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¹ INSERM U583, Institut des Neurosciences de Montpellier, Groupe d'Etude des Désordres Vestibulaires, Hôpital Saint Eloi, BP74 103, 34091 Montpellier Cedex 5, France
² Institut de Génomique Fonctionnelle, Département de Pharmacologie Moléculaire, CNRS UMR5203, 141 Rue de la Cardonille, 34094 Montpellier Cedex 5, France

	Abstract

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Glutamate is thought to be the main neurotransmitter at the synapse between the type I vestibular hair cell and its cognate calyx afferent. The present study was designed to identify the type of glutamate receptors involved in neurotransmission at this unusual synapse. Immunocytochemistry showed that AMPA GluR2, NMDA NR1 and NR2A/B subunits of the glutamate receptors were confined to the synaptic contact. We then examined the electrical activity at calyx terminals using direct electrophysiological recordings from intact dendritic terminals in explanted turtle posterior crista. We found that sodium-based action potentials support a background discharge that could be modulated by the mechanical stimulation of the hair bundle of the sensory cells. These activities were prevented by blocking both the mechano-electrical transduction channels and L-type voltage-gated Ca²⁺ channels involved in synaptic transmission. Although pharmacological analysis revealed that NMDA receptors could operate, our results show that AMPA receptors are mainly involved in synaptic neurotransmission. We conclude that although both AMPA and NMDA glutamate receptor subunits are present at the calyx synapse, only AMPA receptors appear to be involved in the synaptic transmission between the type I vestibular hair cell and the calyx afferent.

(Received 4 July 2006; accepted after revision 31 July 2006; first published online 3 August 2006)
Corresponding authors J. Bonsacquet & C. Chabbert: INSERM U583, Institut des Neurosciences de Montpellier, Hôpital Saint Eloi, BP74 103, 80 Rue Fliche, 34091 Montpellier Cedex 5 France. Email: jbonsacquet{at}univ-montp2.frcchabbert{at}univ-montp2.fr

	Introduction

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The vestibular calyx synapse is an unusual structure formed by an extension of the primary vestibular neuron terminals surrounding the basolateral part of the type I vestibular hair cell. In evolution, the development of this structure coincided with the conquest of the air and land by the higher vertebrates (Wersall, 1956). The nature of the glutamate receptors involved in neurotransmission at this synapse remains unknown, despite being essential for the transfer of the vestibular sensory information. There is no doubt that chemical synaptic transmission occurs at the calyx synapse since the type I hair cell has dense vesicles closely associated with synaptic ribbons (Hamilton, 1968; Gulley & Bagger-Sjoback, 1979; Goldberg et al. 1990; Lysakowski & Goldberg, 1997). The physiological evidence for chemical neurotransmission derives from recording of miniature excitatory postsynaptic potentials (mEPSPs) in vestibular primary neurons in the crista ampullaris of lizards (Schessel et al. 1991) or chickens (Yamashita & Ohmori, 1990). However, neither the neurotransmitter nor the type of the receptors involved in generating the synaptic activities could be identified, because of the lack of pharmacological characterization in these studies. Immunocytochemical studies in mammals revealed that subunits from the AMPA-type glutamate receptor (Matsubara et al. 1999) or the NMDA-type receptor (Ishiyama et al. 2002) are present at calyx terminals of vestibular primary neurons, whereas the mRNAs of several glutamate receptor subunits have been identified in their somata (Fujita et al. 1994; Niedzielski & Wenthold, 1995). However, the role of these subunits in synaptic transmission at the calyx synapse remains to be determined.

Here, we investigated the presence of AMPA and NMDA receptors at the calyx synapse using immunocytochemistry for the GluR2, NR1 and NR2A/B subunits of the glutamate receptors. We also developed direct electrophysiological recordings at calyx terminals in situ in the turtle vestibular epithelia. We used the loose patch configuration of the patch-clamp technique, which preserves the integrity of the calyx structure, to record the spontaneous and the evoked activities triggered by mechanical deflections of the sensory cell's hair bundles. Our results reveal that although subunits from both AMPA and NMDA receptors are present at the calyx terminal, only AMPA receptors are involved in background and mechanically evoked synaptic transmission.

