On the involvement of multiple muscarinic receptor subtypes in the activation of phosphoinositide metabolism in rat cerebral cortex

We have examined the activation of phosphoinositide metabolism by muscarinic agonists in rat cerebral cortex, in an attempt to delineate the mechanisms by means of which some selective antagonists inhibit this response in a manner that deviates from simple mass action law. The accumulation of [3H]inositol phosphates induced by the full agonist carbamylcholine in cell aggregates preparations was inhibited by muscarinic antagonists with the following order of potency: telenzepine greater than atropine greater than 4-diphenylacetoxy-N-methyl-piperidine methbromide greater than pirenzepine greater than hexahydro-sila-difenidol greater than AF-DX 116. The same order of potency was found for the competition of these antagonists with [3H]telenzepine binding to M1 muscarinic receptors. The inhibition of the formation of [3H]inositol phosphates activated by acetylcholine, carbamylcholine, and oxotremorine-M by pirenzepine and telenzepine showed biphasic curves, with 62-73% of the response being inhibited with high affinity. Atropine, AF-DX 116, and pirenzepine shifted the concentration-response curves of oxotremorine-M to the right in a parallel manner. However, pirenzepine at micromolar concentrations showed deviation from linearity of the Schild regression. The blockade by high concentrations of pirenzepine and telenzepine showed less than additive dose ratios when assayed in the presence of atropine, suggesting deviation of their antagonism from simple competition. However, after alkylation with propylbenzilylcholine mustard in the presence of low concentrations of pirenzepine, the response to carbamylcholine and oxotremorine-M showed monophasic inhibition curves by pirenzepine and linear Schild regression for this antagonist. These results support the interpretation that the formation of [3H]inositol phosphates is activated by multiple muscarinic receptor subtypes in rat cerebral cortex. The profile of affinities of muscarinic antagonists indicates that a major component of the response is activated by an M1 receptor subtype and a minor component is probably mediated by M3 muscarinic receptors when acetylcholine, carbamylcholine, or oxotremorine-M are used to stimulate the response. Conversely, pirenzepine inhibited the response induced by methacholine and bethanechol in a monophasic manner with high affinity (Ki = 13 nM), suggesting that these agonists can selectively stimulate phosphoinositide metabolism through activation of M1 muscarinic receptors in rat cerebral cortex.     

Inhibition of phosphoinositide turnover by selective muscarinic antagonists in the rat striatum. Correlation with receptor occupancy

In the rat corpus striatum, receptor occupancy and the inhibition of phosphoinositide turnover by muscarinic antagonists have been examined under very similar conditions with respect to tissue preparation and buffer composition. The results suggest a good correlation between receptor occupancy and inhibition by muscarinic antagonists, of the carbachol-stimulated turnover of inositol phospholipids, measured by the accumulation of [3H]inositol phosphates in the presence of 5 mM LiCl. In the presence of 10 mM carbachol (CCh), the accumulation of labeled inositol phosphates was increased 8-fold above basal levels (EC50 = 95 microM). Inclusion of antagonists resulted in a dose-dependent inhibition of the 0.1 mM CCh-stimulated inositol phosphate accumulation, with a rank order of potency of atropine greater than trihexyphenidyl greater than pirenzepine greater than or equal to gallamine. Radioligand binding studies with [3H]-l-quinuclidinyl benzilate [( 3H]QNB) in a cell aggregate preparation revealed a single class of saturable, high affinity [3H]QNB binding sites exhibiting a Kd of 74 pM and a Bmax of 2.85 pmol/mg protein. The antagonists examined were able to inhibit the binding of [3H]QNB with the same rank order of potency as for the inhibition of carbachol-stimulated phosphoinositide turnover (atropine greater than trihexyphenidyl greater than pirenzepine greater than or equal to gallamine). Although the inhibition of phosphoinositide turnover and [3H]QNB binding by the nonselective antagonist atropine was best described by interaction at a single site, inhibition of phosphoinositide turnover and [3H]QNB binding by both pirenzepine, which is selective for M1 receptors, and gallamine, which is selective for M2 receptors, is complex. Pirenzepine was much more potent than gallamine for both binding to receptors and inhibiting phosphoinositide turnover. Nonlinear curve-fitting analysis indicated that slope factors for inhibition of phosphoinositide turnover (analogous to Hill coefficient for binding) by only subtype selective antagonists were significantly less than unity. The above-mentioned antagonist interactions together with the apparently multicomponent stimulation of phosphoinositide turnover by carbachol suggest that phosphoinositide turnover may be coupled to more than one muscarinic receptor subtype in the corpus striatum.     

