Nitrergic Prejunctional Inhibition of Purinergic Neuromuscular Transmission in the Hamster Proximal Colon

doi:10.1152/jn.00686.2002

Nitrergic Prejunctional Inhibition of Purinergic Neuromuscular Transmission in the Hamster Proximal Colon

Hayato Matsuyama, AbuBakr El-Mahmoudy, Yasutake Shimizu, and Tadashi Takewaki

Department of Pathogenetic Veterinary Science, The United Graduate School, Gifu University, Yanagido 1-1, Gifu, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Matsuyama, Hayato, AbuBakr El-Mahmoudy, Yasutake Shimizu, and Tadashi Takewaki. Nitrergic Prejunctional Inhibition of Purinergic Neuromuscular Transmission in the Hamster Proximal Colon. J. Neurophysiol. 89: 2346-2353, 2003. Neurogenic ATP and nitric oxide (NO) may play important roles in the physiological control of gastrointestinal motility. However,the interplay between purinergic and nitrergic neurons in mediatingthe inhibitory neurotransmission remains uncertain. This studyinvestigated whether neurogenic NO modulates the purinergic transmissionto circular smooth muscles of the hamster proximal colon. Electricalactivity was recorded from circular muscle cells of the hamsterproximal colon by using the microelectrode technique. Intramuralnerve stimulation with a single pulse evoked a fast purinergicinhibitory junction potential (IJP) followed by a slow nitrergicIJP. The purinergic component of the second IJP evoked by pairedstimulus pulses at pulse intervals between 1 and 3 s became smallerthan that of the first IJP. This purinergic IJP depression couldbe observed at pulse intervals <3 s, but not at longer ones, andfailed to occur in the presence of NO synthase inhibitor. ExogenousNO (0.3-1 µM), at which no hyperpolarization is produced, inhibitedpurinergic IJPs, without altering the nitrergic IJP and exogenouslyapplied ATP-induced hyperpolarization. In the presence of bothpurinoceptor antagonist and nitric oxide synthase (NOS) inhibitor,intramural nerve stimulation with 5 pulses at 20 Hz evoked vasoactiveintestinal peptide (VIP)-associated IJPs, suggesting that VIPcomponent may be masked in the IJPs of the hamster proximal colon.Our results suggest that neurogenic NO may modulate the purinergictransmission to circular smooth muscles of the hamster proximalcolon via a prejunctional mechanism. In addition, VIP may be involvedin the neurotransmitter in the hamster proximalcolon.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Evidence from functional and morphological studies indicates that nitric oxide (NO), ATP, and vasoactive intestinal peptide(VIP) play important roles in the physiological control of gastrointestinalmotility (Burnstock 2001; Crist et al. 1992; Keef et al. 1993;Kishi et al. 1996; Rae and Muir 1996). Although the inter-relationshipsamong these mediators underlying the nonadrenergic noncholinergic(NANC) inhibitory neuromuscular transmission have been a subjectof considerable debate, three possible interrelationships havebeen proposed. Neurogenic VIP causes relaxation through productionof NO in target muscle cells of the guinea pig gastric fundusand rat colon (Dick et al. 2000; Grider 1993) and in myentericneurons of opossum internal anal sphincter (Chakder and Rattan1996). On the other hand, VIP release is stimulated by NO in therat small intestine (Kurjak et al. 2001) and hamster jejunum (Matsuyamaet al. 2002). ATP, which could be released from intrinsic nerves,evokes membrane hyperpolarization in circular smooth muscle cellsvia production of NO in postsynaptic target cells in the caninejejunum (Xue et al. 2000). To our knowledge, however, relationshipsbetween nitrergic and purinergic neuromuscular transmissions inthe gastrointestinal tract have not yet beenestablished.

Previous electrophysiological and anatomical studies have demonstrated that the hamster is a useful model for the investigationof nitrergic innervation in the gastrointestinal tract (Matsuyamaet al. 1999; Toole et al. 1998). The purpose of this study wasto investigate whether neurogenic NO modulates the purinergictransmission to circular smooth muscles of the hamster proximalcolon. For this purpose, we used the ATP receptor antagonists,cibacron blue 3GA (CB 3GA) and suramin, and the NOS inhibitor,N^G-nitro-L-arginine methyl ester (L-NAME). We also examined theeffects of exogenously applied ATP andNO.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Tissue preparation

Male Syrian hamsters, 5-10 wk old, were lightly anesthetized with diethyl ether and exsanguinated via the carotid arteries,using a protocol approved by the Gifu University Animal Care andUse Committee in accordance with Japanese Department of Agricultureguidelines. Tissue preparations were similar to those previouslydescribed for hamster ileum (Matsuyama et al. 1999). Briefly,a length of about 3-4 cm of the ascending colon, which extendsfrom the ceco-colic junction to a horse-shoe-shaped loop, wasdefined as the proximal colon. Whole segments, 1 cm long, werefixed to a rubber block in a 4-ml organ bath with pins and perfusedwith physiological salt solution (PSS) at a constant flow rateof about 3 ml/min. The composition of the PSS was as follows (inmM): 137 NaCl, 4.0 KCl, 0.5 NaH₂PO₄, 11.9 NaHCO₃, 2.0 CaCl₂, 1.0MgCl₂, and 5.6 glucose. Atropine (0.1 µM), guanethidine (1 µM),and nifedipine (0.2 µM) were routinely added to the PSS. The PSSwas previously oxygenated by bubbling with 95% O₂-5% CO₂ gas mixtureand maintained at 32 ± 0.5°C. Tissues were allowed to equilibratefor approximately 45-60 min before experiments wereundertaken.