	Methods

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The animals were cared for and used in accord with the French Ministry of Agriculture and the European Community Council Directive no. 86/609/EEC, OJL 358, 18 December 1986. Turtles, Pseudemys scripta elegans (7 cm ventral diameter) were deeply anaesthetized by an intraperitoneal injection of 6% sodium pentobarbital (Sanofi-Synthelabo, Montpellier, France). The turtles were dissected at 4°C in artificial perilymph solution (APS) (mM): 137 NaCl, 5 KCl, 2 CaCl₂, 1 MgCl₂, 10 Hepes, 11 glucose, pH 7.35.

Immunocytochemistry

Turtle posterior cristae were fixed by immersion in paraformaldehyde, 4% in 0.1 M phosphate buffer saline (PBS, pH 7.4) at 4°C for 1 h. The samples were embedded in agarose, 4% in PBS (Invitrogen, Cergy Pontoise, France), and cut into 50 µm sections using a vibrating blade microtome (Vibratome series 1000, Technical Products International, St Louis, MO, USA) in ice-cold PBS. Free-floating sections were incubated for 1 h at 4°C in PBS containing 10% normal donkey serum and 0.3% Triton X-100. The sections were then incubated overnight at 4°C with mouse anti-GluR2 monoclonal antibodies (1: 200; Chemicon, Temecula, CA, USA), mouse anti-NMDAR1 monoclonal antibodies (1: 500; BD Biosciences Pharmingen, San Diego, CA, USA), rabbit anti-NMDAR2A/B polyclonal antibodies (1: 500; Chemicon), and rabbit antineurofilament 200 polyclonal antibodies (1: 800; Sigma, Saint Louis, MO, USA) or mouse anti-neurofilament 200 clone N52 monoclonal antibodies (1: 800; Sigma) in PBS containing 5% normal donkey serum and 0.1% Triton X-100. After rinsing with PBS, sections were incubated for 2 h at room temperature with biotinylated anti-rabbit IgG (1: 200; Jackson ImmunoResearch Laboratories, West Grove, PA, USA) or biotinylated antimouse IgG (1: 200; Jackson Laboratories), and subsequently incubated with streptavidin Alexa-Fluor 546 conjugate (1: 500; Invitrogen) for glutamate receptors subunits, and fluorescein-isothiocyanate (FITC)-conjugated antirabbit IgG (1: 300, Jackson Laboratories) or Alexa-Fluor 488 antimouse IgG (1: 1000, Invitrogen) for neurofilaments. Sections were then mounted in Fluorsave Reagent (Calbiochem, France) and observed with a Bio-Rad MRC 1024 laser scanning confocal microscope equipped with x40 and 63 objectives. The specificity of immunostaining was routinely checked by omitting the primary antibody. Controls showed no specific fluorescence when primary antibodies were omitted (data not shown).

Western blotting

Mouse and turtle brains were washed twice in ice-cold PBS and homogenized with 10–15 strokes using a glass-Teflon homogenizer in cold homogenization buffer (0.32 M sucrose, 10 mM Hepes, pH 7.4, 2 mM EDTA) containing a cocktail of protease inhibitors (Roche, France). Washed membrane pellets (P1) were obtained by a series of centrifugations. Briefly, the homogenate was centrifuged at 280 g for 20 min at 4°C, the supernatant was collected and re-centrifuged at 200 000 g for 15 min (4°C). The pellet (P1) thus obtained was resuspended in homogenization buffer and centrifuged again at 200 000 g for 15 min (4°C). P1 was resuspended in Hepes lysis buffer (50 mM Hepes, pH 7.4, 2 mM EDTA, protease inhibitors) and passed five times through a 26G needle. Protein concentration was determined and proteins were solubilized in 1% Triton X-100 for 45 min at 4°C. Membrane proteins (50 µg) were subjected to SDS-PAGE, transferred to a nitrocellulose membrane, which was then saturated overnight with 5% fat-free milk. The membrane was incubated overnight with the same primary antibodies as those used for immunocytochemistry (1: 1000), washed, and incubated for 1 h with the appropriate secondary antibodies coupled to peroxidase. Bands were visualized using SuperSignal West Pico or Femto chemiluninescent substrate (Pierce Biotechnology, Inc., Rockford, IL, USA).