Selectivity of oxomemazine for the M1 muscarinic receptors

The binding characteristics of pirenzepine and oxomemazine to muscarinic receptor were studied to evaluate the selectivity of oxomemazine for the muscarinic receptor subtypes in rat cerebral microsomes. Equilibrium dissociation constant (KD) of (-)-[3H]quinuclidinyl benzilate([3H]QNB) determined from saturation isotherms was 64 pM. Analysis of the pirenzepine inhibition curve of [3H]QNB binding to cerebral microsome indicated the presence of two receptor subtypes with high (Ki = 16 nM, M1 receptor) and low (Ki = 400 nM, M3 receptor) affinity for pirenzepine. Oxomemazine also identified two receptor subtypes with about 20-fold difference in the affinity for high (Ki = 84 nM, OH receptor) and low (Ki = 1.65 microM, OL receptor) affinity sites. The percentage populations of M1 and M3 receptors to the total receptors were 61:39, and those of OH and OL receptors 39:61, respectively. Both pirenzepine and oxomemazine increased the KD value for [3H]QNB without affecting the binding site concentrations and Hill coefficient for the [3H]QNB binding. Oxomemazine had a 10-fold higher affinity at M1 receptors than at M3 receptors, and pirenzepine a 8-fold higher affinity at OH receptors than at OL receptors. Analysis of the shallow competition binding curves of oxomemazine for M1 receptors and pirenzepine for OL receptors yielded that 69% of M1 receptors were of OH receptors and the remaining 31% of OL receptors, and that 29% of OL receptors were of M1 receptors and 71% of M3 receptors. However, M3 for oxomemazine and OH for pirenzepine were composed of a uniform population. These results suggest that oxomemazine could be classified as a selective drug for M1 receptors and also demonstrate that rat cerebral microsomes contain three different subtypes of M1, M3 and the other site which is different from M1, M2 and M3 receptors.     

Interaction of agonists and selective antagonists with gastric smooth muscle muscarinic receptors

Summary The interaction of cholinergic agonists and antagonists with smooth muscle muscarinic receptors has been investigated by measurement of displacement of the muscarinic antagonist [³H]QNB (quinuclidinyl benzilate) in membranes prepared from toad stomach. The binding of [³H]QNB was saturable, reversible and of high affinity (K _D = 423 pM). The muscarinic receptor subtypes present in gastric smooth muscle were classified by determining the relative affinities for the selective antagonists pirenzepine (M₁), AF-DX 116 (M₂) and 4-DAMP (M₃). The results from these studies indicate the presence of a heterogeneous population of muscarinic receptor subtypes, with a majority (88%) exhibiting characteristics of M₃ receptors and a much smaller population (12%) exhibiting characteristics of M₂ receptors. The binding curve for the displacement of [³H]QNB binding by the agonist oxotremorine was complex and was consistent with presence of two affinity states: 24% of the receptors had a high affinity (K _D = 4.7 nM) for oxotremorine and 76% displayed nearly a 1,000-fold lower affinity (K _D = 4.4 M). When oxotremorine displacement of [³H]QNB binding was determined in the presence GTPS, high affinity binding was abolished, indicating that high affinity agonist binding may represent receptors coupled to G proteins. Moreover, pertussis toxin pretreatment of membranes also abolished high affinity agonist binding, indicating that the muscarinic receptors are coupled to pertussis toxin-sensitive G proteins. Reaction of smooth muscle membranes with pertussis toxin in the presence [³²P]NAD caused the [³²P]-labelling of a 40 kD protein that may represent the subunit(s) of G proteins that are known to be NAD-ribosylated by the toxin. We conclude that both M₃ and M₂ receptors may be coupled to G proteins in a pertussis-sensitive manner. Send offprint requests to T. W. Honeyman at the above address     

Muscarinic binding sites on bovine pulmonary arterial endothelial cells in culture.

