M2 Muscarinic Receptor Inhibition of Agonist-induced Cyclic Adenosine Monophosphate Accumulation and Relaxation in the Guinea Pig Ileum

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HISTAMINE

Vol. 280, Issue 1, 189-199, 1997

M₂ Muscarinic Receptor Inhibition of Agonist-induced Cyclic Adenosine Monophosphate Accumulation and Relaxation in the Guinea Pig Ileum¹

Rennolds S. Ostrom and Frederick J. Ehlert

Department of Pharmacology, College of Medicine, University of California, Irvine, Irvine, California

	Abstract

Top Abstract Introduction Methods Results Discussion References

The purpose of this study was to characterize the role of M₂ muscarinic receptors in inhibiting relaxant effects of drugsthat stimulate cyclic AMP (cAMP) accumulation in the guinea pigileum. We investigated the ability of oxotremorine-M (oxo-M) toinhibit cAMP accumulation in the presence of agonists that stimulateadenylyl cyclase in other cells and tissues. Appreciable stimulationof cAMP (>50% over basal levels) was achieved with forskolin andmaximally effective concentrations of isoproterenol, cicaprost,prostaglandin E₁, prostaglandin E₂ and prostaglandin I₂, withthe stimulation over basal levels of cAMP being 14.9-, 2.51-,2.45-, 2.27-, 2.28- and 1.52-fold, respectively. Moderate or nocAMP stimulation was observed with dopamine, 5-hydroxytryptamine,5-methoxytryptamine, dimaprit, vasoactive intestinal peptide,SKF-38393, 2-chloroadenosine, CGS-21680, prostaglandin D₂, secretinand vasopressin. Oxo-M (1 µM) inhibited cAMP accumulation by 35%under basal conditions. Oxo-M inhibited specific agonist-stimulatedcAMP levels by 20 to 70%. However, oxo-M caused little or no inhibitionof specific prostaglandin I₂- and cicaprost-stimulated cAMP levels(5 and 0%, respectively). In general, there was a correlationbetween the abilities of the various agonists to stimulate cAMPaccumulation and to cause relaxation of the isolated ileum, withan exception being cicaprost. Experiments were carried out withisolated ileum to determine whether activation of M₂ receptorsinhibited the relaxant effects of the various agonists. In theseexperiments, the ileum was first treated with N-(2-chloroethyl)-4-piperidinyldiphenylacetate to selectively inactivate M₃ receptors. Afterthis treatment phase, contractile responses to oxotremorine-Mwere measured in the presence of histamine and a given relaxantagent. These measurements were repeated in the presence of theM₂-selective antagonist AF-DX 116. Analysis of the data showedthat part of the contractile response to oxotremorine-M couldbe attributed to an M₂-mediated inhibition of the relaxation.This M₂ component of the contractile response was greatest whenforskolin or isoproterenol was used as the relaxant agent. Incontrast, little or no M₂ response was measured in the presenceof dopamine and cicaprost.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Smooth muscle from tissues such as the gastrointestinal tract (Michel and Whiting, 1988; Zhang et al., 1991; Gomez et al.,1992), uterus (Eglen et al., 1989), urinary bladder (Monferiniet al., 1988; Noronha-blob et al., 1989), ciliary body (WoldeMussieet al., 1993) and airways (Gies et al., 1989; Eglen et al., 1994)of various species contains a mixture of M₂ and M₃ muscarinicreceptors. The smooth muscle of the ileum also contains M₂ andM₃ receptors, as demonstrated in radioligand binding experiments(Giraldo et al., 1988; Michel and Whiting, 1990), mRNA analysis(Maeda et al., 1988) and immunoprecipitation studies with subtype-selectiveantibodies (Wall et al., 1991; Dörje et al., 1991). Under standardconditions the contractile response of the ileum is mediated bythe M₃ muscarinic receptor, which couples to phospholipase C bothin ileal smooth muscle (Candell et al., 1990) and in cells transfectedwith the M₃ receptor (Peralta et al., 1988). However, this subtypecomprises only about 20% of the total muscarinic receptors inthe ileum (Candell et al., 1990; Michel and Whiting, 1990). TheM₂ muscarinic receptor accounts for the remaining 80% of the muscarinicreceptor population and is known to mediate a pertussis toxin-sensitiveinhibition of adenylyl cyclase in ileal smooth muscle (Candellet al., 1990), in the heart (Ehlert et al., 1989) and in cellstransfected with the M₂ subtype (Kurose et al., 1983). In intactcell preparations of the longitudinal muscle of the guinea pigileum, activation of M₂ receptors inhibits the accumulation ofcAMP stimulated by beta adrenergic agonists and various otheragonists (Reddy et al., 1995). In contrast, M₂ receptors inhibitonly the increase in cAMP elicited by isoproterenol and forskolinin the longitudinal muscle of the rat ileum (Griffin and Ehlert,1992). Because cAMP has been shown to relax smooth muscle (Berridge,1975), it has been suggested that M₂ receptors may play a rolein contraction by inhibiting the relaxant effects of agents thatincrease cAMP (Candell et al., 1990; Griffin and Ehlert, 1992).

This prediction has been borne out in studies on smooth muscle that had been treated with 4-DAMP mustard to inactivate mostof the M₃ receptors. Such treatment causes a 20- to 40-fold reductionin the potency of highly efficacious agonists when contractionsare measured under standard conditions in the ileum and trachea(Thomas et al., 1993; Watson et al., 1995; Thomas and Ehlert,1996). The large decrease in agonist potency can be attributedto the loss of M₃ receptors. However, if contractions are measuredin the same tissues in the presence of histamine and forskolin,a highly potent muscarinic response occurs that is blocked byselective antagonists in a manner consistent with an M₂ response(Thomas et al., 1993; Thomas and Ehlert, 1996). Presumably, themechanism for this contraction involves an M₂-mediated inhibitionof the relaxant effects of forskolin. This M₂-mediated contractileresponse is pertussis toxin-sensitive, unlike the standard contractileresponse, which is insensitive to pertussis toxin (Thomas andEhlert, 1994, 1996). Using the same strategy, little or no contractileeffects were detected for M₂ receptors in the rat fundus and guineapig esophagus (Thomas and Ehlert, 1996). M₂ receptors have alsobeen shown to inhibit the relaxant effects of isoproterenol onhistamine-induced contractions of the ileum but not of the trachea(Thomas et al., 1993; Reddy et al., 1995; Watson et al., 1995).The reason for this difference between relaxant agents is unclearbut may be related to the greater ability of forskolin to increasecAMP levels, compared with isoproterenol. Other investigatorshave used a different technique to detect a role for the M₂ receptorin contraction of the trachea (Fernandes et al., 1992; Watsonand Eglen, 1994). However, see work by Roffel et al. (1993, 1995)for an opposing viewpoint.

It has long been known that isoproterenol is more effective at relaxing histamine-induced contractions, compared with thoseelicited by a muscarinic agonist (Van Amsterdam et al., 1989;Roffel et al., 1993). These observations have been interpretedas evidence that activation of M₂ receptors inhibits the cAMPaccumulation elicited by isoproterenol, thereby reducing its relaxanteffects against M₃-induced contractions, whereas histamine iswithout effect on cAMP levels. Alternatively, it has been proposedthat cross-talk may occur between phospholipase C activation (viaM₃ receptor stimulation) and the beta adrenergic signal transductionpathway (Roffel et al., 1993). A correlation between phosphoinositidehydrolysis and the shift in beta adrenergic receptor potency hasbeen demonstrated (Van Amsterdam et al., 1989), and this effectmay involve protein kinase C inactivation of G_s, resulting infunctional uncoupling of beta adrenergic receptors (Pyne et al.,1992; Grandordy et al., 1994). Both M₂ and M₃ receptor-mediatedantagonism of isoproterenol relaxant potency may be at work tovarying degrees in different tissues, or a yet unknown responsemay be mediated by the M₂ receptor. Regardless, the functionalrole of the M₂ receptor in contraction has not been clearly definedin all smooth muscle tissues.

