Abstract
Rhythmic electrical activity is a hallmark of the developing embryonic CNS and is required for proper development in addition to genetic programs. Neurotransmitter release contributes to the genesis of this activity. In the mouse spinal cord, this rhythmic activity occurs after embryonic day 11.5 (E11.5) as waves spreading along the entire cord. At E12.5, blocking glycine receptors alters the propagation of the rhythmic activity, but the cellular source of the glycine receptor agonist, the release mechanisms, and its function remain obscure. At this early stage, the presence of synaptic activity even remains unexplored. Using isolated embryonic spinal cord preparations and whole-cell patch-clamp recordings of identified motoneurons, we find that the first synaptic activity develops at E12.5 and is mainly GABAergic. Using a multiple approach including direct measurement of neurotransmitter release (i.e., outside-out sniffer technique), we also show that, between E12.5 and E14.5, the main source of glycine in the embryonic spinal cord is radial cell progenitors, also known to be involved in neuronal migration. We then demonstrate that radial cells can release glycine during synaptogenesis. This spontaneous non-neuronal glycine release can also be evoked by mechanical stimuli and occurs through volume-sensitive chloride channels. Finally, we find that basal glycine release upregulates the propagating spontaneous rhythmic activity by depolarizing immature neurons and by increasing membrane potential fluctuations. Our data raise the question of a new role of radial cells as secretory cells involved in the modulation of the spontaneous electrical activity of embryonic neuronal networks.
Introduction
A remarkable feature of the developing CNS is its ability to generate spontaneous electrical activity (O'Donovan, 1999; Ben-Ari, 2001; Zhang and Poo, 2001). This activity consists of explosive bursts of action potentials separated by long silences that can spread between brain regions. Such spontaneous activity is thought to be initiated by nonsynaptic transmitter release during early development and then synaptically at later stages (O'Donovan, 1999; Ben-Ari et al., 2004). Although the mechanisms of synaptically driven spontaneous activity have yet to be elucidated, it is clear that many excitatory neurotransmitters are involved in the genesis of these bursts (O'Donovan et al., 1998) and that activity-dependent network depression likely allows the periods of quiescence between bursts (Tabak et al., 2001). Spontaneous electrical activity that occurs at early stages of development before and during the formation of synaptic networks is needed for neuronal proliferation, migration, and differentiation (Spitzer, 2006). This nonsynaptic early activity was extensively monitored using optical imaging of intracellular Ca2+ and revealed the presence of calcium transients engaging the release of endogenous neurotransmitters and gap junctions (Gu and Spitzer, 1997; Spitzer, 2006). However, the identity of the cellular source of these transmitters is less clear: are they released by newly born neurons or by embryonic progenitors cells such as radial cells (RCs), which represent both neuroepithelial cells and radial glial cells in early embryos (Barry and McDermott, 2005)? In the hippocampus, it has been assumed that GABA and glutamate are released by newborn neurons (Demarque et al., 2002). In the developing cortex, taurine, a glycine receptor (GlyR) agonist is thought to be released from immature neurons (Flint et al., 1998). In addition, the mechanisms that underlie the nonsynaptic release also remain to be clarified. Paracrine processes operating via unknown pathways are suggested to underlie the liberation of taurine, GABA, and glutamate during early development (Flint et al., 1998; Demarque et al., 2002; Liu et al., 2005; Bordey, 2007).
In the mouse spinal cord (SC), experiments based on extracellular recordings and pharmacology suggest that glycinergic transmission is important to the occurrence of spontaneous rhythmic activities at early stages [as early as embryonic day 12.5 (E12.5)] (Hanson and Landmesser, 2003; Ren and Greer, 2003). However, at this stage, glycinergic interneurons are extremely sparse (Allain et al., 2006), suggesting that GlyR agonists could have a non-neuronal origin. In this study, we investigated the possibility of a nonsynaptic release of glycine at early stages of development in the lumbar SC. Using multiple direct approaches, we demonstrate that RCs release glycine at the onset of synaptogenesis in the SC. We show that glycine release from RCs is independent of action potential firing and is not vesicular. Instead, glycine release is elicited by cell membrane stretch and likely involves volume-sensitive outwardly rectifying (VSOR) chloride channels. We finally demonstrate that this early basal glycine release influences the excitability of SC neurons, thereby modulating the propagation of bursts of action potentials in the isolated embryonic SC.
Materials and Methods
Isolated spinal cord preparation.
