binding in the cerebellum. When tissues were preincubated with paraoxon (10 μM), radiolabeling of a subset of quinuclidinyl benzilate binding sites was blocked and the apparent densities of these organophosphate-sensitive receptors in all three tissues were decreased (16% maximal) by parathion but increased (up to 37%) by chlorpyrifos. Similarly, parathion decreased whereas chlorpyrifos increased [³H]cis-methyldioxolane binding sites in all three brain regions. We propose that differential modulation of these organophosphate-sensitive muscarinic receptors contributes to differences in acute toxicity following exposure to these pesticides.     

Ligand Binding to CNS Muscarinic Receptor Is Transiently Modified by Convulsant 3-Mercaptopropionic Acid Administration

The administration of convulsant drugs has proven a powerful tool to study experimental epilepsy. We have already reported that the administration of convulsant 3-mercaptopropionic acid (mp) at 150 mg/kg enhances binding affinity of muscarinic antagonist [³H]quinuclidinyl benzilate ([³H]QNB) to certain rat CNS membranes during seizure and postseizure without affecting site number. Results obtained with a 100-mg/kg dose of mp have shown reversible increases in [³H]QNB binding to cerebellum and hippocampus, whereas a delayed response has been found in striatum. Neither a subconvulsant dose nor in vitro addition modifies binding. In order to evaluate preseizure, seizure as well as early (30 min) and late (24 h) postseizure stages, we employed a 50 mg/kg dose and tested [³H]QNB binding to CNS membranes. Changes in binding were as follows (in %): in cerebellum, +37, +86, and +40 at preseizure, seizure and early postseizure stages, respectively, but there was a decrease at late postseizure; in hippocampus, +27 at pre- and seizure stages, but a decrease at early and late postseizure. No changes were found in striatum or cerebral cortex membranes at any stage studied. Saturation curves analysed by Scatchard plots indicated that changes in [³H]QNB binding to cerebellar membranes are attributable to an increase in ligand affinity at seizure, followed by a decrease in binding site number at postseizure. A similar profile was observed for hippocampus except that the decrease in binding site number, though lower than at postseizure, was already evident at seizure stage. Results confirm a region-specific response to the convulsant and transient changes provide an example of neuronal plasticity.     

Muscarinic receptor binding in the mouse heart: the selective modulatory effect of fluoride ion on agonist binding

The effect of fluoride ion on the binding of the specific muscarinic agonist ligand [³H]c is methyldioxolane ([³H]CD) to the mouse cardiac muscarinic receptor was investigated. Utilizing equilibrium ligand binding experiments, sodium fluoride (10mM) was shown to decrease [³H]CD binding, measured at a concentration of 2 nM, by 52%. Studies with several different ions demonstrated that the reduction in [³H]CD binding was a specific effect of fluoride. This fluoride modulation was selective for agonist binding, as no effect of fluoride on the binding of the muscarinic antagonist [³H](?) quinuclidinyl benzilate (QNB) was observed.     

Ketamine prevents seizures and reverses changes in muscarinic receptor induced by bicuculline in rats

The cholinergic system has been implicated in several experimental epilepsy models. In a previous study bicuculline (BIC), known to antagonize GABA-A postsynaptic receptor subtype, was administered to rats at subconvulsant (1 mg/kg) and convulsant (7.5 mg/kg) doses and quinuclidinyl benzilate ([³H]-QNB) binding to CNS membranes was determined. It was observed that ligand binding to cerebellum increases while it decreases in the case of hippocampus. Saturation binding curves showed that changes were due to the modification of receptor affinity for the ligand without alteration of binding site number. The purpose of this study was to assay muscarinic receptors employing other BIC dose (5 mg/kg), which induces seizures and allows the analysis of a postseizure stage as well. To study further muscarinic receptor involvement in BIC induced seizures, KET was also employed since it is a well known anticonvulsant in some experimental models. The administration of BIC at 5 mg/kg to rats produced a similar pattern of changes in [³H]-QNB binding to those recorded with 1.0 and 7.5 mg/kg doses. Here again, changes were observed in receptor binding affinity without alteration in binding site number for cerebellum or hippocampus membranes. Pretreatment with KET (40 mg/kg) prevented BIC seizures and reverted [³H]-QNB binding changes induced by BIC administration. The single administration of KET invariably resulted in [³H]-QNB binding decrease to either cerebellar or hippocampal membranes. KET added in vitro decreased ligand binding likewise. Results of combined treatment with KET plus BIC are hardly attributable to the single reversion of BIC effect since KET alone invariably decreased ligand binding. It is suggested that besides alteration of cholinergic muscarinic receptor other(s) neurotransmitter system(s) may well also be involved.     

