L-689,660, a novel cholinomimetic with functional selectivity for M1 and M3 muscarinic receptors.

1. L-689,660, 1-azabicyclo[2.2.2]octane, 3-(6-chloropyrazinyl)maleate, a novel cholinomimetic, demonstrated high affinity binding (pKD (apparent) 7.42) at rat cerebral cortex muscarinic receptors. L-689,660 had a low ratio (34) of pKD (apparent) values for the displacement of binding of the antagonist ([3H]-N-methylscopolamine ([3H]-NMS) compared with the displacement of the agonist [3H]-oxotremorine-M ([3H]-Oxo-M), in rat cerebral cortex. Low NMS/Oxo-M ratios have been shown previously to be a characteristic of compounds that are low efficacy partial agonists with respect to stimulation of phosphatidyl inositol turnover in the cerebral cortex. 2. L-689,660 showed no muscarinic receptor subtype selectivity in radioligand binding assays but showed functional selectivity in pharmacological assays. At M1 muscarinic receptors in the rat superior cervical ganglion, L-689,660 was a potent (pEC50 7.3 +/- 0.2) full agonist in comparison with (+/-)-muscarine. At M3 receptors in the guinea-pig ileum myenteric plexus-longitudinal muscle or in trachea, L-689,660 was again a potent agonist (pEC50 7.5 +/- 0.2 and 7.7 +/- 0.3 respectively) but had a lower maximum response than carbachol. In contrast L-689,660 was an antagonist at M2 receptors in guinea-pig atria (pA2 7.2 (95% confidence limits 7, 7.4)) and at muscarinic autoreceptors in rat hippocampal slices. 3. The putative M1-selective muscarinic agonist, AF102B (cis-2-methylspiro-(1,3-oxathiolane 5,3')-quinuclidine hydrochloride) was found to have a profile similar to L-689,660 but had up to 100 times less affinity in binding and functional assays.(ABSTRACT TRUNCATED AT 250 WORDS)     

Muscarinic cholinergic agonists and antagonists of the 3-(3-alkyl-1,2,4-oxadiazol-5-yl)-1,2,5,6-tetrahydropyridine type. Synthesis and structure-activity relationships

A series of 3-(3-alkyl-1,2,4-oxadiazol-5-yl)-1,2,5,6-tetrahydro-1-methylpyr idines (2a-q) were synthesized and tested for central muscarinic cholinergic receptor binding affinity by using [3H]oxotremorine-M and [3H]QNB as ligands and in a functional assay using guinea pig ileum. The analogues with unbranched C1-8-alkyl substituents (2a-g) were agonists, whereas the compounds with branched or cyclic substituents (2h-m) were antagonists. The alkyl ether analogues (2o-q) were also agonists but had lower receptor binding affinity than the corresponding alkyl analogues. The 3-(5-alkyl-1,2,4-oxadiazol-3-yl)-1,2,5,6-tetrahydro-1-methylpyridi ne analogues had only ver low affinity for the central muscarinic receptors and were weak antagonists in the ileum assay. A few 3-(3-butyl-1,2,4-oxadiazol-5-yl)-1,2,5,6-tetrahydro-1-methylpyr idines substituted with methyl or hydrogen in the 1-, 5-, or 6-position were synthesized and tested. N-Desmethyl analogue 7 was a potent muscarinic agonist, whereas N-desmethyl-5-methyl analogue 11 and N-methyl-6-methyl analogue 13 both were antagonists with lower muscarinic receptor affinity. The 3-(3-butyl-1,2,4-oxadiazol-5-yl)quinuclidine (17) and tropane (15) analogues were both very potent antagonists with high affinity for central muscarinic receptors. The ratio [IC50(QNB)/IC50(Oxo-M)] x 0.162 proved to be a good indicator of the efficacy of the compounds in the guinea pig ileum assay.     

Novel functional M1 selective muscarinic agonists. Synthesis and structure-activity relationships of 3-(1,2,5-thiadiazolyl)-1,2,5,6-tetrahydro-1-methylpyridines .

