[The antiparkinson activity of muscarinic antagonists depending on their selectivity for individual m-cholinoreceptor subtypes]

The dependence between the activity parameters of muscarine antagonists in the prevention of haloperidol catalepsy in rats and those in tests characterizing the interaction of ligands and various subtypes of m-cholinoceptors was studied. It was established by constructing the mathematical dependence that blockade of m1-cholinoceptors increases, while that of m2-cholinoceptors reduces the antiparkinsonian activity of the drugs. The activity of the muscarine antagonist pentiphan in the prevention of haloperidol-induced catalepsy in rats exceeds the activity of such traditional antiparkinsonian drugs as cyclodol and amedin.

Characterization of the muscarinic receptor mediating contraction of the dog prostate

1. We have studied the effects of muscarinic cholinoceptor agonists and subtype-preferring antagonists on the isometric contraction of smooth muscle strips from dog prostate. 2. Acetylcholine and carbachol induced contraction of prostate strips from the peripheral zone, ('the capsule'). Bethanechol contracted the tissue but not at lower doses. McN-A-343 and oxotremorine-M showed the same effects. 3. Blocking alpha- and beta-adrenoceptors with phentolamine and propranolol, respectively, did not modify carbachol-induced contractions. 4. The nicotinic receptor blocker, hexamethonium (10(-6)-10(-4) M) did not affect the contractile response evoked by a single dose of carbachol (10(-5) M), whilst the muscarinic receptor antagonist, atropine (10(-11)-10(-9) M), inhibited it in a competitive manner. 5. The muscarinic M1 (pirenzepine), M2 [AF-DX 116, himbacine (M2/M4) and methoctramine], M3 (HHSID and f-F-HHSID), and putative M4 (tropicamide) antagonists reduced significantly the carbachol-induced contractions. The pIC50 values were: atropine (10.01) > himbacine (8.3) > methoctramine (7.85) > AF-DX 116 (7.60) > HHSID (7.21) > p-F-HHSID (7.10) > pirenzepine (7.30) > tropicamide (7.00). 6. The antagonist profile indicates that an predominant M2 receptor subtype could mediate the muscarinic contraction in the canine prostate.

Regulation of the expression and function of the M2 muscarinic receptor

Since the cloning and expression of many of the G protein-coupled receptors during the 1980s, there has been a massive increase in our understanding of many aspects of their function. The use of molecular biology to engineer and express mutant receptors has made it possible to determine key amino acids involved in receptor function. Although advances in molecular biology have contributed greatly to our understanding of the pharmacology and structure of the five subtypes of muscarinic receptor, much remains to be learned about the factors that regulate their expression and function. This review by El-Bdaoui Haddad and Jonathan Rousell describes the current state of awareness and highlights recent advances made in the elucidation of the mechanisms involved in muscarinic receptor regulation. Because most is known about the regulation of expression of the M2 receptor subtype, particular attention will be paid to it. Furthermore, this receptor subtype plays an important role in regulating acetylcholine output from airway cholinergic nerves, and there is substantial evidence from studies both in vivo and in vitro in human and animal models that these receptors are dysfunctional in asthma.

Selective muscarinic antagonists. II. Synthesis and antimuscarinic properties of biphenylylcarbamate derivatives

A novel series of biphenylylcarbamate derivatives were synthesized and evaluated for binding to M1, M2 and M3 receptors and for antimuscarinic activities. Receptor binding assays indicated that biphenyl-2-ylcarbamate derivatives had high affinities for M1 and M3 receptors and good selectivities for M3 receptor over M2 receptor, indicating that the biphenyl-2-yl group is a novel hydrophobic replacement for the benzhydryl group in the muscarinic antagonist field. In this series, quinuclidin-4-yl biphenyl-2-ylcarbamate monohydrochloride (8l, YM-46303) exhibited the highest affinities for M1 and M3 receptors, and selectivity for M3 over M2 receptor. Compared to oxybutynin, YM-46303 showed approximately ten times higher inhibitory activity on bladder pressure in reflexly-evoked rhythmic contraction, and about 5-fold greater selectivity for urinary bladder contraction against salivary secretion in rats. Moreover, selective antagonistic activity was also observed in vitro. Further evaluation of antimuscarinic effects on bradycardia and pressor in pithed rats, and on tremor in mice, showed that YM-46303 can be useful for the treatment of urinary urge incontinence as a bladder-selective M3 antagonist with potent activities and fewer side effects.

