Postsynaptic enhancement by motilin of muscarinic receptor cation currents in duodenal smooth muscle

Kazunori Yamada, Hiroe Yanagida, Yushi Ito, and Ryuji Inoue

Department of Pharmacology, Faculty of Medicine, Kyushu University, Fukuoka 812-82, Japan

    ABSTRACT
Top
Abstract
Introduction
Methods
Results
Discussion
References

We have investigated a potential role of motilin in amplifying the postsynaptic muscarinic responses in the rabbit duodenal smooth muscle cells, using the whole cell variant of patch-clamp technique. Stimulation of motilin receptors by exogenously applied motilin (1 nM) resulted in a large increase in carbachol (CCh)-induced atropine-sensitive cation current (ICCh) at threshold concentrations of CCh (0.3-1 µM) at 30°C. This potentiation was abolished in the presence of a specific blocker of motilin receptor (GM109) and was attenuated with increased concentrations of either motilin or CCh, being virtually absent with maximally effective concentrations of these agonists. Motilin failed to potentiate ICCh when the ambient temperature was reduced to 20°C or if the cation current had been directly activated by internal perfusion with guanosine 5'-O-(3-thiotriphosphate) (50 µM) bypassing the muscarinic receptor. These results suggest that some biochemical processes, such as enzymatic reactions, might be involved in the motilin-induced potentiation and that its site of action might be the muscarinic receptor and/or associated G proteins.

cation channel; gut smooth muscle; migrating motor complex

    INTRODUCTION
Top
Abstract
Introduction
Methods
Results
Discussion
References

MOTILIN HAS BEEN IMPLICATED as a gut peptide hormone in initiating an intermittent migrating motor complex in the fasting gut (14, 27). This has been supported by the observation that the plasma motilin levels fluctuate in synchrony with the interdigestive migrating motor complex, but stay depressed during a postprandial period, and that intravenous administration of motilin or several erythromycin derivatives that are motilin agonists can induce a similar motor complex (10). There is, however, substantial evidence that in in vivo experiments the motor complex provoked by intravenous administration of motilin or its analogs is exclusively susceptible to muscarinic receptor and ganglion blockade by atropine and hexamethonium, respectively, and that functional or mechanical removal of vagal inputs greatly diminishes such actions of motilin (19, 20, 27). Although considerable variations have been found in the actions of motilin, depending on the region of the gut and the species used, and some involvement of nonvagal and nonneural pathways has also been postulated (8, 27), these results strongly point to the importance of cholinergic (vagal) nerves in the motilin-initiated gut motor activity in vivo.

In contrast, as well recognized in in vitro experiments, anticholinergic agents or the axonal conduction blocker (tetrodotoxin) has been found to exert little effect on the contraction of isolated muscle strips elicited by exogenously applied motilin (1, 25, 26, 29). Thus the in vitro results rather favor a direct action of motilin via the postsynaptic motilin receptors on gut smooth muscle. This possibility has recently been confirmed in patch-clamp experiments using single cells dissociated from the rabbit duodenal smooth muscle (29). In this study it has been demonstrated that in addition to causing Ca2+ release from internal stores and depressing the voltage-dependent Ca2+ currents, motilin is capable of activating monovalent-cation selective, voltage-independent, and Ca2+-independent channels (29), the properties of which are largely different from those of voltage-dependent divalent cation-permeable cation channels that are linked to the muscarinic receptor via a pertussis toxin-sensitive G protein and are ubiquitously found in the whole gut (muscarinic cation channels; 2, 5, 12, 17).

In the present study we have attempted to reconcile these apparently discrepant results. We have used single dissociated cells from the rabbit duodenal smooth muscle combined with the patch-clamp technique, which helps us to eliminate possible contamination or interactions with nonmuscle factors. As the result of this work, we have found that at least one of the excitatory effects of the cholinergic system on rabbit duodenal smooth muscle, activation of muscarinic cation channels, can be effectively amplified by a preceding stimulation of motilin receptors on the myocyte.

