Excitotoxicity in the Enteric Nervous System

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Volume 17, Number 22, Issue of November 15, 1997

Excitotoxicity in the Enteric Nervous System

Annette L. Kirchgessner, Min-Tsai Liu, and Frederick Alcantara
Department of Anatomy and Cell Biology, Columbia University College of Physicians and Surgeons, New York, New York 10032

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Glutamate, the major excitatory neurotransmitter in the CNS, is also an excitatory neurotransmitter in the enteric nervoussystem (ENS). We tested the hypothesis that excessive exposureto glutamate, or related agonists, produces neurotoxicity in entericneurons. Prolonged stimulation of enteric ganglia by glutamatecaused necrosis and apoptosis in enteric neurons. Acute and delayedcell deaths were observed. Glutamate neurotoxicity was mimickedby NMDA and blocked by the NMDA antagonist D-2-amino-5-phosphonopentanoate.Excitotoxicity was more pronounced in cultured enteric gangliathan in intact preparations of bowel, presumably because of areduction in glutamate uptake. Glutamate-immunoreactive neuronswere found in cultured myenteric ganglia, and a subset of entericneurons expressed NMDA (NR1, NR2A/B), AMPA (GluR1, GluR2/3), andkainate (GluR5/6/7) receptor subunits. Glutamate receptors wereclustered on enteric neurites. Stimulation of cultured entericneurons by kainic acid led to the swelling of somas and the growthof varicosities ("blebs") on neurites. Blebs formed close to neuriteintersections and were enriched in mitochondria, as revealed byrhodamine 123 staining. Kainic acid also produced a loss of mitochondrialmembrane potential in cultured enteric neurons at sites whereblebs tended to form. These observations demonstrate, for thefirst time, excitotoxicity in the ENS and suggest that overactivationof enteric glutamate receptors may contribute to the intestinaldamage produced by anoxia, ischemia, and excitotoxins presentin food.
Key words: necrosis; apoptosis; NMDA; kainic acid; glutamate transporters; bleb formation; rhodamine 123

INTRODUCTION

Excessive exposure to glutamate causes cell death ("excitotoxicity") in CNS neurons (Choi, 1988, 1995). Excitotoxicity consistsof necrosis and apoptosis and is thought to occur via a breakdownin ionic homeostasis mediated by NMDA and non-NMDA glutamate receptorsubtypes. Neurons can be protected from excitotoxicity by Ca²⁺ buffers (Tymianski et al., 1993); therefore, increases in [Ca²⁺]_i are involved in causing excitotoxic cell death (Choi, 1988,1992). Consistent with this idea, both NMDA and kainic acid increase[Ca²⁺]_i in central neurons (MacDermott et al., 1986; Brorson et al.,1994). Moreover, excessive exposure to either glutamate receptoragonist produces neuronal cell loss (Choi et al., 1988). Increasesin [Ca²⁺]_i produced by these excitotoxins occur at sites that are richin mitochondria and produce a loss of mitochondrial membrane potential(Ankarcrona et al., 1995; Bindokas and Miller, 1995). Mitochondrialfunction seems to determine the mode of neuronal death in excitotoxicity.Early necrosis develops in neurons that lose mitochondrial membranepotential. Delayed apoptosis develops in neurons that recovermitochondrial potential and energy levels.

Substantial evidence suggests that glutamate is an excitatory neurotransmitter in the enteric nervous system (ENS). The bowelcontains glutamate-immunoreactive neurons, enteric neurons expressboth NMDA and non-NMDA receptors, and high affinity glutamatetransporters are present in enteric ganglia (Burns et al., 1994;Burns and Stephens, 1995; Liu et al., 1997). In addition, glutamatedepolarizes enteric neurons and mediates fast synaptic transmissionin the ENS (Liu et al., 1997). Pharmacological studies have alsobeen consistent with the idea that neurogenic motile (Shannonand Sawyer, 1989; Wiley et al., 1991) or secretory (Rhoads etal., 1995) responses of the gut involve enteric glutamatergicreceptors.

The abundance of subsets of glutamate receptors that increase [Ca²⁺]_i (MacDermott et al., 1986; Hollmann et al., 1991) in the ENSmay render enteric neurons vulnerable to glutamate-mediated neurotoxicity.The neurotoxic effects of glutamate in the ENS have not been examined;therefore, we determined whether excitotoxicity occurs in guineapig enteric neurons. We determined (1) the type of cell death(necrosis or apoptosis) resulting from the exposure of entericganglia to glutamate, (2) the ability of subtype-specific agoniststo mimic the neurotoxic effects of glutamate, and (3) whetherexcitotoxicity in enteric neurons is associated with morphologicalchanges and/or disruptions in mitochondrial membrane potential.Our results demonstrate that excitotoxicity occurs in the ENS.Both necrosis and apoptosis were observed in a subset of submucosaland myenteric neurons after exposure to glutamate. The effectsof glutamate were mimicked by NMDA and prevented by an NMDA antagonist.Kainate receptor immunoreactivity was demonstrated in entericganglia, and exposure to kainic acid caused somatic cell swellingand the formation of "blebs" on enteric neurites. Bleb formationseemed to be linked with a loss of mitochondrial membrane potential.Our results show that the process of excitotoxicity in the ENSis similar to that observed in the CNS.

MATERIALS AND METHODS
Preparation of whole mounts. Male guinea pigs (250-350 gm) were stunned and exsanguinated. This procedure has been approvedby the Animal Use and Care Committee of Columbia University. Asegment of ileum was excised and placed in oxygenated (95% O₂/5%CO₂) Krebs' solution of the following composition (mM): NaCl (121.3),KCl (5.95), CaCl₂ (2.5), NaHCO₃ (14.3), NaH₂PO₄ (1.34), MgCl₂(1.2), and glucose (12.7). A 7.0 cm segment of ileum was cut openand pinned (mucosal surface up) in a dish coated with a siliconeelastomer. Under microscopic control, the mucosa was graduallyscraped away to reveal the submucosal and myenteric layers ofthe intestinal wall. The methods used to obtain whole mounts,containing either the submucosal or the myenteric plexus withadherent longitudinal muscle (LMMP), were similar to those describedpreviously (Kirchgessner and Gershon, 1988). The Krebs' solutioncontained nifedipine (1.0 µM) to block longitudinal muscle contractionswhile we dissected the tissue. The preparations were transferredto a recording chamber (volume, 1.0 ml) and secured with stainlesssteel hooks. Preparations were superfused (3.0 ml/min; 36°C) withoxygenated Krebs' solution. Enteric ganglia were visualized onthe stage of a Zeiss (Axiovert 100) inverted microscope at a magnificationof 20 or 40×.