Physiological recordings

Turtles were deeply anaesthetized (sodium pentobarbital, 6%) and decapitated, and a sagittal cut was made in the head. The brain was then removed and the posterior ampulla was transferred to the recording chamber. The sensory epithelium remained connected to the brainstem by the terminal branch of the eighth nerve. The ampulla was opened to access the neuroepithelium and the cupula removed in low calcium (0.1 mM) APS to preserve hair bundle integrity. Explants were anchored to a parafilm base mounted on a glass coverslip in a recording chamber filled with 2 ml of oxygenated APS. The bath was renewed at a rate of 0.5 ml min^–1 at a distance from the sample to avoid any mechanical stimulation of the hair bundles. Recordings were taken at room temperature (21–23°C). Electrical activities were recorded by using the loose patch clamp configuration of the patch-clamp technique. This method was found to be well suited for overcoming difficulties of establishing stable recordings, encountered using the whole-cell mode due to the peculiar shape of the calyx terminal, which is formed by close apposition of membrane layers rather than a cylindrical cable. Recording pipettes filled with APS with an impedance of 1.5–3 M were placed on the external membrane of the calyx terminal while maintaining a positive pressure during the approach. Seal resistances ranged between 50 and 100 M. Electrical activities were recorded and filtered at 5 or 10 kHz using an Axopatch 200B patch clamp amplifier, controlled by a 1322-A Digidata controller (Axon Instruments/Molecular Devices Corp., Union City, CA, USA). Data were sampled at 5 kHz (pCLAMP9, Axon Instruments). Frequency analysis was performed using SERF v2.62 software (http://www.bram.org/serf/serf.php). The mean frequency of the background activities was determined during 3–5 min recordings. Statistical significances were determined using Student's t test. The recordings at the calyx terminals often lasted for more than 1 h, attesting to the viability of our preparations.

Identification and pharmacology

To identify the afferent fibre under investigation, we broke the dendrite membrane at the end of the experiment, allowing Lucifer yellow contained in the recording pipette to diffuse into the terminal. Dye loading into the calyx terminal was examined using a two-photon microscope (Radiance 2000, Bio-Rad, UK). Data sampled in the present study were taken from multicalyx bearing afferents that are restricted to the central part of the hemi-crista (Brichta & Peterson, 1994). Hair bundles were deflected using a velocity controlled perfusion system (Microlab 500B/C Series Diluter, Hamilton Company, Reno, NV, USA). APS was delivered to the hair bundles through calibrated pipettes with 30 µm diameter tips placed 1 mm from the epithelium. The preparation was orientated to evoke a maximal response (usually perpendicular to the sensory epithelia) and APS was applied with a velocity between 1 and 10 µl s^–1. Pharmacological agents were applied in the bath solution at the following concentrations: TTX (0.5 µM), gentamicin (100 µM), FM1-43 (5 µM), nitrendipine (15 µM), the competitive AMPA/KA receptor antagonist NBQX (1,2,3,4-tetrahydro-6-nitro-2,3-dioxo-benzo[f]quinoxali-ne-7-sulphonamide) (5 µM), the specific non-competitive AMPA receptor antagonist GYKI 53784 ((–)1-(4-aminophenyl)-4-methyl-7,8-methylenedioxy-4,5-dihydro-3-methylcarbamoyl-2,3-benzodiazepine; 15 µM; Lilly Research Laboratories, USA), the selective non-competitive NMDA receptor antagonist MK-801 (5R,10S-(+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine hydrogen maleate; 20 µM) and the NMDA receptor antagonist D-AP5 (D-2-amino-5-phosphonopentanoate; 50 µM).