A series of novel 3-(3-substituted-1,2,5-thiadiazol-4-yl)-1,2,5,6-tetrahydro- 1-methylpyridines (substituted-TZTP; 5a-l, 7a-h, 8, 9c-n, 11, 13j) were synthesized and tested for central muscarinic cholinergic receptor affinity by using [3H]-oxotremorine-M (Oxo-M) and [3H]-pirenzepine (Pz) as ligands. The potency and efficacy of the compounds for the pharmacological defined M1 and M2 muscarinic receptors were determined on isolated electrically stimulated rabbit vas deferens and on spontaneously beating isolated guinea pig atria, respectively. Selected compounds were also tested for M3 activity in the isolated guinea pig ileum. The C1-8 alkoxy-TZTP 5a-l analogues all displaced [3H]-Oxo-M and [3H]-Pz with low nanomolar affinity. Depicting chain length against Oxo-M binding and against Pz binding the unbranched C1-8 alkoxy-TZTP (5a-h) derivatives produced U-shaped curves with butoxy- (5d) and (pentyloxy)-TZTP (5e) as the optimum chain length, respectively. This U-shaped curve was also seen in the ability of the compounds 5a-h to inhibit the twitch height in the vas deferens preparation. The (pentyloxy)- (5e) and the (hexyloxy)-TZTP (5f) analogues produced an over 90% inhibition of the twitch height with IC50 values in the low picomolar range. In both the atria and in the ileum preparations 5f had low efficacy and potency. With the (alkylthio)-TZTP (7a-h) analogues the structure-activity relationship was similar to the one observed with the alkoxy (5a-h) analogues, but generally 7a-h had higher receptor affinity and was more potent than the corresponding 5a-h. However, the C3-8 alkyl-TZTP (9c,e,g,h) analogues had 10-100 times lower affinity for the central muscarinic receptors than the corresponding alkoxy and alkylthio derivatives, and their efficacy in the vas deferens preparation was too low to obtain IC50 values. The unsubstituted TZTP (11) compound was a potent but nonselective muscarinic agonist. The two 3-(3-butoxy/(hexyloxy)-1,2,5-oxadiazol-4-yl)-1,2,5,6-tetrahy dro-1- methylpyridines (butoxy/hexyloxy)-OZTP; 19a/b) were also synthesized and tested. Both 19a and 19b had much lower affinity for the central muscarinic receptors than 5d and 5f, and the efficacy of 19a,b was too low to give IC50 values in the vas deferens preparation. Therefore, the C5-6 (alkyloxy)/(alkylthio)-TZTP's represent a unique series of potent functional M1 selective muscarinic agonists.     

Sialic acid residues as catalysts for M2-muscarinic agonist-receptor interactions.

The role of sialic acid residues in the interactions of muscarinic agonists with the cardiac M2 muscarinic receptor was investigated by competitive binding experiments using the lipophilic radioligand (-)-[benzilic-4,4-3H]quinuclidinyl benzilate ([3H]QNB) and the hydrophilic ligand [N-methyl-3H]scopolamine methyl chloride ([3H]NMS). Direct labeling of the agonist binding sites was performed with the radiolabeled agonist [methyl-3H]oxotremorine M acetate ([3H]oxo-M). Neuraminidase decreased the affinity of the M2-selective agonist carbamylcholine in competitive binding experiments performed with [3H]QNB and [3H]NMS. The binding of the M1-selective agonist (4hydroxy-2-butynyl)trimethylammonium chloride m-chlorocarbanilate (McN-A-343), of the M1-selective antagonist pirenzepine, and of the M2-selective antagonist 11-([2-[(diethylamino)methyl]-1 piperidinyl]acetyl)-5,11-dihydro-6H-pyrido(2,3b)(1,4)benzodiazepin -6-on (AF-DX-116) were not affected by neuraminidase. Neuraminidase did not modify the binding parameters of 3H-antagonists but reduced the number of agonist binding sites revealed by [3H]oxo-M. The removal of sialic acid decreased the half-life of the receptor-agonist complex. The present results suggest that removal of sialic acid reduces the formation of super-high affinity agonist-receptor complexes. Sialic acid may catalyze macroscopic binding by enhancing accumulation of the agonist at the membrane surface.     