These experiments were performed in accordance with European Community guiding principles on the care and use of animals (86/609/CEE; Official Journal of the European Communities no. L358; December 18, 1986), French Decree no. 97/748 of October 19, 1987 (Journal Officiel de la République Française; October 20, 1987) and the recommendations of the Centre National de la Recherche Scientifique. Embryonic SCs from mice were obtained as described previously (Delpy et al., 2008). Briefly, pregnant mice were anesthetized by intramuscular injection of a mix of ketamine and xylazine. Embryos were removed, and the SC was isolated. Whole SCs were then maintained for 1 h before recording in an artificial CSF (ACSF) containing the following (in mm): 130 NaCl, 26 NaHCO3, 1.25 NaH2PO4, 3 KCl, 10 glucose, 2 CaCl2, and 2 MgCl2, at 32°C, continuously bubbled with a 95% O2–5% CO2 gas mixture.
Whole-cell recordings and analysis.
The isolated SC was placed in a recording chamber and continuously perfused at room temperature (20–24°C) with the oxygenated ACSF (1.9 ml/min). Standard whole-cell voltage-clamp recordings of motoneurons (MNs) were made under direct visualization using an infrared-sensitive CCD video camera. MNs were easily distinguishable by their location in the ventral area and by their size. To confirm motoneuronal identity, the recorded cells were filled with Neurobiotin (2 mg/ml) and revealed in combination with an Islet1/2 staining; Islet1/2 is a specific marker of embryonic MNs (Ericson et al., 1992) (see Fig. 3A,B). Whole-cell patch-clamp electrodes were pulled from thick-wall borosilicate glass using a Brown-Flaming puller (Sutter Instrument). The tip of the electrode was fire-polished using a microforge (Narishige). Patch-clamp electrodes had resistances of 2–4 MΩ. For voltage-clamp experiments, the electrode was filled with a solution containing the following (in mm): 135 CsCl, 2 MgCl2, 4 Na3ATP, 10 EGTA, and 10 HEPES, pH 7.2 (290 mosmol/kg H2O). For current clamp, the electrode contained the following (in mm): 92 K-gluconate, 38 KCl, 5 NaCl, 10 HEPES, 2 MgATP, and 1 EGTA, pH 7.4 [285 mosmol/kg H2O; equilibrium potential for chloride ions, ECl ≈ −30 mV (i.e., close to the physiological values measured at these embryonic ages) (Delpy et al., 2008)]. Events were recorded using an Axopatch 200B or a Multiclamp 700B amplifier (Molecular Devices). Data were low-pass filtered (2 kHz) and acquired at 10 kHz on a computer using pClamp9 software. Spontaneous events were recorded at a holding potential of −60 mV.
A synaptic current was defined as an event having a fast rise time and a slow decay time. The spontaneous synaptic activity was analyzed during a recording period of 5–10 min. Spontaneous synaptic events were digitized with pClamp9 software (Molecular Devices). Events were detected using a derivative threshold method using Axograph 4.9 (Molecular Devices) and were further accepted or rejected on the basis of their time course (Muller et al., 2006).
Single-channel activity was measured by constructing point-per-point amplitude histograms of successive short data segments (5–10 s) to minimize distortion caused by slow basal current fluctuations (see Fig. 2). The point-per-point amplitude histograms were then averaged. The effects of drugs on single channel activity were analyzed by comparing the averaged point-per-point amplitude histograms obtained from traces of identical duration. The basal current noise peak distribution was fitted using a single Gaussian curve. As shown in Figure 2, single-channel currents have an inward direction. The single-channel current activity was estimated by measuring the area of the point-per-point amplitude histograms for current values lower than 2 times the SD value of the Gaussian curve describing the basal current noise distribution (SD values usually ranged from 0.5 to 1.3 pA between recordings).
Extracellular recordings and stimulations.
In the same experimental conditions as for whole-cell recordings, spontaneous activity was recorded extracellularly from E12.5 spinal cords using a glass electrode placed into the ventral cord and connected to a high-gain AC amplifier (ISO-DAM8A-4 Bio-amplifier System; World Precision Instruments). Filtered (bandwidth, 300 Hz to 10 kHz) raw signals were integrated off-line and analyzed using Spike2 software (Cambridge Electronic Design). Changes in burst area and burst duration were calculated from cervical, thoracic, and lumbar recordings. Data in the present study correspond to mean modifications across the three spinal cord levels. Episodes of activity were induced by electrical stimulations, through a bipolar electrode positioned at cervical level, using a Master-8-vp connected to ISO-Flex isolation units (A.M.P.I.).
Sniffer recordings.