	Results

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Immunolocalization of AMPA and NMDA subunits at calyx terminals

Several studies have shown that glutamate is the main excitatory neurotransmitter involved in synaptic transmission between the type I vestibular hair cell and the calyx terminal (Dechesne et al. 1984; Dememes et al. 1990). To identify the glutamate receptors involved in calyx neurotransmission in the turtle posterior crista, we looked for the presence of AMPA and NMDA receptors by using antibodies against the GluR2, NR1 and NR2A/B subunits. Immunoreactivity for each antibody appeared as bright spots restricted to the synaptic contact between the type I hair cells and their cognate afferent fibre (Fig. 1). Multiple bright spots were found at single calyx terminals. These observations indicated that both the AMPA and NMDA receptors were present at the calyx terminal in the turtle crista. Western blot analysis confirmed the specificity of the antibodies in the turtle. The immunoblots illustrated in Fig. 1 showed single bands that migrated for both turtle and mouse tissue with apparent molecular masses of 102, 120 and 180 kDa corresponding to GluR2, NR1 and NR2A/B subunits, respectively, in the mouse brain (Petralia & Wenthold, 1992; Petralia et al. 1994).

View larger version (74K): [in this window] [in a new window]   Figure 1.  Immunolocalization of GluR2, NR1 and NR2A/B subunits at turtle calyx terminals Laser confocal micrographs of double immunofluorescence using antibodies against the GluR2, NR1 and NR2A/B glutamate receptors subunits as indicated (red labelling) and neurofilaments (green labelling). Immunoreactivities to the glutamate receptor subunits appear as bright spots at the contact between the type I hair cell and its calyx terminal. Calyx terminals of afferent fibres innervating type I sensory cells are identified by neurofilament staining. Scale bar = 10 µm and applies to all panels. Western blot analysis of SDS gels of turtle (T) and mouse (M) whole brain using indicated antibodies. Apparent molecular masses are given on the left.

We used the loose-patch configuration of the patch-clamp technique to record the electrical activities at calyx terminals from the central parts of the turtle hemi-cristae. A patch pipette inserted through the surface of the sensory epithelium was gently apposed against the external membrane of the calyx terminal in situ in a whole-mount explant (Fig. 2A and B). Most of the calyx terminals (78%; n = 31) displayed a background electrical activity (mean frequency: 16.5 ± 14 spikes s^–1), while some remained silent (22%; n = 9). We were able to reversibly suppress these transient variations in the membrane voltage by the substitution of sodium by choline in the bathing medium (n = 4) and to completely remove them with 0.5 µM TTX (n = 11) (Fig. 2C). We then checked whether hair cells are involved in generating the background firing at the calyx terminal by using specific blockers of the mechano-electrical transduction (MET) channels. In less than 30 s, 100 µM of gentamicin (n = 6) or 5 µM of FM1-43 (n = 3) completely abolished the background activity recorded at calyx terminals (Fig. 2D), indicating that an influx of cations through the MET channels was required to generate the firing. Furthermore, 15 µM of nitrendipine, the L-type voltage-gated calcium channels specific blocker, reversibly blocked the background discharge of the terminals (n = 3) (Fig. 2E). Mechanical stimulation of the hair bundles of the sensory cells increased the firing frequency both in the fibres displaying background activity (n = 15) and in the silent fibres (n = 9) (Fig. 3A and B). The mechanically evoked activities were blocked by 0.5 µM TTX (n = 9) and were prevented by 100 µM gentamicin (n = 7) (Fig. 3C and D). Together, these observations confirmed that this preparation and recording method were appropriate for monitoring the electrical activity at intact calyx terminals, thus allowing access to the synaptic transmission at calyx synapses.