Thiochrome enhances acetylcholine affinity at muscarinic M4 receptors: receptor subtype selectivity via cooperativity rather than affinity

Thiochrome (2,7-dimethyl-5H-thiachromine-8-ethanol), an oxidation product and metabolite of thiamine, has little effect on the equilibrium binding of l-[3H]N-methyl scopolamine ([3H]NMS) to the five human muscarinic receptor subtypes (M1-M5) at concentrations up to 0.3 mM. In contrast, it inhibits [3H]NMS dissociation from M1 to M4 receptors at submillimolar concentrations and from M5 receptors at 1 mM. These results suggest that thiochrome binds allosterically to muscarinic receptors and has approximately neutral cooperativity with [3H]NMS at M1 to M4 and possibly M5 receptors. Thiochrome increases the affinity of acetylcholine (ACh) 3- to 5-fold for inhibiting [3H]NMS binding to M4 receptors but has no effect on ACh affinity at M1 to M3 or M5 receptors. Thiochrome (0.1 mM) also increases the direct binding of [3H]ACh to M4 receptors but decreases it slightly at M2 receptors. In agreement with the binding data, thiochrome does not affect the potency of ACh for stimulating the binding of guanosine 5'-O-(3-[35S]thiotriphosphate) ([35S]GTPgammaS) to membranes containing M1 to M3 receptors, but it increases ACh potency 3.5-fold at M4 receptors. It also selectively reduces the release of [3H]ACh from potassium-stimulated slices of rat striatum, which contain autoinhibitory presynaptic M4 receptors, but not from hippocampal slices, which contain presynaptic M2 receptors. We conclude that thiochrome is a selective M4 muscarinic receptor enhancer of ACh affinity and has neutral cooperativity with ACh at M1 to M3 receptors; it therefore demonstrates a powerful new form of selectivity, "absolute subtype selectivity", which is derived from cooperativity rather than from affinity.     

Evaluation of an agonist index: affinity ratio for compounds active on muscarinic cholinergic M2 receptors

1 A protocol for predicting full agonist, partial agonist, and antagonist profiles of compounds with M₂ muscarinic cholinergic receptor activity was developed using radioligand binding assay techniques with [³H]-N-methyl scopolamine (NMS) and [³H]-Oxotremorine-M (Oxo-M) as radioligands. 2 Full muscarinic cholinergic receptor agonists such as muscarine and oxotremorine-M expressed a high agonist index (> 3000 for M₁ muscarinic cholinergic receptors and > 900 for M₂ muscarinic cholinergic receptor), whereas muscarinic receptor antagonists (selective or non-selective) for different receptor subtypes gave a low (0.5–10) agonist index. 3 Functional studies performed on preparations of guinea-pig ileum and heart were consistent with radioligand binding assay experiments. 4 The above results suggest that similarly as already established for the M₁ muscarinic cholinergic receptor subtype, evaluation of the [³H]-NMS/[³H]-Oxo-M ratio may provide useful information on the profile of compounds acting at the M₂ muscarinic cholinergic receptor subtype. 5 The availability of simple and predictive techniques for the characterization of muscarinic M₂ cholinergic receptor agonists, may help the identification of new compounds in therapeutic areas in which stimulation or inhibition of this receptor is desirable.     