Electrophysiological recording

Membrane potential was recorded using conventional glass microelectrodes filled with 3 M KCl with a tip resistance of 50-80M $Omega$ . The electrode was inserted into the circular muscle cellsof the deep layer from the serosal side (Takewaki and Ohashi 1977).Successful insertion was confirmed when a sharp change in thevoltage to a membrane potential negative to about $-$ 50 mV was observedand remained stable for $>=$ 5 min. A pair of silver wire electrodes,one placed in the intestinal lumen and the other in the organbath, was used for electrical field stimulation (EFS) of intramuralnerves of the preparation. To record membrane potential responsesto EFS, a microelectrode was inserted into a smooth muscle celllocated within 2 mm of the stimulating electrode. Inhibitory junctionpotentials (IJPs) were evoked by EFS of intramural nerves of thetissue with square-wave pulses (1 and 5 pulses) of 0.5 ms durationat 15 V. Membrane potential changes were displayed on an oscilloscope(CS 4025, Kenwood, Tokyo, Japan). Analog electrical signals wererecorded on a thermal-array recorder (RTA-1100M, Nihon Kohden,Tokyo, Japan) for illustration andanalysis.

Local application of ATP

ATP was administered by a pressure application device (PV 800 Pneumatic PicoPump, World Precision Instruments). A micropipette(10 µm tip diam) filled with variable concentration of ATP (0.01to 1.0 mM) was placed as close as possible to the recording electrode.Pressure pulses at 15 psi and 50 ms duration were used to deliverATP. Pressure ejection of PSS did not significantly alter themembrane potential of the smoothmuscle.

Preparation of NO solution

A stock solution of NO was prepared as described by Stark et al. (1991). NO gas was injected into PSS that had been deoxygenatedpreviously by bubbling with helium for 2 h to yield a stock solutionof NO ranging from 0.01 to 1.0% (vol/vol). The deoxygenated solutionhad no effect on the membranepotential.

Preparation of oxyhemoglobin

Oxyhemoglobin (Oxy-Hb) was prepared by a modification of the method described by Martin et al. (1984). A 10-fold molar excessof sodium dithionite (Na₂S₂O₄), a reducing agent, was added toa 1 mM solution of purchased hemoglobin in distilled water. ExcessNa₂S₂O₄ was removed by dialyzing three times against 100 volumesof distilled water at 4°C. The solutions were frozen in aliquotsat $-$ 20°C and stored for $<=$ 14days.

Drugs

L-NAME, CB 3GA, suramin, L-arginine, D-arginine, atropine, guanethidine, nifedipine, hemoglobin (bovine), VIP, VIP(6-28),and tetrodotoxin (TTX) were obtained from Sigma (St. Louis, MO).All agents were dissolved in distilled water. Stock solutionswere prepared at more than 100 times higher concentrations thanthose used for experiments. Final concentrations of distilledwater in the bathing solution were <0.01% and thus had no effecton the membrane potential. Drug concentrations given in the textwere the final concentrations in the bathing solution. NO solutionswere kept at 4°C and diluted to their final concentrations inPSS.

Data processing and statistical analysis

Data are expressed as mean ± SE, and n represents the number of experiments performed using different tissue preparationsfrom different hamsters. When recordings were obtained from morethan one cell in an individual preparation, the mean value wascalculated and used. Differences between the mean values wereanalyzed by one-way ANOVA, followed by the Dunnett's test formultiple group comparisons, or Student's t-test (paired or unpaired)for comparison of two groups. P value <0.05 was consideredsignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

General observations

The mean resting membrane potential recorded from the circular smooth muscle cells of the hamster proximal colon was $-$ 50.7± 0.5 mV (n = 103 cells from 20 preparations). The circular smoothmuscle cells displayed small discharges of irregular frequencyand amplitude ( $<=$ 3 mV). EFS (0.5 ms duration, 15 V) with singlepulses produced IJPs, which was comprised of two components. TheseIJPs were almost completely abolished by TTX (0.1 µM; n = 7; datanot shown). The first component of the IJP (fast IJP) reacheda peak value about 0.6 s after stimulation. The second slower-developinghyperpolarizing component (slow IJP) reached a peak value afterabout 2 s and slowly returned to the control membrane potential(Figs. 1 and 2). The latency and duration of the fast and slowIJPs are summarized in Table 1. In 84% of preparations, EFS witha single pulse evoked fast and slow components, while only thefast component of IJPs was evoked by nerve stimulation in theremaining preparations (Fig. 3B). In 25% of preparations, theIJPs were followed by a poststimulus depolarization, which hada peak at about 6 s after the stimulus (Fig. 3A). The nature ofthis poststimulus depolarization is not known (He and Goyal 1993).