Preparation of isolated myenteric ganglia. Ganglia were isolated from the small intestine of adult guinea pigs according tothe method of Yau et al. (1989). Briefly, sheets of LMMP werestripped from segments of gut, placed in Krebs' solution (at 4°C),and minced with scissors. The tissue was incubated for 30 min(at 37°C) in Krebs' solution containing bovine serum albumin (BSA;0.1%; Sigma, St. Louis, MO), collagenase (type 1A; 0.25%; Sigma),protease (type XV; 0.2%; Sigma), and deoxyribonuclease (type I;25 µg/ml; Sigma). The partially digested tissue was mechanicallydisrupted by suction of the tissue into a pipette (100 µl) tofree the ganglia, and the suspension was placed on ice and allowedto settle. The pellet was resuspended in enzyme-free Krebs' solutioncontaining BSA and was allowed to settle again. The supernatantand aliquots of the pellet were placed in a plastic culture dish,and individual ganglia were visualized with a dissecting microscope(Olympus) and harvested by suction into a 20 µl pipette. Gangliawere placed in a culture dish containing maintenance medium (DMEM;GIBCO, Grand Island, NY) supplemented with 10% fetal bovine serum,penicillin (100 U/ml), and streptomycin (100 µg/ml).

Cell culture. Ganglia were plated, under microscopic control, onto sterile poly-L-lysine (100 µg/ml)- and laminin (10 µg/ml)-coatedglass coverslips (22 mm²) in petri dishes 35 mm in diameter. Approximately 20 gangliaper coverslip were grown in maintenance medium in a humidifiedincubator in an atmosphere containing 5% CO₂. The antimitoticagent cytosine arabinoside (10 µM; Sigma) was added to the cultureson day 3 to stop non-neuronal cell division. Ganglia were usedbetween 5 and 7 d in culture.

Exposure conditions. Whole-mount preparations and cultures of myenteric ganglia were exposed to glutamate (3 mM), NMDA (100µM), or kainic acid (300 µM), either alone or in the presenceof an antagonist. These concentrations of agonist were chosenbecause they cause cell death in CNS neurons. Moreover, in preliminarystudies, lower concentrations of these agonists did not affectthe viability of enteric neurons in whole-mount preparations,using the protocol of this study. The NMDA antagonist D-2-amino-5-phosphonopentanoate(AP-5; 50 µM) was present 10 min before, during, and after exposureto agonist.

Whole-mount preparations of gut were exposed to glutamate or NMDA in Krebs' solution (60 min). NMDA was prepared in Mg²⁺-free Krebs' solution, because it is known that the NMDA receptoris blocked by magnesium. After exposure, the solution was washedout thoroughly, and the preparations were pinned down in silicone-elastomer-coateddishes and cultured for 24-48 hr in DMEM containing streptomycinand penicillin as described above.

Coverslips containing isolated myenteric ganglia were placed in a chamber (Adams and List Associates, Westbury, NY) and mountedon the stage of an inverted microscope. Ganglia were then incubatedwith agonist-containing media for 60 min (glutamate, NMDA, andkainic acid). Exposure to drugs was performed at room temperaturein DMEM. After exposure, the solution was washed out thoroughlyand replaced with tissue culture medium before the dishes werereturned to the incubator. Little or no cell death [propidiumiodide (PI) uptake or formation of apoptotic nuclei] occurredin control tissues if this protocol was used and glutamate wasomitted.

Assessment of necrosis. Cell viability was determined (1) before exposure, (2) during exposure, and (3) 24 hr after exposureto drug. Preliminary studies showed that 1 d after exposure toglutamate (or agonist), the process of necrosis was primarilycomplete. Necrosis was assessed in all experiments by the fluorescentdye PI (Molecular Probes, Eugene, OR), which is excluded fromlive cells. Cell death in whole mounts of gut was determined usingthe combination of PI and SYTO-13 (Molecular Probes), a membrane-permeantdye that yields green fluorescent chromatin. Whole mounts of gutwere incubated with SYTO-13 (0.5 µM) for 30 min at 37°C, placedon the stage of an inverted microscope, and exposed to glutamate(or NMDA) in the presence of PI (5 µg/ml) for 60 min. SYTO-13-labeledcells were visualized by vertical fluorescence microscopy witha FITC filter set (excitation, 480 ± 15 nm; dichroic, 505 nm;emission, 535 ± 20 nm; Chroma). PI fluorescence was visualizedusing a rhodamine filter set (excitation, 540 ± 12.5 nm; dichroic,565 nm; emission, 605 ± 27.5 nm; Chroma). Switching between thetwo filter sets was done with a computer-controlled filter wheel(Sutter Instruments). An intensified CCD camera (VideoScope International)recorded the fluorescent images. All data acquisition and subsequentimage processing were done on a Pentium 100-based computer (Dell)with Metamorph imaging software (Universal Imaging Corporation,West Chester, PA). Images were taken every 5 min for 60 min inthe presence of a neutral density filter to minimize photobleachingand phototoxicity. For each image, eight frames were averagedfor each of the two excitation wavelengths.

Necrosis and viability in cell cultures were assayed using the combination of PI and fluorescein diacetate (FDA; MolecularProbes). Cultures were incubated (for 30 min) with FDA (15 µg/ml)and exposed to glutamate or kainic acid (300 µM) in the presenceof PI, as described above. PI exclusion and FDA uptake and metabolismwere used to determine cell viability. Living cells labeled withFDA were visualized with the interference filter set for fluorescein,and nuclei of dead cells were stained with PI and revealed withthe rhodamine filter.

PI labeling of glutamate (or agonist)-treated preparations was also determined 24 hr after exposure to drug. PI-labeled cellsin glutamate-exposed enteric ganglia were photographed and comparedwith PI-labeled cells in control preparations. To quantify theamount of cell damage, we digitized the photographic slides ofrepresentative ganglia with a slide scanner (SprintScan; Polaroid),and the number of PI-labeled cells per ganglion was determinedusing Metamorph imaging software.

Assessment of apoptosis. After exposure to glutamate, NMDA, or Krebs' solution (control), preparations were cultured for 48hr and fixed with 4% paraformaldehyde (3 hr at room temperature).In both whole mounts of enteric ganglia and cell cultures, apoptosiswas characterized by in situ fragmentation of DNA and was determinedusing a detection kit (ApopTag FITC Kit; Oncor) based on directimmunofluorescence detection of digoxigenin-labeled 3 $'$ -OH endsof genomic DNA fragments. The kit was used according to the manufacturer'sinstructions. Nonspecific labeling was investigated by omittingterminal deoxynucleotidyl transferase during the first step ofthe labeling procedure. In some experiments, enteric neurons werefirst labeled by demonstrating the immunoreactivity of neuron-specificenolase (NSE; see below).