Positive cooperativity in the binding of alcuronium and N-methylscopolamine to muscarinic acetylcholine receptors

The effect of the neuromuscular blocker alcuronium on the binding of N-[3H]-methylscopolamine [( 3H]NMS) and l-[3H]quinuclidinylbenzilate ([3H]QNB) to muscarinic binding sites in rat heart atria, longitudinal smooth muscle of the ileum, cerebral cortex, cerebellum, and submaxillary glands was measured using filtration techniques. In the presence of 10(-5) M alcuronium, the binding of [3H]NMS (which was present at a subsaturating concentration of 2 x 10(-10) M) was increased 5.3-fold in the atria and smooth muscle and 3-fold in the cerebellum; no increase was observed in the brain cortex and salivary glands. The binding of [3H]NMS was inhibited at 10(-3) M and higher concentrations of alcuronium. The rates of [3H]NMS association to and dissociation from muscarinic binding sites in the atria were diminished by 10(-5) M alcuronium. Scatchard plots of [3H]NMS binding data obtained with and without 10(-5) M alcuronium indicated that the maximum number of binding sites was not altered by the drug, whereas the apparent Kd for [3H]NMS was diminished. In contrast to [3H] NMS, the effects of alcuronium on the binding of [3H]QNB were only inhibitory. The concentration of alcuronium required to diminish the binding of [3H]QNB by 50% (IC50) was 4-7 microM in the atria, ileal smooth muscle, and the cerebellum, 140 microM in the brain cortex, and 1200 microM in the parotid gland. The results suggest that the binding of low concentrations of alcuronium to muscarinic receptors in the heart, ileal smooth muscle, and cerebellum allosterically increases the affinity of muscarinic receptors towards [3H]NMS, although not [3H]QNB. At high concentrations, alcuronium inhibits the binding of muscarinic ligands, presumably by competition for the classical muscarinic binding site. Positive cooperativity induced by alcuronium appears to be specific for the m2 (cardiac) subtype of muscarinic receptors.     

In vitro down-regulation predicts agonist efficacy at central muscarinic cholinergic receptors

Agonist induced short-term down-regulation of central muscarinic cholinergic receptors in mechanically dissociated cells of the mouse brain has been shown to predict the efficacy of agonists at muscarinic receptors. Pretreatment of cells with full agonists such as carbachol or oxotremorine M resulted in a loss of available muscarinic cholinergic receptors of about 30% using [3H]N-methylscopolamine [( 3H]NMS) as radioligand, whereas a second group of agonists e.g. RS 86 were only weakly active in this regard producing a significantly smaller loss of cell surface muscarinic cholinergic receptors. The magnitude of down-regulation of muscarinic receptors induced by pretreatment with several cholinergic drugs correlates fairly well with their ability to stimulate the phosphatidylinositol turnover. It seems that the agonist induced down-regulation of muscarinic cholinergic receptors on mechanically dissociated neurons of the mouse brain is a simple screening method to test for centrally acting cholinergic agonists.     

Muscarinic receptor heterogeneity in rat central nervous system. II. Brain receptors labeled by [3H]oxotremorine-M correspond to heterogeneous M2 receptors with very high affinity for agonists

We compared the binding characteristics of muscarinic receptors labeled by [3H]oxotremorine-M ([3H]oxo-M) in homogenates of brain cortex and heart from rat. In both tissues [3H]oxo-M bound, with the same KD (6.5 nM), to a fraction of the receptors labeled by [3H]-N-methylscopolamine ([3H]NMS). This [3H]oxo-M receptor population represented, respectively, 15-20% and 35-40% of the total number of [3H]NMS receptors in cortex and heart. The three unlabeled agonists oxotremorine, carbamylcholine, and pilocarpine, when tested in competition with [3H]oxo-M, displayed a homogeneous super high affinity toward [3H]oxo-M-labeled receptors, and were unable to discriminate between brain and heart receptors labeled by [3H]oxo-M. By contrast, selective muscarinic antagonists showed some selectivity for either brain or heart [3H]oxo-M-labeled receptors. We analyzed competition curves between [3H]oxo-M and secoverine, pirenzepine, AF-DX 116, dicyclomine, or gallamine, assuming the existence of one or two receptor subclasses. Heart muscarinic receptors labeled by [3H]oxo-M were homogeneous M2 receptors of the C type with very low affinity for pirenzepine (Ki = 400 nM). Brain [3H]oxo-M-labeled receptors were heterogeneous receptors, with 30% (the B type) having a higher affinity for dicyclomine and a lower affinity for AF-DX 116 and gallamine than cardiac receptors, whereas the remaining 70% (the C type) showed "cardiac-like" binding properties. Both [3H]oxo-M-labeled subtypes in cortex homogenates had a low affinity for pirenzepine, indicating that [3H]oxo-M labeled only B and C (M2) receptors in this tissue. GTP inhibited completely [3H]oxo-M binding in heart homogenates with an IC50 at 300 nM. In cortex homogenates, GTP showed the same potency, but its efficacy was much lower (with only 30% maximal inhibition). [3H]oxo-M dissociation kinetics were monophasic in heart homogenates and biphasic in cortex homogenates. [3H]oxo-M dissociation from both tissues was slowed by gallamine and d-tubocurarine and accelerated by GTP. We found no correlation between B versus C [3H]oxo-M receptors, GTP-sensitive versus GTP-insensitive receptors, and rapidly versus slowly dissociating receptors, suggesting that [3H] oxo-M labeled a large variety of muscarinic receptor-regulatory protein complexes, all having an SH affinity for agonists.     