The purpose of the studies in the present report was to investigate the ability of the M₂ receptor in the guinea pig ileumto inhibit both the cAMP accumulation and the relaxant effectsof a variety of agents known to stimulate adenylyl cyclase inother cells and tissues. Our results are consistent with the postulatethat the functional role of the M₂ receptor in contraction dependson the amount of cAMP accumulation stimulated by the relaxantagent and the extent to which the M₂ receptor inhibits the increasein cAMP.

	Methods

Top Abstract Introduction Methods Results Discussion References

cAMP accumulation. Male Hartley guinea pigs (250-300 g) were sacrificed by asphyxiation with CO₂, followed by exanguination. Their ilea wereimmediately dissected, and the longitudinal muscle was removedby the method of Rang (1964) and immediately placed in ice-coldKRB buffer (124 mM NaCl, 5 mM KCl, 1.3 mM MgCl₂, 26 mM NaHCO₃,1.2 mM KH₂PO₄, 1.8 mM CaCl₂, 10 mM glucose) gassed with O₂/CO₂(19:1). Strips of muscle were cross-chopped at 350 µm with a McIlwaintissue chopper, washed extensively and equilibrated at 37°C for15 min. In some experiments, tissues were incubated with the aziridiniumion of 4-DAMP mustard (40 nM) for 1 hr in the presence of AF-DX116 (1 µM). After this incubation the tissue was washed extensivelyto remove 4-DAMP mustard and AF-DX 116. The slices were incubatedin 10 ml of KRB buffer with [³H]adenine (1.0 µM, 50 µCi) for 40 min at 37°C, to allow uptakeand incorporation into endogenous ATP. Slices were washed threetimes to remove extracellular [³H]adenine and were allowed to equilibrate for 15 min. Aliquots(70-100 µl) of gently packed tissue slices were incubated for10 min at 37°C in KRB buffer (0.7 ml) containing 3-isobutyl-1-methylxanthine(0.5 mM) and various agonists. Ro2-01724 was substituted for 3-isobutyl-1-methylxanthinein experiments where 2-chloroadenosine or CGS-21680 was used,because of the ability of 3-isobutyl-1-methylxanthine to blockadenosine receptors. Reactions were stopped by the addition of0.3 ml of trichloroacetic acid (30%, w/v). Approximately 2000cpm of [³²P]cAMP was added to each sample as an internal standard. The tubeswere centrifuged, and the [³H]cAMP and [³H]ATP were separated from the supernatant fraction using the chromatographymethod described by Salomon et al. (1974). The supernatant wasapplied to a cation exchange column (1.25 ml of Dowex AG 50W-X4,200-400 mesh) and washed twice with 1.25 ml of water. This eluatewas collected, and the radioactivity was measured as the incorporationof [³H]adenine into [³H]ATP. The Dowex column was positioned over a column of neutralalumina (0.6 g), and the [³H]cAMP was eluted onto the alumina column with 5 ml of water.The [³H]cAMP was eluted from the alumina with 4 ml of 0.1 M imidazoleHCl (pH 7.5). This fraction was collected and the radioactivitywas measured to determine the amount of accumulated [³H]cAMP. The [³H]cAMP values were corrected for recovery of the internal standardand are expressed as a percentage of the amount of incorporationof [³H]adenine, to correct for any variation in the amount of tissueadded to each assay.

Isolated ileum. Male Hartley guinea pigs were sacrificed as described above, and the whole ileum was rapidly removed. The most distal 10 cmof ileum was discarded and 2- to 3-cm ileal segments were cut,flushed with KRB buffer to remove ileal contents and mounted longitudinallyin an organ bath containing KRB buffer at 37°C, gassed with O₂/CO₂(19:1). Isometric contractions were measured with a force transducerand recorded on a polygraph and are expressed as the mass (grams)required to generate the measured force. The ileum was equilibratedfor 1 hr at a resting tension equivalent to a load of 0.5 g. Threetest doses of the muscarinic agonist oxo-M or histamine were addedto the bath to ensure reproducibility of the preparation. Ilealsegments that did not achieve >60% of the maximum from the testdoses were discarded. Between each test dose the ileum was washedwith fresh KRB buffer and incubated for 5 min. To calculate anEC₅₀ value for oxo-M, 6 to 10 concentrations of the compound,spaced geometrically every 0.33 log units, were added cumulativelyto the bath, and contractile responses were recorded. After anEC₅₀ value for oxo-M was obtained, the ileum was washed and incubatedfor 30 min before additional measurements were made. In some experiments,tissues were incubated with the aziridinium ion of 4-DAMP mustard(40 nM) for 1 hr in the presence of AF-DX 116 (1 µM). Tissueswere washed extensively to remove AF-DX 116 and unreacted 4-DAMPmustard. When an EC₅₀ value for oxo-M was to be obtained in thepresence of AF-DX 116, the antagonist was incubated with the ileumfor 30 min before contractions were measured.

Formation of the aziridinium ion of 4-DAMP mustard. 4-DAMP mustard undergoes two sequential reactions in aqueous solution at neutral pH. The first of these is the cyclizationto its reactive aziridinium ion, and the second is the hydrolysisof the aziridinium ion to the stable alcohol product. In all experimentsin which it was used, 4-DAMP mustard (10 µM) was first incubatedin 10 mM phosphate buffer (pH 7.4) at 37°C for 30 min, to allowformation of the reactive aziridinium ion (Thomas et al., 1992).Immediately after cyclization, the solution of the aziridiniumion was placed on ice and used immediately.

Data analysis. Oxo-M inhibition of cAMP accumulation was calculated in two ways. Total inhibition (I_t) was calculated for each experimentwith the following equation:

It<IT>=</IT><FENCE><FR><NU><IT>O</IT></NU><DE><IT>C</IT></DE></FR><IT>−1</IT></FENCE><IT>×100</IT> (1)

where O denotes the fold stimulation of cAMP in the presence of oxo-M and C denotes the fold stimulation of cAMP in the absenceof oxo-M. The mean ± S.E.M. of the paired data are expressed intable 1. Inhibition of agonist-stimulated cAMP accumulation (I_a)was calculated with the following equation:

Ia<IT>=</IT><FENCE><FR><NU><IT>O−b</IT>o</NU><DE><IT>C−b</IT>c</DE></FR><IT>−1</IT></FENCE><IT>×100</IT> (2)

where C and O are defined as above (mean values used), b_o denotes the basal cAMP accumulation in the presence of oxo-M (meanof 0.65-fold) and b_c denotes the basal cAMP accumulation in theabsence of oxo-M (1.0-fold). The EC₅₀ values of oxo-M (concentrationof oxo-M required for half-maximal response) for contraction andinhibition of cAMP accumulation were estimated by nonlinear regressionanalysis of the data according to an increasing or decreasinglogistic equation, as described previously (Candell et al., 1990).In some instances, a two-component model was used to analyze thecontractile response data measured in 4-DAMP mustard-treated tissuein the presence of histamine and a relaxing agent. For this analysis,the following equation was fitted to the data by nonlinear regressionanalysis:

y=Max<FENCE><FR><NU>MaxH[oxo-M]<IT>H1</IT></NU><DE>[oxo-M]<IT>H1</IT><IT>+</IT>EC<IT>50</IT>H<IT>H1</IT></DE></FR><IT>+</IT><FR><NU>(<IT>1−Max</IT>H)[oxo-M]<IT>H2</IT></NU><DE>[oxo-M]<IT>H2</IT><IT>+</IT>EC<IT>50</IT>L<IT>H2</IT></DE></FR></FENCE> (3)