To make a “sniffer” electrode (Young and Poo, 1983), an outside-out patch was pulled from a transfected CHO cell line expressing the GlyR α2 subunit (Mangin et al., 2003). Homomeric GlyR α2 subunits, highly specific for glycine, were characterized by a high elementary conductance (100–120 pS), a long mean open time, and little desensitization, making them a good sensor for glycine (Mangin et al., 2003). As a control, the electrode was first positioned outside the SC to verify any glycine contamination in the recording medium. The electrode was then pushed inside the SC and positioned within the motoneuronal area. Outside-out patch-clamp electrodes (5–10 MΩ) were pulled from thick-wall borosilicate glass, fire-polished, and filled with the following (in mm): 130 CsCl, 4 MgCl2, 4 Na2ATP, 10 EGTA, 10 HEPES, pH 7.2; osmolarity, 290 mosmol/kg H2O. Single-channel currents were recorded using an Axopatch 200B amplifier (Molecular Devices). Recordings were filtered at 10 kHz, sampled at 50 kHz, and stored on a PC computer. Membrane potential was held at −50 mV throughout the experiment. Analysis of the sniffer currents was performed using Axograph 4.9 software (Molecular Devices). Decay rates of sniffer currents were estimated by measuring the duration of the sniffer current at 20% of the peak amplitude (see Fig. 7). One thousand consecutive points were averaged to measure changes in current amplitude with time (sampling rate, 50 kHz).
Chinese hamster ovarian cells (CHO-K1; ATCC CCL61) were maintained in a 95% air–5% CO2 humidified incubator, at 35°C, in DMEM supplemented with 0.11 g/L sodium pyruvate, 6 g/L d-glucose, and 10% (v/v) heat-inactivated fetal bovine serum (all from Invitrogen). Cells were passaged every 5–6 d (up to a maximum of 20 times). For electrophysiological recordings, cells were seeded onto glass coverslips coated with poly-l-ornithine (0.1 mg/ml). Glycine receptor α2 subunit cloning and transfection were performed as described by Mangin et al. (2003).
Pharmacological agents.
All drugs were bath-applied. The glycine receptor antagonist strychnine hemisulfate salt (1–5 μm; Sigma-Aldrich), the GABAA receptor antagonist gabazine (2 μm; Sigma-Aldrich), and TTX (0.5–1 μm; Sigma-Aldrich) were dissolved in the bathing solution. The glycine membrane transporter 1 (GlyT1) blocker N-[3-(4′-fluorophenyl)-3-(4′-phenylphenoxy)propyl]sarcosine hydrochloride (ALX-5407) (1 μm; Sigma-Aldrich) was dissolved in ACSF. The nonspecific GlyT blocker O-[(2-benzyloxyphenyl-3-flurophenyl)methyl]-l-serine (ALX-1393) (0.5 μm; Sigma-Aldrich), flufenamic acid (100 μm; Sigma-Aldrich), 4-(2-butyl-6,7-dichloro-2-cyclopentylindan-1-on-5-yl)oxybutyric acid(DCPIB) (10 μm), the proton pump inhibitor bafilomycin A1 (4 μm; Tocris), and capsaicin (10 μm; Sigma-Aldrich) were dissolved in DMSO (final concentration, 0.1%). 1-[2-(4-Methoxyphenyl)-2-[3-(4-methoxyphenyl)propoxy]ethyl]-1H-imidazole hydrochloride (SKF-96365) (30–100 μm; Tocris), gadolinium (GdCl3) (100 μm; Sigma-Aldrich), adenosine triphosphate (ATP-Na) (20 μm; Sigma-Aldrich), DCPIB (10 μm; Tocris), and phloretin (10 μm; Sigma-Aldrich) were dissolved in ACSF. ATP-Na was first solubilized in sterile cold water to obtain 20 mm and then diluted to 20 μm in ACSF before use. Capsaicin (Tocris) was first solubilized in DMSO (Sigma-Aldrich) to obtain 10 mm, and then diluted to 10 μm in ACSF (0.1% DMSO final concentration).
SCs were incubated for 1–3 h in the presence of bafilomycin A1 before recordings. ACSF containing 0.1% DMSO did not affect synaptic activity or GlyR activation (data not shown).
Immunohistochemistry.