Labeling with rhodamine 123. Mitochondria were stained with rhodamine 123 (R123; 10 µg/ml; Molecular Probes) for 15 min. R123stains mitochondria selectively by virtue of, and according to,their transmembrane potential (Duchen and Biscoe, 1992). The fluorescenceof the dye has been shown to be stable within neurons for >10hr (Bindokas and Miller, 1995). Images were obtained using standardrhodamine optics, as described above, before and during exposureto kainic acid. Fluorescence intensity was colorized to improvediscrimination of intensity values.

Immunocytochemistry. Laminar preparations of gut or isolated myenteric ganglia were fixed for 3 hr with 4% formaldehyde (freshlyprepared from paraformaldehyde) in 0.1 M sodium phosphate buffer,pH 7.4, at room temperature and washed 3 times with PBS. To locateproteins in the tissue by immunocytochemistry, we exposed thepreparations to PBS containing 0.5% Triton X-100 and 4% horseserum for 30 min to permeabilize the tissue and reduce backgroundstaining. Immunoreactivity was then demonstrated by incubatingthe tissues with affinity-purified rabbit polyclonal antibodies(24-48 hr; 4°C) to GluR1 and GluR2/3 (0.5 µg/ml; Petralia andWenthold, 1992), EAAC1 (0.06 µg/ml; Rothstein et al., 1993), GluR5/6/7(Huntley et al., 1993), or NSE (1:3000; Polysciences, Warrington,PA); mouse monoclonal antibodies to calbindin (CBP; 1:100; Sigma)or nonphosphorylated neurofilament H (SMI-32; 1:500; SternbergerMonoclonals); or goat antibodies to calretinin (1:6000; Chemicon,Temecula, CA) (see Table 1). In most experiments, bound antibodywas visualized by incubating tissues for 3 hr with indocarbocyanine(Cy3)-labeled or FITC-labeled species-specific secondary antibodiesto IgG (diluted 1:4000; Jackson ImmunoResearch, West Grove, PA);however, SMI-32 immunoreactivity was demonstrated with the Elitekit (Vector Laboratories, Burlingame, CA) and visualized withdiaminobenzidine (DAB substrate kit; Vector Laboratories). Thetissues were washed with PBS and coverslipped with Vectashield(Vector Laboratories). DAB-stained cultures were mounted in glyceroland borate buffer. Control sections were incubated without primaryantibody. Cy3 fluorescence was visualized using a Chroma Opticalfilter set (excitation, 540 ± 12.5 nm; dichroic, 565 nm; emission,605 ± 27.5 nm).

Table 1. Primary antisera used

Antiserum Host species Dilution Source Demonstration of specificity citations

Glutamate Rabbit 1:500 Chemicon, Temecula, CA Marc et al., 1990; Kalloniatis and Fletcher, 1993

GluR1 Rabbit 1.0 µg/ml Gift of Dr. R. J. Wenthold, NIH Petralia and Wenthold, 1992; Wenthold et al., 1992; Liu et al., 1997

GluR2/3 Rabbit 0.5 µg/ml Gift of Dr. R. J. Wenthold, NIH Petralia and Wenthold, 1992; Wenthold et al., 1992; Liu et al., 1997; recognizes both subunit proteins

SMI-32 Mouse 1:500 Sternberger Monoclonals Inc., Baltimore, MD Reacts with a nonphosphorylated epitope in neurofilament H

NR1 Rabbit 1.0 µg/ml Gift of Dr. R. J. Wenthold, NIH Petralia et al., 1994b; directed against the C terminus of the rat NMDAR1 receptor and recognizes four of the eight receptor splice variants

NR2A/B Rabbit 1.0 µg/ml Gift of Dr. R. J. Wenthold, NIH Petralia et al., 1994a; recognizes the A and B subunits of the NMDAR2 receptor

EAAC1 Rabbit 0.06 µg/ml Gift of Dr. J. D. Rothstein, Johns Hopkins University Rothstein et al., 1993; Liu et al., 1997

GluR5/6/7 Rat 4 µg/ml Pharmingen, San Diego, CA Recognizes common epitope to kainic acid receptor subunits GluR5-7; Chen et al., 1996

Calretinin Goat 1:6000 Chemicon, Temecula, CA Jacobowitz and Winsky, 1991

Calbindin Mouse 1:100 Sigma, St. Louis, MO Reacts specifically with calbindin-D (28 kDa)

Glutamate-immunoreactive structures were identified by immunocytochemistry with rabbit antibodies to glutamate (Marc et al.,1990; Kalloniatis and Fletcher, 1993). Rabbit antisera raisedagainst glutamate conjugated by glutaraldehyde to thyroglobulinwere obtained from Chemicon. Tissues were fixed with paraformaldehyde(4.0%) and glutaraldehyde (0.5%) for 1 hr at room temperature.The antibody is specific for glutamate fixed to proteins by glutaraldehyde.Preparations were then placed in sodium cyanoborohydride (1.0%for 30 min), rinsed, and processed by immunocytochemistry as describedabove. The primary antibody (diluted 1:500-1000) was applied for24-48 hr at 4°C. Double-label immunocytochemistry was used toexamine the coexpression of glutamate and calbindin. It was madepossible by using primary antibodies raised in different species.Immunoreactivity was visualized with species-specific secondaryantibodies coupled to different fluorophores.

Confocal microscopy. Whole mounts were examined using an LSM 410 Laser Scanning Confocal Microscope (Zeiss, Thornwood, NY)equipped with a krypton/argon laser and attached to a Zeiss Axiovert100 television microscope. Usually, 5-10 optical sections weretaken at 0.5 µm intervals. Images of 512 × 512 pixels were obtainedand processed using Adobe Photoshop 3.0 (Adobe Systems, MountainView, CA) and printed using a Tektronix Phaser 440 printer.

Drugs. Compounds used included (1) glutamic acid from Sigma, (2) AP-5 and NMDA from Tocris Cookson (St. Louis, MO), and (3)kainic acid from Research Biochemicals (Natick, MA).

Statistics. All statistical comparisons were done by one-way ANOVA, followed by Dunnett's t test (p < 0.05; Statview 4.5).