View larger version (44K): [in this window] [in a new window]   Figure 2.  Characterization of electrical activity recorded at identified calyx terminals A, micrograph illustrating the approach of the recording pipette from the left through the surface of the posterior crista to directly access the calyx terminals for loose patch recordings. B, stack of 20 optical sections of another calyx terminal loaded with Lucifer Yellow after recording, taken using a two-photon microscope. Inset, single optical section of the same calyx terminal. The pipette is seen on the right of the calyx being recorded (arrow). Scale bars = 10 µm in A and B. C–E, blocking effect of indicated compounds on the background activity recorded at calyx terminals. Drugs were applied for 30 s and traces demonstrate their effects on the background activity. (gap in C: 30 s; gap in E: 25 min). Scale values in the bottom trace apply to all traces.

View larger version (21K): [in this window] [in a new window]   Figure 3.  Effects of hair bundle displacements on the electrical activities recorded at calyx terminals Hair bundles were displaced using a velocity controlled perfusion system represented by a small line below each trace. A and B, representative traces of mechanically evoked discharges at calyx terminals displaying background activity (A) or at a silent calyx terminal (B). C and D, blocking effects of TTX (C) and gentamicin (D) on the background and the mechanically evoked activities. Representative traces in control conditions (above) and after exposure for 30 s to the indicated compounds. Scale voltage value in bottom trace apply to all traces.

We then studied the effect of selective NMDA and non-NMDA antagonists on the background and the mechanically evoked activities recorded at calyx terminals. As illustrated in Fig. 4, the non-competitive NMDA receptor antagonist MK801 (20 µM) did not significantly affect the background (Fig. 4A) nor the mechanically evoked discharge rates (Fig. 4B) (P > 0.2; n = 6). In contrast, the AMPA/KA receptor antagonist NBQX (5 µM) blocked both the background (n = 8) and the mechanically evoked (n = 12) activities (Fig. 4A and B). A similar blocking effect was observed using the specific AMPA receptor antagonist GYKI 53784 (15 µM; n = 3) (Fig. 4C). Complete recovery of the background and mechanically evoked activities was observed after 30–50 min washing with APS (not shown). Mean discharge frequencies did not significantly differ prior to GYKI application and after washing (P > 0.2; n = 3). In the three calyx terminal tested, the mechanically evoked activities always recovered before the background activities. Since NMDA receptors are present at the calyx synapse (see above), we studied their potential functionality. Perfusion of Mg²⁺ free APS combined with the NMDA receptor coagonist glycine (10 µM) significantly enhanced the background discharge recorded at the calyx terminal (P < 0.05; n = 8) (Fig. 4D). The complete reversion of this effect was obtained by application of NMDA receptor antagonist D-AP5 (50 µM) (n = 4). These results demonstrate that the NMDA receptors are functional. Altogether, these results show that although both AMPA and NMDA receptors are both present at calyx synapse, only AMPA receptors are involved in standard conditions in the background and mechanically evoked synaptic transmission.