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Fig. 1. Antagonizations of purinoceptor by cibacron blue 3GA (CB 3GA) and suramin inhibits fast neuromuscular transmission. A: responses to single pulses (0.5 ms, 15 V), delivered at dot mark, were characterized by fast followed by slow components of the inhibitory junction potentials (IJPs). Times to peak of fast and slow components of the IJPs from the stimulus are shown as the time indicated by the bar under FC and SC, respectively. The slow IJP was unchanged by CB 3GA and suramin. B: summary plots of the amplitude of the fast IJPs. The amplitude of fast IJP was significantly inhibited by CB 3GA and suramin. Each bar represents the mean ± SE of 8 observations. $dagger$ P < 0.01, significantly different from the control (Dunnett's test).

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Fig. 2. Inhibition of nitric oxide synthase (NOS) and nitric oxide (NO) chelation inhibit slow neuromuscular transmission. A: overlays of pairs of IJPs. Times to peak of fast and slow components of the IJPs from the stimulus are shown as the time indicated by the bar under FC and SC, respectively. The fast was unchanged by N^G-nitro-L-arginine methyl ester (L-NAME) and Oxy-Hb. The dotted line in A shows control IJP. B: IJPs in response to single pulse (0.5 ms, 15 V) delivered at dot mark before and after the application of L-NAME (200 µM). L-NAME caused depolarization of membrane potential. L-NAME enhanced the fast IJP but inhibited the slow IJP. C: summary plots of the amplitude of slow IJPs. Amplitude of a slow IJP was significantly inhibited by L-NAME and Oxy-Hb. Each bar represents the mean ± SE of 8-9 observations. $dagger$ P < 0.01, *P < 0.05; significantly different from the control (Dunnett's test).

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Table 1. Temporal parameters of inhibitory junction potentials

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Fig. 3. Depression of purinergic transmission by endogenous NO. A and B: IJPs in response to single pulse (0.5 ms, 15 V), delivered at dot mark, delivered every 2 s (Ab and Bb) and 10 s (Aa and Ba). The fast IJP was inhibited by 2-s stimulus intervals but not by 10-s stimulus intervals. Solid and open circles represent conditioning and test pulses, respectively. A and B were recorded from separate preparations. B: slow IJP was not detected in this preparation. C and D: summary plot of the relative amplitudes of test IJPs. Amplitude of the fast component of test IJPs was significantly inhibited by endogenous NO when paired pulse stimulation was delivered with an interpulse interval of 1-3 s, but not at pulse intervals ranging between 10 and 30 s. However, pulse intervals ranging between 0.05 s (20 Hz) and 0.5 s (2 Hz) increased the amplitude of the fast IJPs. $dagger$ P < 0.01, *P < 0.05; significantly different from the respective control (Dunnett's test).

Effects of CB3GA, suramin, L-NAME, and Oxy-Hb on IJPs

Perfusion with CB 3GA (200 µM), suramin (100 µM), L-NAME (50 µM), and Oxy-Hb (10 µM) alone, had no effect on the membranepotential (n = 8). However, higher concentrations of L-NAME (200µM) and OxyHb (50 µM) induced depolarization of the membrane potential(n = 9; Table 2; Fig. 2B). Both CB 3GA and suramin inhibitedthe fast, but not the slow, IJPs (n = 8; Fig. 1). The amplitudesof the slow IJPs were 5.0 ± 0.8 and 5.0 ± 0.9 mV before and afterthe application of CB 3GA, respectively (paired t-test; P > 0.05;n = 8), and 5.0 ± 0.8 and 5.0 ± 0.9 mV for before and after theapplication of suramin, respectively (paired t-test; P > 0.05;n = 8). On the other hand, L-NAME (50 µM) and Oxy-Hb (10 µM) inhibitedthe slow IJPs but had no effect on the fast IJPs (n = 8; Fig.2). In these experiments, the amplitudes of the fast IJPs beforeand after the application of L-NAME (50 µM) were 16.9 ± 0.6 and17.2 ± 1.1 mV, respectively (paired t-test; P > 0.05; n = 8),and those of Oxy-Hb (50 µM) were 16.6 ± 0.5 and 17.7 ± 1.1 mV,respectively (paired t-test; P > 0.05; n = 8). Addition of L-NAME(200 µM) and Oxy-Hb (50 µM) enhanced the amplitude of the fastIJPs from 16.7 ± 1.1 to 22.8 ± 1.6 mV and 15.1 ± 1.1 to 21.5 ±1.2 mV, respectively (unpaired t-test; P < 0.05; n = 9). The inhibitionby L-NAME (200 µM) of slow IJPs was completely reversed by subsequentaddition of L-arginine (5 mM) but not by its stereoisomer D-arginine(5 mM). The amplitudes of fast IJPs before the application ofL-arginine and D-arginine were 14.2 ± 1.7 mV (unpaired t-test;P < 0.05; n = 5) and 22.0 ± 1.0 mV (paired t-test; P > 0.05; n= 9), respectively (paired t-test; P > 0.05; n = 4).