We have investigated the presence and nature of muscarinic binding sites on membranes from cultured bovine pulmonary arterial endothelial cells (BPAE). BPAE were harvested and subcultured nonenzymatically; experiments were performed 3-5 days postconfluence and between 10 and 25 passage numbers. Utilizing radioligand binding techniques with the muscarinic receptor antagonists [3H]3-quinuclidinyl benzilate ([3H]QNB) and [3H]N-methylscopolamine ([3H]MS) as probes, we identified a small population of atropine-sensitive muscarinic sites (1,800-2,000 sites/cell or 7-8 fmol/mg protein). Muscarinic binding sites on BPAE membranes resembled classical muscarinic receptors in that (a) the binding of 2 nM [3H]QNB was inhibited by muscarinic agonists and antagonists, (b) [3H]QNB binding was 30 times more sensitive to R(-)- than to S(+)-QNB, (c) binding of the muscarinic receptor agonist carbamylcholine involved high and low affinity components, (d) the stable GTP analog, Gpp(NH)p (100 microM) shifted agonist binding curves to the right by a factor of three, and (e) the high affinity binding of the agonist [3H]oxotremorine-M to muscarinic receptors was depressed by Gpp(NH)p. On the other hand, gallamine, which allosterically regulates muscarinic receptor binding in other tissues, did not affect the rates of dissociation of [3H]QNB, [3H]MS or [3H]oxotremorine-M from BPAE binding sites. We concluded that BPAE in culture exhibit muscarinic binding sites which possess many but not all of the properties associated with classical muscarinic receptors.     

Radioligand binding characteristics of the chicken cardiac muscarinic receptor

Summary The muscarinic receptor present in chicken cardiac membranes was characterised using a ligand binding approach and compared to the M1, M2 and M3 receptors that can be identified in ligand binding studies at present. [³H]N-methylscopolamine and [³H]pirenzepine appeared to label the same population of muscarinic receptors in chicken cardiac membranes since the density of sites labeled by the two radioligands was similar. Furthermore, affinity estimates of 8 muscarinic receptor antagonists for chicken cardiac muscarinic receptors were the same irrespective of whether [³H]N-methylscopolamine or [³H]pirenzepine was used as the radioligand. The chicken cardiac muscarinic receptor displayed high affinity for pirenzepine (pK _i = 7.9) and so did not appear to represent an M2 receptor. Despite the high affinity of chicken cardiac muscarinic receptors for pirenzepine, affinity estimates for dicyclomine (pK _i = 8.0), CPPS (pK _i = 8.4) and 4DAMP (pK _i = 8.6) in chicken heart were not consistent with the presence of M1 receptors. The chicken cardiac muscarinic receptor also displayed significant differences to the M3 receptor since it displayed high affinity for AF-DX 116 (pK _i = 7.1) and methoctramine (pK _i = 8.4). Finally, chicken heart muscarinic receptors displayed high affinity for gallamine (pK _i = 7.0) and pirenzepine suggesting that the receptor was different to the M4 muscarinic receptor of the NG108-15 cell line. These findings suggest that chicken heart expresses a novel muscarinic receptor subtype distinct from the M1, M2, M3, and M4 subtypes already described. Send offprint requests to A. Michel.     

Cholinergic stimulation of drinking from the lateral hypothalamus: indications for M2 muscarinic receptor mediation

Available evidence suggests that muscarinic receptor binding sites may exist in at least two heterogenous subclasses (M1 and M2), distinguished by their affinity for the antagonist pirenzepine. In order to evaluate the role of these receptors in comsummatory behaviour a series of conventional and putatively receptor selective drugs were tested for their effects on water consumption following injection (0.5 microliter/30 sec) into the perifornical hypothalamic area of non-deprived rats. Of the conventional agonists tested, carbachol and oxotremorine were approximately equipotent and arecoline was about 16 X weaker. Of the putative M1 agonists tested, pilocarpine was about 50 X weaker than carbachol and the remainder (MCNA343, AHR602, AH6405) were inactive. Inhibition of carbachol (1 microgram) induced drinking was subsequently measured. The most potent inhibition was found using scopolamine, a non selective antagonist. 4-DAMP was approximately 7 X weaker than scopolamine, but was more potent than the putative M1 antagonists pirenzepine, telenzepine or dicyclomine. In a separate series of experiments the affinity of these drugs for [3H]pirenzepine forebrain receptors (M1) and [3H]QNB brainstem receptors (M2) was determined to confirm their receptor binding selectivity. No systematic relationship was found between agonist potency and M1 or M2 affinities. M2 receptor involvement was indicated by the antagonist data which show a close relationship between rank potency order and M2 receptor affinity. An important role for M1 receptors is excluded by the absence of a clear relationship between potency order and M1 affinity. The data therefore suggest an important role for M2 receptors in mediating drinking stimulated by muscarinic receptor activation.     