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.     

Anomalous binding of [3 H] N-methyl-quinuclidinyl benzilate methyl chloride to human lymphocyte muscarinic receptors

Using the muscarinic cholinergic ligand [³ H] N-methyl quinuclidinyl benzilate methyl chloride ([³ H] NM-QNB), we demonstrated that intact, viable human lymphocytes posses specific muscarinic binding sites. Equilibrium binding studies show that muscarinic acethylcholine receptor are devided into two subtype; high affinity (Ms) and low affinity types (Mw) for the ligand.     

3-Mercaptopropionic acid administration increases the affinity of [H]Quinuclidinyl benzilate binding to membranes of the striatum and cerebellum

It is known that quinuclidinyl benzilate (QNB) binds specifically and with high affinity to the cholinergic muscarinic receptor and that behaves as a potent antagonist of this receptor.

We have analysed -[³H]QNB binding to rat CNS membranes after the administration of the convulsant 3-mercaptopropionic acid (MP) (150 mg·kg⁻¹, i.p.). The studies were done in rats killed at two stages: during and after seizures. No changes in [³H]QNB binding to hippocampus and cerebral cortex membranes were found. [³H]QNB binding increased about 40 and 80% in striatum and cerebellum membranes, respectively. The changes were observed both in seizure and postseizures states. The study was extended to the assay of [³H]QNB binding kinetic constants in the anatomical areas modified by the convulsant. The analysis of the saturation curves indicated an increase in the binding affinity but no change in the number of binding sites. Hill number values were near the unit suggesting a non-cooperative interaction between the ligand and the receptor, and the labelling of a homogeneous population of receptor sites.

The results suggest the participation of some cholinergic pathways in the development and maintenance of MP-induced seizures.     

Myocardial muscarinic acetylcholine receptor: Choline and tris unmask heterogeneity of antagonist binding sites

The binding properties of myocardial muscarinic acetylcholine receptors are altered in the presence of choline or Tris. The binding of the antagonist [³H]quinuclidinyl benzilate is reduced in the presence of choline or Tris buffer, when compared to parallel determinations in a physiologic salt solution or phosphate buffer. Scatchard analysis indicates the reduced binding is due to a decrease in the apparent number of receptor sites. Experiments with other organic buffers exclude the possibility that the reduced binding in Tris is due to the absence of sodium ions. In the presence of choline or Tris up to 45% of the receptors are not accessible to [³H]quinuclidinyl benzilate. The remaining sites maintain their high affinity for the antagonist. A heterogeneity of antagonist sites is evident.     

Sphingosine inhibits muscarinic cholinergic receptor binding in rat parotid acinar cells

1. Sphingosine inhibited the binding of [³H]quinuclidinyl benzilate (QNB), a potent and specific muscarinic antagonist, in dispersed rat parotid acinar cells.2. The inhibition of [³H]QNB binding was expressed as decrease in affinity without significant change of a number of membrane sites.3. The effect of Sphingosine on the binding was not affected by the chelation of extracellular Ca²⁺.4. H-7, an inhibitor of protein kinase C, failed to decrease [³H]QNB binding.5. Stearylamine, an analogue of Sphingosine, was as effective as Sphingosine in inhibiting [³H]QNB binding.6. These results suggest that Sphingosine inhibits muscarinic cholinergic receptor binding by a mechanism that is independent on extracellular Ca²⁺ and protein kinase C.     

Isolation of rat brain subcellular fraction enriched in putative neurotransmitter receptors and synaptic junctions

A simple reliable method was developed for the rapid isolation of a synaptic plasma membrane-enriched fraction from rat brain. The procedure involves the direct lysis of a crude mitochondrial fraction followed by a combined flotation-sedimentation density gradient centrifugation in a fixed-angle centrifuge rotor. All fractions have been characterized with respect to relative enrichment of (Na⁺–K⁺) ATPase activity as well as putative cholinergic neurotransmitter receptors determined by [¹²⁵I]-bungarotoxin and [³H]quinuclidinyl benzilate binding. The 2-to 4-fold relative enrichment of putative receptor binding sites correlated well with the 4-fold enrichment of morphologically identifiable synaptic junctions in the synaptic plasma membrane enriched fraction.     