A novel series of non-quaternary oxadiazoles acting as full agonists at muscarinic receptors

1 A novel series of non-quaternary oxadiazole-based muscarinic agonists demonstrated high affinity for muscarinic receptors. 2. These agonists possessed high efficacy in the nanomolar range at muscarinic receptors in the superior cervical ganglion, atrium and ileum but did not show selectivity across the tissue preparations. 3. Two amino oxadiazoles, one from a quinuclidine series (L-660,863) and one from a 1-azanorbornane series (L-670,207) possessed a high ratio of potency for displacing the binding of [3H]-N-methyl-scopolamine ([3H]-NMS) to potency for displacing the agonist [3H]-oxotremorine-M cortex. 4. The two azanorbornane derivatives L-670,548 and L-670,207 stimulated the turnover of phosphatidylinositol in the cortex with a potency higher than that obtained with any other known muscarinic agonist (ED50 0.26 and 0.18 microM respectively). 5. The maximum response obtained with L-670,207 was greater than that observed for carbachol but was comparable to that of the natural ligand acetylcholine. 6. These oxadiazole muscarinic agonists are among the most potent and efficacious non-quaternary muscarinic agonists ever described.     

Synthesis, molecular modeling studies, and muscarinic receptor activity of azaprophen analogues

Synthesis, radioligand binding, and pharmacologic activities of a series of muscarinic receptor ligands including and related to azaprophen (6-methyl-6-azabicyclo[3.2.1]octan-3 alpha-ol 2,2-diphenylpropionate, 1) have been measured to determine activity and selectivity for muscarinic receptor subtypes. Pharmacologic affinities of antagonists were determined as pA2 values for antagonism of methacholine-induced tension responses in guinea pig ileum. Binding affinities were measured by competition against [3H]QNB binding in guinea pig ileum, rat heart and brain, and m1- or m3-transfected Chinese hamster ovary (CHO) cells. The efficacies of muscarinic agonists in brain were determined by the ratio of binding affinities against [3H]QNB or [3H]NMS and [3H]oxotremorine-M ([3H]Oxo-M). Nine muscarinic antagonists, including azaprophen, did not discriminate significantly between the subtypes of muscarinic receptors. KI values for receptor binding for azaprophen (1) were between 8.81 x 10(-11) and 4.72 x 10(-10) M in ileum, heart, brain, and m1- or m3-transfected CHO cells. The alpha- and beta-benzilate esters 5 and 6 are as potent as azaprophen, and diphenylacetate esters 3 and 4 and N-(6)-benzyl alpha-isomer 7 are less potent than azaprophen. Significant stereoselectivity was exhibited with (+)-azaprophen being approximately 200 times more potent than the (-)-enantiomers and the 3 beta-ol isomer 2 being ca. 50 times less potent than azaprophen in all systems. A molecular modeling-molecular mechanics study was conducted to account for the difference. Putative muscarinic agonists (analogues and isomers of 6-methyl-6-azabicyclo[3.2.1]octan-3-ol acetate) did not discriminate muscarinic receptor subtypes with KI values between 2.77 x 10(-6) and 4.33 x 10(-5) M without significant stereoselectivity in the systems examined. The most active analogue was (1R,3R,5S)-6-[1(R)-phenylethyl]-6-azabicyclo[3.2.1]octan-3 alpha-ol acetate. However, efficacies of these putative agonists were in general very low.     