Muscarinic receptor subtypes in porcine detrusor: comparison with humans and regulation by bladder augmentation

The properties of muscarinic acetylcholine receptors of porcine and human bladder detrusor were compared in radioligand binding studies using [3H]quinuclidinylbenzylate as the radioligand. The receptor affinity for the radioligand and the density of muscarinic receptors was similar in male and female pigs and in humans (Kd = 35 +/- 8 pM, Bmax = 153 +/- 30 fmol/mg protein). Atropine and subtype-selective antagonists had steep and monophasic competition curves in porcine and human detrusor with a rank order of potency of atropine >> hexahydro-sila-difenidol > or = AF-DX 116 > or = pirenzepine, indicating the presence of a homogeneous population of M2 muscarinic receptors. In female pigs bladder outflow obstruction generated by partial urethral ligation or its surgical treatment by ileum augmentation or autoaugmentation did not significantly alter expression of muscarinic receptors or of alpha2A-adrenoceptors, but the power was insufficient to exclude alterations of less than 60%. We conclude that porcine and human detrusor express muscarinic receptors of the M2 subtype; despite these qualitative similarities the use of the porcine model may be limited by large biological variance with regard to quantitative receptor expression.

Arrestin-independent internalization of the m1, m3, and m4 subtypes of muscarinic cholinergic receptors

To understand what processes contribute to the agonist-induced internalization of subtypes of muscarinic acetylcholine receptors, we analyzed the role of arrestins. Whereas the m2 mAChR has been shown to undergo augmented internalization when arrestins 2 and 3 are overexpressed (Pals-Rylaarsdam, R., Gurevich, V. V., Lee, K. B., Ptasienski, J. A., Benovic, J. L., and Hosey, M. M. (1997) J. Biol. Chem. 272, 23682-23689), the agonist-induced internalization of m1, m3, and m4 mAChRs was unchanged when arrestins 2 or 3 were overexpressed in transiently transfected HEK-tsA201 cells. Furthermore, when a dominant-negative arrestin was used to interrupt endogenous arrestin function, there was no change in the internalization of the m1, m3, and m4 mAChR whereas the internalization of the beta2 adrenergic receptor was completely blocked. Wild-type and GTPase-deficient dominant-negative dynamin were used to determine which endocytic machinery played a role in the endocytosis of the subtypes of mAChRs. Interestingly, when dynamin function was blocked by overexpression of the GTPase-deficient dynamin, agonist- induced internalization of the the m1, m3, and m4 mAChRs was suppressed. These results suggested that the internalization of the m1, m3, and m4 mAChRs occurs via an arrestin-independent but dynamin-dependent pathway. To ascertain whether domains that confer arrestin sensitivity and dynamin insensitivity could be functionally exchanged between subtypes of mAChRs, chimeric m2/m3 receptors were analyzed for their properties of agonist-induced internalization. The results demonstrated that the third intracellular loop of the m2 mAChR conferred arrestin sensitivity and dynamin insensitivity to the arrestin-insensitive, dynamin-sensitive m3 mAChR while the analogous domain of the m3 mAChR conferred arrestin resistance and dynamin sensitivity to the previously arrestin-sensitive, dynamin-insensitive m2 mAChR.

The use of irreversible ligands to inactivate receptor subtypes: 4-DAMP mustard and muscarinic receptors in smooth muscle

Irreversible ligands are useful tools for investigating the function of receptor subtypes in various physiological processes. The mechanism for alkylation involves the formation of a reversible receptor complex followed by a covalent reaction. The extent of receptor alkylation is determined by the dissociation constant of the reversible complex and the rate constant for conversion to the covalent complex. Selectivity can be achieved if the irreversible ligand exhibits a difference in its dissociation constants for receptor subtypes. Selective alkylation can also be achieved using a selective competitive inhibitor to protect the desired receptor subtype. By using the non-M2-selective irreversible antagonist, 4-DAMP mustard, in combination with the competitive M2-selective antagonist, AF-DX 116, it has been possible to achieve a highly selective inactivation of all non-M2 subtypes of the muscarinic receptors in smooth muscle and has enabled the discovery of the functional role of M2 receptors in smooth muscle.