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Table 2. Effects of CB 3GA, suramin, Oxy-Hb, and L-NAME on membrane potential

Effects of pulse intervals on IJPs

To examine if nerve excitation influences the next purinergic or nitrergic inhibitory neurotransmission, we studied the effectof conditioning pulse (0.5 ms duration, 15 V)-evoked IJPs on thetest pulse (0.5 ms duration, 15 V)-evoked IJPs (test IJPs) byapplying pulse intervals ranging between 0.05 and 30 s (Fig. 3).Pulse intervals ranging between 10 and 30 s had no influence onthe test IJPs. On the other hand, significant depression of thefast component of the test IJPs was observed by application ofpulse intervals ranging between 1 and 3 s (n = 9; Fig. 3C). Pulseintervals ranging between 0.05 and 0.5 s increased the amplitudeof the fast IJP (Fig. 3D). EFS with two pulses delivered at 0.05-sintervals evoked fast and slow IJPs, with amplitudes of 22.1 ±0.8 and 6.4 ± 0.5 mV, respectively (n =9).

L-NAME was used in an attempt to inhibit the neurogenic NO produced by the conditioning pulse and was anticipated to modifythe purinergic component of the test pulse. Both L-NAME and Oxy-Hbreversed the depression of fast component of the test IJP (n =7; Fig. 4). Higher concentrations of L-NAME (200 µM) and Oxy-Hb(50 µM) enhanced the amplitude of the fast IJPs (Fig. 4, B andC). The inhibitory effects of L-NAME (200 µM) were completelyreversed by L-arginine (5 mM) but not by D-arginine (5 mM). Theamplitudes of fast component of the test IJPs before and afterthe application of L-arginine were 2.5 ± 0.9 and 28.0 ± 1.4 mV,respectively (unpaired t-test; P < 0.05; n = 5). The amplitudesof the fast component of the test IJPs before and after the applicationof D-arginine were 2.4 ± 0.8 and 2.3 ± 1.0 mV, respectively (pairedt-test; P > 0.05; n = 4). These results indicate that endogenousNO may inhibit purinergic IJPs at pulse intervals more than 0.05s.

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Fig. 4. Effects of L-NAME and Oxy-Hb on purinergic IJP depression. A-D: overlays of pairs of IJPs in response to single pulse (0.5 ms, 15 V), delivered at dot mark, delivered every 2 s. Solid and open circles represent conditioning and test pulses, respectively. E: summary plot of the amplitudes of IJPs. L-NAME and Oxy-Hb significantly reduced the purinergic IJP depression. Each bar represents the mean ± SE of 7 observations. $dagger$ P < 0.01 significantly different from the respective control (Dunnett's test).

Effect of exogenous NO on IJP and ATP-induced hyperpolarization

Application of exogenous NO at various concentrations ranging from 0.3 to 1 µM inhibited the fast test IJPs; however, nitrergicIJP was not altered (n = 8). There were no significant alterationsin the membrane potential of the smooth muscle (n = 10) by exogenouslyapplied NO (0.3-1 µM). Higher concentrations of NO (3-10 µM) induceda concentration-dependent increase in hyperpolarization (Fig.5). Repetitive (3-s intervals) pressure pulses of exogenous ATPproduced hyperpolarizations. The amplitudes of the first and secondATP-induced hyperpolarizations were constant. The ATP-inducedhyperpolarizations were not significantly altered by exogenouslyapplied NO (1 µM; Fig. 6). The amplitudes of ATP (1 mM)-inducedhyperpolarizations in the absence and presence of the exogenousNO (1 µM) were 10.2 ± 0.7 and 10.1 ± 0.8 mV, respectively (pairedt-test; P > 0.05; n = 6).

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Fig. 5. Effect of exogenously applied NO on membrane potential and IJPs. A: NO caused a concentration-dependent hyperpolarization. B: IJPs in response to single pulses (0.5 ms, 15 V), delivered at dot mark, derived every 20 s. NO was applied at the time indicated by the bar. IJP during application of NO was defined as the test IJP. C: summary plot of the amplitudes of the test IJPs. Exogenously applied NO significantly inhibits purinergic IJPs but did not alter nitrergic IJPs. Each represents the mean ± SE of 8 observations. $dagger$ P < 0.01, *P < 0.05; significantly different from the respective control (Dunnett's test).

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Fig. 6. Effect of exogenously applied NO on the ATP-induced hyperpolarization. Pressure application of ATP induced hyperpolarization. NO was applied at the time indicated by the bar. NO did not alter the ATP-induced hyperpolarization.