Effects of in vivo and in vitro treatments with N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline on putative muscarinic receptor subtypes in rat brain

N-Ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ) was found to irreversibly decrease the Bmax of [3H](-)-quinuclidinyl-benzilate [(-)QNB] binding in rat brain following in vivo administration or by incubation of tissue homogenates with EEDQ in vitro. A greater reduction in the Bmax of [3H](-)QNB binding was observed in the hippocampus and cortex than in the brainstem following in vivo or in vitro treatment with EEDQ. Competition of pirenzepine for [3H](-)QNB binding was best described by computer-derived models assuming two binding sites in all brain regions. However, following EEDQ treatment there was a rightward shift in the pirenzepine competition curves for the remaining [3H](-)QNB-binding sites in all brain regions. Computer analysis of the pirenzepine competition curves indicated that this was due to a selective decrease in the number of [3H](-)QNB-binding sites having high affinity for pirenzepine. Although the binding of [3H](-)QNB to the site having lower affinity for pirenzepine was apparently unaltered, the affinity of pirenzepine for this binding site was significantly lowered following both in vivo and in vitro treatment with EEDQ. Thus, EEDQ differentially modifies muscarinic receptor-binding sites having high and low affinity for pirenzepine. The reduction in the Bmax of [3H](-)QNB binding and the rightward shift in the pirenzepine competition curve elicited by EEDQ both in vivo and in vitro could be prevented by coadministration of reversible muscarinic antagonists, thereby demonstrating that EEDQ interacts at the ligand recognition site of muscarinic receptors. These data suggest that the putative muscarinic receptor subtypes discriminated by pirenzepine may represent differences in the accessibility of pirenzepine and EEDQ to a homogeneous population of [3H](-)QNB-binding sites or, alternatively, that these muscarinic receptor-binding sites discriminated by pirenzepine and EEDQ represent structurally distinct molecular entities.     

Effect of the lipid environment on the differential affinity of purified cerebral and atrial muscarinic acetylcholine receptors for pirenzepine

Muscarinic acetylcholine receptors (mAChRs) of porcine cerebral membrane (predominantly M1 subtype) and porcine atrial membrane (M2 subtype) showed the same affinity for the muscarinic antagonist [3H]quinuclidinylbenzylate [( 3H]QNB). In contrast, the affinity for pirenzepine (another muscarinic antagonist) of 86% of binding sites in the cerebral membrane (H sites) was 34-fold higher than that in the atrial membrane. After purification of mAChRs by affinity chromatography, this difference was less than 3-fold. This phenomenon was fully reversed by insertion of purified mAChRs into either cerebral or atrial membranes whose native muscarinic binding sites had been alkylated with propylbenzilycholine mustard, indicating that the purified receptors recovered their original affinities for pirenzepine upon interaction with membrane components. To examine the effect of the interaction between receptors and lipid components on the affinities for [3H]QNB and pirenzepine, binding experiments were carried out with mAChRs inserted into various lipid preparations. When purified cerebral and atrial mAChRs were inserted into cholesteryl hemisuccinate, their affinities for [3H]QNB and pirenzepine became close to the membrane values and were 7- and 50- to 60-fold higher than those of receptors inserted into phosphatidylcholine, respectively. When insertion was carried out into either cholesteryl hemisuccinate, phosphatidylcholine, or cholesteryl hemisuccinate/phosphatidylcholine mixtures, (80:20 and 50:50, w/w), the affinity of cerebral H sites for pirenzepine was only 3- to 5-fold higher than that of atrial receptors, but it became 20- and 60-fold higher when the receptors were inserted in a cholesteryl hemisuccinate/phosphatidylcholine mixture (20:80, w/w) and in a cholesteryl hemisuccinate/phosphatidylcholine/phosphatidylinositol mixture (4:48:48, w/w), respectively. These results suggest that the affinities of mAChRs for antagonists, in particular the differential affinities of cerebral and atrial mAChRs for pirenzepine, are modulated by the lipid environment.     