Autoradiographic localisation of muscarinic cholinergic receptor subtypes in human placenta

The localisation of M1-M4 muscarinic cholinergic receptor subtypes was investigated in sections of normal human term placenta by light microscope autoradiography. Muscarinic cholinergic receptor subtypes were found almost exclusively in syncytiotrophoblast. Neither other cellular components of placenta, nor blood vessels were labelled. Quantitative analysis of the density of silver grains developed in sections incubated with the different protocols for labelling M1-M4 receptor subtypes, revealed that syncytiotrophoblast expresses all subtypes of muscarinic cholinergic receptor investigated. A higher density of binding sites was found in the apical than in the basal portion of syncytiotrophoblast. The demonstration of muscarinic cholinergic receptors in syncytiotrophoblast suggests that a cholinergic system may have a role in regulating transport of compounds from maternal to foetal interface.

Receptor subtype-specific regulation of muscarinic acetylcholine receptor sequestration by dynamin. Distinct sequestration of m2 receptors

Sustained stimulation of muscarinic acetylcholine receptors (mAChRs) and other G protein-coupled receptors usually leads to a loss of receptor binding sites from the plasma membrane, referred to as receptor sequestration. Receptor sequestration can occur via endocytosis of clathrin-coated vesicles that bud from the plasma membrane into the cell but may also be accomplished by other, as yet ill-defined, mechanisms. Previous work has indicated that the monomeric GTPase dynamin controls the endocytosis of plasma membrane receptors via clathrin-coated vesicles. To investigate whether mAChRs sequester in a receptor subtype-specific manner via dynamin-dependent clathrin-coated vesicles, we tested the effect of overexpressing the dominant-negative dynamin mutant K44A on m1, m2, m3, and m4 mAChR sequestration in HEK-293 cells. The m1, m2, m3, and m4 mAChRs sequestered rapidly in HEK-293 cells following agonist exposure but displayed dissimilar sequestration pathways. Overexpression of dynamin K44A mutant fully blocked m1 and m3 mAChR sequestration, whereas m2 mAChR sequestration was not affected. Also, m4 mAChRs, which like m2 mAChRs preferentially couple to pertussis toxin-sensitive G proteins, sequestered in a completely dynamin-dependent manner. Following agonist removal, sequestered m1 mAChRs fully reappeared on the cell surface, whereas sequestered m2 mAChRs did not. The distinct sequestration of m2 mAChRs was also apparent in COS-7 and Chinese hamster ovary cells. We conclude that the m2 mAChR displays unique subtype-specific sequestration that distinguishes this receptor from the m1, m3, and m4 subtypes. These results are the first to demonstrate that receptor sequestration represents a new type of receptor subtype-specific regulation within the family of mAChRs.

Endogenous acetylcholine in the dorsal hippocampus reduces anxiety through actions on nicotinic and muscarinic1 receptors

Dorsal hippocampal cholinergic modulation of behavior in different tests of anxiety was investigated by direct injection of the muscarinic M1 and M2 receptor antagonists, pirenzepine and gallamine, and the nicotinic receptor antagonist mecamylamine. In the social interaction test, the anxiogenic effect of pirenzepine (30-100 ng) provided evidence for a tonic cholinergic anxiolytic action mediated by postsynaptic M1 receptors. The anxiogenic action of mecamylamine (30 and 100 ng) was most likely mediated by its action of presynaptic nicotinic receptors to reduce acetylcholine release. Gallamine (10-1,000 ng) was without effect, suggesting that M2 receptors in this brain region do not play a significant role in this behavioral test. On Trial 1 in the elevated plus-maze, the receptor antagonists were without any effect, but in those with a previous 5-min experience of the plus-maze pirenzepine and mecamylamine had anxiogenic effects in the dose range of 30-300 ng; gallamine (100 and 300 ng) was without significant effect.

Ethanol disrupts carbamylcholine-stimulated release of arachidonic acid from Chinese hamster ovary cells expressing different subtypes of human muscarinic receptor

Ethanol disrupts signal transduction mediated by a variety of G-protein coupled receptors. We examined the effects of ethanol on arachidonic acid release mediated by muscarinic acetylcholine receptors. Chinese hamster ovary (CHO) cells transfected with the different subtypes of human muscarinic receptors (M1 to M5) were incubated with [3H]arachidonic acid ([3H]AA) for 18 hr, washed, and exposed to the cholinergic agonist carbamylcholine for 15 min. Carbamylcholine induced [3H]AA release from CHO cells expressing M1, M3, or M5, but not M2 or M4, muscarinic receptors. Dose response curves revealed that carbamylcholine stimulated [3H]AA release by up to 12-fold with an ECo of approximately 0.4 microM; maximal responses were obtained with 10 microM carbamylcholine. Exposure of M1-, M3-, or M5-expressing cells to ethanol for 5 min before stimulating with carbamylcholine reduced [3H]AA release by 40 to 65%; 50% of the maximal inhibition was obtained with an ethanol concentration of 30 to 50 mM. Ethanol did not affect basal [3H]AA release measured in the absence of carbamylcholine. Dose response curves suggest that ethanol acts as a noncompetitive inhibitor of muscarinic receptor-induced [3H]AA release insofar as maximal [3H]AA release was depressed in the presence of ethanol with no apparent change in the EC50 for stimulation by carbamylcholine. Exposure of CHO cells to 38 mM ethanol for 48 hr increased [3H]AA release induced by carbamylcholine without affecting basal [3H]AA release or altering the EC50 for carbamylcholine. These results indicate that ethanol acutely inhibits muscarinic receptor signaling through the arachidonic acid pathway in a noncompetitive manner, but chronically enhances muscarinic signaling through the same pathway.