In this equation, Max denotes the maximal contractile response, Max_H denotes the proportion of the high-potency component,H1 and H2 denote the high- and low-potency Hill coefficients andEC_50H and EC_50L denote the EC₅₀ values of the high- and low-potencycomponents of the contractile response curve. The contractileresponse data measured in the absence of AF-DX 116 were analyzedaccording to equation 1. The data measured in the presence ofAF-DX 116 were also analyzed according to equation 1, except withthe high- and low-potency EC₅₀ values multiplied by constants(shift_H and shift_L, respectively) corresponding to the factorsby which AF-DX 116 increased the EC₅₀ values. In this analysis,the data obtained in the presence and absence of AF-DX 116 wereanalyzed simultaneously, sharing the estimates of Max, Max_H, H1,H2, EC_50H and EC_50L between the two sets of data. In most of theanalyses, the estimates of shift_H and shift_L were set at constantscorresponding to the expected values for AF-DX 116 (1.0 µM) atM₂ and M₃ receptors (see "Results").

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TABLE 1
Oxo-M inhibition of agonist-stimulated cAMP accumulation

Compounds. 4-DAMP mustard was synthesized in our laboratory as described previously (Thomas et al., 1992). Radiolabeled chemicals wereobtained from ICN Biochemicals (Costa Mesa, CA). Cicaprost wasobtained as a generous gift from Dr. Fiona McDonald of ScheringAG (Berlin, Germany). AF-DX 116 was acquired from Boehringer IngelheimPharmaceuticals (Ridgefield, CT). SKF-38393, CGS-21680 and oxo-Mwere obtained from Research Biochemicals Inc. (Natick, MA). Allother drugs and chemicals were obtained from Sigma Chemical Co.(St. Louis, MO).

	Results

Top Abstract Introduction Methods Results Discussion References

Muscarinic inhibition of agonist-stimulated cAMP accumulation. We measured the ability of the highly efficacious muscarinic agonist oxo-M to inhibit the cAMP accumulation elicited by avariety of agents that have been shown to stimulate adenylyl cyclasein other tissues. The cAMP-stimulating agents were used at concentrationsfrom 0.8 to 10 µM, whereas oxo-M was always used at a nearly maximallyeffective concentration of 1 µM. The largest increase in cAMPwas elicited by forskolin (10 µM), which stimulated cAMP levels14.9-fold, from a basal value of 0.35 ± 0.04% (expressed as apercentage of the total [³H]adenine-labeled nucleotides) to 5.35 ± 1.32%. Moderate stimulationof cAMP (2.51-1.52-fold stimulation over basal) was observed withisoproterenol (1 µM), PGE₁ (10 µM), PGE₂ (10 µM), cicaprost (0.8µM) and PGI₂ (10 µM), with stimulations over basal being 2.51-,2.27-, 2.28-, 2.45- and 1.52-fold, respectively (table 1). Littleor no cAMP stimulation was observed with dopamine, 5-HT, 5-MT,dimaprit, VIP, SKF-38393, 2-chloroadenosine, CGS-21680, prostaglandinD₂, secretin and vasopressin. Oxo-M (1 µM) inhibited basal cAMPlevels by 35%. Indomethacin and tetrodotoxin had no effect onthe oxo-M inhibition of basal cAMP (data not shown). Oxo-M (1µM) inhibited the cAMP measured in the presence of the variousagents by 21 to 67% (total inhibition). PGI₂ and cicaprost wereexceptions, with oxo-M exerting total inhibition of only 12 and17%, respectively. Because part of the total inhibition can beattributed to inhibition of basal cAMP levels, we also tabulatedthe percent inhibition of agonist-stimulated cAMP, as describedin "Methods." This percentage was calculated after the basal valuesin the absence (1.0-fold) and presence (0.65-fold) of oxo-M weresubtracted from the agonist-stimulated values in the absence andpresence of oxo-M, respectively (table 1). Such a calculationestimates the specific inhibition of each agonist effect by muscarinicreceptor activation. Using this calculation, oxo-M specificallyinhibited forskolin-, isoproterenol-, PGE₁-, PGE₂-, dopamine-and VIP-stimulated cAMP levels by 70, 38, 20, 29, 26 and 39%,respectively. PGI₂-, cicaprost-, 5-MT- and dimaprit-stimulatedcAMP levels were not specifically inhibited by oxo-M (0, 5, 0and 0%, respectively).

The potency of oxo-M for inhibiting cAMP accumulation was estimated by measuring oxo-M concentration-response curves in thepresence of either forskolin (10 µM), isoproterenol (1 µM), dopamine(10 µM) or cicaprost (0.8 µM) (fig. 1). To keep the experimentalconditions the same as those of subsequent contractile studies,tissue was treated for 1 hr with 4-DAMP mustard plus 1 µM AF-DX116 (see "Methods") to inactivate M₃ receptors selectively. Ourgroup has previously shown that this treatment does not effectmuscarinic inhibition of stimulated cAMP accumulation (Thomaset al., 1993

). Oxo-M caused a concentration-dependent inhibitionof the cAMP accumulation elicited by each of the stimulators.The potency of oxo-M for inhibiting the cAMP accumulation elicitedby each of the agonists was approximately the same, yielding pEC₅₀values of 6.66, 6.80, 6.69 and 6.68 for forskolin, isoproterenol,dopamine and cicaprost, respectively (table 2). The maximal inhibitionelicited by a high concentration of oxo-M varied with the agonistused to stimulate cAMP accumulation (table 2; fig. 1). The greatestmaximal effect was observed with forskolin (72%), followed bydopamine (51%), isoproterenol (45%) and cicaprost (27%). In figure1, cAMP accumulation is plotted without subtraction of the basalvalues.

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Fig. 1. Oxo-M inhibition of cAMP accumulation stimulated by 10 µM forskolin ( $open circle$ ), 1 µM isoproterenol ( $bullet$ ), 0.8 µM cicaprost ( $square$ ) and10 µM dopamine ( $black-square$ ). Data are expressed as percent inhibition ofstimulated cAMP accumulation (as percent conversion), withoutsubtraction of basal levels. All tissue was treated with 4-DAMPmustard as described in "Methods." Each point represents the mean± S.E.M. of five experiments.

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TABLE 2
Estimates of the pEC₅₀ and maximal effect of oxo-M inhibition of cAMP accumulation stimulated by different agents

Maximal relaxant effects of heterologous agonists. We investigated the ability of each agonist to inhibit histamine-induced contractions in the guinea pig ileum, to identifythose agents having a correlation between their stimulation ofcAMP accumulation and their relaxant ability. The isolated ileumwas contracted with histamine (0.3 µM) and allowed to stabilize,and then a maximal concentration of the cAMP-stimulating agentwas added. The amount of relaxation recorded is expressed as apercentage of the original histamine contraction (table 3). Forthe purpose of making the comparison, the agonists are listedin order of decreasing effectiveness in stimulating cAMP accumulation.In the rightmost column, the percentage relaxation value for eachagonist is listed together with its rank order (in parentheses).The relaxant effects of forskolin, isoproterenol and cicaprostwere rather large, representing 103, 97.5 and 43.9% inhibition,respectively, of the histamine-induced contraction. Dopamine,VIP, CGS-21680, 2-chloroadenosine and SKF-38393 caused a smallamount of relaxation (13-30%).