BIOCHEMICAL CHARACTERISTICS OF MUSCARINIC CHOLINORECEPTORS IN SWINE TRACHEAL SMOOTH MUSCLE

• 1 The tritiated muscarinic cholinoreceptor antagonist quinuclidinyl benzilate, [³H]QNB, was used to characterize the muscarinic receptors associated with homogenized membrane of the smooth muscle from swine trachea. Based on receptor binding assays, the homogenate had specific, saturable, high-affinity receptors for [³H]QNB.
• 2 Specific binding was time- and temperature-dependent. The association of [³H]QNB with the muscarinic receptor reached equilibrium much sooner at 37°C than 25°C at a [³H]QNB concentration of 180 pM (30 min and 2 h, respectively). Equilibrium at both temperatures was attained within 5 min at a [³H]QNB concentration of 1800 pM. All remaining experiments were performed at 37°C.
• 3 Binding was saturable with respect to [³H]QNB and tissue concentrations. Analysis of binding isotherms yielded an apparent equilibrium dissociation constant (K_D) of 51±20 pM and a maximum receptor density (B_max) of 2.17±0.27 pmole/mg protein. The Hill coefficient for [³H]QNB binding was 1.07±0.16. The association (K₁) and dissociation (K_-1) rate constants were determined to be (5.51±0.16) × 10⁸ M^?1 min^?1 and (1.41±0.18) × 10^?2 min^?1, respectively. K_D calculated from the ratio of K₁ and K_-1 was 26.3±3.8 pM; this value is close to the value of K_D calculated from Scatchard plots of binding isotherms.
• 4 The density of muscarinic receptor binding sites was 10-fold greater in tracheal smooth muscle than in tracheal epithelium (0.20±0.03 pmole/mg protein). There is no difference between weanling and young adult swine in the density of muscarinic receptors in tracheal smooth muscle.
• 5 The nonselective muscarinic antagonists atropine, scopolamine and quinuclidinyl benzilate (QNB) competitively inhibited [³H]QNB binding to the homogenate with Hill coefficients of 0.9-1.0 and inhibition constants (K_i) of nanomolar range.
• 6 Competition with selective muscarinic antagonists pirenzepine and 3-quinuclidinyl xanthene-9-carboxylate (QNX) gave K_i values, 0.26 M and 0.78 nM, respectively, and Hill coefficients of approximately 1. There was a single population of [³H]QNB binding sites of the M₂ subtype for all tested muscarinic antagonists.
• 7 Competition with selective muscarinic agonists pilocarpine and carbachol yielded K_i values of micromolar range, Hill coefficients of less than 1, and revealed the existence of two binding sites (P < 0.01).

     

Muscarinic receptors in canine colonic circular smooth muscle. I. Coexistence of M2 and M3 subtypes.

The parasympathetic neurotransmitter acetylcholine, acting postsynaptically at the smooth muscle muscarinic receptor, is a principle determinant of colonic motility. In order to elucidate the receptor signal-transduction events responsible for muscarinic receptor-induced contraction of colonic circular smooth muscle, we present here and in the accompanying work studies designed to characterize the muscarinic receptors present in colon and to determine their biochemical coupling. Muscarinic receptor subtypes in canine colonic circular smooth muscle were characterized using radioligand binding techniques. The nonselective muscarinic receptor antagonist radioligand [3H]quinuclidinyl benzilate ([3H]QNB) binds rapidly and reversibly to a single class of saturable sites in colon circular smooth muscle membranes, with an affinity (KD) for the antagonist radioligand of 79.8 +/- 12.6 pM and a density of 123.3 +/- 18.7 fmol/mg of protein. Experiments using membranes prepared from isolated cells purified from the circular smooth muscle layer of canine colon (KD = 102.4 +/- 13.5 pM) confirm the smooth muscle origin of the binding and yield a receptor density of 124,340 receptors/cell. The order of potencies of selective muscarinic receptor antagonists in competition with [3H]QNB for binding to colonic receptors is 4-diphenylacetoxy-N-methylpiperidine methobromide greater than methoctramine greater than AF-DX 116 greater than pirenzepine. Unlike other antagonists tested, pirenzepine competition of [3H]QNB binding is biphasic. The high and low affinities deduced from nonlinear fit of the binding data in colon correlate very well with affinities determined for pirenzepine in mixtures of both submandibular gland (M3) and atrium (M2), indicating the presence of two muscarinic receptor subtypes (82% M2, 18% M3) in colon circular smooth muscle. The muscarinic agonist carbachol binds to both high and low affinity sites in colon, and addition of guanine nucleotide (100 microM GTP gamma S) shifts the agonist competition curve to the right, without eliminating high affinity binding sites. Agonist competition studies with a known ratio of M2 and M3 receptors, obtained by mixing pure M2 and M3 populations, predict the result obtained in colon. cDNA probes specific for each of the muscarinic receptors m1 through m4 were hybridized to colon RNA in a Northern blot analysis. Only m2 and m3 probes hybridized to colon RNA, suggesting the presence of both M2 and M3 receptors. Our data demonstrate that the colon circular smooth muscle contains muscarinic receptors of both the M2 and M3 subtypes, which may be coupled to disparate signal transduction pathways important in the physiological actions of acetylcholine in this tissue.     