Sequestration of human muscarinic acetylcholine receptor hm1-hm5 subtypes: effect of G protein-coupled receptor kinases GRK2, GRK4, GRK5 and GRK6

Sequestration of porcine muscarinic acetylcholine receptor m2 subtypes (m2 receptors) expressed in COS-7 cells is facilitated by coexpression of G protein-coupled receptor kinases 2 (GRK2). We examined the effect of coexpression of GRK2, GRK4 delta, GRK5 and GRK6 on sequestration of human m1-m5 receptors expressed in COS-7 cells, which was assessed as loss of [3H]N-methylscopolamine binding activity from the cell surface. Sequestration of m4 receptors as well as m2 receptors was facilitated by coexpression of GRK2 and attenuated by coexpression of the dominant negative form of GRK2 (DN-GRK2). Sequestration of m3 and m5 receptors also was facilitated by coexpression of GRK2 but not affected by coexpression of DN-GRK2. On the other hand, proportions of sequestered m1 receptors were not significantly different with coexpression of GRK2 and DN-GRK2. GRK4 delta, GRK5 and GRK6 did not facilitate sequestration of m1-m5 receptors in COS-7 cells, except that the sequestration of m2 receptors tended to be facilitated by coexpression of GRK4 delta, GRK5 and GRK6. However, coexpression of GRK4 delta, GRK5, but not GRK6, in BHK-21 cells facilitated sequestration of m2, but not m3, receptors. These results indicate that the effect of GRK2 to facilitate receptor sequestration is not restricted to m2 receptors but is generalized to other muscarinic receptors except m1 receptors and that other kinases, including GRK4 delta, GRK5 and endogenous kinase(s) in COS-7 cells, also contribute to sequestration of m2 and m4 receptors.

Subtype-selective positive cooperative interactions between brucine analogues and acetylcholine at muscarinic receptors: radioligand binding studies

We studied the interactions of strychnine, brucine, and three of the N-substituted analogues of brucine with [3H]N-methylscopolamine (NMS) and unlabeled acetylcholine at m1-m5 muscarinic receptors using equilibrium and nonequilibrium radioligand binding studies. The results were consistent with a ternary allosteric model in which both the primary and allosteric ligands bind simultaneously to the receptor and modify the affinities of each other. The compounds had Kd values in the submillimolar range, inhibited [3H]NMS dissociation, and showed various patterns of positive, neutral, and negative cooperativity with [3H]NMS and acetylcholine, but there was no predictive relationship between the effects. Acetylcholine affinity was increased approximately 2-fold by brucine at m1 receptors, approximately 3-fold by N-chloromethyl brucine at m3 receptors, and approximately 1.5-fold by brucine-N-oxide at m4 receptors. The existence of neutral cooperativity, in which the compound bound to the receptor but did not modify the affinity of acetylcholine, provides the opportunity for a novel form of drug selectivity that we refer to as absolute subtype selectivity: an agent showing positive or negative cooperativity with the endogenous ligand at one receptor subtype and neutral cooperativity at the other subtypes would exert functional effects at only the one subtype, regardless of the concentration of agent or its affinities for the subtypes. Our results demonstrate the potential for developing allosteric enhancers of acetylcholine affinity at individual subtypes of muscarinic receptor and suggest that minor modification of a compound showing positive, neutral, or low negative cooperativity with acetylcholine may yield compounds with various patterns of cooperativity across the receptor subtypes.