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TABLE 3
Correlation of cAMP accumulation and relaxant efficacy of maximal concentrations of various receptor agonists

Figure 2 shows the relaxant effects of the various agents plotted against their stimulation of cAMP accumulation, expressedrelative to basal levels (basal cAMP = 1.0). It can be seen thatthere is a general correlation between the ability of agents tostimulate cAMP accumulation and to relax histamine-induced contractions.These data indicate that the ability of an agonist to stimulatecAMP accumulation is predictive of its relaxant efficacy (fig.2). One notable exception is cicaprost (0.8 µM), which causeda large increase in cAMP accumulation (2.45 ± 0.25-fold) but onlya modest amount of relaxation (43.9 ± 5.43%). It may be that thisprostanoid derivative has a small contractile component to itsaction that partially opposes a large cAMP-mediated relaxation,resulting in a net relaxation much less than that expected fromits cAMP response. If the data for cicaprost are excluded, figure2 suggests that nearly complete inhibition (97%) of 0.3 µM histamine-inducedcontractions occurs when cAMP levels are increased approximately2.5-fold over basal levels (e.g., isoproterenol at 1 µM) and thatthe increase in cAMP accumulation elicited by forskolin (14.9-fold)greatly exceeds that required to cause complete relaxation.

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Fig. 2. Comparison of cAMP accumulation (fold stimulation over basal level) and relaxant activity (percent relaxation of histamine-inducedcontraction) of maximal concentrations of various receptor agonists.Each data point represents a mean of 3 to 10 experiments.

Relaxant effects of agonists on muscarinic and histamine-induced contractions. The potencies of the various agents for inhibiting histamine- and oxo-M-mediated contractions were compared. Only those agentsthat demonstrated significant relaxant effects (forskolin, isoproterenol,dopamine and cicaprost) were investigated. For these experiments,the isolated ileum was precontracted with either histamine (0.3µM) or oxo-M (40 nM). These concentrations were chosen becausethey reliably produced contractions of equal size. Over the courseof these studies, the estimates of the average tension ± S.E.M.(expressed in units of mass) elicited by histamine and oxo-M were3.20 ± 0.22 g and 3.33 ± 0.20 g, respectively (not statisticallydifferent, P = .67). Cumulative concentration-relaxation curveswere measured for each relaxing agent against histamine and oxo-M(fig. 3). The EC₅₀ value and maximal relaxant effect for eachagent are listed in table 4. In general, each agent was moreeffective at inhibiting histamine-induced contractions, comparedwith oxo-M-induced contractions. At high concentrations, forskolincaused complete inhibition of both histamine- and oxo-M-inducedcontractions. In contrast, the maximal relaxant effect of theother agents was always much less when oxo-M was used as the contractileagent, compared with histamine.

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Fig. 3. Concentration-response curves for relaxation by various agents (A-D) against contractions induced by 0.3 µM histamine ( $open circle$ )and 40 nM oxo-M ( $bullet$ ). Data are presented as the percent decreasein tension of the initial contraction. Each point represents themean ± S.E.M. of three experiments.

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TABLE 4
Relaxant potencies of various agents against histamine- and oxo-M-induced contractions

Contractile responses in 4-DAMP mustard-treated ilea. To determine whether the M₂ receptor could elicit an indirect contraction by preventing the relaxant effects of the variouscAMP-stimulating agents, we measured contractile responses tooxo-M in isolated ileum according to the experimental design shownin figure 4. In the first phase of the experiments (treatmentphase), the ileum is incubated with 4-DAMP mustard (40 nM) inthe presence of AF-DX 116 (1 µM) for 1 hr and then washed extensively(Thomas et al., 1993). This treatment inactivates most of theM₃ receptors without affecting the M₂ receptors. In the secondphase (test phase), the ileum is contracted with a nearly maximallyeffective concentration of histamine, and then a relaxant agentis added. After a stable relaxation is achieved, increasing concentrationsof oxo-M are added to the bath so that cumulative concentration-responsecurves can be measured. These test phase measurements are repeatedin the presence of AF-DX 116 to characterize the muscarinic receptorsubtypes mediating the contraction. Experiments carried out underthese conditions are shown in figure 5, B to E. In figure 5, thehorizontal lines denote the size of the contraction elicited byhistamine (0.3 µM) alone (upper line) and in combination withthe relaxant agent (lower line). A summary of EC₅₀ values andHill coefficients is found in table 5.

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Fig. 4. Schematic pen tracing illustrating the experimental protocol of the treatment and test phases when contractile responses aremeasured in ilea treated with 4-DAMP mustard.

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Fig. 5. Effects of AF-DX 116 on the contractile response to oxo-M in tissues treated with 4-DAMP mustard under standard conditions(A) and conditions of elevated cAMP (B-E). Except under standardconditions (A), ileal segments were contracted with histamine(0.3 µM) and relaxed with 10 µM forskolin (B), 1 µM isoproterenol(C), 10 µM dopamine (D) or 0.8 µM cicaprost (E) before oxo-M-inducedcontractions were measured. $bullet$ , Control; $open circle$ , 1 µM AF-DX 116. Inall experiments, tissues were treated with 4-DAMP mustard as describedin "Methods." Each point represents the mean ± S.E.M. of fourto eight experiments.

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TABLE 5
Effects of 1 µM AF-DX 116 on estimates of the EC₅₀ and Hill coefficient for oxo-M-induced contractions under standardconditions and conditions of elevated cAMP

For purposes of comparison, we first measured contractions under standard conditions, i.e., without first contracting withhistamine and relaxing with a relaxant agent. Under these conditions,oxo-M contracted the ileum with an EC₅₀ value of approximately22 nM. This contractile response is mediated by the M₃ receptor,as demonstrated by several investigators (Candell et al., 1990

;Eglen and Harris, 1993

). After 4-DAMP mustard treatment, oxo-Mwas still capable of eliciting a response under these conditions,but with 9-fold lower potency. Figure 5A shows the contractileresponses to oxo-M under standard conditions after 4-DAMP mustardtreatment. Under these conditions, AF-DX 116 (1.0 µM) caused a2.8-fold increase in the EC₅₀ value of oxo-M. This degree of shiftis consistent with an M₃ receptor-mediated contraction, as demonstratedby application of the simple competitive inhibition relationship:

K<SUB>B</SUB><IT>=</IT><FR><NU>[AF-DX<IT> 116</IT>]</NU><DE><IT>CR−1</IT></DE></FR>

(4)

in which K_B denotes the dissociation constant of AF-DX 116, and CR denotes the shift in the concentration-response curve(i.e., EC₅₀ value of oxo-M in the presence of AF-DX 116 dividedby that measured in the absence of AF-DX 116). Equation 4 yieldsan estimate of 6.26 for the pK_B value of AF-DX 116, which is inexcellent agreement with the binding affinity (K_d value) measuredin Chinese hamster ovary cells transfected with the M₃ subtypeof the muscarinic receptor (6.10) (Esqueda et al., 1996

). Whenforskolin (10 µM) was used as the relaxing agent, AF-DX 116 causeda 25-fold rightward shift of the oxo-M concentration-responsecurve, increasing the EC₅₀ from 16.3 nM to 473 nM and causinga change in the Hill coefficient from 1.0 to 1.9 (table 5; fig.5B). This degree of shift yields an estimate of 7.38 for the pK_Bvalue of AF-DX 116, which is in close agreement with the K_d valueof AF-DX 116 measured in Chinese hamster ovary cells transfectedwith the M₂ subtype (7.27) (Esqueda et al., 1996

). These resultsindicate that the M₂ receptor mediates the contractile responsein the presence of histamine and forskolin after 4-DAMP mustardtreatment. When tested in the same experimental paradigm but withother relaxant agents, AF-DX 116 usually caused shifts intermediatebetween those expected for M₂ receptor- and M₃ receptor-mediatedcontractions (table 5; fig. 5, C-E), suggesting that both M₂and M₃ receptors contribute to the contraction. However, whencicaprost was used as the relaxant agent, the antagonistic effectof AF-DX 116 (2.7-fold shift) was consistent with that expectedfor an M₃ response, with little or no contribution of the M₂ receptor.