View larger version (29K): [in this window] [in a new window]   Figure 4.  Effects of non-NMDA and NMDA antagonists on the firing activity at a calyx synapse A, representative traces of background activity in one calyx terminal under control condition (upper trace), after 3 min exposure to the non-competitive NMDA receptor antagonist MK-801 (20 µM; middle trace), and after 2 min subsequent exposure to the AMPA receptor blocker NBQX (5 µM; lower trace). Corresponding effect on the discharge rate is illustrated on the right. (Bins 2 s; mean background frequency before drug application: 3.1 spikes s–1.) B, representative traces of mechanically evoked firing activities at a calyx terminal under control condition (left trace), after 5 min exposure to MK-801 (20 µM; middle trace) and after 2 min subsequent exposure to NBQX (5 µM; right trace). (Bins 200 ms; mean background frequency: 3.5 spikes s–1; mean mechanically evoked frequency: 34 spikes s–1.) C, effect of GYKI 53784 (15 µM) on the firing activities at calyx terminal (left traces), 2 min after drug application (upper trace), and 50 and 60 min after rinsing with APS (lower traces). Corresponding discharge rate histogram is illustrated on the right. (Bins 5 s; mean frequency before drug application: 5.2 spikes s–1; gaps: 40 min; 15 min.) D, functionality of NMDA receptors at calyx synapse. Representative traces of background activity in one calyx terminal under control condition (upper trace), 20 min after the start of the Mg2+ free APS + 10 µM glycine (left lower trace), and after 8 min subsequent exposure to D-AP5 (50 µM; right lower trace) (gaps: 40 min; 8 min). Corresponding discharge rate histogram is illustrated on the right. (Bins 5 s; control mean frequency: 0.7 spikes s–1; mean frequency after Mg2+ free APS: 4.1 spikes s–1; mean frequency after D-AP5 block: 0.5 spikes s–1.) Traces in A, B, C and D are from different calyx terminals. M.S. mechanical stimulation.

	Discussion

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We detected sodium-based action potentials within the calyx terminal. The pattern of the background activity was not different from those recorded in the turtle vestibular nerve. Their mean frequencies were very similar to those found in the non-myelinated segment below the calyx terminals in the chick crista (Yamashita & Ohmori, 1990) and in the myelinated segment proximal to Scarpa's ganglion in the turtle (Brichta & Goldberg, 2000a). Furthermore, our recordings showed that silent units are also present, as previously reported in the turtle (Brichta & Goldberg, 2000a). The recorded discharges were found to depend strictly on the hair cell activities as these were modulated when the hair bundles of the sensory cells were displaced. In addition, the discharges were completely blocked by MET channel blockers, such as gentamicin (Kroese et al. 1989) and FM1-43 (Gale et al. 2001; Meyers et al. 2003). We previously demonstrated that gentamicin had a fast blocking effect on isolated vestibular hair cells (Chabbert et al. 1994). In the present study, its effect, as that of FM1-43, is also very fast (within 30 s) suggesting a direct action on the transduction channels rather than a long-term toxic effect on the hair cells or the terminals. Therefore, we can interpret the background activity as a consequence of cation influx through a small population of MET channels that remain open at rest, as previously demonstrated both in vestibular (Corey & Hudspeth, 1983) and auditory hair cells (Crawford & Fettiplace, 1985). The inhibitory effect of nitrendipine showed for the first time that the transmitter release is mediated by the L-type calcium channel previously described in vestibular hair cells (Bao et al. 2003). Given the reduced number of type II hair cells (Jorgensen, 1974; Brichta & Peterson, 1994; Lysakowski, 1996) and the small percentage of synapses between type II hair cells and calyces in the central zone of the epithelia (less than 15%, A. Lysakowski personal communication), we can reasonably conclude that we mainly recorded afferent discharge resulting from activation of type I hair cells.