    METHODS
Top
Abstract
Introduction
Methods
Results
Discussion
References

Materials and cell dispersion. Albino rabbits of either sex, weighing 1.5-2 kg (Nihon White), were exsanguinated under anesthesia with intravenous pentobarbital. A cylindrical segment of duodenum (about 5 cm from the pylorus) was excised. A plastic pole (about 1 cm in diameter and 10 cm in length) was inserted through the lumen of the cylindrical segment, the ends of which were fixed tightly on the pole using thin silk threads. The segment of duodenum was successively incubated at 35°C in Ca2+-free physiological salt solution (for composition, see below) for 10-20 min until the whole segment became fully relaxed and then in Ca2+-free physiological salt solution containing 2 mg/ml collagenase (type I, 250 U/mg) at 35°C for 20-25 min. The digested segment was cut open longitudinally and stored in a refrigerator in 0.5 mM Ca2+-containing Krebs solution supplemented with 1 mg/ml fat-free bovine serum albumin and 1 mg/ml soybean trypsin inhibitor. Single cells were dispersed just before use (within 6 h after enzymatic digestion), by gently triturating, with a blunt-tipped Pasteur pipette, minced pieces of digested longitudinal muscle that had mechanically been peeled off from the mucosa with fine forceps. The recording system used for the patch-clamp experiments was essentially the same as described previously (29). Briefly, to generate voltage pulse or ramp commands, or to amplify the current signal sampled from the clamped cells, an Axopatch 1-C amplifier (Axon Instruments) was used in conjunction with an analog-to-digital, digital-to-analog converter (MacLab/4; AD Instruments, New South Wales, Australia), which was run under the software Chart v.3. Cell capacitance and series resistance (<15 MOmega ) were not compensated. To record long-lasting events, the data were digitized and stored on videotape after pulse code modulation (PCM-501ES, Sony, Tokyo, Japan). For illustration and data analysis, a Macintosh computer (Performa 575) and its standard attached softwares (Microsoft Excel v.4.0; KleidaGraph v.3.04; MacDraw Pro v.1.5) were used. To minimize errors arising from the noisy fluctuating nature of carbachol (CCh)- or motilin-induced currents when determining the current amplitude, the current traces were averaged over a period of at least 2 s before and after the application of agonists.

Solutions. We had confirmed in preliminary experiments that CCh- and motilin-induced inward currents in rabbit duodenal smooth muscle are mainly cationic, as has been reported for other parts of the intestine (2, 12, 17). Thus, to facilitate more selective recording of a cationic current component, high Cs+, low Cl- solution was loaded into the cell (for composition, see below), and the membrane was clamped close to the predicted equilibrium potential of Cl- (-45 mV). Liquid junction potentials arising at the interface between the bathing and internal solutions were measured as described elsewhere (ca. 6 mV; Ref. 28), and corrected a posteriori. The temperature of the bathing solution was kept at 30-31°C (higher temperatures resulted in progressive cell deterioration), except for the experiments shown in Fig. 6. The composition of modified Krebs solution was (in mM) 137 Na+, 5.5 K+, 1.2 Mg2+, 2 Ca2+, 132.2 Cl-, 15.5 HCO<SUP>−</SUP><SUB>3</SUB>, 1.1 H<SUB>2</SUB>PO<SUP>−</SUP><SUB>4</SUB>, and 11.9 glucose, continuously aerated with 95% O2 and CO2. The composition of Ca2+-free cell dispersing solution was (in mM) 140 Na+, 5 K+, 1.2 Mg2+, 147.4 Cl-, 11.9 glucose, and 10 N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES), adjusted at pH 7.35-7.4 with tris(hydroxymethyl)aminomethane (Tris) base. The composition of high Cs+, low Cl- internal solution was (in mM) 130 Cs+, 2 Mg2+, 20 Cl-, 110 aspartate-, 2 SO<SUP>2−</SUP><SUB>4</SUB>, 2 Na2ATP, 5 creatine phosphate (Tris salt), 10 ethylene glycol-bis(beta -aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA), 4 Ca2+, and 10 HEPES, titrated to 7.2 with Tris base.