Muscarinic receptor subtypes in the rat prostate gland

Muscarinic receptor subtypes mediating carbachol-induced contractions of the rat prostatic smooth muscle were determined. The rank order of potency of muscarinic receptor antagonists in blocking the effects of carbachol was (mean pKB estimates in parentheses): atropine (8.90) >> para-fluorohexahydrosiladifenidol (7.75) > or = hexahydrosiladifenidol (7.62) > methoctramine (6.89) > or = pirenzepine (6.68) > or = himbacine (6.67). The specific binding of [3H]quinuclidinyl benzilate to the rat prostatic homogenates was competitively inhibited by (mean pKi values in parentheses): atropine (8.89) >> hexahydrosiladifenidol (7.86) > para-fluorohexahydrosiladifenidol (7.28) > or = himbacine (7.22) > pirenzepine (6.63) > or = methoctramine (6.38). These profiles, whilst different, indicate the probable involvement of muscarinic M3 receptors in the carbachol-induced contraction.

Subtypes of the muscarinic receptor in smooth muscle

Muscarinic receptors are expressed in smooth muscle throughout the body. In most instances, the muscarinic receptor population in smooth muscle is composed of mainly the M2 and M3 subtypes in an 80% to 20% mixture. The M3 subtype mediates phosphoinositide hydrolysis and calcium mobilization, whereas the M2 subtype mediates an inhibition of cAMP accumulation. In addition, a variety of ionic conductances are elicited by muscarinic receptors. Muscarinic agonists stimulate a nonselective cation conductance that is pertussis toxin-sensitive and dependent on calcium. The pertussis toxin-sensitivity of this response suggests that it is mediated by M2 receptors. Following agonist induced depolarization of smooth muscle, voltage dependent calcium channels are activated to enable an influx of calcium. In some instances, muscarinic agonists enhance this conductance through a mechanism involving protein kinase C, whereas in other instances, muscarinic agonists suppress this calcium conductance. Smooth muscle often contains calcium activated potassium channels that tend to repolarize the membrane following calcium influx. Activation of muscarinic receptors suppresses this potassium conductance in some smooth muscles. Under standard conditions, muscarinic agonists elicit pertussis toxin-insensitive contractions through activation of the M3 receptor. When most of the M3 receptors are inactivated, it is possible to measure a pertussis toxin-sensitive contractile response to muscarinic agonists that is most likely mediated through M2 receptors. M2 receptors also cause an indirect contraction by inhibiting the relaxant effects of agents that increase cAMP (e.g., forskolin and isoproterenol).

Characterization of postjunctional muscarinic receptors mediating contraction in rat anococcygeus muscle

The present study was designed to characterize the postjunctional muscarinic receptors mediating contraction in rat anococcygeus muscle by means of a series of muscarinic agonists and subtype-preferring key muscarinic antagonists. Cumulative addition of muscarinic agonists elicited concentration-dependent contractions with the following rank order of potency (pD2 values): (+)-muscarine (6.36) > or = oxotremorine M (6.21) > or = arecaidine propargyl ester (APE) (6.18) > carbachol (5.68) = (+/-)-methacholine (5.65) > 4-(4-chlorophenyl-carbamoyloxy)-2-butynyltrimethylammonium chloride (4-Cl-McN-A-343) (4.28) > 4-(3-chlorophenylcarbamoyloxy)-2-butynyltrimethylammonium chloride (McN-A-343) (3.89). (+)-Muscarine, oxotremorine M, carbachol and (+/-)-methacholine behaved as full agonists, whereas APE, 4-Cl-McN-A-343 and McN-A-343 displayed partial agonism. The contractile responses of the rat anococcygeus muscle to (+/-)-methacholine were competitively antagonized by pirenzepine (pA2 = 6.92), 11-[[4-[4-(diethylamino)butyl]-1-piperidinyl]acetyl] 5,11-dihydro-6H-pyrido(2,3-b) (1,4)-benzodiazepine-6-one (AQ-RA 741; pA2 = 6.75), himbacine (pA2 = 7.11), (+/-)-p-fluoro-hexahydro-sila-difenidol (p-F-HHSiD; pA2 = 7.68) and the (R)- and (S)-enantiomers of hexahydro-difenidol [(R)-HHD: pA2 = 8.52; (S)-HHD: pA2 = 6.06]. A comparison of the pA2 values derived from studies of contraction in rat anococcygeus muscle with literature binding (pKi values) and functional affinities (pA2 values) obtained at native M1-M4 receptors strongly suggests that the postjunctional muscarinic receptors mediating contraction in rat anococcygeus muscle are of the M3 subtype.