RESULTS

Glutamate induces necrosis in a subset of enteric neurons
Enteric cells loaded with the membrane-permeant chromatin dye SYTO-13 were exposed to glutamate in the presence of the membrane-impermeantchromatin dye PI, according to the method of Ankarcrona et al.(1995). Although cells with intact membranes retained the greenfluorescence of SYTO-13 and excluded PI, nuclei of cells withdamaged membranes were progressively stained by PI and shiftedto orange-red because PI gained entry into the nucleus (Fig. 1A).Within 10 min of exposure to glutamate, 3.1 ± 0.2 cells in submucosalganglia took up PI (Fig. 1A). PI-labeled nuclei were large andappeared to belong to neurons. The number of necrotic cells increasedwith time; however, no further increase occurred after 40 minof exposure to glutamate. At this time, 5.4 ± 0.3 cells/ganglionwere stained by PI. In contrast to cells in submucosal ganglia,cells in myenteric ganglia retained the green SYTO-13 color andexcluded PI (Fig. 1B). These results demonstrate that during glutamateexposure a subset of submucosal neurons died by necrosis; however,myenteric neurons remained healthy. PI did not stain cells withinenteric ganglia in control preparations; however, PI-labeled nucleiwere observed in the connective tissue surrounding ganglia (Fig.1A,B). These cells may have been damaged by the dissection.
Fig. 1. Top. Glutamate induces necrosis in enteric neurons. A, Whole mounts of submucosa were incubated with SYTO-13 to loadenteric cells. Preparations were exposed to glutamate in the presenceof PI for 60 min. Neurons that died by necrosis progressivelyexhibited a fluorescence shift from green to yellow to red becausePI gained entry into the nucleus 1, Control. SYTO-13-labeled nuclei(green) are present within a ganglion. 2, After a 10 min exposureto glutamate (3 mM). 3, After a 30 min exposure to glutamate (3mM). Three neurons took up PI (arrows). B, Myenteric ganglionafter a 30 min exposure to glutamate. Only SYTO-13-labeled cellsare present within the ganglion; however, PI-labeled cells arepresent outside the ganglion. C, Myenteric ganglion exposed toglutamate (60 min) and subsequently reincubated in culture mediumfor 24 hr. Many SYTO-13-labeled nuclei within the ganglion havetaken up PI (shift toward yellow fluorescence). D, Necrosis ofenteric cells stimulated by glutamate. Whole mounts of entericganglia (n = 10) were exposed to glutamate (Glut; 60 min) andthen incubated in culture medium for 24 hr. A significant numberof cells underwent necrosis in both enteric plexuses. Necroticcells include neurons and probably glia. The NMDA antagonist D-2-amino-5-phosphonopentanoate(AP-5) blocked glutamate-induced necrosis. *p < 0.001. Scale bars:A-C, 30 µm.
Fig. 2. Bottom. Glutamate and NMDA induce apoptosis in enteric neurons. Preparations of gut were exposed to glutamate or NMDA(60 min) and subsequently reincubated in culture medium for 48hr. A, Submucosal ganglion in a control preparation. NSE (red)immunoreactivity is present in a subset of cell bodies (arrow)and nerve fibers. B-D, Exposure to glutamate induces apoptosis(arrow; green) in submucosal (B) and myenteric (C) NSE-immunoreactiveneurons and in cells in the circular muscle layer (D). E, NMDAproduces apoptosis in myenteric neurons (arrow). F, The effectof NMDA is blocked by AP-5. Scale bars, 30 µm.

[View Larger Version of this Image (89K GIF file)]

To investigate whether enteric neurons that survived the early phase of glutamate exposure underwent delayed cell death, wereincubated whole mounts of glutamate-exposed gut in normal mediumfor 24 hr. Within 24 hr of exposure to 3 mM glutamate, the majorityof submucosal and myenteric neurons took up PI, resulting in theyellow fluorescence observed in Figure 1C. The yellow color wasproduced by the superimposition of the red and green dyes. Bothlarge and small nuclei were double-labeled with SYTO-13 and PI.PI-labeled cells were not found in ganglia in control tissue (Fig.1D); however, nuclei in the serosa and longitudinal muscle werelabeled (data not shown). Lower concentrations of glutamate (500µM-1 mM) did not produce necrosis in submucosal or myenteric neuronsusing this protocol.

In the CNS, excitotoxicity is mediated, at least in part, by NMDA receptors (Choi et al., 1988). Enteric neurons express bothNR1 and NR2A/B subunits and are depolarized by NMDA (Liu et al.,1997); therefore, we examined the ability of the NMDA antagonistAP-5 to antagonize glutamate-induced necrosis in enteric neurons.AP-5 (50 µM) was present before (10 min), during, and after (10min) the exposure to glutamate (as described above). The preparationswere then incubated for 24 hr in culture medium. Necrosis wasdetermined by PI uptake. Treatment of preparations of gut withAP-5 prevented glutamate-induced necrosis (Fig. 1D); therefore,glutamate-mediated neurotoxicity in enteric neurons, as seen incentral neurons, is also dependent on events linked to NMDA receptoractivation.

Glutamate and NMDA induce apoptosis in enteric neurons
The next set of experiments was performed to determine whether enteric neurons exposed to glutamate underwent delayed celldeath by apoptosis. Preparations of bowel were incubated withglutamate, as described above, followed by normal medium for 48hr. The preparations were then fixed, permeabilized, and stainedwith the terminal deoxynucleotidyl transferase-mediated dUTP-biotinnick end labeling (TUNEL) method. After exposure to glutamate,cells in submucosal and myenteric ganglia had apoptotic nuclei(Fig. 2B,C). Double labeling with antibodies to NSE was used todetermine whether neurons were labeled by TUNEL. NSE-immunoreactivenerve cell bodies and fibers were detected in submucosal (Fig.2A,B) and myenteric ganglia (Fig. 2C,E,F). A subset of apoptoticnuclei belonged to enteric neurons in both plexuses (Fig. 2B,C).Apoptotic nuclei also belonged to non-neuronal cells, includingmuscle cells in the circular (Fig. 2D) and longitudinal musclelayers and, probably, enteric glia. Apoptotic nuclei of entericneurons were significantly smaller than were the nuclei of necroticor normal neurons (p < 0.05; n = 30). The number of apoptoticneurons within enteric ganglia was determined (Fig. 3). On average,~50 cells were apoptotic in myenteric ganglia (n = 100). No apoptoticcells were detected in enteric ganglia exposed to Krebs' solutionalone. Apoptosis also occurred after exposure of enteric gangliato NMDA (Figs. 2E, 3). The number of apoptotic cells per ganglionproduced by exposure to NMDA was similar to that produced by exposureto glutamate. AP-5 significantly (p < 0.05) blocked NMDA-inducedapoptosis (Figs. 2F, 3). AP-5 was present before, during, andafter exposure to NMDA.
Fig. 3. Apoptosis of enteric neurons stimulated by glutamate or NMDA. Neuronal apoptosis is produced by exposure to glutamate (orNMDA) in whole-mount preparations of LMMP (n = 10) and in culturedmyenteric ganglia (n = 8). Apoptosis is attenuated by AP-5.
[View Larger Version of this Image (30K GIF file)]

Myenteric ganglia in culture
Exposure of whole-mount preparations of gut to glutamate produced cell death in a subset of enteric neurons. Necrosis wasobserved in submucosal neurons both during and after the exposureto glutamate; however, only delayed death occurred in myentericneurons. It is well known that excitotoxicity is more pronouncedin cell culture (Choi et al., 1987). Many of the difficultiesencountered in applying glutamate to intact systems are becauseof the presence of an avid glutamate transport system. The immunoreactivitiesof three high-affinity glutamate transporters have been detectedin enteric ganglia (Liu et al., 1997). High concentrations ofglutamate are required to depolarize enteric neurons, unless glutamateuptake is blocked (Liu et al., 1997). These results suggest thatthe problems of glutamate uptake may also pertain to whole mountsof the bowel; therefore, we studied the effects of glutamate onneurons from cultured myenteric ganglia.