Chemicals. HEPES and EGTA was purchased from Dojin (Kumamoto, Japan), CCh and porcine motilin from Sigma, and GM109 was a kind gift from Chugai Pharmaceutical.

Statistics. All data are expressed as means ± SE, and statistical significance was evaluated by paired or unpaired t-test with criteria given in each figure.

    RESULTS
Top
Abstract
Introduction
Methods
Results
Discussion
References

Figure 1A demonstrates examples of inward currents induced at -50 mV, in response to CCh added to the bath (1 and 10 µM). Activation of the inward currents, which was strongly attenuated after 4-6 h of pretreatment with pertussis toxin (1 µg/ml, 36°C; data not shown), occurred in a dose-dependent manner with a threshold as low as 0.3 µM (Fig. 1B). Empirical fitting of this dose dependence with a Hill-type equation indicated that the half-maximal activation of the currents occurs at 9 µM with a cooperative coefficient of about 1 (Fig. 1B). These results, in addition to other biophysical features of the currents such as a U-shape, voltage dependence, and reversal potential close to 0 mV under the conditions in which K+ and Cl- currents are suppressed (inset in Fig. 2; for ionic conditions see METHODS), strongly suggest that the channels underlying these inward currents may be related to the pertussis toxin-sensitive G protein-coupled, voltage-dependent cation channel family that includes the muscarinic receptor-operated channel, which is the main regulator of membrane excitability in the mammalian gut smooth muscle (2, 5, 11, 17, 18, 23).


View larger version (16K):
[in this window]
[in a new window]
 
Fig. 1.   Dose-response relationship of carbachol (CCh) concentration vs. CCh-induced inward current (ICCh). Bath and pipette contained physiological salt solution and high Cs+, low Cl- internal solutions, respectively. Holding potential (HP) was set to -50 mV. A: actual records of ICCh induced by 2 different concentrations of CCh (1 and 10 µM). CCh was added to bath at bars. Rate of solution change was estimated to be ~10 s by switching from physiological salt solution to excess K+ bathing solution. B: peak amplitude of ICCh at -50 mV plotted against CCh concentration. Symbols and vertical bars indicate means ± SE obtained from 5 to 20 cells. Smooth solid curve represents best nonlinear least-square fit of data points with Hill equation, Imax/[1 + (Kd/[CCh])n], where Imax, Kd, and n denote amplitude of maximally activated ICCh, half-maximal activating CCh concentration, and cooperative coefficient, respectively.


View larger version (26K):
[in this window]
[in a new window]
 
Fig. 2.   Current-voltage relationship (I-V curve) of CCh- and motilin-induced inward currents. Recording conditions were the same as in Fig. 1, except that slow-rising voltage ramps (-100-50 mV, 2 s) were applied, which appear in Figs. 1, and 3-5, as vertical deflections. To avoid contamination with voltage-dependent Ca2+ currents, 1 µM nicardipine was added to bath. CCh- or motilin-sensitive currents (inset) are defined as difference between net membrane currents in presence (solid curves) and absence (control, dotted curve) of CCh (100 µM) or motilin (10 nM), respectively (see Ref. 29).

Stimulation of motilin receptor (0.1-100 nM), preceding the application of CCh, which itself induces a monovalent cation-selective, voltage-independent current (IMot; also see the inset in Fig. 2 and Ref. 29), caused a pronounced enhancement of inward current induced in response to CCh (ICCh). In the example shown in Fig. 3A, a more than fivefold increase in the amplitude of ICCh was achieved after the application of motilin (i.e., the inward component superimposed on IMot). The enhancing effect of motilin on ICCh was, however, not consistently observed in all cells tested. Of 86 cells tested, about one-half (41 cells) exhibited clear enhancement; the other cells showed no increase or even a slight decrease. This apparent inconsistency could not be accounted for by contamination with nonmuscle cells such as neurons, because almost all cells yielded by our dispersion procedure had the spindle-shaped appearance typical of smooth muscle cells and contracted rapidly to acetylcholine. Variable cell surface damage during the course of enzymatic digestion and time-dependent rundown of ICCh due to internal dialysis might contribute to the diversity of the results or differing distributions of motilin or muscarinic receptors on the rabbit duodenal smooth muscle.