Effect of VIP(6-28) on IJPs and VIP-induced hyperpolarizations

To investigate whether peptidergic transmission contributes to the IJP generation, we tested the effect of VIP receptor antagonist,VIP(6-28), on IJPs evoked by EFS (0.5 ms duration, 15 V) withsingle pulses and trains of five pulses. Exogenously applied VIP(0.3-3 µM) induced a concentration-dependent increase in hyperpolarization,which was inhibited by the application of VIP(6-28) (1 µM). Theamplitude of VIP (3 µM)-induced hyperpolarization was 6.5 ± 0.7and 1.2 ± 0.4 mV before and after the application of VIP(6-28),respectively (unpaired t-test; P < 0.05; n = 6). Addition of VIP(6-28)had no effect on the membrane potential (Table 2), and both componentsof single pulse stimulation evoked IJPs. The amplitudes of fastand slow components of the single pulse-evoked IJPs were 17.1± 0.7 and 5.0 ± 0.4 mV, respectively, in control, and 16.8 ± 0.6and 4.9 ± 0.3 mV, respectively, in the presence of VIP(6-28) (pairedt-test; P > 0.05; n = 7). On the other hand, VIP(6-28) significantlyinhibited the CB 3GA- and L-NAME-resistant IJPs evoked by trainsof five pulses at 20 Hz (Fig. 7).

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Fig. 7. Effect of vasoactive intestinal peptide [VIP(6-28)] on the CB 3GA- and L-NAME-resistant IJPs. IJPs are evoked by trains of 5 pulses. Note that trains of 5 pulses evoked ATP- and NO-insensitive IJPs.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The results of this study suggest that neurogenic NO modulates purinergic transmission from enteric neuron to the circularmuscles of the hamster proximal colon via a prejunctional mechanism.Our evidence in support of this conclusion can be summarized asfollows: 1) L-NAME, a nitric oxide synthase (NOS) inhibitor, reversedthe purinergic IJP-depression produced by the second stimulusof paired stimuli delivered with pulse intervals ranging between1 and 3 s; 2) exogenously applied NO inhibited purinergic IJP;and 3) neither the first nor second ATP-induced hyperpolarizationwas affected by exogenous NO. Although ATP and NO have been widelyrecognized as mediators for NANC inhibitory neurotransmissions(Boeckxstaens et al. 1993; Burnstock 2001; Crist et al. 1992;Jenkinson and Reid 2000; Rae and Muir 1996; Smits and Lefebvre1996; Toole et al. 1998; Xue et al. 1999, 2000), such an inhibitoryaction of neurogenic NO on the purinergic transmission, has notbeen demonstrated previously in the gastrointestinal tract. Ourdata confirm that both endogenously and exogenously applied NOinhibited purinergic IJPs but did not have significant effecton exogenously applied ATP-induced hyperpolarizations. These observationsmay explain the prejunctional effects of NO on the purinergictransmissions.

In the present study, nitrergic IJPs lasted about 3 s after EFS, indicating that the effect of neurogenic NO can be maintainedfor about 3 s after stimulation. When the test pulse was applied1-3 s after the conditioning pulse, the amplitude of the purinergicIJP evoked by the test pulse was significantly smaller than thatevoked by the conditioning. In support of these observations,it has been demonstrated that the decay rate of NO has a half-liferanging between 0.5 and 5 s (Lancaster 1994). Furthermore, whenNANC nerve stimulations were applied at a pulse interval rangingbetween 0.5 and 2 s, NANC relaxations were completely inhibitedby a NOS inhibitor in the canine fundus (Bayguinov et al. 1999).Thus stimulus intervals shorter than 3 s may enable neurogenicNO to regulate the purinergic transmission in the hamster proximalcolon.

This study emphasizes the interplay between purinergic transmission and spontaneously released NO in mediating the inhibitoryneurotransmission underlying IJPs. L-NAME significantly alteredthe purinergic component of the single pulse-evoked IJP, indicatingthat intrinsic, spontaneously released NO may affect the purinergictransmission to circular smooth muscle cells of the hamster proximalcolon. The hypothesis is consistent with the observation thattonic release of NO regulated the spontaneous electrical and contractileactivities of the canine colon (Keef et al. 1997) and that L-NAMEcaused depolarization of resting potential in the canine ileocolonicsphincter (Ward et al. 1992). However, the inhibitory role ofspontaneously released NO on the purinergic neuromuscular transmissionhas not been reportedpreviously.

In this study, two pulses of EFS delivered at 2-20 Hz enhanced summation of the purinergic and nitrergic components of theIJPs. The nitrergic component of the IJPs induced by two pulsesat 2-20 Hz was unaffected by CB 3GA. These results suggest thatthe nitrergic component is not inhibited but enhanced by eitherneurogenic ATP or stimulus condition. Consistent with this observation,ATP was proposed to cause hyperpolarization via NO productionin postsynaptic target cells in the canine jejunum (Xue et al.2000). Thus ATP might enhance nitrergic neuromuscular transmissionin the hamster proximal colon. Another possibility is that EFSwith two pulses at 2-20 Hz might produce summation of nitrergicIJPs in the hamster proximal colon. In the rat colon, EFS withtwo pulses at 10 Hz produced summation of IJPs (Kishi et al. 1996).Further studies are necessary to confirm the above twopossibilities.