An average of 11 of 20 myenteric ganglia became attached to the coverslip and began to extend neurites on day 3 in culture.Neurites grew progressively and eventually made contact with neuritesfrom other ganglia. The presence of neuronal cell bodies and nervefibers was confirmed by the demonstration of calretinin (Fig.4A,B) and calbindin (Fig. 4C) immunoreactivities. Calretinin-and calbindin-immunoreactive neurons were present in isolatedganglia. Calretinin-immunoreactive neurons were abundant (Fig.4A) and were characterized by short, stubby dendrites (Fig. 5B),a feature consistent with Dogiel type I morphology (Costa et al.,1996). A subset of calretinin-immunoreactive neurons migratedaway from the ganglia and extended neurites into the periphery(Fig. 4A). Calbindin-immunoreactive neurons were only found withinthe core of ganglia. These neurons had smooth cell bodies, a featureconsistent with Dogiel type II morphology (Furness et al., 1994).Calbindin-immunoreactive processes were rare. The number of calbindin-immunoreactiveneurons within a ganglionic core was ~15 neurons per ganglion(counts from five ganglia). This is less than the number of neuronsin intact myenteric ganglia of guinea pig small intestine.
Fig. 4. Characterization of cultured myenteric neurons. A, B, Calretinin-immunoreactive neurons are numerous in cultured myentericganglia. Neurons are characterized by short dendrites (B). C,Calbindin-immunoreactive neurons are also found in cultured myentericganglia; however, they have a relatively smooth appearance. Scalebars, 30 µm.
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Fig. 5. Glutamate-immunoreactive neurons are found in cultured myenteric ganglia. A-C, Glutamate immunoreactivity is found in a subsetof cell somas and is abundant in varicose processes. Glutamateimmunoreactivity appears to be present on spines (C; arrows).D, E, A subset of glutamate-immunoreactive neurons (D; arrow)contains calbindin immunoreactivity (E; arrow). F, A subset ofcultured myenteric neurons expresses EAAC1 immunoreactivity. Themajority of EAAC1-immunoreactive cells are smooth in shape; however,"star-shaped" EAAC1-immunoreactive cells are also observed (inset).Scale bars, 30 µm.
[View Larger Version of this Image (145K GIF file)]

Cultured myenteric ganglia contain glutamatergic neurons and neurons that express EAAC1 immunoreactivity
If glutamate mediates neurotoxicity in the ENS, then as seen in other sites where excitotoxicity occurs, cultured myentericganglia would be expected to contain neurons that can be demonstratedwith glutamate-selective antibodies (Marc et al., 1990; van denPol, 1991). Glutamate-immunoreactive neurons were found in culturedmyenteric ganglia (Fig. 5A,B,D). All of the glutamate-immunoreactiveneurons expressed choline acetyltransferase (ChAT) immunoreactivity(data not shown), and a subset also contained calbindin immunoreactivity(Fig. 5D,E). All of the glutamate-immunoreactive neurons exhibitedDogiel type II morphology (Fig. 5A,B,D); nevertheless, only ~10%of them costored calbindin, which is a marker associated with~70% of Dogiel type II myenteric neurons (Costa et al., 1996).

Glutamate-immunoreactive processes were abundant in culture. Processes were highly varicose both within and extending awayfrom ganglia (Fig. 5A-D). Glutamate immunoreactivity was presentat sites that appeared to look like spines (Fig. 5C) and at pointsof contact between neurites (Fig. 5A,C). Glutamate immunoreactivitywas also enriched in growth cones. Varicose axons occasionallyformed baskets around neuronal cell bodies (Fig. 5B).

Cultured myenteric ganglia were immunostained with antibodies against a high affinity glutamate transporter to determine whetheran inactivating mechanism is present to terminate the action ofglutamate. Four high affinity glutamate transporters have beenidentified in rat and/or human CNS tissue, including the neuronalsubtypes EAAC1 and EAAT4 (Rothstein et al., 1994; Kanai et al.,1995) and the astroglial subtypes GLT-1 and GLAST (Rothstein etal., 1994; Storm-Mathisen et al., 1995). Antibodies to the neuronaltransporter EAAC1 (Rothstein et al., 1994) were used to test immunocytochemicallythe hypothesis that this molecule is present in cultured myentericganglia. A subset of enteric neurons was found to be EAAC1 immunoreactive(Fig. 5F). These cells were predominantly Dogiel type II, theshape associated with glutamate-immunoreactive neurons (see above);however, smaller, EAAC1-immunoreactive cells were also present(Fig. 5F, inset). EAAC1 immunoreactivity was punctate and wasfound within the cytoplasm and proximal processes of labeled cells.EAAC1-immunoreactive neurites were found within ganglia.

Ionotropic glutamate receptors are found within cultured myenteric ganglia
The distribution of NMDA (NR1 and NR2A/B) receptor subunits in isolated myenteric ganglia was examined using subunit specificantibodies (Table 1). NR1 and NR2A/B immunoreactivities werefound in cultured ganglia (Fig. 6A-C). Immunoreactivity was punctateand found in the soma of the majority of enteric neurons (Fig.6C). NR1 immunoreactivity was also found in neurites that extendedaway from cultured ganglia (Fig. 6A,B). "Hotspots" of immunoreactivitywere present at the sites of intersection between neurites (Fig.6B), and NR1 immunoreactivity was frequently enriched in growthcones (data not shown).
Fig. 6. Ionotropic glutamate receptor immunoreactivity is found in cultured myenteric ganglia. A-C, A subset of cultured myentericneurons express NR1 immunoreactivity. Punctate immunoreactivityis found in the cytoplasm. Moreover, clusters of NR1 immunoreactivityare found along neurites (A, B), near neurite intersections (B;arrow). D, A subset of cultured myenteric neurons express GluR1immunoreactivity. E, F, A subset of cultured myenteric neuronsexpress GluR2/3 immunoreactivity. Immunostaining is found in thesoma and neurites. B, E, F, Confocal photomicrographs. Scale bars,30 µm.
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To compare the localization of other ionotropic glutamate receptor subunits with that of NR1 and NR2A/B, we used antibodiesagainst the AMPA-selective glutamate receptor subunits GluR1 andGluR2/3 (Table 1). The majority of neurons were immunopositivefor GluR1 (Fig. 6D) and GluR2/3 (Fig. 6E,F). GluR2/3-immunoreactiveprocesses were also observed (Fig. 6E,F).