View larger version (30K):
[in this window]
[in a new window]
 
Fig. 3.   Selective augmentation of ICCh by motilin. Experimental conditions are same as in Fig. 1. A: CCh (0.3 µM) was applied before and about 7 min after application of 1 nM motilin. Note that amplitude of ICCh was greatly increased in presence of 1 nM motilin. B: pretreatment with 1 µM atropine abolished effect of 1 µM CCh to produce inward current in presence of 1 nM motilin. C: 100 nM GM109 antagonized enhancing effect of motilin (1 nM) on ICCh. Very small current fluctuations observed during application of GM109 are likely to be artifacts of solution change. Traces in A-C are representative of 4-5 different experiments.

The enhanced ICCh seen when superimposed on IMot is likely to be a genuine CCh current, because atropine (1 µM) selectively abolished the current component induced by CCh without affecting IMot, and conversely GM109, a specific antagonist of motilin (26), antagonized the increasing effect of motilin on ICCh (Fig. 3, B and C). Furthermore, the enhanced current maintained its characteristic U-shaped current-voltage relationship in the inward portion (Fig. 4C; Refs. 2, 5, 16, 18), whereas that of IMot is nearly ohmic in the corresponding portion of membrane potential (compare with Fig. 2), as has already been reported (29). These results strongly suggest that the "enhanced ICCh" is the result of selective potentiation of the muscarinic receptor-activated cation current.


View larger version (23K):
[in this window]
[in a new window]
 
Fig. 4.   Motilin-induced ICCh potentiation is inversely proportional to motilin concentration. A: degree of ICCh potentiation by motilin (10 nM) decreased with decline of motilin-induced current (IMot). B: peak amplitude of enhanced CCh (1 µM)-sensitive current (measured as the averaged inward current superimposed on IMot) is normalized to ICCh amplitude before application of motilin and plotted against motilin concentration. Symbols and bars represent means ± SE from 3 to 5 experiments. * Statistically significant difference between relative values and their controls (paired t-test, P < 0.05). C: current-voltage relationship of motilin-potentiated ICCh. For details of curve construction, refer to legend for Fig. 2.

Potentiation of ICCh by motilin outlasted the washout of motilin (Fig. 4A), but the extent of potentiation appeared to be paralleled by the magnitude of the underlying IMot. As IMot declined, the extent of potentiation of ICCh gradually faded. This might reflect a slow dissociation of motilin from its receptor and/or switch-off of the cellular signaling pathways initiated by motilin-receptor activation. We did not pursue the details of this phenomenon, but no essential difference was found in the extent of potentiation immediately after termination of motilin application (3-10 min) and in the continued presence of motilin. Thus both data were included in the evaluation.

The enhancing effect of motilin on ICCh appears to be inversely correlated with the motilin concentration. As graphically summarized in Fig. 4B, the maximal effect of motilin was obtained at 1 nM, and the effect was dramatically diminished at higher concentrations. With 100 nM motilin, which contracts the cell and depolarizes the membrane maximally, in all cells examined the potentiation of ICCh was no longer observed (0.86 ± 0.13, n = 4). On the other hand, when the concentration of motilin was fixed to produce the maximal potentiating effect (1 nM), the effect was most pronounced near the activation threshold for CCh (0.3-1 µM) but became marginal or even decremental at 100 µM CCh, which was sufficient to activate ICCh maximally (Fig. 5A). To gain further insight into the mechanisms underlying this observation, we tested two extreme concentrations of CCh on the same cell. As illustrated in Fig. 5B, the amplitude of ICCh induced by 1 µM CCh after motilin-induced potentiation was comparable to that of maximally activated ICCh (with 100 µM CCh), thus suggesting that the potentiating effect of motilin may saturate when ICCh is already fully activated. Although more accurate quantification was not feasible due to cell-to-cell variation and time-dependent rundown of ICCh, qualitatively the same results were obtained from four other cells. We therefore speculate that saturation of motilin's effects on ICCh reflects a leftward shift of the CCh-ICCh activation curve (see Fig. 1).