Dicyclomine, benzhexol and oxybutynine distinguish between subclasses of muscarinic binding sites

The interactions of various unlabelled antimuscarinic drugs with the muscarinic receptors in the cerebral cortex, heart and urinary bladder were studied by a receptor binding technique, using (-)[3H]QNB as radioligand. In contrast to the other drugs examined, dicyclomine, benzhexol, oxybutynine and pirenzepine were bound with a significantly higher affinity in the cortex than in the heart and bladder. Furthermore, not only pirenzepine, but also dicyclomine and benzhexol were capable of distinguishing between two populations of muscarinic binding sites in the cortex. The low affinity sites for these drugs in the cortex were characterised by dissociation constants which were similar to those determined in the heart and the bladder, respectively. It was concluded that dicyclomine and benzhexol, like pirenzepine, are selective antagonists at the putative M1-receptor. Oxybutynine exhibited the same affinity profile but the tissue selectivity of this drug was less pronounced.     

Characterization of cholinergic muscarinic receptors in the rabbit iris

The sphincter smooth muscle of the iris is innervated by excitatory parasympathetic nerve fibers, and the activation of these fibers results in the breakdown of phosphatidylinositol 4,5-bisphosphate into its derived second messengers, myosin light chain phosphorylation and muscle contraction. The present study characterizes the muscarinic acetylcholine receptors (mAChRs) of the rabbit iris employing [3H]N-methylscopolamine ([3H]NMS) and L-[3H]quinuclidinyl benzilate ([3H]QNB) as probes. Binding studies indicated that [3H]NMS and [3H]QNB bound to homogeneous populations of mAChRs with apparent Bmax values of 0.67 and 1.09 pmol/mg protein respectively. Binding of radioligands was rapid, saturable, stereospecific, reversible, and inhibited by specific muscarinic agonists and antagonists in a competitive manner. [3H]NMS displayed a lower amount of nonspecific binding and a faster association and dissociation rate than [3H]QNB. The relative potencies for displacement of both radioligands, based on their Ki values, were (-)QNB greater than atropine greater than (+)QNB greater than pirenzepine greater than pilocarpine. Antagonist displacement of the radioligands appeared to obey the law of mass action, indicating interaction with a single binding site. However, displacement of the radioligands by the agonists carbamylcholine and methacholine indicated interaction with both high and low affinity binding sites. Comparison of the displacement of [3H]NMS and [3H]QNB by pirenzepine in microsomal fractions from rabbit iris, ileal muscle and cerebral cortex revealed the presence of a single subtype of mAChR in the iris which had an affinity for PZ that was slightly higher than that of ileal M2 receptors, but lower than that of brain M1 receptors. This suggests that the mAChRs in the iris may represent a subclass of receptors within the M2 subtype, or they may constitute an entirely different subtype of mAChRs.     

Analogues of Carbacholine: Synthesis and Relationship between Structure and Affinity for Muscarinic and Nicotinic Acetylcholine Receptors

A series of acyclic and heterocyclic analogues of carbacholine ( 1 ) was synthesized using N-methylcarbacholine (MCC, 2 ), N,N-dimethylcarbacholine (DMCC, 3 ), and the corresponding tertiary amine ( 4 ) as leads. Whereas nicotinic acetylcholine receptor affinity was determined using [³H]nicotine as the radioactive ligand, [³H]oxotremorine-M ([³H]Oxo-M) and [³H]quinuclidinyl benzilate ([³H]QNB), in some cases supplemented with [³H]pirenzepine ([³H]PZ), were used as radioligands for muscarinic acetylcholine receptors on rat brain membranes. On the basis of receptor binding data, nicotinic/muscarinic (N/M) selectivity factors were determined, and muscarinic receptor efficacy (M agonist index) and M₁ selectivity (M₂/M₁ index) estimated. In most cases, quaternized analogues showed higher affinity than the corresponding tertiary amines for muscarinic and, in particular, nicotinic receptor sites. Among the new compounds, N,N-diethylcarbacholine ( 9e ) (IC₅₀ = 0.046 μM), (S)-1-methyl-2-(N,N-diethyl-aminocarbonyloxymethyl)pyrrolidine ( 17k ) (IC₅₀ = 0.068 μM), and the corresponding quaternized analogue, 18k (IC₅₀ = 0.018 μM) showed the highest nicotinic receptor affinity. The tertiary amine, 17k showed much higher nicotinic receptor affinity than the acyclic analogue, 4 (IC₅₀ = 5.7 μM), and the N/M selectivity factor determined for 17k (150) is an order of magnitude lower than that of nicotine (1400). The N/M selectivity factors for MCC ( 2 ) and DMCC ( 3 ), previously reported to be highly selective nicotinic receptor ligands, were shown to be 6.5 and 60, respectively, the latter value being comparable with that of 18k (89).     