The biphasic nature of the control isoproterenol curve (fig. 5C) is consistent with this notion. Therefore, we analyzed thiscurve according to a two-component model, by nonlinear regressionanalysis, as described in "Methods." Regression analysis showedthat the data were consistent with a two-component model havinghigh- and low-potency EC₅₀ values of 15.5 and 736 nM, respectively.The high-potency component accounted for 54% of the overall maximalresponse. In the presence of AF-DX 116 (1.0 µM), the high- andlow-potency EC₅₀ values were shifted 17.2- and 1.1-fold, respectively.These shifts are very similar to those expected for antagonismof M₂ (20-fold) and M₃ (2.26-fold) responses, assuming pK_d valuesof 7.27 and 6.1 for AF-DX 116 at M₂ and M₃ receptors, respectively(see eq. 4). Because errors in the estimates of parameters bynonlinear regression analysis are correlated, we analyzed eachcurve by setting the shift values for the high- and low-potencycomponents equal to values expected for antagonism of M₂-mediated(20-fold) and M₃-mediated (2.3-fold) responses, respectively.A summary of this analysis appears in table 5. The contributionof the M₂ component was greatest with forskolin (100%, 1.8 g)as the relaxant agent, intermediate with isoproterenol (39%, 1.6g) or dopamine (38%, 0.7 g) and least with cicaprost. The datawith cicaprost were not analyzed by a two-site model, becausethe antagonistic effect of AF-DX 116 (2.7-fold shift) was approximatelythe same as that observed under standard conditions (2.8-fold),consistent with the response being entirely mediated by the M₃receptor.

	Discussion

Top Abstract Introduction Methods Results Discussion References

Reddy et al. (1995) have demonstrated that a variety of agents, including beta adrenergic agonists and prostaglandins, stimulatecAMP accumulation in slices of the longitudinal muscle of theguinea pig ileum. Those investigators measured the cAMP responseto each agonist at a concentration of 10 µM and in the presenceof a low concentration of forskolin (0.1 µM), which enhanced thecAMP response. Among the compounds tested, PGE₁ elicited the largestincrease in cAMP over basal levels (5.3-fold). Intermediate increasesin cAMP were noted with PGE₂ (3.4-fold) and isoproterenol (3.0-fold),whereas the smallest increases were observed with VIP (2.3-fold),5-HT (1.7-fold) and the beta-3-selective agonist BRL 37344 (1.4-fold).In the present study, we observed a similar pattern of cAMP stimulationwith these agonists, although the absolute stimulation was about50% less, on average. This decrease can be attributed to the lackof forskolin (0.1 µM) in our assays, because Reddy et al. reportedthat forskolin enhanced the cAMP response to isoproterenol (10µM) by 40%. We also observed appreciable stimulation of cAMP bythe prostanoid derivative cicaprost (2.45-fold), PGI₂ (1.52-fold),the H₂ histamine agonist dimaprit (1.32-fold) and 5-MT (1.25-fold).

When measured in the presence of the highly efficacious muscarinic agonist oxo-M (1.0 µM), the cAMP accumulation elicitedby the various agonists was substantially inhibited. Presumably,this muscarinic inhibition is mediated by the M₂ receptor because,in both rat and guinea pig ileum, subtype-selective antagonistsblock the inhibition in a manner consistent with an M₂ response(Candell et al., 1990; Griffin and Ehlert, 1992; Reddy et al.,1995). In the present study, both basal and agonist-stimulatedcAMP accumulation was inhibited by oxo-M. To estimate that componentof the muscarinic inhibition that could be attributed to specificinhibition of agonist-stimulated cAMP accumulation, we subtractedthe appropriate basal values from the data, as described in "Methods,"before estimating the percentage inhibition. These calculationsyielded an estimate of 70% for the inhibition of forskolin-stimulatedcAMP accumulation by oxo-M. In contrast, oxo-M inhibited the cAMPaccumulation elicited by isoproterenol, PGE₁, PGE₂, dopamine,5-HT and VIP to a lesser extent (38, 20, 29, 26, 23 and 39%, respectively)and was without effect on the cAMP accumulation elicited by cicaprost,PGI₂, 5-MT or dimaprit. Thus, activation of M₂ muscarinic receptorsinhibits the increase in cAMP elicited by almost all of the agoniststested. In the rat ileum, M₂ receptors mediate inhibition of forskolin-and isoproterenol-stimulated cAMP accumulation but not that elicitedby PGE₁ or PGE₂ (Griffin and Ehlert, 1992). The different responsesof these two tissues may be due to the greater abundance of M₂receptors in the guinea pig ileum (Michel and Whiting, 1990; Candellet al., 1990).

In addition to cAMP, other mediators elicit relaxation in smooth muscle, including cyclic GMP, which may be stimulated eitherdirectly or indirectly (through nitric oxide synthase pathways).To identify agents that cause relaxation through cAMP, we measuredthe ability of the agents listed in table 1 to inhibit histamine-inducedcontractions, so that it would be possible to identify agentsshowing a positive correlation between cAMP accumulation and relaxation.Among the compounds tested, only forskolin, isoproterenol, cicaprostand dopamine caused appreciable relaxation. CGS-21680, 2-chloroadenosine,SKF-38393 and VIP elicited small inconsistent relaxations andother agents, such as PGE₁, PGE₂, PGI₂, 5-HT, 5-MT and dimaprit,caused small contractions, presumably due to their respectiveabilities to activate multiple receptor subtypes, including somecoupled to phosphoinositide hydrolysis. Among the relaxant agonists,there was a general correlation between the potential of agoniststo stimulate cAMP and their ability to cause relaxation, suggestingthat cAMP is the predominant mechanism for relaxation (fig. 2).One notable exception was cicaprost, the prostanoid IP receptor-selectiveagonist, which caused proportionately greater cAMP accumulationthan relaxation. Lawrence et al. (1992) characterized prostanoidreceptors in the guinea pig ileum and found that the IP receptoris implicated in direct smooth muscle relaxation and, to a lesserextent, neuronal stimulation of acetylcholine release. Indeed,in our experiments with cicaprost, a small contractile componentfrequently preceded relaxation. This effect accounts for the factthat cicaprost caused less relaxation than predicted from itspotential to stimulate cAMP accumulation.