View larger version (22K):
[in this window]
[in a new window]
 
Fig. 5.   Dependence on CCh concentration of motilin-induced ICCh potentiation. A: peak amplitude of (1 nM) motilin-potentiated ICCh is normalized to ICCh amplitude in absence of motilin and plotted against CCh concentration. * Statistically significant difference between relative values and their controls (paired t-test, P < 0.05). B, a: maximum (1 nM) motilin-potentiated ICCh (1 µM CCh) does not exceed maximum ICCh activated solely by CCh (100 µM). B, b: ICCh induced by maximal CCh concentration (100 µM) cannot be further potentiated by motilin.

The speculated leftward shift of the CCh-ICCh activation curve might result from increased sensitivity of the muscarinic receptors after motilin receptor stimulation. Consistent with this idea, the magnitude of the guanosine 5'-O-(3-thiotriphosphate)-induced cation current, which would reflect the opening of the same cation channels as activated by muscarinic receptor but bypassing the receptor (11, 15, 16, 30), was not significantly affected by motilin in its both developing and steady phases (Fig. 6A). The intracellular pathway(s) linking the motilin receptor may not involve the pertussis toxin-sensitive G protein, because no significant difference was found in the amplitude of IMot between cells treated with pertussis toxin (1 µg/ml, 36°C, 4-6 h) and those of time-matched control (data not shown). These results suggest that the cellular mechanism underlying the potentiation of ICCh by motilin might be different from that for the activation of ICCh, which is likely to involve the pertussis toxin-sensitive G protein (see above), but at present we have no definite evidence against the possibility that the pathway mediating the motilin-induced ICCh potentiation may also be pertussis toxin sensitive.


View larger version (28K):
[in this window]
[in a new window]
 
Fig. 6.   Guanosine 5'-O-(3-thiotriphosphate) (GTPgamma S)-induced cation current (IGTPgamma S) is not potentiated by motilin. A: 50 µM GTPgamma S was included in internal solution and continuously perfused into clamped cell. A noisy cation current, the properties of which are similar to ICCh (11, 30) developed and reached a steady current level within 10-20 min from the disruption of the patch membrane (i.e., start of the whole cell condition). Addition of 1 nM motilin failed to potentiate IGTPgamma S. No clear increase was observed in IGTPgamma S, even when motilin was added in developing phase of IGTPgamma S. B: lowering ambient temperature inhibits motilin-induced ICCh potentiation. Extent of motilin (1 nM)-induced ICCh potentiation at 2 different ambient temperatures (20 and 30-31°C) is shown (columns) with SE. Number of experiments is given in parentheses in each column. * Statistically significant difference (unpaired t-test, P < 0.01).

The potentiating effect of motilin on ICCh may involve some biochemical events such as enzymatic reactions. In accordance with this proposal, lowering the temperature to 20°C from 30-31°C almost completely abolished the enhancing effects of motilin (Fig. 6B).

    DISCUSSION
Top
Abstract
Introduction
Methods
Results
Discussion
References

The major finding of this study is that in rabbit duodenal smooth muscle cells potent amplification of the postsynaptic muscarinic responses (i.e., activation of inward currents) could be induced after the stimulation of motilin receptors, under conditions that exclude any contributions of nonmuscular factors. This amplification is specific for the muscarinic cation conductance because its characteristic features such as voltage dependence and sensitivity to atropine remained essentially unchanged after motilin-induced potentiation and could clearly be distinguished from those of the cationic conductance induced by motilin per se. This is of particular physiological significance because the muscarinic cation channels have been found ubiquitously in the whole gastrointestinal tract and are thought to play a central role in the excitatory regulation of the gut motility. Owing to the remarkable and dynamic dependence of the depolarizing actions of these channels on the membrane potential, intracellular free Ca2+ concentration and probably the mechanical state (2, 5, 11-13, 15, 17, 18, 21, 28), they likely serve to tune finely the Ca2+ spike activity (i.e., by altering its frequency and duration), a critical determinant for the kinetics of the gut motility (4, 6, 9, 17, 22).