Previous studies suggested that neuronal ATP and NO may contribute to IJPs and thus regulate gastrointestinal motility inthe guinea pig taenia coli (Den Hertog et al. 1985) and opossumesophagus (Conklin et al. 1995). L-NAME inhibited the IJPs andrelaxations in the canine small intestine (Stark et al. 1991)and canine fundus (Bayguinov et al. 1999). On the other hand,L-NAME reduced the threshold volume required to trigger emptyingof the guinea pig small intestine (Waterman and Costa 1994). Anotherinhibitor of NOS, N^G-monomethyl-L-arginine, inhibited the increase rate of transientlower esophageal sphincter relaxations induced by gastric distensionin human (Hirsch et al. 1998). Endogenous and exogenous ATP inhibitedintestinal peristalsis in the guinea pig small intestine (Heinemannet al. 1999). L-NAME and a P2-purinoceptor antagonist, suramin,attenuated relaxations of the antrum in anesthetized rats (Glasgowet al. 1998). Furthermore, electrical and reflex stimulation ofenteric nerves produce NO-associated IJPs in the guinea pig colon(Watson et al. 1996). These findings indicate that purinergicand nitrergic IJPs might underlie the peristaltic reflex. Furthermore,the inhibition of NOS activity shortened a latency of peristalticwave initiation and increased a velocity of propulsion of an intraluminallydistended balloon in the rabbit distal colon (Ciccocioppo et al.1994). The existence of NOS and ATP was found in the myentericplexus of rat ileum and colon (Belai and Burnstock 1994) and humanstomach and small intestine (Belai and Burnstock 2000), suggestingthat NO and ATP may be released from the nerves. Thus it is likelythat neurogenic NO-induced inhibition of purinergic transmissionmight be involved in the mechanism that regulates gastrointestinalperistalticmovement.

The enteric nervous system has been mapped for ATP, NOS, and VIP by immunohistochemistry. These studies showed colocalizationof nitrergic neurons and either ATP or VIP in myenteric neuronsof the rat ileum and colon (Belai and Burnstock 1994) and humancolon (Porter et al. 1997). Furthermore, previous studies demonstratedthat NO can stimulate VIP release from the isolated myentericplexus of the guinea pig ileum (Grider and Jin 1993) and rat smallintestine (Kurjak et al. 2001), suggesting a possible presynapticstimulating role for NO on VIP release. Thus evidence based onthe overlapping for NOS and VIP suggests the existence of interactionbetween these neurotransmitters in mediating the inhibitory neurotransmission.In the myenteric plexus of the rat ileum and colon (Belai andBurnstock 1994) and human stomach and small intestine (Belai andBurnstock 2000), ATP and NOS are colocalized. Although the interrelationshipbetween neurogenic ATP and NO in mediating the inhibitory neurotransmissionis not completely understood, our data provide strong supportfor further relationship betweenthem.

Paired pulse stimulation of the nerves from 0.05 to 0.5 s may evoke facilitation of action potential in purinergic nerves(Landfield et al. 1986) and thus give rise to an enhancement ofevoked neurotransmitter release in the hamster proximal colon.These data consistent with the observations that elevation ofnumber of the action potential on the nerve axons or close tothe release sites resulted in depolarization of membrane potentialand enhancement of neurotransmitter release (Khakh and Henderson2000). Endogenous ATP has acted on presynaptic P2X receptors toenhance the amount of neurotransmitter released (LePard et al.1997). These observations may explain why there is an increasein the amplitude of the fast IJP in the hamster proximalcolon.

This study revealed that VIP was involved in the IJPs evoked by trains of five pulses at 20 Hz but not in the IJPs evokedby single pulse stimulation in the hamster proximal colon. Thereforewe speculate that stronger stimulus strength is needed to addthe VIP component to the IJPs in the hamster proximal colon. Thishypothesis is consistent with the following observations: 1) singlepulse stimulation resulted in an ATP-mediated IJP, which was unaffectedby VIP receptor antagonist, but trains of pulses resulted in VIP-mediatedIJP in the guinea pig ileum (Crist et al. 1992) and 2) trainsof pulses evoked VIP-associated IJPs in the hamster jejunum (Matsuyamaet al. 2002).

In conclusion, we have demonstrated in the present study that neurogenic NO seems to modulate the purinergic transmissionto the circular smooth muscle of the hamster proximal colon viaa prejunctional mechanism. The results obtained with pharmacological,electrophysiological, and morphological studies support the rolesof ATP and NO as important NANC inhibitory neurotransmitters inthe hamster proximalcolon.

	ACKNOWLEDGMENTS

This work was supported by a Grain-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Scienceand Technology, Japan(13660297).