It is well established that isoproterenol is more effective at inhibiting histamine-induced contractions in the trachea, comparedwith those elicited by muscarinic agonists (Van Amsterdam et al.,1989; Roffel et al., 1993). To explain the differential effectsof isoproterenol, Torphy et al. (1983) suggested that muscarinicinhibition of adenylyl cyclase protects the muscarinic contractilemechanism from the cAMP-mediated relaxant effects of isoproterenol.It is now known, of course, that inhibition of adenylyl cyclaseand stimulation of contractions are mediated by two differentmuscarinic receptors (i.e., M₂ and M₃ receptors, respectively)(Peralta et al., 1988; Candell et al., 1990). Histamine lacksthis two-pronged mechanism, so its contractile response is moresensitive to the relaxant effects of isoproterenol. Although directevidence for a role of the M₂ receptor in inhibiting the relaxanteffects of isoproterenol on M₃-mediated contractions in the tracheaand ileum has been obtained by several investigators (Thomas etal., 1993; Watson et al., 1995), it is unclear whether the M₂mechanism is the only mechanism that accounts for the differentialrelaxant effects of isoproterenol (Roffel et al., 1995). We choseto compare the relaxant potential of the various cAMP-stimulatingagents against histamine- and oxo-M-induced contractions, to obtaina simple measure of whether the M₂ receptor diminished the relaxanteffect of the agent. If an agent was more effective at inhibitinghistamine-induced contractions, compared with those elicited byoxo-M, then a role for the M₂ receptor might be inferred. Thegreatest differential relaxant effects were noted with forskolin,isoproterenol and dopamine, whereas little or no discriminationwas noted with cicaprost (fig. 3). Oxo-M inhibition of cAMP levelsstimulated by each of these agents (table 1) followed a similarpattern. Thus, there appears to be at least a rough correlationbetween the extent to which the M₂ receptor inhibits the cAMPaccumulation elicited by a drug and the extent to which the drugdisplays differential relaxant effects.

In examining the data shown in figure 3, it becomes apparent that there is no simple way to quantify the differential relaxanteffects of the various agents. Forskolin exhibited a 6-fold differencein relaxant potency between histamine and oxo-M but no changein maximal response, whereas the other agents showed differencesin both potency and maximal response. If the mechanism for thereduced relaxant activity in the presence of oxo-M is caused byM₂-mediated inhibition of cAMP accumulation, then, in the presenceof oxo-M, relaxing agents should behave as if they are less efficaciousat stimulating cAMP accumulation, and hence relaxation. A usefulmeasure of the apparent decrease in intrinsic efficacy is thedegree of receptor inactivation that would cause an equivalentloss of activity. We have used the term "stimulus inactivation"to denote this decrement in relaxant activity against oxo-M-inducedcontractions, and we have described a means of calculating thisparameter in the "Appendix." Table 4 lists our estimates of thisparameter. It can seen that there is a rough correlation betweenthe ability of oxo-M to inhibit both the relaxant stimulus andthe cAMP accumulation elicited by the various agents. Interestingly,this correlation becomes closer if the inhibition of cAMP accumulationis calculated by subtracting the control basal value (1.0-fold)from both the stimulated and inhibited values before calculatingthe percentage inhibition by oxo-M. When calculated in this manner,the oxo-M inhibition of the cAMP accumulation stimulated by forskolin(73%), isoproterenol (61%), dopamine (110%) and cicaprost (29%)is in agreement with the degree to which oxo-M inhibits the relaxantstimulus generated by the agents (82, 68, 93 and 4%, respectively).

As described above, forskolin was able to cause complete inhibition (100%) of both histamine- and oxo-M-induced contractions,whereas isoproterenol, dopamine and cicaprost showed reduced maximalresponses against oxo-M, relative to histamine. This behaviorcan be rationalized with the relationship between relaxation andcAMP levels shown in figure 2. It can be seen that complete relaxation(100%) of histamine-induced contractions occurs when cAMP levelsare stimulated approximately 2.5-fold over basal. Even thoughoxo-M inhibited forskolin-stimulated cAMP levels by 70%, the residuallevel of cAMP in the presence of forskolin and oxo-M (4.5-foldover basal) (table 1) still exceeded that required for maximalrelaxation. In contrast, the cAMP levels elicited by isoproterenol,dopamine and cicaprost in the presence of oxo-M (1.59-, 0.96-and 2.03-fold, respectively) (table 1) were insufficient to causecomplete relaxation.

To further explore the role of the M₂ receptor in opposing smooth muscle relaxation, we used the novel method outlined infigure 4, which was previously developed in our laboratory (Thomaset al., 1993). We first inactivated M₃ receptors with the irreversiblealkylating agent 4-DAMP mustard and then measured responses toa muscarinic agonist in the presence of histamine and a relaxingagent. When forskolin was used as the relaxant agent, the K_B valuesof AF-DX 116, methoctramine, p-fluorohexahydrosiladifenidol andpirenzepine were in good agreement with their respective bindingaffinities for native and cloned M₂ receptors but much differentfrom those reported for the M₁, M₃, M₄ and M₅ subtypes (Ehlertand Thomas, 1995; Esqueda et al., 1996). Thus, under the conditionsof the experiment, oxo-M acts through the M₂ receptor to releasethe brake that forskolin has put on histamine-induced contractions.Thomas et al. (1993) and Reddy et al. (1995) have used this strategyto show that the M₂ receptor also opposes the relaxant effectof isoproterenol on histamine-induced contractions in the guineapig ileum. In this study, we have reexamined forskolin and isoproterenol,so that data on contractions and cAMP accumulation could be comparedfor a group of relaxant agents.

When forskolin was used as the relaxing agent under the experimental conditions shown in figure 4, AF-DX 116 (1.0 µM) shiftedthe concentration-response curve for oxo-M to the right 25-fold,in a manner consistent with simple competition at an M₂ muscarinicreceptor. The calculated K_B value (7.38) was nearly the same asthe estimate of the binding affinity of AF-DX 116 for the clonedM₂ receptor (7.27) when measured in modified KRB buffer (Esquedaet al., 1996). The maximal response of oxo-M was only about 55%of that of the histamine-induced contraction, suggesting thatthe M₂ receptor cannot fully oppose the inhibitory effect of forskolinon histamine-induced contractions. When isoproterenol was usedas the relaxant agent during the test phase, the concentration-responsecurve of oxo-M had a low slope and appeared biphasic, suggestinghigh- and low-potency components. AF-DX 116 simplified the curveby causing a greater apparent competition at the high-potencycomponent. We reasoned that at low concentrations oxo-M was actingthrough the AF-DX 116-sensitive M₂ receptor to disinhibit histamine-inducedcontractions, whereas at high concentrations oxo-M might be elicitingcontractions through M₃ receptors not inactivated by 4-DAMP mustard.The contribution of the M₃ receptor could account for the largemaximal response, which frequently exceeded the histamine-inducedcontraction, although these did not differ statistically. Consequently,we analyzed the data according to a two-component model, assumingthat AF-DX 116 (1.0 µM) should cause shifts of 20- and 2.3-foldin the M₂ and M₃ components of the concentration-response curve,respectively. Regression analysis yielded estimates of the sizeof the M₂ component when the different relaxing agents were used.The size of the M₂ component of the contractile response appearsto be related to the amount of the relaxation induced by the specificrelaxant agent and the extent to which the M₂ receptor inhibitedthe increase in cAMP elicited by the agent. When expressed inmass equivalents, the maximal contractile responses of the M₂components were 1.8 and 1.6 g when forskolin and isoproterenolwere used as relaxing agents, respectively. No M₂ component wasapparent when cicaprost was used as the relaxant agent, in agreementwith the one-site analysis, where the shift induced by AF-DX 116was in close agreement with an M₃ response. These estimates correlateroughly with the extent to which oxo-M inhibited the cAMP accumulationelicited by forskolin (70%), isoproterenol (38%) and cicaprost(5%). Although oxo-M caused a 26% inhibition of dopamine-stimulatedcAMP accumulation, dopamine elicited a relatively small relaxation,so that the M₂ component of the response was only 0.7 g. Collectively,these data show general agreement between the extent to whichactivation of the M₂ receptor opposes the ability of a drug tostimulate cAMP accumulation and its ability to inhibit histamine-inducedcontractions.