The most interesting aspect of motilin-induced potentiation of ICCh is that the potentiation occurs maximally near the activation threshold of CCh (on average 3.5-5-fold with 0.3-1 µM CCh) and with a relatively low concentration of motilin (1 nM) that can itself induce only partial contraction (e.g., Fig. 1D in Ref. 29). In contrast, the potentiation diminished almost completely at higher concentrations of these agonists (Fig. 4 and 5). These results provide at least two important insights into the mechanism by which motilin exerts its complex actions under in vivo and in vitro conditions. First, the extent of motilin-induced amplification of postsynaptic cholinergic responses is likely to be closely associated with the prevalent in vivo parasympathetic tone. Thus, if we assume that parasympathetic tone is elevated after food intake and gradually declines during fasting, the inverse dependence of motilin-induced potentiation of ICCh on CCh concentration might serve most advantageously to enhance the gut motility when the parasympathetic tone has been decreased, i.e., during the fasting state. Conversely, this mechanism would become much less significant when the parasympathetic tone was elevated, e.g., during the progression of digestion. In this regard, it is interesting to note that the plasma motilin level is depressed during the postprandial period, whereas it starts to fluctuate in the fasting state, in an apparent association with the atropine-sensitive migrating motor complex (27). Such a temporally inversed relationship between the cholinergic nervous and plasma motilin activities might further help accentuate the postsynaptic amplification of muscarinic responses by motilin.

Second, the virtual resistance to atropine or tetrodotoxin pretreatment of motilin-induced contractions in in vitro studies could partly be accounted for by our observation that high concentrations of motilin (100 nM) are unable to potentiate ICCh (Fig. 4B), whereas such concentrations can themselves, probably through inositol 1,4,5-trisphosphate-mediated Ca2+ release and secondary activation of voltage-dependent Ca2+ influx, provoke strong sustained contractions, the amplitudes of which are comparable to the maximal contractions induced by CCh (Fig. 1 in Ref. 29). In accordance with these observations, contractions induced by a near-threshold concentration of CCh (0.3 µM) tended to be enhanced after the application of 1 nM motilin (6-39% increase, n = 5), but this effect was dramatically reduced with higher concentrations of motilin (10-100 nM) or CCh (10-100 µM). Similar results have also been described by Strunz et al. (24) that the subthreshold concentration of 13-norleucine-motilin (a biologically active synthetic analog of motilin) reduces the acetylcholine dose required for producing half-maximal contractions by about 30-fold, with a slight increase in the maximal response (about 15%). Such a remarkable shift of dose-response relationship for CCh-induced contraction is indeed compatible with the leftward shift of dose-response curve for ICCh by motilin observed in the present study. This is probably accounted for by the increased sensitivity of the muscarinic receptor coupled to the cation channel (Fig.6A). Although the in vivo relationship between the actions of motilin and the cholinergic system seems complicated by many factors, including their bidirectional interactions as well as the involvement of other intestinal peptides and/or unidentified nonneural factors (7, 8, 27), we would like to emphasize at least that the inconsistency with respect to atropine sensitivity between in vivo and in vitro experiments may arise in part from insufficient attention to the dose-dependent interactions between motilin and the muscarinic receptors at the postsynaptic level. Further carefully designed experiments are warranted to provide a less equivocal understanding of this current controversial issue.

    ACKNOWLEDGEMENTS

We are grateful to Dr. A. F. Brading, Univ. Dept. of Pharmacology, Oxford, United Kingdom, Chugai Pharmaceutical, and Miyuki Yoshikawa for improving our manuscript, kindly providing us with GM109, and technically assisting us, respectively.

    FOOTNOTES

Portions of this study were presented at the Annual Conference of the Japanese Pharmacological Society in Makuhari, Chiba, Japan, in March, 1997.

Address reprint requests to R. Inoue.