	FOOTNOTES

Address for reprint requests: T. Takewaki, Dept. of Pathogenetic Veterinary Science, United Graduate School, Gifu Univ., Yanagido1-1, Gifu, Japan (E-mail: tt{at}cc.gifu-u.ac.jp).

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Bayguinov O, Keef KD, Hagen B, and Sanders KM. Parallel pathways mediate inhibitory effects of vasoactive intestinal polypeptide and nitric oxide in canine fundus. Br J Pharmacol 126: 1543-1552, 1999[ISI].
Belai A, and Burnstock G. Evidence for coexistence of ATP and nitric oxide in non-adrenergic, non-cholinergic (NANC) inhibitory neurones in the rat ileum, colon and anococcygeus muscle. Cell Tissue Res 278: 197-200, 1994[ISI][Medline].
Belai A, and Burnstock G. Pattern of distribution and co-localization of NOS and ATP in the myenteric plexus of human fetal stomach and intestine. Neuroreport 11: 5-8, 2000[ISI][Medline].
Boeckxstaens GE, Pelckmans PA, Herman AG, and Maercke YMV. Involvement of nitric oxide in the inhibitory innervation of the human isolated colon. Gastroenterology 104: 690-697, 1993[ISI][Medline].
Burnstock G. Purinergic signaling in gut. In: Purinergic and Pyrimidinergic Signaling II: Cardiovascular, Respiratory, Immune, Metabolic and Gastrointestinal Tract Function: Handbook of Experimental Pharmacology,, edited by Abbracchio MP, and Williams M. Berlin: Springer-Verlag, 2001, vol. 151, p. 141-238.
Chakder S, and Rattan S. Evidence for VIP-induced increase in NO production in myenteric neurons of opossum internal anal sphincter. Am J Physiol 270: G492-G497, 1996[Medline].
Ciccocioppo R, Onori L, Messori E, Candura SM, Coccini T, and Tonini M. Role of nitric oxide-dependent and -independent mechanisms in peristalsis and accommodation in the rabbit distal colon. J Pharmacol Exp Ther 270: 929-937, 1994[Abstract/Free Full Text].
Conklin JL, Murray J, Ledlow A, Clark E, Hayek B, Picken H, and Rosenthal G. Effects of recombinant human hemoglobin on motor functions of the opossum esophagus. J Pharmacol Exp Ther 273: 762-767, 1995[Abstract/Free Full Text].
Crist JR, He XD, and Goyal RK. Both ATP and the peptide VIP are inhibitory neurotransmitters in the guinea-pig ileum circular muscle. J Physiol (Lond) 447: 119-131, 1992[Abstract/Free Full Text].
Den Hertog A, Pielkenrood J, and Van den Akker J. Responses evoked by electrical stimulation, adenosine triphosphate, adenosine and 4-aminopyridine in taenia caeci of the guinea-pig. Eur J Pharmacol 109: 373-380, 1985[ISI][Medline].
Dick JMC, Van Geldre LA, Timmermans JP, and Lefebvre RA. Investigation of the interaction between nitric oxide and vasoactive intestinal polypeptide in the guinea-pig gastric fundus. Br J Pharmacol 129: 751-763, 2000[ISI].
Glasgow I, Mattar K, and Krantis A. Rat gastroduodenal motility in vivo: involvement of NO and ATP in spontaneous motor activity. Am J Physiol 275: G889-G896, 1998[Medline].
Grider JR. Interplay of VIP and nitric oxide in regulation of the descending relaxation phase of peristalsis. Am J Physiol 264: G334-G340, 1993[ISI][Medline].
Grider JR, and Jin JG. VIP release and L-citrulline production from isolated ganglia of the myenteric plexus: regulation of VIP release by nitric oxide. Neuroscience 54: 521-526, 1993[ISI][Medline].
He XD, and Goyal RK. Nitric oxide involvement in the peptide VIP-associated inhibitory junction potential in the guinea-pig ileum. J Physiol 461: 485-499, 1993[Abstract/Free Full Text].
Heinemann A, Shahbazian A, Bartho L, and Holzer P. Different receptors mediating the inhibitory action of exogenous ATP and endogenously released purines on guinea-pig intestinal peristalsis. Br J Pharmacol 128: 313-320, 1999[ISI].
Hirsch DP, Holloway RH, Tytgat GN, and Boeckxstaens GE. Involvement of nitric oxide in human transient lower esophageal sphincter relaxations and esophageal primary peristalsis. Gastroenterology 115: 1374-1380, 1998[ISI][Medline].
Jenkinson KM, and Reid JJ. Evidence that adenosine 5'-triphosphate is the third inhibitory non-adrenergic non-cholinergic neurotransmitter in the rat gastric fundus. Br J Pharmacol 130: 1627-1631, 2000[ISI].
Keef KD, Du C, Ward SM, Mcgregor B, and Sanders KM. Enteric inhibitory neural regulation of human colonic circular muscle: role of nitric oxide. Gastroenterology 105: 1009-1016, 1993[ISI][Medline].