Glutamate induces necrosis and apoptosis in cultured myenteric ganglia
In contrast to myenteric neurons in whole-mount preparations, cultured myenteric neurons were extremely sensitive to glutamateexposure. To examine the fate of cultured enteric neurons, weloaded cells with FDA according to the method of Jones and Senft(1985). This procedure is based on the hydrolysis of FDA to fluoresceinby nonspecific esterases in the cells. The fluorescein is retainedonly in cells that have an intact cell membrane. FDA-labeled neuronswere visualized with the interference filter set for fluoresceinand exposed to glutamate (3 mM) in the presence of PI (for 1 hr).

Before the exposure to glutamate (or in control preparations), FDA-labeled neurons were abundant in cultured ganglia (Fig.7A). Some PI-labeled nuclei were also observed; however, thesecells were never labeled with FDA and probably consisted of non-neuronalcells that were killed by cytosine arabinoside. During the exposureto glutamate, cells lost the green fluorescence of FDA, and nucleiof cells with damaged membranes were progressively stained byPI (Fig. 7B) and shifted to orange-red because PI gained entryinto the nucleus (Fig. 7C). Within 4 min of exposure to glutamate,10.2 ± 0.4 FDA-labeled cells took up PI. The number of necroticcells increased with time, and at 22 min, 44.8 ± 3.6 cells werelabeled with PI. No further increase in PI-labeled cells was observed.Necrosis was characterized by swelling of the nucleus. In addition,red debris appeared in the culture dish from the cells that hadundergone necrosis. In contrast to cells exposed to glutamate,cells incubated with Krebs' solution retained the green FDA colorand excluded PI (data not shown). AP-5 significantly blocked glutamate-inducednecrosis in cultured enteric cells (p < 0.05); therefore, at leastpart of the neurotoxic effects of glutamate on cultured entericcells is mediated by NMDA receptors.
Fig. 7. Top. Glutamate induces necrosis in cultured myenteric neurons. Cultured myenteric ganglia were incubated with FDA tolabel viable enteric cells. Cultures were exposed to glutamatein the presence of PI. Neurons that died by necrosis progressivelyexhibited a fluorescence shift from green to yellow to red becausePI gained entry into the nucleus. A, Control. Numerous FDA-labeledcells (green) are present within a ganglion. B, After a 10 minexposure to glutamate (3 mM). C, After a 30 min exposure to glutamate(3 mM). Many FDA-labeled nuclei within the ganglion have takenup PI (shift toward red fluorescence). Scale bars, 30 µm.
Fig. 8. Middle. GluR5/6/7 immunoreactivity is found in enteric ganglia. A, B, GluR5/6/7-immunoreactive neurons are presentin submucosal ganglia. C, GluR5/6/7-immunoreactive varicositiesencircle an unlabeled myenteric neuron ( $star$ ). Scale bars, 30 µm.

Fig. 9. Bottom. Treatment of cultured myenteric neurons with kainic acid leads to cell swelling, growth of varicosities (blebs),and loss of mitochondrial membrane potential. A-C, Cultured myentericneurons exposed to kainic acid and immunostained with antibodiesto SMI-32. After kainic acid treatment, blebs are found (arrows)on SMI-32-immunoreactive neurites near neurite intersections (C;arrowheads). D, Control. Blebs are not found on SMI-32-immunoreactiveneurites in cultures exposed to Krebs' solution alone. E, Pseudocoloredimage of R123 intensity. Mitochondria stained with rhodamine 123(R123) are clustered along neurites, often near neurite intersections(arrow). F-H, Pseudocolored images of R123 staining (arrows) ina neurite before (F), immediately after (G), and 5 min after (H)exposure to kainic acid. Kainic acid causes a collapse of mitochondrialmembrane potential as indicated by an increase in fluorescence(G). There is also a more uniform distribution of the dye. Becausedepolarization is prolonged, there is an eventual loss of thedye (H). Staining intensity is colorized as indicated by the scale.Scale bars, 30 µm.

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When glutamate-treated isolated ganglia were cultured for 24 hr, apoptotic nuclei were found (Fig. 3). Apoptotic nuclei couldbe seen among normal cells; therefore, only a subset of cellsunderwent apoptosis. Unlike excitotoxin-induced necrosis, cellsundergoing apoptosis because of glutamate exposure remained adherentto the culture dish with their projections intact.

Kainate receptor subunit immunoreactivity is found in enteric ganglia
Necrosis and apoptosis of central neurons are also mediated by excessive activation of non-NMDA receptors (Choi, 1988). Prolongedstimulation of cultured cerebellar neurons with kainic acid resultsin swelling of somas and growth of varicosities or blebs, followedby degeneration (Bindokas and Miller, 1995). The hypothesis thatkainic acid is an enteric excitotoxin requires that enteric neuronsexpress kainate receptors. Immunocytochemistry was thus used todetermine whether evidence of the expression of this receptorcould be obtained. Antibodies to the C-terminal portions of kainatereceptor subunits GluR5/6/7 were used to identify immunocytochemicallythe neurons on which these receptor subunits are located (Table1).

Intense GluR5/6/7 immunoreactivity was present throughout the ENS in rats (Fig. 8A-C). In general, immunolabeling was cytoplasmic,filling the perikarya and, occasionally, the proximal dendritesof a subset of enteric neurons. In addition, the staining intensityof somata varied. Some were very intensely stained; others weremore lightly stained. The cytoplasmic localization of kainatereceptors in enteric neurons agrees with previous studies thathave visualized these receptors in fixed and permeabilized centralneurons, using C-terminal antibodies (Huntley et al., 1993). Atleast part of the internal labeling may represent receptor subunitsin synthesis or in transport to and from the cell membrane, similarto the proposals for AMPA-selective glutamate receptor subunits(Wenthold et al., 1990). GluR5/6/7-immunoreactive neurons wereonly found in submucosal ganglia (Fig. 8A,B); however, punctateimmunoreactivity was found in both submucosal and myenteric ganglia(Fig. 8A-C). Rings of immunoreactivity were found to circle asubset of myenteric neurons (Fig. 8C). No immunostaining was observedin control preparations incubated without primary antibodies.