Agonist binding to M1 muscarinic receptors is sensitive to guanine nucleotides

Putative M1 (high-affinity pirenzepine) muscarinic receptors in rabbit hippocampal membranes, treated with 0.1 mM N-ethylmaleimide (NEM), were selectively labeled with [3H]pirenzepine. A single class of binding sites was labeled with a Kd of 3.4 nM, consistent with the pharmacologically-defined M1 subtype of muscarinic receptors. While full muscarinic agonists bound to high- and low-affinity states of [3H]pirenzepine-labeled M1 sites with a KL/KH ratio of approximately 100, the ratio for partial muscarinic agonists was approximately 10. The high-affinity binding of all agonists tested required divalent cations, and was interconverted to low-affinity binding in the presence of the non-hydrolyzable GTP analogue, guanylyl imidodiphosphate (GppNHp). Direct labeling of the high-affinity agonist state of M1 receptors was achieved with 5 nM [3H]oxotremorine-M by selectively uncoupling the high-affinity agonist state of M2 (low-affinity pirenzepine) receptors with NEM. The rate of dissociation of [3H]Pxotremorine-M from M1 receptors was accelerated 6-fold by GppNHp. These results provide further evidence which suggests that putative M1 muscarinic receptors activate second messenger systems by coupling to NEM-insensitive guanine nucleotide-binding proteins.     

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.     

Functional comparison of muscarinic partial agonists at muscarinic receptor subtypes hM1, hM2, hM3, hM4 and hM5 using microphysiometry.

1. This study describes the pharmacological comparison of the muscarinic partial agonists sabcomeline, xanomeline and milameline at human cloned muscarinic receptor subtypes (hM1-5). 2. Radioligand binding studies at the hM1-5 muscarinic receptor subtypes were compared with functional studies using microphysiometry using carbachol as the standard full agonist. 3. In binding assays none of the compounds studied displayed preferential affinity for the M1,3,4 or M5 subtypes although carbachol was less potent at hM1 than hM3,4,5. 4. In functional studies, all of the compounds studied displayed similar levels of efficacy across the muscarinic receptors with the exception of M3, where there was a large apparent receptor reserve and the compounds behaved essentially as full agonists. 5. Sabcomeline was the most potent agonist in functional studies but also showed the lowest efficacy. In terms of potency, xanomeline showed some selectivity for M1 over M2 receptors and milameline showed some selectivity for M2 over M1 receptors. 6. These results show the value of microphysiometry in being able to compare receptor pharmacology across subtypes irrespective of the signal transduction pathway. 7. None of the partial agonists showed functional selectivity for M1 receptors, or indeed any muscarinic receptor, in the present study.     