Biochemical Evidence of Selective Nerve Cell Changes in the Normal Ageing Human and Rat Brain

Abstract: Atrophy with ageing of human whole brain, entire temporal lobe, and caudate nucleus was assessed in autopsy specimens, by biochemical techniques. Only the caudate nucleus showed changes. Markers for several neurotransmitter systems were also examined for changes with age. In neocortex and temporal lobe of human brain, small decreases were detected in markers of cholinergic nerve terminals, whereas a large decrease (79%) occurred in the caudate nucleus. Findings were similar in striatum from 3–33-month-old rats. No change occurred in binding of [³H]quinuclidinyl benzilate by human samples. Markers of serotonergic terminals were also unchanged in human and rat brain. By contrast, binding of [³H]lysergic acid diethylamide and [³H]serotonin was decreased (32–81%) in human neocortex and temporal lobe, but not in caudate nucleus. A 43% loss of a marker of γ-aminobutyrate terminals occurred in human neocortex, while [³H]muscimol binding increased (179%). No changes were detected in markers of catecholamine synapses in temporal lobe or rat striatum. Hence, with human ageing there appears to be a loss of markers of γ-aminobutyrate neurones intrinsic to neocortex and acetylcholine cells intrinsic to the caudate nucleus, as well as a change in postsynaptic serotonin receptors in neocortex. These losses are accompanied by relative preservation of markers of ascending projections from basal forebrain and brain stem.     

Structure-binding relationship of quinuclidinyl benzilate analogs on N4TG1 neuroblastoma muscarinic receptors

By Scatchard plot analysis of [³H]QNB (quinuclidinyl benzilate) binding, there are 2×10⁵ muscarinic sites/cell with aK _d about 10 nM in N4TG1 neuroblastoma cells. We have now examined a group of compounds structurally related to aprophen and QNB for their ability to compete with the binding of QNB to the muscarini receptor. Using this structure-inhibition relationship, the functional groups of the muscarinic ligand necessary for binding were partially characterized. It was found that the quinuclidinyl ring structure of QNB can be substituted by either alkane, H, or pyrrolidine at the N without loosing their ability to bind. The addition to the quinuclidinyl ring increases the bulk of the structure and decreases binding. Like the benzilate in QNB, a similar hydrophobic structure is apparently required for the 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.     

Choline acetyltransferase activity and muscarinic binding in brain regions of aging fischer-344 rats

Muscarinic receptor binding and choline acetyltransferase (EC 2.3.1.6.) activity were assayed in three brain regions of 4-, 12- and 24-month-old Fischer-344 rats. Statistically significant age differences in cholinergic parameters were observed in each region. The affinity for [³H]quinuclidinyl benzilate increased in the cortex (24 vs 12 and 4 months), but B_max decreased in the cortex (24 vs 12 vs 4 months), striatum (24 vs 12 vs 4 months) and hippocampus (24 vs 12 and 24 vs 4). Assays of carbamylcholine inhibition of [³H]quinuclidinyl benzilate binding in the hippocampus showed that high affinity agonist binding increased with age (24 vs 12 and 4 months), and the percentage of muscarinic binding to high affinity agonist sites decreased (24 vs 12 vs 4 months). In addition, the affinity of the agonist oxotremorine for muscarinic binding sites also increased in the hippocampus (12 and 24 vs 4 months). Although the K_m of choline acetyltransferase for choline chloride did not change in any region tested, the K_m for acetyl coenzyme A decreased in the hippocampus (24 vs 12 months), but increased (4 vs 12 months) and then decreased (12 vs 24 months) in the striatum. Statistically significant age-related declines in V_max for choline acetyltransferase were noted in the striatum (24 < 12 < 4 months), but no age differences in this parameter were observed in the cortex or the hippocampus. Statistically significant positive correlations between V_max for choline acetyltransferase and B_max for [³H]quinuclidinyl benzilate binding were observed in each of the brain regions of 4-, 12- and 24-month-old rats.

The findings have implications for use of the Fischer-344 male rat as an animal model of aging and age-related disorders of the human brain, including dementia of the Alzheimer type.     

Effect of age on adrenergic and dopaminergic receptor binding in rat brain

The effects of age on receptor binding of adrenergic and dopaminergic ligands were studied in rat cerebral cortex and striatum respectively. Compared to rats 5 months of age, 25-month old rats had a significant decrease in specific binding of the β-adrenergic antagonist ligand ³H-DHA, the α-adrenergic ligand ³H-WB-4101 in cortex, and the dopaminergic antagonist ³H-spiperone in striatum. Scatchard analysis of ligand binding indicated that the decrease in specific binding was due to a decrease in the number of receptors and not to a change in the affinity of the ligand for the receptor.     