Modulation of central muscarinic receptor binding in vitro by ultralow levels of the organophosphate paraoxon

Homogenates of calf caudate nuclei were found to contain at least three distinct subclasses of cholinergic, muscarinic receptors. These subtypes, labeled with [3H]quinuclidinyl benzilate (QNB), can be separated by rapid filtration with the use of the selective ligands, pirenzepine, AF-DX116, and 4-DAMP which have high affinity for the M1, M2, and M3 subtypes, respectively. Paraoxon was found to modulate [3H]QNB binding in a noncompetitive manner at concentrations below those needed to affect acetylcholinesterase activity. Pretreatment of the membrane protein with high concentrations of both the M2 selective antagonist, AF-DX116, and the M3 selective antagonist, 4-DAMP, protected against paraoxon inhibition of [3H]QNB binding, while the M1 selective antagonist pirenzepine did not. Paraoxon sensitive sites, M2 and M3, are found predominantly on presynaptic neurons in the central nervous system. It is postulated that blockade of these sites may interfere with negative feedback inhibition of acetylcholine release and facilitate the development of behavioral and motor deficits that may be associated with chronic exposure to low levels of organophosphates.     

Prejunctional M1 and postjunctional M3 muscarinic receptors in the circular muscle of the guinea-pig ileum

The effects of subtype-selective muscarinic receptor antagonists on electrically evoked release of acetylcholine and muscle contraction were compared in circular muscle preparations of the guinea-pig ileum. Incubation of the preparation with [³H]choline resulted in the formation of [³H]acetylcholine. Electrical stimulation caused the release of [³H]acetylcholine which was abolished by tetrodotoxin and omission of calcium from the medium. 5-Hydroxytryptamine (10 M) and the nicotinic agonist 1,1-dimethyl-4-phenylpiperazinium (300 M) did not change acetylcholine release. The muscarinic antagonists pirenzepine (M1 selective), AF-DX 116 (M2 selective) and hexahydrosiladifenidol (M3 selective) caused concentration-dependent increases in the evoked release of acetylcholine, and inhibitions of the circular muscle contraction. The postjunctional affinity constants (pA₂ values) obtained for hexahydrosiladifenidol (8.06), pirenzepine (6.95) and AF-DX 116 (6.60) identified the muscular receptor as an M3 subtype. Pirenzepine was more potent in facilitating the evoked release than hexahydrosiladifenidol and AF-DX 116. These findings suggest that the release of acetylcholine in the circular muscle is inhibited by M1 muscarinic autoreceptors whereas muscle contraction is mediated by M3 receptors.     

Binding of selective antagonists to four muscarinic receptors (M1 to M4) in rat forebrain

To compare the proportions of four muscarinic receptors in different rat brain regions, we used competition curves with four selective antagonists, at 1-[N-methyl-3H]scopolamine methyl chloride [( 3H]NMS) binding equilibrium and after allowing [3H]NMS dissociation for 35 min. Himbacine and methoctramine were shown to discriminate two muscarinic receptor subtypes having a high affinity for 4-diphenylacetoxy-N-methylpiperidine methiodide and hexahydrosiladifenidol, intermediate affinity for pirenzepine, and low affinity for AF-DX 116. One M4 subtype had a high affinity for himbacine and methoctramine; it was found predominantly in homogenates from rat striatum (46% of total [3H]NMS receptors) and in lower proportion in cortex (33% of [3H]NMS receptors) and hippocampus (16% of [3H]NMS receptors). Its binding properties were identical to those of muscarinic receptors in the neuroblastoma x glioma NG 108-15 hybrid, suggesting that it was encoded by m4 mRNA. The M3 subtype (typically found in rat pancreas, a tissue expressing the m3 mRNA) had a low affinity for himbacine and methoctramine and represented about 10% of all [3H]NMS receptors in rat brain cortex, hippocampus, striatum, and cerebellum. M1 and M2 receptors were identified in rat brain by their high affinity for pirenzepine and AF-DX 116, respectively.     