Use of frozen sections for the pharmacological characterization of compounds active on neurotransmitter receptors

Radioligand binding assay represents an important technique in pharmacological and pharmaceutical research for assessing the receptor profile of new drugs or of compounds under development. In this study, the pharmacological profile and the receptor specificity of compounds active on dopamine and muscarinic cholinergic receptor subtypes were evaluated using as a receptor source, membrane preparations or frozen sections. Dopamine D1-like receptors were assayed in membrane preparations or frozen sections of rat striatum and kidney with [3H]-SCH 23390 as a ligand. Rat striatum, kidney and atrium were used as a source of dopamine D2-like receptors with [3H]-spiperone as a ligand. The non-selective muscarinic cholinergic receptor antagonist [3H]-N-methyl-scopolamine was used to label muscarinic cholinergic receptors in the rat. Frontal cortex represented the source of M1 receptor subtype, heart the source of M2 receptor subtype, sub maxillary gland the source of M3 receptor subtype and striatum the source of M4 receptor subtype. With the exception of cardiac tissue, no significant differences were noticeable in the affinity of dopaminergic or muscarinic cholinergic compounds tested using membrane particles or 8 microns thick slide-mounted section. In the heart, frozen sections gave lower dissociation constant and inhibition constant values than membranes. The above findings suggest that radioligand binding assay on slide-mounted tissue sections may represent a suitable technique for assessing the receptor profile of drugs under development for the treatment of disorders characterised by dopaminergic or muscarnic cholinergic dysfunction.

Characterization of muscarinic receptor subtypes that mediate antinociception in the rat spinal cord

Spinal cholinergic receptors are involved in mediating antinociceptive effects. To characterize the receptor subtypes modulating nociceptive transmission, we first determined the antinociceptive effects of intrathecally administered muscarinic agonists (McN-A-343 and carbachol) and a cholinesterase inhibitor (neostigmine) in rats. The antagonist potencies of muscarinic antagonists with different preferences for muscarinic receptors [atropine, pirenzepine (M1), methoctramine (M2), and 4-diphenylacetoxy-N-methylpiperidine methiodide (4-DAMP; M3)] were then examined for McN-A-343, carbachol, and neostigmine. After determining the time of peak effect for each antagonist, the just maximally effective (JME) dose of each agonist was given in conjunction with one of the several doses of the antagonists. The three agents produced a dose-dependent increase in paw withdrawal latency, with the following 50% effective dose and the following JME doses: neostigmine 6 and 14 nmol, carbachol 29 and 110 nmol, and McN-A-343 354 and 630 nmol. The rank of order of potency (and median infective dose in nanomoles) for the antagonists was: neostigmine = (atropine 14 > 4-DAMP 44 > > methoctramine > 137, and pirenzepine > 236); carbachol = (pirenzepine 0.5 = atropine 0.6 > 4-DAMP 5 > > methoctramine > 137); McN-A-343 = (pirenzepine 0.5 > atropine 3 > 4-DAMP 6 > > methoctramine > 137). Our results suggest that the M1 and possibly the M3 muscarinic receptors mediate spinal antinociception in the rat.

IMPLICATIONS

Spinal muscarinic agonists, such as carbachol and the cholinesterase inhibitor neostigmine, induce a potent analgesia in the rat. Using selective receptor antagonists, we have shown that these effects are likely mediated by spinal M1 and/or M3 receptor subtypes.

Identification of muscarinic receptor subtypes in RINm5F cells by means of polymerase chain reaction, subcloning, and DNA sequencing

Carbachol can stimulate insulin release in RINm5F cells by a mechanism that does not involve the elevation of cytosolic free Ca2+ concentrations or the activation of conventional protein kinase Cs (Mol Pharmacol 47:863-870, 1995). Thus, a novel signal transduction pathway links the muscarinic activation of the cells to increased insulin secretion. The question arises as to whether the pathway results from a novel receptor, different from the five established muscarinic receptors, or whether a "normal" receptor in the RINm5F cell activates a novel pathway. To distinguish between these two possibilities, the muscarinic receptors in the RINm5F cell were identified. Using polymerase chain reaction, combined with subcloning and DNA sequencing techniques, the cDNAs that encode the established M3 and M4 receptors were identified. The cDNAs for the Ml, M2, and M5 receptors were not found. Pharmacological studies showed a rank order of potency for muscarinic receptor subtype antagonists to inhibit carbachol-induced insulin release (half-maximal inhibitory concentration [pIC50] values given in parentheses): atropine (nonselective, 9.0) > 4-diphenyl-acetoxy-N-methyl piperidine methiodide (M3/M1, 8.6) > para-fluoro-hexahydrosiladiphenidol (M3, 8.1) > hexahydrosiladiphenidol (M3, 8.0) > tropicamide (M4, 6.4) > pirenzepine (M1, 6.1) > methoctramine (M2, 5.9). This antagonist profile suggests that it is the M3 receptor that mediates carbachol-induced insulin release. In this case, the novel signaling involved in the unusual carbachol response would not be due to a novel receptor but to the well-characterized M3 receptor. It appears, therefore, that the novel portion of the signaling pathway lies downstream of the M3 receptor and may consist of products of phosphatidylinositol hydrolysis, other than inositol triphosphate and diacylglycerol, resulting from the activation of phospholipase C. While a contributory role of the M4 receptor cannot be ruled out, there is no evidence in its favor other than its presence in the cell.