Studies on Muscarinic Binding Sites in Human Brain Identified with [3H]Pirenzepine

Pirenzepine, a potent antimuscarinic agent with apparent selectivity for a subtype (M1) of muscarinic receptors, was used in tritiated form to characterize its binding to human brain tissue. Specific [3H]pirenzepine binding showed rapid association and dissociation. From kinetic and competitive binding experiments, its KD was 5.5 nM and 9 nM, respectively. Regional distribution of [3H]pirenzepine binding determined in parallel with [3H]quinuclidinyl benzilate binding, a nonselective muscarinic antagonist, indicated a significant correlation for the maximum number of binding sites for the two radioligands in 13 brain regions, with the highest amount of binding for each in the putamen and the least in the cerebellum. Binding for [3H]pirenzepine averaged 57% of that for [3H]quinuclidinyl benzilate, with a range of 20% (cerebellum) to 77% (frontal cortex). Most antidepressants and neuroleptics tested had affinities for [3H]pirenzepine binding sites that were not significantly different from their previously reported values obtained with the use of [3H]quinuclidinyl benzilate.     

Brain Soluble Fractions Which Modulate Na+, K+-ATPase Activity Likewise Modify Muscarinic Receptor

Two brain soluble fractions, named peaks I and II, which respectively stimulate and inhibit neuronal Na⁺, K⁺-ATPase activity, have been isolated by gel filtration in Sephadex G-50. Since cholinergic transmission seems related to such enzyme activity, in this study we evaluated the effect of brain peak I, peak II, a more purified fraction II-E and commercial ouabain, on specific binding of the muscarinic antagonist [³H]quinuclidinyl benzilate to membranes from rat cerebellum, hippocampus and cerebral cortex. We found that binding was increased by peak I and decreased by peak II, II-E and ouabain, all effects proving concentration-dependent. Since the changes exerted on the muscarinic receptor followed a pattern similar to the one already described for synaptosomal membrane Na⁺, K⁺-ATPase activity, both systems seem to interact at a functional level.     

Characterization of Neurotransmitter Receptors in the Rat Hippocampal Formation

The hippocampal formation has been extensively research in terms of its putative neurotransmitters, anatomical connections, and behavioral relevance. An aspect of importance is the assessment of apparent neurotransmitter receptors by using receptor binding assays. In the present study, such assays were done in vitro to investigate alpha 1-adrenergic, alpha 2-adrenergic, beta-adrenergic, muscarinic cholinergic, benzodiazepine, and opiate receptors in the rat hippocampal formation. The corresponding radioligands for these receptors were [3H]prazosin, [3H]p-aminoclonidine, [3H]dihydroalprenolol, [3H]quinuclidinyl benzilate, [3H]flunitrazepam, and [3H]naloxone. An analysis of the binding parameters for the ligands indicated saturable binding of a high affinity and the following rank order of maximal binding capacities: [3H]flunitrazepam greater than [3H]quinuclidinyl benzilate greater than [3H]naloxone greater than [3H]p-aminoclonidine greater than [3H]prazosin greater than [3H]dihydroalprenolol. Competition experiments with pharmacologic agonists and antagonists confirmed the specificity of each ligand. The results are integrated with information on other types of receptors and with neurotransmitter concentrations, and discussed in terms of hippocampal function.     

Two-step isomerization of quinuclidinyl benzilate-muscarinic receptor complex

A kinetic analysis was made of the dissociation reaction of the muscarinic receptor-l-[³H]quinuclidinyl benzilate complex at 25°C in 0.05 M K-phosphate buffer. The course of the reaction was followed by the decrease in the concentration of the membrane-bound radiolabelled antagonist while rebinding was prevented by the excess of nonradioactive quinuclidinyl benzilate. It was found that both bi- and mono-exponential kinetic curves of the process can be observed, depending on the time moment when the dissociation reaction is started. If the receptor-ligand complex had been incubated for a sufficiently long time before the excess of the nonradioactive ligand was added to “displace” the radioactive ligand from the complex, the dissociation reaction followed the first-order kinetics. The bi-exponential kinetics of the dissociation process was obtained if the displacement was started within a short time interval after the complex formation between the receptor and l-[³H]quinuclidinyl benzilate. The data obtained were analysed within the framework of a reaction scheme containing two consecutive isomerization steps of the receptor-antagonist complex. The “isomerized” receptor-ligand complexes differ in their dissociation rate and therefore their interconversion changes the observed kinetic behaviour of the dissociation reaction of the receptor-ligand complex.