AMPA GluR2 and NMDA NR1 subunits have been previously identified at calyx synapses in mammals (Matsubara et al. 1999; Ishiyama et al. 2002). Our immunocytochemical data demonstrate that these proteins are expressed at the same location in reptiles, suggesting that such synaptic equipment is common in higher vertebrates. Beside the punctuate labelling clearly identifiable at the synapse, a slight diffuse labelling is present in the hair cell cytoplasm. Although this could be considered as non-specific labelling, it cannot be excluded that it reflects the presence of presynaptic receptors, as the NMDA receptor has been previously described at calyx synapses in the rat (Ishiyama et al. 2002) and in central nervous system (Berretta & Jones, 1996; Breukel et al. 1998) where it modulates glutamate release. In the cochlear system, AMPA receptors have been reported as the only glutamate receptors involved in quantal synaptic activity between cochlear afferents and inner hair cells (Ruel et al. 1999; Ruel et al. 2000; Glowatzki & Fuchs, 2002). The first pharmacological evidence for the involvement of non-NMDA receptors in vestibular neurotransmission was recently provided from the blocking effect of the AMPA/KA receptor blocker CNQX on the synapse activity at bouton terminals of turtle posterior crista (Holt et al. 2006). The present study further demonstrates that the AMPA receptor mediates chemical neurotransmission between type I hair cells and their cognate afferents, since GYKI 53784 has been reported to be a selective AMPA receptor antagonist (Ruel et al. 2002). The presence of the GluR2 subunit is of special interest with regard to its involvement in defining the calcium impermeability of the AMPA receptors (Hollmann et al. 1991). Whether other AMPA receptor subunits are present at the calyx terminal and how they participate in shaping the calyx synaptic activity should be investigated, as the mRNAs of five subunits (GluR2-6) of this receptor have been previously reported in the cell body of Scarpa's ganglion neurons in mammals (Niedzielski & Wenthold, 1995). The expression of the NR1 and NR2A/B subunits at the calyx terminal in the turtle raises several questions about the putative functional role of the NMDA receptor since it is not involved in either the background or the mechanically evoked activities. Conversely, in lower vertebrates, its activation is essential for the background activity, while it seems to be less involved in the mechanically evoked transmission (Soto et al. 1994). In the present study, the lack of activation cannot be interpreted as the consequence of missing subunits needed to form a functional receptor, since the combination of NR1 and NR2 subunits is sufficient to form a functional NMDA channel (for review see Nakanishi, 1992). We demonstrated the functionality of these receptors by removing the Mg²⁺ block which normally leads to a non-permeant ionic channel at hyperpolarized membrane potential although they bind their agonist glutamate and coagonist glycine (Mayer & Westbrook, 1987; Ascher & Nowak, 1988). It may therefore be possible that under our stimulation conditions the depolarization of the terminal is not sufficient to reach the threshold for NMDA receptor activation. Such depolarization could occur during periods of high activity giving to these receptors a significant role. In addition, we cannot exclude that the NMDA receptor may be activated under specific conditions, such as the reported excitatory efferent activation on the calyx terminals (Brichta & Goldberg, 2000b) and/or pathophysiological conditions as reported in the cochlea after excitotoxicity (Puel, 1995; d'Aldin et al. 1997). In the giant terminal calyx of Held located in the medial nucleus of the trapezoid body (MNTB), it has been shown that NMDA receptors are essential for synapse maturation, while their involvement declines with age (Bellingham et al. 1998; Joshi & Wang, 2002). Such a developmental phenomenon would explain the lack of involvement of NMDA receptors in the vestibule of mature turtles.

In a theoretical analysis, Goldberg (1996) proposed that neurotransmission at the calyx synapse may involve cooperation between conventional synaptic transmission and intercellular K⁺ ion accumulation. The latter may modulate the conventional transmission by depolarizing both the pre- and postsynaptic elements and by possibly activating the NMDA pathway. The present results constitute the first direct demonstration that conventional synaptic transmission occurs at the calyx synapse. The modulatory effect of the K⁺ fluxes on neurotransmission still remains to be demonstrated; this hypothesis seems more and more relevant regarding the recent results obtained on the bouton synapse, which confirm the major role of K⁺ in neurotransmission (Holt et al. 2006).

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	Acknowledgements

 
We thank Professor J. M. Goldberg, Dr A. Lysakowski and Dr E. Glowatzki for their valuable comments on the work, Drs J. Ruel and S. Bartolami for helpful discussions, and C. Travo for participating in preliminary immunocytochemical studies. This work was supported by le Centre National des Etudes Spatiales and Ministère de la Recherche et des Nouvelles Technologies.

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