Characterization of the muscarinic receptor subtype(s) mediating contraction of the guinea-pig lung strip and inhibition of acetylcholine release in the guinea-pig trachea with the selective muscarinic receptor antagonist tripitramine

1. The muscarinic receptor subtypes mediating contraction of the guinea-pig lung strip and inhibition of the release of acetylcholine from cholinergic vagus nerve endings in the guinea-pig trachea in vitro have previously been characterized as M2-like, i.e. having antagonist affinity profiles that are qualitatively similar but quantitatively dissimilar compared to cardiac M2 receptors. The present study sought to establish definitely the identity of these receptor subtypes by using the selective muscarinic receptor antagonist, tripitramine. Guinea-pig atria and guinea-pig trachea (postjunctional contractile response) were included for reference. 2. It was found that tripitramine antagonized methacholine-induced contractions of the guinea-pig lung strip with pKB value of 8.76 +/- 0.05. Both the parallel shifts of the concentration-response curves and the slope of the Schild plot begin not significantly different from unity (when antagonist preincubation was for 2 h) indicated the involvement of a single population of receptors in the contractile response. From the pKB values obtained with tripitramine and a range of other selective muscarinic receptor antagonists (cf. Roffel et al., 1993), this single population of receptors can only be classified as M2-like. 3. Tripitramine antagonized methacholine-induced chronotropic and inotropic responses in guinea-pig right and left atria with apparent pKB values of 9.4-9.6. However, such values were only obtained when antagonist preincubation was relatively long and/or antagonist concentration relatively high (e.g with 1 h at 100 or 300 nM but 3 h at 30 nM). It thus appears that low concentrations of tripitramine do not readily equilibrate with M2 receptors in guinea-pig atria nor with M2-like receptors in the guinea-pig lung strip. 4. Tripitramine increased electrical field stimulation-induced cholinergic twitch contractions in guinea-pig trachea in concentrations of 0.3-100 nM, by blocking prejunctional muscarinic inhibitory autoreceptors; with higher concentrations, twitch contractions were progressively diminished, as a result of blocking postjunctional M3 receptors (apparent pKB value 6.07 +/- 0.15). The pEC20 value (-log concentration that increases twitch by 20% maximum) was 8.29 +/- 0.08, which would suggest that M4 receptors are involved in this response. 5. Oxotremorine-induced inhibition of the release of prelabelled [3H]-acetylcholine from guinea-pig trachea, under conditions where there is no auto-feedback, was blocked by tripitramine (2 h preincubation) with a pKB value of 8.56 +/- 0.06. The slope of the corresponding Schild plot was not significantly different from unity, which together with the parallel shifts of the concentration-response curves indicated the involvement of a single muscarinic receptor subtype. 6. Since the pKB value for tripitramine at prejunctional receptors in guinea-pig trachea is in between the affinities towards M2 and M4 receptors, correlation plots were constructed to compare the pKB values obtained with tripitramine and a range of other selective muscarinic receptor antagonists (cf. Kilbinger et al., 1995) to reported affinities at M1-M4 receptors. This showed rather similar distribution patterns of the data points around the line of equality in the case of M2 and M4 receptor subtypes. However, the correlation coefficient was markedly better for M2 (0.9667) than for M4 (0.5976). Since recent evidence suggests that M4 receptors are not expressed in cholinergic nerves from guinea-pig trachea, it is concluded that prejunctional muscarinic autoinhibitory receptors in this tissue exhibit an atypical M2 type character, with a pharmacological profile distinct from cardiac M2 receptors.