When forskolin was used as the relaxing agent during the test phase, the concentration-response curve of oxo-M was relativelysimple and lacked the low-potency M₃ component characteristicof the data collected with the other relaxant agents. It seemslikely that the higher levels of cAMP elicited by forskolin mayhave completely suppressed M₃-mediated contractions already greatlyinhibited by 4-DAMP mustard.

The potency of oxo-M for eliciting contractions through the M₂ mechanism is very high. More specifically, when measured duringthe test phase in the presence of different relaxant agents, theEC₅₀ values of the M₂ component were in the range of 8 to 16 nM.In contrast, the EC₅₀ value of oxo-M for eliciting contractionsthrough the M₃ receptor under standard conditions was approximately30 to 40 nM. Moreover, after 4-DAMP mustard treatment, the EC₅₀value of the standard contractile response was increased to 207nM. Thus, even after the M₃ response has been greatly suppressed,oxo-M can elicit contractions through the M₂ mechanism with about20-fold greater potency, underscoring the significance of thisphenomenon.

When measured under the conditions of the test phase, M₂-mediated contractions were most easily detected when forskolin wasused as the relaxing agent. Under these conditions, the contractileresponse to oxo-M yielded a relatively simple concentration-responsecurve that was shifted to the right 25-fold in the presence ofthe M₂-selective antagonist AF-DX 116 (1.0 µM). When the otherrelaxant agents were used, the M₃ receptor contributed to thecontractile response, thereby diminishing the relative contributionof the M₂ receptor and making it more difficult to detect theM₂ component of the response. These observations correlate generallywith our measurements of cAMP. Forskolin caused by far the largestincrease in cAMP accumulation, and oxo-M inhibited forskolin-stimulatedcAMP levels by 70%. In contrast, oxo-M inhibited isoproterenol-stimulatedcAMP accumulation by only 38% and the cAMP levels elicited bythe other agents by less. We previously suggested (Thomas andEhlert, 1996) that these observations might explain, in part,why it was possible to measure an M₂-mediated inhibition of therelaxant effect of forskolin, but not isoproterenol, on histamine-inducedcontractions of the trachea (Watson et al., 1995). Detecting arole for the M₂ receptor in inhibiting the relaxant effects ofisoproterenol in the trachea may be easier when more M₃ receptorsare selectively inactivated. Regardless, M₂ receptors have beenshown to inhibit the relaxant effects of forskolin on M₃-mediatedcontractions of the trachea (Thomas and Ehlert, 1996). Differencesin the contractile effects of the M₂ receptor in different tissuesmight also be explained by a variation in the density and couplingefficiency of the receptor. A decrease in the latter might accountfor our inability to measure an M₂-mediated inhibition of therelaxant effect of forskolin on histamine-induced contractionsof the rat fundus and guinea pig esophagus (Thomas and Ehlert,1996).

In summary, our results confirm that the M₂ receptor has the role of inhibiting the relaxant effects of agents that increasecAMP in the guinea pig ileum. The involvement of the M₂ receptorin this role depends upon the amount of cAMP elicited by the agentand the extent to which the M₂ receptor opposes the increase incAMP.

	Footnotes

Accepted for publication September 10, 1996.

Received for publication April 15, 1996.

¹ This work was supported by National Institutes of Health Grant NS30882.

Send reprint requests to: Frederick J. Ehlert, Ph.D., Department of Pharmacology, College of Medicine, University of California, Irvine, Irvine, CA 92717.

	Abbreviations

AF-DX 116, [[2-[(diethylamino)methyl]-1-piperidinyl]acetyl]-5,11-dihydro-6H-pyrido[2,3b][1,4]benzodiazepine-6-one; cAMP, cyclic AMP; 4-DAMP mustard, N-(2-chloroethyl)-4-piperidinyl diphenylacetate; 5-HT, 5-hydroxytryptamine; KRB, Krebs Ringer bicarbonate; 5-MT, 5-methoxytryptamine; oxo-M, oxotremorine-M; PGE₁, prostaglandin E₁; PGE₂, prostaglandin E₂; PGI₂, prostaglandin I₂; VIP, vasoactive intestinal peptide.

	Appendix

A method for estimating the extent to which oxo-M reduced the effectiveness of the various relaxant agents is described below.In the absence of oxo-M, the relationship between the relaxantresponse against histamine-induced contractions (y_h) and the concentrationof the relaxant agent (X) can be described by the following equationof Furchgott:

yh<IT>=f </IT><FENCE><FR><NU><IT>eXR</IT>T</NU><DE><IT>X+K</IT><IT>d</IT></DE></FR></FENCE> (A1)

In equation A1, e denotes the intrinsic efficacy of the relaxant agent, R_T denotes the total receptor concentration, K_d denotesthe dissociation constant of the relaxant agent for its receptorand f denotes the function describing the relationship betweenthe stimulus and the response (i.e., stimulus = occupancy × intrinsicefficacy). In the case of forskolin, K_d denotes the dissociationconstant of forskolin for its site on adenylyl cyclase. In thepresence of oxo-M, we propose that the relaxant response is reducedbecause oxo-M inhibits the cAMP accumulation elicited by the relaxantagent. Although oxo-M does not directly affect the intrinsic efficacyof the relaxant agent, it does make the agent behave as if ithas reduced intrinsic efficacy. Thus, in the presence of oxo-M,the relaxant response (y_o) can be described by

yo<IT>=f </IT><FENCE><FR><NU><IT>qeX′R</IT>T</NU><DE><IT>X′+K</IT><IT>d</IT></DE></FR></FENCE> (A2)

in which X $'$ denotes the concentration of the relaxant agent when oxo-M is used as the contractile agent and q denotes theapparent factor by which the intrinsic efficacy has been reduced.In the text, we refer to q as "stimulus inactivation." To calculateq, equivalent degrees of relaxation are compared in the presenceof histamine and oxo-M:

f <FENCE><FR><NU>eXRT</NU><DE><IT>X+K</IT><IT>d</IT></DE></FR></FENCE><IT>=f </IT><FENCE><FR><NU><IT>qeX′R</IT>T</NU><DE><IT>X′+K</IT><IT>d</IT></DE></FR></FENCE> (A3)

Rearranging and taking the logarithm of both sides yields:

log<IT>X=</IT>log<FENCE><FR><NU><IT>X′qK</IT><IT>d</IT></NU><DE><IT>Kd+</IT>(<IT>1−q</IT>)<IT>X′</IT></DE></FR></FENCE> (A4)

Nonlinear regression analysis was used to fit the equation shown above to the relaxation data to obtain estimates of q andK_d. Estimates of the concentration of relaxant agent (X) wereinterpolated from the histamine relaxation curve that yieldedresponses equivalent to those generated by the relaxant agentat concentration X $'$ when oxo-M was used as the contractile agent.This analysis is analogous to the method of Furchgott (1966),as described previously (Ehlert, 1986).