Received 9 June 1997; accepted in final form 30 November 1997.

    REFERENCES
Top
Abstract
Introduction
Methods
Results
Discussion
References

1.   Adachi, H., H. Toda, S. Hayashi, M. Noguchi, T. Suzuki, K. Torizuka, H. Yajima, and K. Koyama. Mechanism of the excitatory action of motilin on isolated rabbit intestine. Gastroenterology 80: 783-788, 1981[Medline].

2.   Benham, C. D., T. B. Bolton, and R. J. Lang. Acetylcholine activates an inward current in single mammalian smooth muscle cells. Nature 316: 345-347, 1985[Medline].

3.   Bolton, T. B. Mechanisms of action of transmitter and other substances on smooth muscle. Physiol. Rev. 59: 606-718, 1979[Free Full Text].

4.   Bulbring, E., and H. Kuriyama. Effects of changes in external sodium and calcium concentrations on spontaneous electrical activity in smooth muscle of the guinea-pig taenia caeci. J. Physiol. (Lond.) 166: 29-58, 1963.

5.   Carl, A., H. K. Lee, and K. M. Sanders. Regulation of ion channels in smooth muscles by calcium. Am. J. Physiol. 271 (Cell Physiol. 40): C9-C34, 1996[Abstract/Free Full Text].

6.   El-Sharkawy, T. Y., and J. H. Szurszewski. Modulation of canine antral circular muscle by acetylcholine, noradrenaline and pentagastrin. J. Physiol. (Lond.) 279: 309-320, 1978[Abstract].

7.   Fox, J. E. T., E. E. Daniel, J. Jury, N. S. Track, and S. Chiu. Cholinergic control mechanisms for immunoreactive motilin release and motility in the canine duodenum. Can. J. Physiol. Pharmacol. 61: 1042-1049, 1982.

8.   Hall, K. E., G. R. Greeberg, T. Y. El-Sharkawy, and N. E. Diamant. Relationship between porcine motilin-induced migrating motor complex-like activity, vagal integrity, and endogenous motilin release in dogs. Gastroenterology 87: 76-85, 1984[Medline].

9.   Huizinga, J. D., G. Cheng, N. E. Diamant, and T. Y. El-Sharkawy. Electrophysiological basis of excitation of canine colonic circular muscle by cholinergic agents and substance P. J. Pharmacol. Exp. Ther. 231: 692-699, 1984[Abstract].

10.   Inatomi, N., H. Satoh, Y. Maki, N. Hashimoto, Z. Itoh, and S. Omura. An erythromycin derivative, EM-523, induces motilin-like gastrointestinal motility in dogs. J. Pharmacol. Exp. Ther. 251: 707-712, 1989[Abstract].

11.   Inoue, R., and G. Isenberg. Acetylcholine activates nonselective cation channels in guinea-pig ileum through a G protein. Am. J. Physiol. 258 (Cell Physiol. 27): C1173-C1178, 1990[Abstract/Free Full Text].

12.   Inoue, R., and G. Isenberg. Effect of membrane potential on acetylcholine-induced inward current in guinea-pig ileum. J. Physiol. (Lond.) 424: 57-71, 1990[Abstract].

13.   Inoue, R., and G. Isenberg. Intracellular calcium modulates acetylcholine-induced inward current in guinea-pig ileum. J. Physiol. (Lond.) 424: 73-92, 1990[Abstract].

14.   Itoh, Z., I. Aizawa, R. Honda, K. Hiwatashi, and E. F. Couch. Control of lower esophageal sphincter contractile activity by motilin in conscious dogs. Dig. Dis. 23: 341-345, 1978.

15.   Kim, S. J., S. C. Ahn, I. So, and K. K. Kim. Role of calmodulin in the activation of carbachol-activated cationic current in guinea-pig gastric antral myocytes. Pflügers Arch. 430: 757-762, 1995[Medline].

16.   Komori, S., M. Kawai, T. Takewaki, and H. Ohashi. GTP-binding protein involvement in membrane currents evoked by carbachol and histamine in guinea-pig ileal muscle. J. Physiol. (Lond.) 450: 105-126, 1992[Abstract].