Positive cooperativity of acetylcholine and other agonists with allosteric ligands on muscarinic acetylcholine receptors

It is well known that allosteric modulators of muscarinic acetylcholine receptors can both diminish and increase the affinity of receptors for their antagonists. We investigated whether the allosteric modulators can also increase the affinity of receptors for their agonists. Twelve agonists and five allosteric modulators were tested in experiments on membranes of CHO cells that had been stably transfected with genes for the M1-M4 receptor subtypes. Allosterically induced changes in the affinities for agonists were computed from changes in the ability of a fixed concentration of each agonist to compete with [3H]N-methylscopolamine for the binding to the receptors in the absence and the presence of varying concentrations of allosteric modulators. The effects of allosteric modulators varied greatly depending on the agonists and the subtypes of receptors. The affinity for acetylcholine was augmented by (-)-eburnamonine on the M2 and M4 receptors and by brucine on the M1 and M3 receptors. Brucine also enhanced the affinities for carbachol, bethanechol, furmethide, methylfurmethide, pilocarpine, 3-(3-pentylthio-1,2,5-thiadiazol-4-yl)-1,2,5,6-tetrahydro-1- methylpyridine (pentylthio-TZTP), oxotremorine-M, and McN-A-343 on the M1, M3, and M4 receptors, for pentylthio-TZTP on the M2 receptors, and for arecoline on the M3 receptors. (-)-Eburnamonine enhanced the affinities for carbachol, bethanechol, furmethide, methylfurmethide, pentylthio-TZTP, pilocarpine, oxotremorine and oxotremorine-M on the M2 receptors and for pilocarpine on the M4 receptors. Vincamine, strychnine, and alcuronium displayed fewer positive allosteric interactions with the agonists, but each allosteric modulator displayed positive cooperativity with at least one agonist on at least one muscarinic receptor subtype. The highest degrees of positive cooperativity were observed between (-)-eburnamonine and pilocarpine and (-)-eburnamonine and oxotremorine-M on the M2 receptors (25- and 7-fold increases in affinity, respectively) and between brucine and pentylthio-TZTP on the M2 and brucine and carbachol on the M1 receptors (8-fold increases in affinity). The discovery that it is possible to increase the affinity of muscarinic receptors for their agonists by allosteric modulators offers a new way to subtype-specific pharmacological enhancement of transmission at cholinergic (muscarinic) synapses.

Muscarinic receptor subtypes in human iris-ciliary body measured by immunoprecipitation

PURPOSE

To determine the relative levels of the five muscarinic receptor subtypes in the anterior segment of the human eye.

METHODS

Antisera selective for each of the five muscarinic receptor proteins were incubated with [3H]-QNB bound receptors solubilized from human iris sphincter, ciliary muscle, and ciliary processes. Precipitation of the radiolabeled receptor-antibody complexes and scintillation counting enabled quantitation of the subtypes in the various tissues. Reverse transcription-polymerase chain reaction was performed on the tissues and cultured smooth muscle cells derived from them.

RESULTS

Approximately 60% to 75% of the muscarinic receptors in the human iris sphincter and ciliary body are the m3 subtype. Lower levels (5% to 10%) of the m2 and m4 receptors are present in these tissues. The m1 receptor (7%) was detected in the ciliary processes and iris sphincter and the m5 receptor (5%), which is usually found only in the central nervous system, was present in the iris sphincter.

CONCLUSIONS

The m3 subtype is the predominant muscarinic receptor in the anterior segment of the human eye. The extensive heterogeneity of muscarinic receptors makes it difficult to predict whether subtype-selective drugs will have an improved efficacy and side-effect profile.

Pharmacologic characterization of muscarine receptor subtypes in rat gastric fundus mediating contractile responses

The role of four muscarinic receptor subtypes M1, M2, M3 and M4 which have been characterized pharmacologically was examined in motility control of isolated rat gastric fundus. Acetylcholine produced concentration-dependent tonic contraction of isolated rat fundus (EC50 = 9.64 +/- 0.14 x 10(-8)M). These contractions were concentration-dependently antagonized by atropine (KB = 2.45 x 10(-11)M), M1 selective blockers telenzepine (KB = 6.64 x 10(-11)M) and pirenzepine (KB = 2.3 x 10(-8)M), and hexocyclium (KB = 2.82 x 10(-10)M). M3-selective blocker p-fluoro-hexahydro-sila-difenidol (pFHHSiD) was a less potent antagonist (KB = 2.3 x 10(-8)M), while M2 and M4-selective methoctramine produced only weak blockade of tonic contractions caused by acetylcholine (KB = 4.68 x 10(-6)M). These results suggest that only M1 and M3 muscarinic receptors have functional roles in motility control of rat gastric fundus, M1 receptors being more important.