On the interaction of gallamine with muscarinic receptor subtypes

The interaction of gallamine with muscarinic receptor subtypes was examined using radioligand binding studies. In competition studies using [3H]N-methylscopolamine [( 3H]NMS), gallamine displayed high affinity for the rat cardiac and guinea-pig uterine M2 muscarinic receptors and for the atypical muscarinic receptor present in chicken heart. Gallamine displayed low affinity for rat glandular and human 1321 N1 astrocytoma cell M3 receptors and also for the M4 receptors of NG108-15 and PC12 cells. The compound displayed intermediate affinity for M1 receptors of rat cortex labeled using [3H]pirenzepine. The interaction of gallamine with the M1 and M2 receptors appeared to be competitive at the low concentrations required to determine affinity estimates. Thus, gallamine inhibited the binding of [3H]pirenzepine to M1 receptors and [3H]NMS to M2 receptors at concentrations that were 263- and 23-fold lower, respectively, than those required to decrease radioligand dissociation kinetics. Furthermore, gallamine, at a concentration that inhibited between 63 and 71% of specific radioligand binding, had no effect on the observed rate of association of the radioligand with either the M1 or the M2 receptor. At the M3 glandular receptor, there was little separation between the concentrations of gallamine that produced inhibition of binding and those that decreased the association and dissociation rates of [3H]NMS. It is therefore difficult to determine if the inhibition of binding seen in competition studies on the M3 receptor was produced through a competitive or an allosteric mechanism. Despite its possible allosteric properties at the M3 receptor, gallamine can be used to detect heterogeneity of muscarinic receptor subtypes in several tissues and therefore represents a useful tool for defining muscarinic receptor subtypes.     

The binding of [3H]4-diphenylacetoxy-N-methylpiperidine methiodide to longitudinal ileal smooth muscle muscarinic receptors

Muscarinic receptors present in longitudinal ileum were characterized using the non-selective radioligand [3H]N-methylscopolamine [( 3H]NMS) and the M3 selective radioligand [3H]4-diphenylacetoxy-N-methylpiperidine methiodide [( 3H]4DAMP). In saturation studies, [3H]4DAMP, but not [3H]NMS, identified two populations of binding sites with 17% of the sites (155 fmol/mg protein) displaying high affinity (Kd = 0.39 nM) for [3H]4DAMP and the remaining sites displaying low affinity for the radioligand (Kd = 4.43 nM). In competition studies gallamine and methoctramine, but not AF-DX 116, identified two populations of [3H]NMS binding sites. Affinity estimates for gallamine and methoctramine indicated that 80% of the [3H]NMS binding sites were of the M2 subtype. The minor population of [3H]NMS binding sites could not be readily characterized, due partly to the low selectivity of the competing ligands and also to the relatively low density of the sites. In studies using the M3 muscarinic receptor selective radioligand [3H]4DAMP, the minor population of sites could be preferentially labeled by using a low concentration (0.4 nM) of [3H]4DAMP. Under these conditions, [3H]4DAMP labeled approximately equal levels of the two muscarinic receptor binding sites present in the ileum. Competition studies with AF-DX 116, gallamine and methoctramine indicated that the two [3H]4DAMP binding sites displayed the pharmacology expected of the M2 and M3 receptors, respectively. These results provide additional evidence that longitudinal ileal smooth muscle membranes contain both M2 and M3 muscarinic receptors and indicate that [3H]4DAMP is a useful ligand for identifying heterogeneity of muscarinic receptor subtypes.     

Secoverine is a non-selective muscarinic antagonist on rat heart and brain receptors

In an attempt to determine if the selectivity of secoverine observed in vivo and in isolated tissues might be due to selective association with muscarinic receptor subtypes, we analyzed the binding of secoverine to three different receptors with specific radioligands: rat cardiac receptors (M2 receptors with low affinity for atropine), and rat cerebral cortical M1 receptors and M2 receptors with high affinity for atropine. At concentrations up to 10(-6) M, secoverine interaction with muscarinic receptors was competitive and of high affinity (Ki 4.10(-9) M) for cardiac and brain receptors. A detailed analysis using, in addition to [3H]N-methylscopolamine, the agonist [3H]oxotremorine-M (selective for high affinity binding sites at cardiac receptors) and the M1-selective antagonist [3H]pirenzepine at brain receptors, revealed identical affinities towards both receptor types, making it unlikely that secoverine distinguished the different muscarinic receptor subtypes. At concentrations between 10(-6) and 10(-3) M, secoverine interaction with an additional receptor site resulted in profound changes of tracer kinetics, suggesting the formation of a ternary complex (secoverine-radioligand-muscarinic receptor). The potency of secoverine for provoking this allosteric interaction was both tracer- and tissue-dependent. It is concluded that secoverine does not differentiate between M1, brain M2 and cardiac M2 receptors or between cardiac receptors with high, low and very low affinity for agonists. At very high concentrations secoverine recognized an allosteric site on the muscarinic receptors and reduced the dissociation rates of the 3H-ligands.     