	References

Top Abstract Introduction Methods Results Discussion References

Berridge, M. J.: The interaction of cyclic nucleotides and calcium in the control of cellular activity. Adv. Cyclic Nucleotide Res. 6: 1-98, 1975[Medline].
Candell, L. M., Yun, S. H., Tran, L. L. P. and Ehlert, F. J.: Differential coupling of subtypes of the muscarinic receptor to adenylate cyclase and phosphoinositide hydrolysis in the longitudinal muscle of the rat ileum. Mol. Pharmacol. 38: 689-697, 1990[Abstract].
Dörje, F., Levey, A. I. and Brann, M. R.: Immunological detection of muscarinic receptor subtype proteins (m1-m5) in rabbit peripheral tissues. Mol. Pharmacol. 40: 459-462, 1991[Abstract].
Eglen, R. M. and Harris, G. C.: Selective inactivation of muscarinic M₂ and M₃ receptors in guinea-pig ileum and atria in vitro. Br. J. Pharmacol. 190: 946-952, 1993.
Eglen, R. M., Michel, A. D. and Whiting, R. L.: Characterization of the muscarinic receptor subtype mediating contractions of the guinea pig uterus. Br. J. Pharmacol. 96: 497-499, 1989[Medline].
Eglen, R. M., Reddy, H., Watson, N. and Challiss, R. A. J.: Muscarinic acetylcholine receptor subtypes in smooth muscle. Trends Pharmacol. Sci. 15: 114-119, 1994[Medline].
Ehlert, F. J.: Coupling of muscarinic receptors to adenylate cyclase in the rabbit myocardium: Effects of receptor inactivation. J. Pharmacol. Exp. Ther. 240: 23-30, 1986[Abstract/Free Full Text].
Ehlert, F. J., Delen, F. M., Yun, S. H., Friedman, D. J. and Self, D. W.: Coupling of subtypes of the muscarinic receptor to adenylate cyclase in the corpus striatum and heart. J. Pharmacol. Exp. Ther. 251: 660-671, 1989[Abstract/Free Full Text].
Ehlert, F. J. and Thomas, E. A.: Functional role of M₂ muscarinic receptors in the guinea pig ileum. Life Sci. 56: 965-971, 1995[Medline].
Esqueda, E. E., Gerstin, E. H., Griffin, M. T. and Ehlert, F. J.: Stimulation of cAMP accumulation and phosphoinositide hydrolysis by M₃ muscarinic receptors in the rat peripheral lung. Biochem. Pharmacol. 52: 643-658, 1996[Medline].
Fernandes, L. B., Fryer, A. D. and Hirshman, C. A.: M₂ muscarinic receptors inhibit isoproterenol-induced relaxation of canine airway smooth muscle. J. Pharmacol. Exp. Ther. 262: 119-126, 1992[Abstract/Free Full Text].
Furchgott, R. F.: The use of $beta$ -haloalkylamines in the differentiation of receptors and in the determination of dissociation constants of receptor-agonist complexes. Adv. Drug Res. 3: 21-55, 1966.
Gies, J. P., Bertrand, C., Vanderheyden, P., Waeldele, F., Dumont, P., Pauli, G. and Landry, Y.: Characterization of muscarinic receptors in human, guinea pig and rat lung. J. Pharmacol. Exp. Ther. 250: 309-315, 1989[Abstract/Free Full Text].
Giraldo, E., Viganó, M. A., Hammer, R. and Ladinsky, H.: Characterization of muscarinic receptors in guinea pig ileum longitudinal smooth muscle. Mol. Pharmacol. 33: 617-625, 1988[Abstract].
Gomez, A., Martos, F., Bellido, I., Marquez, E., Gargia, A. J., Pavia, J. J. and Sanchez De La Cuesta, F.: Muscarinic receptor subtypes in human and rat colon smooth muscle. Biochem. Pharmacol. 43: 2413-2419, 1992[Medline].
Grandordy, B. M., Mak, J. C. W. and Barnes, P. J.: Modulation of airway smooth muscle $beta$ -adrenoceptor function by a muscarinic agonist. Life Sci. 54: 185-191, 1994[Medline].
Griffin, M. T. and Ehlert, F. J.: Specific inhibition of isoproterenol-stimulated cyclic AMP accumulation by M₂ muscarinic receptors in rat intestinal smooth muscle. J. Pharmacol. Exp. Ther. 263: 221-225, 1992[Abstract/Free Full Text].
Kurose, H., Katada, T., Amano, T. and Ui, M.: Specific uncoupling by islet-activating protein, pertussis toxin, of negative signal transduction via alpha-adrenergic, cholinergic, and opiate receptors in neuroblastoma × glioma hybrid cells. J. Biol. Chem. 258: 4870-4875, 1983[Abstract/Free Full Text].
Lawrence, R. A., Jones, R. L. and Wilson, N. H.: Characterization of receptors involved in the direct and indirect actions of prostaglandins E and I on the guinea-pig ileum. Br. J. Pharmacol. 105: 271-278, 1992[Medline].
Maeda, A., Kubo, T., Mishina, M. and Numa, S.: Tissue distribution of mRNAs encoding muscarinic acetylcholine receptor subtypes. FEBS Lett. 239: 339-342, 1988[Medline].
Michel, A. D. and Whiting, R. L.: Methoctramine reveals heterogeneity of M2 muscarinic receptors in longitudinal ileal smooth muscle membranes. Eur. J. Pharmacol. 145: 305-311, 1988[Medline].
Michel, A. D. and Whiting, R. L.: The binding of [³H]4-diphenylacetoxy-N-methylpiperidine methiodide to longitudinal ileal smooth muscle muscarinic receptors. Eur. J. Pharmacol. 176: 197-205, 1990[Medline].
Monferini, E., Giraldo, E. and Ladinsky, H.: Characterization of the muscarinic receptor in the rat urinary bladder. Eur. J. Pharmacol. 147: 453-458, 1988[Medline].
Noronha-blob, L., Lowe, V., Patton, A., Canning, B., Costello, D. and Kinnier, W. J.: Muscarinic receptors: Relationships among phosphoinositide breakdown, adenylate cyclase inhibition, in vitro detrusor muscle contractions and in vivo cystometrogram studies in guinea pig bladder. J. Pharmacol. Exp. Ther. 249: 843-851, 1989[Abstract/Free Full Text].
Peralta, E. G., Ashkenazi, A., Winslow, J. W., Ramachandran, J. and Capon, D. J.: Differential regulation of PI hydrolysis and adenylyl cyclase by muscarinic receptor subtypes. Nature (Lond.) 334: 434-437, 1988[Medline].
Pyne, N. J., Grady, M. W., Shehnaz, D., Stevens, P. A., Pyne, S. and Rodger, I. W.: Muscarinic blockade of $beta$ -adrenoceptor-stimulated adenylyl cyclase: The role of stimulatory and inhibitory guanine-nucleotide binding regulatory proteins (G_s and G_i). Br. J. Pharmacol. 107: 881-887, 1992[Medline].
Rang, H. P.: Stimulant actions of volatile anaesthetics on smooth muscle. Br. J. Pharmacol. 22: 356-365, 1964[Medline].
Reddy, H., Watson, N., Ford, A. P. D. W. and Eglen, R. M.: Characterization of the interaction between muscarinic M₂ receptors and $beta$ -adrenergic subtypes in guinea pig isolated ileum. Br. J. Pharmacol. 114: 49-56, 1995[Medline].
Roffel, A. F., Meurs, H., Elzinga, C. R. S. and Zaagsma, J.: Muscarinic M2 receptors do not participate in the functional antagonism between methacholine and isoprenaline in guinea pig tracheal smooth muscle. Eur. J. Pharmacol. 249: 235-238, 1993[Medline].
Roffel, A. F., Meurs, H., Elzinga, C. R. S. and Zaagsma, J.: No evidence for a role of muscarinic M₂

M2 Muscarinic Receptor Inhibition of Agonist-induced Cyclic Adenosine Monophosphate Accumulation and Relaxation in the Guinea Pig Ileum1

M₂ Muscarinic Receptor Inhibition of Agonist-induced Cyclic Adenosine Monophosphate Accumulation and Relaxation in the Guinea Pig Ileum¹