17.  Kuriyama, H., K. Kitamura, T. Itoh, and R. Inoue. Physiological features of visceral smooth muscle cells with special reference to receptors and ion channels. Physiol. Rev. In press.

18.   Lee, H. K., O. Bayguinov, and K. M. Sanders. Role of nonselective cation current in muscarinic responses of canine colonic muscle. Am. J. Physiol. 265 (Cell Physiol. 34): C1463-C1471, 1993[Abstract/Free Full Text].

19.   Mizumoto, A., G. Sano, Y. Matsunaga, O. Yamamoto, Z. Itoh, and K. Ohshima. Mechanism of motilin-induced contractions in isolated perfused stomach. Gastroenterology 105: 425-432, 1993[Medline].

20.   Ohtawa, M., A. Mizumoto, N. Hayashi, K. Yanagida, Z. Itoh, and S. Omura. Mechanism of gastroprokinetic effect of EM523, an erythromycin derivative, in dogs. Gastroenterology 104: 1320-1327, 1993[Medline].

21.   Pacaud, P., and T. B. Bolton. Relation between muscarinic receptor cationic current and internal calcium in jejunal smooth muscle cells. J. Physiol. (Lond.) 441: 477-499, 1991[Abstract].

22.   Sanders, K. M. Ionic mechanisms of electrical rhythmicity in gastrointestinal smooth muscles. Annu. Rev. Physiol. 54: 439-453, 1992[Medline].

23.   Sims, S. M. Cholinergic activation of a non-selective cation current in canine gastric smooth muscle is associated with contraction. J. Physiol. (Lond.) 449: 377-398, 1992[Abstract].

24.   Strunz, U., W. Domschke, S. Domschke, P. Mitznegg, E. Wunsch, E. Jaeger, and L. Demling. Potentiation between 13-norleucine-motilin and acetylcholine on rabbit pyloric muscle in vitro. Scand. J. Gastroenterol. Suppl. 39: 29-33, 1976[Medline].

25.   Strunz, U., W. Domschke, P. Mitznegg, S. Domschke, E. Schubert, E. Wunsch, E. Jaeger, and L. Demling. Analysis of the motor effects of 13-norleucine motilin on the rabbit, guinea-pig, rat, and human alimentary tract in vitro. Gastroenterology 68: 1485-1491, 1975[Medline].

26.   Takanashi, H., K. Yogo, K. Ozaki, M. Ikuta, M. Akima, H. Koga, and H. Nabata. GM109: a novel, selective motilin antagonist in the smooth muscle of the rabbit small intestine. J. Pharmacol. Exp. Ther. 273: 624-628, 1995[Abstract].

27.   Vantrappen, G., and P. L. Peeters. Motilin. In: Handbook of Physiology. The Gastrointestinal System. Neural and Endocrine Biology. Bethesda, MD: Am. Physiol. Soc., 1989, sect. 6, vol. 2, chapt. 22, p. 545-558.

28.   Waniishi, Y., R. Inoue, and Y. Ito. Preferential potentiation by hypotonic cell swelling of muscarinic cation current in guinea pig ileum. Am. J. Physiol. 272 (Cell Physiol. 41): C240-C253, 1997[Abstract/Free Full Text].

29.   Yamada, K., S. Chen, N. A. Abdullah, M. Tanaka, Y. Ito, and R. Inoue. Electrophysiological characterization of a motilin agonist, GM611, on rabbit duodenal smooth muscle. Am. J. Physiol. 271 (Gastrointest. Liver Physiol. 34): G1003-G1006, 1996[Abstract/Free Full Text].

30.   Zholos, A. V., and T. B. Bolton. G-protein control of voltage dependence as well as gating of muscarinic metabotropic channels in guinea pig ileum. J. Physiol. (Lond.) 478: 67-82, 1994[Abstract].


AJP Gastroint Liver Physiol 274(3):G487-G492
0193-1857/98 $5.00 Copyright © 1998 the American Physiological Society