Autoradiographic analyses of agonist binding to muscarinic receptor subtypes

The binding of four muscarinic receptor agonists to regions of rat brain was examined through quantitative autoradiographic techniques. Oxotremorine, arecoline, pilocarpine and bethanechol were chosen based on their different potencies and efficacies in muscarinic second messenger systems. Overall, the order of potency for inhibition of [3H]-l-quinuclidinyl benzilate ([3H]-l-QNB) binding to rat brain slices was oxotremorine greater than pilocarpine = arecoline much greater than bethanechol. Regional assays of agonist potency indicated that all agonists were more selective for brainstem and thalamic regions than for hippocampal and cortical regions. The high selectivity of agonists for areas such as the paraventricular thalamus and the superior colliculus, which also display low affinity for pirenzepine, suggests that muscarinic agonists bind with higher affinity to M2 receptors. Of the four agonists examined, pilocarpine displayed the lowest selectivity for M2 receptors in that IC50 values for pilocarpine were only 3-fold higher in the hippocampal and striatal regions (e.g. CA3: 40.6 +/- 9.4 microM) than in thalamic and brainstem regions (e.g. paraventricular thalamus: 14.9 +/- 6.2 microM). Oxotremorine was 8-fold more potent in the brainstem and thalamus, while arecoline and bethanechol were, respectively, 19- and 100-fold more selective for brainstem and thalamic receptors. Scatchard analyses revealed heterogeneous binding profiles for some agonists within single brain regions, suggesting that multiple agonist sites exist even within regions of predominantly M1 or M2 receptors. For example, arecoline displayed curved Scatchard plots within the external layers of the cerebral cortex, layer CA1 of the hippocampus (predominantly M1 subtype), and the paraventricular thalamus (predominantly M2 subtype). The ability of agonists to recognize multiple sites within a single region may reflect the ability to recognize receptors coupled or uncoupled to second messenger systems through G-proteins.     

Synthesis and muscarinic receptor activity of ester derivatives of 2-substituted 2-azabicyclo[2.2.1]heptan-5-ol and -6-ol.

Radioligand binding affinities of four new muscarinic antagonists and six potential muscarinic agonists which possess the 2-alkyl-2-azabicyclo[2.2.1]heptane ring system have been determined in rat heart, rat brain, and m1- or m3-transfected CHO cell membrane preparations to examine the selectivity for subtypes of muscarinic receptor. The efficacies of the potential muscarinic agonists were determined by the ratio of binding affinities against [3H]QNB and [3H]Oxo-M. Four muscarinic antagonists which have the 2,2-diphenylpropionate side chain at either the C5 (5-endo or 5-exo) or the C6 (6-endo or 6-exo) positions did not discriminate between the subtypes of muscarinic receptors. The 2,2-diphenylpropionate 5-endo substituted compound was the most potent, showing affinities between 4.23 x 10(-10) and 1.18 x 10(-9) M in rat heart, rat brain, and m1- or m3-transfected CHO cell membrane preparations. The rank order of ester potency was 5-endo greater than 5-exo greater than 6-endo greater than 6-exo. A molecular modeling study based on the pharmacophore developed for azaprophen was used to account for the relative potency of these antagonists. Six potential muscarinic agonists which have acetoxy groups in the C5 or C6 position with an N-methyl or N-benzyl substituent did not discriminate subtypes of muscarinic receptors and had affinities between 6.63 x 10(-6) and 4.76 x 10(-5) M in rat heart, rat brain, and m1- or m3-transfected CHO cell membrane preparations. exo-2-Methyl-5-acetoxy-2-azabicyclo[2.2.1]heptane was the most efficacious partial agonist.     

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.