Effect of bay K 8644, a calcium channel agonist,on dog cardiac muscarinic receptors

To investigate further whether the effects of the dihydropyridine (DHP) drugs on calcium channels are related to those of these drugs on muscarinic receptors, the binding characteristics of the DHP calcium channel agonist, Bay K 8644, on muscarinic receptors and calcium channels were compared to those of the DHP calcium channel antagonists, nicardipine and nimodipine in the dog cardiac sarcolemma. Bay K 8644, nicardipine and nimodipine inhibited the specific [³H]QNB binding with K _i values of 16.7μM, 3.5μM and 15.5μM respectively. Saturation data of [³H]QNB binding in the presence of these DHP drugs showed this inhibition to be competitive. Bay K 8644, like nicardipine and nimodipine, blocked the binding of [³H]nitrendipine to the high affinity DHP binding sites, but atropine did not, indicating that the muscarinic receptors and the DHP binding sites on calcium channels are distinct. The K _i value of Bay K 8644 for the DHP binding sites was 4 nM. Nicardipine and nimodipine (K _i :0.1–0.2 nM) were at least 20 times more potent than Bay K 8644 in inhibiting [³H]nitrendipine binding. Thus, the muscarinic receptors were about 4000 times less sensitive than these high affinity DHP binding sites to Bay K 8644. These results suggest that the DHP calcium agonist Bay K 8644 binds directly to the muscarinic receptors but its interaction with the muscarinic receptors is not related to its binding to the DHP binding sites on calcium channels.     

Muscarinic receptor subtypes in bovine adrenal medulla

Muscarinic receptors in bovine adrenal medullary microsomes were characterized by radioligand binding assay, using l-[3H]quinuclidinyl benzilate (QNB), a muscarinic antagonist. Specific [3H]QNB binding to microsomes was rapid, reversible, saturable and of high affinity. Saturation experiments revealed a single class of binding sites for the radioligand with a maximum number of binding sites and an apparent dissociation constant of 162.6 fmoles/mg protein and 40.3 pM respectively. According to computer-assisted nonlinear regression analysis, however, drug/[3H]QNB competition curves indicated the presence of at least two affinity sites for muscarinic agonists (acetylcholine, carbamylcholine, oxotremorine), with a high (K1) and a low (K2) affinity (e.g. K1 = 664.8 nM and K2 = 36.5 microM for acetylcholine). The two affinity sites for acetylcholine showed only minimal regulation by magnesium and guanosine 5'-triphosphate. Furthermore, the presence of two affinity sites was suggested for the antagonists pirenzepine and gallamine, but not for atropine and pilocarpine. The K1 and K2 values for pirenzepine were 23.7 and 429 nM, respectively, with 54.5% of total sites having a high affinity. These results indicate that at least two distinct subtypes of muscarinic receptors exist in the bovine adrenal medulla and that they are distinguished by their relative binding affinity for muscarinic agonists and antagonists. The receptors are predominantly composed of the affinity state termed M1, as described for the receptors of sympathetic ganglia.     

Muscarinic receptor heterogeneity in rat central nervous system. I. Binding of four selective antagonists to three muscarinic receptor subclasses: a comparison with M2 cardiac muscarinic receptors of the C type

We previously observed that [3H]NMS recognizes three types of muscarinic receptors in rat brain (one M1 subclass with high affinity for pirenzepine, and two M2 subclasses with low affinities for pirenzepine), based on distinct affinity and kinetic constants of [3H]NMS for these three subclasses. In this work, we investigated the binding of four selective antagonists to these three (the M1 and two M2) subclasses. We were able to demonstrate that cardiac-like M2 receptors with low affinity for pirenzepine and low affinity for N-methylscopolamine were present not only in cerebellum (as previously shown; see introduction) but also in cortex, striatum, and hippocampus, and the two M2 receptor subclasses were discriminated by dicyclomine, 4-DAMP, and gallamine, as well as by AF-DX 116 and [3H]NMS. Our findings also suggested that the biphasic association and dissociation kinetics of [3H]NMS observed in various brain regions reflect sequential binding to the different receptors.