Keef KD, Murray DC, Sanders KM, and Smith TK. Basal release of nitric oxide induces an oscillatory motor pattern in canine colon. J Physiol 499: 773-786, 1997[Abstract/Free Full Text].
Khakh BS, and Henderson G. ATP receptor-mediated enhancement of fast excitatory neurotransmitter release in the brain. Mol Pharmacol 54: 372-378, 1998[Abstract/Free Full Text].
Kishi M, Takeuchi T, Suthamnatpong N, Ishii T, Nishio H, Hata M, and Takewaki T. VIP- and PACAP-mediated nonadrenergic, noncholinergic inhibition in longitudinal muscle of rat distal colon: involvement of activation of charybdotoxin- and apamin-sensitive K⁺ channels. Br J Pharmacol 119: 623-630, 1996[ISI].
Kurjak M, Fritsch R, Saur D, Schusdziarra V, and Allescher HD. Functional coupling between nitric oxide synthesis and VIP release within enteric nerve terminals of the rat: involvement of protein kinase G and phosphodiesterase 5. J Physiol 534: 827-836, 2001[Abstract/Free Full Text].
Lancaster JR. Stimulation of the diffusion and reaction of endogenously produced nitric oxide. Proc Natl Acad Sci USA 91: 8137-8141, 1994[Abstract/Free Full Text].
Landfield PW, Piter TA, and Applegate MD. The effects of high Mg²⁺ to Ca²⁺ ratios on frequency potentiation in hippocampal slices of young and aged rats. J Neurophysiol 56: 797-811, 1986[Abstract/Free Full Text].
LePard KJ, Messori E, and Galligan JJ. Purinergic fast excitatory postsynaptic potentials in myenteric neurons of guinea-pig: distribution and pharmacology. Gastroenterology 113: 1522-1534, 1997[ISI][Medline].
Martin W, Villani GM, Jothianandan D, and Furchgott RF. Selective blockade of endothelium-dependent and glyceryl trinitrate-induced relaxation by hemoglobin and by methylene blue in the rabbit aorta. J Pharmacol Exp Ther 232: 708-716, 1984.
Matsuyama H, Thapaliya S, and Takewaki T. Cyclic GMP-associated apamin-sensitive nitrergic slow inhibitory junction potential in the hamster ileum. Br J Pharmacol 128: 830-836, 1999[ISI].
Matsuyama H, Unno T, El-Mahmoudy AM, Komori S, Kobayashi H, Thapaliya S, and Takewaki T. Peptidergic and nitrergic inhibitory neurotransmissions in the hamster jejunum: regulation of vasoactive intestinal peptide release by nitric oxide. Neuroscience 110: 779-788, 2002[ISI][Medline].
Porter AJ, Wattchow DA, Brookes SJH, and Costa M. The neurochemical cording and projections of circular muscle motor neurons in the human colon. Gastroenterology 113: 1916-1923, 1997[ISI][Medline].
Rae MG, and Muir TC. Neuronal mediators of inhibitory junction potentials and relaxation in the guinea-pig internal anal sphincter. J Physiol 493: 517-527, 1996[Abstract/Free Full Text].
Smits GJ, and Lefebvre RA. ATP and nitric oxide: inhibitory NANC neurotransmitters in the longitudinal muscle-myenteric plexus preparation of the rat ileum. Br J Pharmacol 118: 695-703, 1996[ISI][Medline].
Stark ME, Bauer AJ, and Szurszewski JH. Effect of nitric oxide on circular muscle of the canine small intestine. J Physiol 444: 743-761, 1991[Abstract/Free Full Text].
Takewaki T, and Ohashi O. Non-cholinergic excitatory transmission to intestinal smooth muscle cells. Nature 268: 749-750, 1977[Medline].
Toole L, Belai A, and Burnstock G. A neurochemical characterisation of the golden hamster myenteric plexus. Cell Tissue Res 291: 385-394, 1998[ISI][Medline].
Ward SM, McKeen ES, and Sanders KM. Role of nitric oxide in non-adrenergic, non-cholinergic inhibitory junction potential in canine ileocolonic sphincter. Br J Pharmacol 105: 776-782, 1992[ISI].
Waterman SA, and Costa M. The role of enteric inhibitory motoneurons in peristalsis in the isolated guinea-pig small intestine. J Physiol 477: 459-468, 1994[Abstract/Free Full Text].
Watson MJ, Lang RJ, Bywater RAR, and Taylor GS. Characterization of the membrane conductance changes underlying the apamin-resistant NANC inhibitory junction potential in the guinea-pig proximal and distal colon. J Auton Nerv Sys 60: 31-42, 1996[ISI][Medline].
Xue G, Farrugia G, Sarr G, and Szurszewski JH. ATP is a mediator of fast inhibitory junction potential in human jejunal circular smooth muscle. Am J Physiol 276: G1373-G1379, 1999[ISI][Medline].
Xue L, Farrugia G, and Szurszewski H. Effect of exogenous ATP on canine jejunal smooth muscle. Am J Physiol 278: G725-G733, 2000.

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