Exposure to kainic acid produces blebs on enteric neurites and uncouples mitochondrial membrane potential
The neurotoxic effects of kainic acid on cultured myenteric neurons were investigated to determine whether, as the immunocytochemicaldata outlined above suggest, these cells express functional kainatereceptors. Cultured enteric ganglia were exposed (60 min) to kainicacid, fixed, and processed for the demonstration of SMI-32 immunoreactivity.Stimulation of enteric neurons with kainic acid resulted in theswelling of SMI-32-immunoreactive somas and the growth of varicosities(blebs) along neurites (Fig. 9A-C). Blebs formed at various pointsalong neurites that appeared to correspond to neurite intersections(Fig. 9C). Control cultures exposed to Krebs' solution alone didnot develop these morphological changes. SMI-32-immunoreactiveneurites in control cultures had varicosities; however, they wereuniform in size (Fig. 9D).

Mitochondrial function is a critical factor that determines the mode of neuronal death in excitotoxicity (Ankarcrona et al.,1995). Necrosis occurs in cultured CNS neurons in which exposureto glutamate or kainic acid produces a rapid collapse in mitochondrialmembrane potential. Apoptosis occurs in neurons that recover energylevels and mitochondrial membrane potential (Ankarcrona et al.,1995; Bindokas and Miller, 1995). In cerebellar granule cells,collapse in mitochondrial membrane potential produced by kainicacid occurs at sites of bleb formation (Bindokas and Miller, 1995);therefore, we determined whether a similar association occursin enteric neurons. Changes in mitochondrial membrane potentialwere monitored in individual enteric neurons by determining changesin the intensity of fluorescence of the dye R123. R123 stainsmitochondria selectively in accordance with their Nernst potential(Duchen and Biscoe, 1992). Collapse of the mitochondrial potentialleads to a release of the dye, an increase in fluorescence, andif stimulation continues, eventual loss of the dye. R123-labeledenteric neurons were exposed to kainic acid, as described above.Images were obtained using standard rhodamine optics, and changesin R123 intensity (mitochondrial membrane potential) were recordedusing an intensified CCD camera.

R123-stained mitochondria were abundant in cultured enteric neurons. Mitochondria were enriched in cell somas (data not shown)and nonuniformly distributed along neurites (Fig. 9E,F). R123-labeledmitochondria were concentrated at neurite intersections (Fig.9E). Application of kainic acid produced a rapid increase (within15 sec) in R123 fluorescence, indicating a collapse of mitochondrialmembrane potential (Figs. 9F,G, 10). A change from a punctate toa diffuse staining pattern within neurites was also observed (Fig.9G). R123 fluorescence intensity gradually decreased during theexposure to kainic acid and, within 5 min, returned to baselinevalues (Figs. 9H, 10). Changes in mitochondrial membrane potentialwere not observed in control cultures exposed to Krebs' solutionalone. When kainic acid exposed preparations were fixed and processedby immunohistochemistry, SMI-32-immunoreactive blebs were foundat sites exhibiting intense R123 fluorescence (data not shown).These results are consistent with the idea that loss of mitochondrialfunction because of excessive stimulation of kainate receptorsis linked with bleb formation in enteric neurons.
Fig. 10. The results depicted in Figure 9F-H are shown graphically. R123 intensity in six boutons (arrows in Fig. 9F) was quantified,background-subtracted, and plotted as a function of time. Applicationof kainic acid (KA) results in an immediate increase in R123 fluorescence,consistent with a loss of mitochondrial potential; however, asexposure to KA continues, R123 intensity decreases with eventualloss of the dye.
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DISCUSSION
Glutamate neurotoxicity was observed in a subset of enteric neurons in both intact preparations of bowel and cultured myentericganglia. Both acute and delayed cell deaths were observed. Exposureof whole-mount preparations of submucosa to glutamate resulted,within minutes, in the death of a subset of neurons. Acute necrosisin enteric ganglia was not observed in LMMP preparations; however,exposure to glutamate resulted by the following day in widespreadneuronal death in myenteric ganglia. A high concentration of glutamatewas needed to produce excitotoxicity in whole-mount preparationsof gut. Glutamate neurotoxicity is difficult to study in intactsystems because of the presence of rapid glutamate uptake. Evenin brain slice preparations, high concentrations of glutamateare required to achieve toxic extracellular concentrations (Garthwaite,1985). It seems likely that the rapid uptake of glutamate in thebowel, mediated by high affinity glutamate transporters includingthe EAAC1 transporter, which is expressed not only by glutamatergicneurons but probably also by their follower cells (Liu et al.,1997), masks the actions of exogenous glutamate on enteric neurons,unless either a high concentration of glutamate is applied orthe transporter is inhibited. Consistent with this idea, exposureto glutamate produced rapid and widespread neuronal cell lossin cultured myenteric ganglia (see below).

Delayed neuronal cell death in enteric ganglia was prevented by the selective NMDA antagonist AP-5. Furthermore, the neurotoxiceffects of glutamate were mimicked by exposure to NMDA. Thesefindings are consistent with the hypothesis that the late phaseof neurotoxicity in the ENS is mostly mediated via the activationof the NMDA receptor. NMDA receptors are abundant in the ENS.Virtually all enteric neurons express both NR1 and NR2A/B subunitmRNA and protein (Burns et al., 1994; Burns and Stephens, 1995;Liu et al., 1997). NR1 subunits are required for the functionalexpression of NMDA receptor channels in CNS neurons; therefore,functional NMDA receptors may be expressed by nearly all typesof enteric neuron. The expression of NR1 subunits by the majorityof enteric neurons suggests that all types of enteric neuron aresusceptible to NMDA excitotoxicity; however, excitotoxicity wasobserved in only a subset of enteric neurons. NMDA receptors withdifferent physiological and pharmacological properties have beendemonstrated; therefore, it is possible that some enteric neuronsmay express NMDA receptors with different functional properties(such as a low Ca²⁺ permeability) from other neurons. Inclusion of various NR2 subunitsin the NMDA receptor composition is one mechanism for such diversity.Studies have shown that varying the particular NR2 subunit combinedwith NR1 yields NMDA receptor channels differing in glycine sensitivityand channel deactivation time (Monyer et al., 1992). A full knowledgeof NMDA receptor composition in different classes of enteric neuronis needed to understand the vulnerability of certain neurons toNMDA toxicity.

Because excitotoxicity is dependent on calcium influx (Choi, 1995) and NMDA-activated channels are permeable to calcium (MacDermottet al., 1986; Mayer and Westbrook, 1987), it seems likely thatactivation of enteric NMDA receptors increases [Ca²⁺]_i. Consistent with this idea, glutamate has been found to increase[Ca²⁺]_i in enteric neurons (Kimball and Mulholland, 1995). Moreover,preliminary data indicate that the effects are mimicked by NMDA(Kirchgessner and Liu, 1996).

In addition to necrosis, glutamate exposure produced apoptosis is a subset of enteric neurons. Apoptotic nuclei were observedin both enteric plexuses and in the muscle layers 48 hr afterglutamate exposure. Apoptotic nuclei were smaller than the nucleiof necrotic cells, and unlike necrotic neurons, apoptotic neuronsexpressed NSE immunoreactivity. Blockade of NMDA receptor channelsby AP-5 protected neurons from apoptosis, suggesting that Ca²⁺ influx through these channels was the initial trigger for thedelayed apoptotic cell death. The formation of apoptotic nucleiafter the exposure to glutamate has been shown to be time anddose dependent (Ankarcrona et al., 1995). Hippocampal neuronsundergo apoptosis ~48 hr after exposure to glutamate (Nitatoriet al., 1995). This corresponds well with the time course of developmentof apoptosis in enteric neurons. Under our conditions, a 60 minexposure to glutamate resulted in apoptosis after a 48 hr incubationin culture medium. At this time, ~50% of myenteric neurons wereapoptotic.

In contrast to whole-mount preparations of gut, cultures of myenteric neurons were shown to be highly susceptible to excitotoxicdamage by glutamate. Cultures of myenteric ganglia contained glutamatergicneurons, as do myenteric ganglia in intact preparations of bowel(Liu et al., 1997). In addition, calbindin- and calretinin-immunoreactiveneurons were observed, which represent putative sensory neuronsand motor neurons, respectively (Furness et al., 1994; Costa etal., 1996). A large subset of myenteric neurons became necroticduring glutamate exposure. Cultured neurons that survived theearly phase of excitotoxicity underwent apoptosis within 24 hr.Cells were identified as neurons because they expressed NSE immunoreactivity.It is likely that in cell culture, uptake mechanisms for removingglutamate from the extracellular space are reduced. In isolatedretinal neurons, glutamate is 1000 times more potent than it isin slice preparations because it is not cleared by a transportsystem (Massey and Maguire, 1995). The immunoreactivities of threehigh affinity glutamate transporters have been detected in entericganglia (Liu et al., 1997); therefore, glutamate uptake may limitthe effects of glutamate on enteric neurons.

Glutamate-induced necrosis and apoptosis in cultured enteric cells were mimicked by NMDA and blocked by an NMDA antagonist;therefore, in cultured enteric ganglia, glutamate toxicity isalso attributed to the overstimulation of the NMDA subtype ofreceptor. Cultured myenteric neurons expressed both NMDA and non-NMDAreceptor immunoreactivity. Immunohistochemical studies indicateda predominantly somatodendritic localization of NMDA- and AMPA-selectiveglutamate receptors, consistent with a postsynaptic function forreceptors composed of these subunits. Enteric glutamate receptorswere clustered along neurites. Recent reports have demonstratedthat both voltage-sensitive Ca²⁺ channels and glutamate receptors are spatially clustered on culturedCNS neurons at sites that appear to correlate with the localizationof synapses (Craig et al., 1993). In our cultures, clusters ofglutamate receptor immunoreactivity were associated with neuriteintersections, sites at which synapses are also likely to form.

In CNS neurons, excitotoxicity is also produced by prolonged stimulation of glutamate receptors with kainic acid, an agonistat AMPA and kainate receptors (Kato et al., 1991; Simonian etal., 1996). Like NMDA, kainic acid increases [Ca²⁺]_i (Brorson et al., 1994). Moreover, rises in [Ca²⁺]_i because of kainic acid exposure are associated with the growthof varicosities (blebs) along neurites and a loss of mitochondrialmembrane potential (Bindokas and Miller, 1995). We determinedwhether exposure to kainic acid produces morphological changesand/or disruptions in mitochondrial membrane potential in entericneurons.

We first determined whether kainate receptor immunoreactivity is found in the ENS using antibodies against kainate-selectivesubunits, GluR5/6/7. Punctate GluR5/6/7 receptor immunoreactivitywas observed in the ENS. GluR5/6/7-immunoreactive neurons wereonly found in the submucosal plexus; however, GluR5/6/7-immunoreactivevaricosities were present in both enteric plexuses. Exposure ofcultured myenteric ganglia to kainic acid produced cell swellingand the formation of blebs along neurites. Blebs formed closeto neurite intersections, sites that were enriched in mitochondriaas revealed by R123 staining. As observed in cerebellar neurons(Bindokas and Miller, 1995), kainic acid produced a collapse inmitochondrial membrane potential in enteric neurons at sites ofbleb formation. Whether the blebs were spatially related to pointsof Ca²⁺ entry, because of the stimulation of glutamate receptors, needsto be determined.

In summary, our data indicate that excitotoxicity occurs in the ENS. Excitotoxicity consists of necrosis and apoptosis inenteric neurons and seems to be primarily mediated by entericNMDA receptors. In the CNS, excitotoxicity is involved in theinjury produced by hypoxia and ischemia (Choi, 1988). Both conditionsare associated with a buildup of extracellular glutamate, an increasein [Ca²⁺]_i, and the generation of nitric oxide (Dawson et al., 1991; Izumiet al., 1992). Hypoxic and ischemic damage occur in peripheraltissues. Intestinal mucosal damage has been reported after intestinalhypoxia and ischemia (Matthews et al., 1995) and may similarlyinvolve excessive activation of glutamate receptors. Excitotoxinsare also present in food and may cause gastrointestinal dysfunction(Perl et al., 1990; Olney, 1994). The most dramatic example ofacute excitotoxin poisoning is the toxic syndrome associated withthe ingestion of domoic acid, a contaminant found in mussels."Shellfish poisoning," which is caused by the ingestion of musselscontaminated by domoic acid, a potent ionotropic non-NMDA receptoragonist, is characterized by severe gastrointestinal symptoms(nausea, vomiting, and diarrhea), profuse respiratory secretions,seizures, and ultimately death (Perl et al., 1990). The evidencedescribed here suggests that glutamate may indeed have a functionalrole in the ENS; therefore, enteric glutamate receptors may havepharmacological importance as targets for drug actions.

FOOTNOTES

Received July 16, 1997; revised Aug. 26, 1997; accepted Aug. 28, 1997.

This work was supported by National Institutes of Health Grants NS 01582 and NS 35951 (A.L.K.). We are especially gratefulto Drs. J. D. Rothstein (Johns Hopkins University) and R. J. Wenthold(National Institutes of Health) for their generous contributionof antibodies. We thank Theresa Swayne for assistance with confocalmicroscopy.

Correspondence should be addressed to Dr. Annette Kirchgessner, Department of Anatomy and Cell Biology, Columbia University,College of Physicians and Surgeons, 630 West 168th Street, NewYork, NY 10032.

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