Immunostaining was performed on SC transverse lumbar sections. For sectioning, E11.5–E15.5 SCs were fixed in 2% paraformaldehyde (PFA) for 2 h, rinsed in 0.1 m PBS, cryoprotected in sucrose, frozen, and transversally cut in 25-μm-thick sections using a Leica CM 3050 S cryostat. For hypotonic tests, E12.5 SCs were incubated for 1 h either in control conditions (325 mosmol/kg H2O ACSF) or in hypotonic ACSF (200 mosmol/kg H2O) with or without specific drugs (see Results) before fixation. For taurine immunostaining, cerebella were collected from adult mice perfused with 2% PFA. Sections were incubated with primary antibodies for 48 h at 4°C in 0.1 m PBS (containing 0.2% BSA and 0.1% Triton X-100). All primary antibodies used are listed in Table 1. To reveal Neurobiotin-injected MNs, streptavidin-Cy5 (1:400; Invitrogen) was added to the primary antibody solution. Then, after three rinses in PBS, SCs were incubated at room temperature for 2 h in appropriate secondary antibodies (1:400; Invitrogen). These were Alexa Fluor 488 goat anti-rabbit or anti-mouse IgG(H+L), Alexa Fluor 546 goat anti-mouse IgG(H+L) or donkey anti-rat IgG(H+L). After rinsing in 0.1 m PBS, SCs were mounted in 90% glycerol/10% PBS/2.5% DABCO [1,4-diazabicyclo(2.2.2)octane] (Sigma-Aldrich). Even though the specificity of the polyclonal rat anti-glycine antibody was verified using immunoblotting by Prof. D. Pow (University of Newcastle, Newcastle, Australia) (Pow et al., 1995), the specificity of the glycine labeling was tested using a glycine–PFA–BSA conjugate as previously referred to (Allain et al., 2006).
Confocal microscopy.
Preparations were analyzed using a BX51 Olympus Fluoview 500 confocal microscope. For quantitative analysis of labeled RC fibers on SC transverse sections, serial optical sections were obtained at a Z-step of 0.3 μm and imaged using an objective 40×/1.00 numerical aperture oil.
Image analysis, quantification, and statistics.
In transverse sections of embryonic lumbar SCs, nestin-immunoreactive (ir), glycine-ir, and double-stained nestin/glycine RC fibers were counted manually in three optical sections (5–11 embryos, three different litters) randomly chosen in the ventral area. The threshold used to determine whether a cell was coimmunolabeled was set at twice the intensity of background noise measured between radial cell fibers. Background noise intensity did not strongly vary between experiments. All values were expressed as mean ± SEM. Statistical significance was assessed by a one-way ANOVA or by nonparametric Mann–Whitney test or Wilcoxon's matched pairs test (GraphPad Software).
Lucifer yellow and Neurobiotin uptake.
For Lucifer yellow (LY) uptake experiments, embryonic SCs (E12.5–E13.5) were isolated with meninges in ACSF (30 min). SCs were then transferred into chambers containing 1 mm LY (Sigma-Aldrich) dissolved in ACSF. To determine whether isotonic solutions can increase LY uptake by RCs, SCs were exposed for 15–20 min to LY dissolved in 200 mosmol/kg H2O solution. For Neurobiotin uptake experiments, SCs were prepared as described above but LY was replaced with 3.5 mm Neurobiotin (Vector Laboratories). All experiments were performed at 32°C. SCs were fixed overnight in 4% PFA and cryoprotected for 24 h in sucrose. Transverse frozen sections (35 μm thick) were made, rinsed in 0.1 m PBS, and mounted with Vectashield (Vector Laboratories). For Neurobiotin staining, cryostat slices were rinsed in PBS and quenched in 50 mm NH4Cl in PBS for 20 min at room temperature. To reveal Neurobiotin-labeled cells, slices were permeabilized in 0.2% (v/v) Triton X-100 (Sigma-Aldrich) and 0.25% (v/v) fish gelatin (Sigma-Aldrich) for 1 h at room temperature. They were then incubated for 3 h at room temperature with streptavidin-Alexa 488 (1:500) (Invitrogen). Slices were then rinsed in PBS before being mounted with Vectashield. Fluorescence was observed under a confocal laser-scanning microscope (Leica SP5) using a 40× oil-immersion objective of numerical aperture 1.25. The dyes LY and Alexa 488 were excited with a 405 nm diode laser and the 488 nm line of an argon laser, respectively. The x–y resolution of each stack was 2048 × 2048 pixels over a scan area of 387.5 × 387.5 μm2. Typically, stacks of 30 sections with an interval of 0.5 μm from the surface were scanned three times to optimize the signal-to-noise ratio. ImageJ public domain software (Wayne Rasband; National Institutes of Health; http://rsb.info.nih.gov/ij/) was used to analyze projections from stack sections. The threshold used to determine whether a cell took up Lucifer yellow or Neurobiotin was set at twice the intensity of background noise measured outside the ventromedial part of the spinal cord (background noise intensity did not strongly vary between experiments). Because somata of RCs are located in the intermediate part of the ventricular zone, the number of stained RCs was estimated by counting fluorescent cell bodies in the ventral part of the ventricular zone (within a 300 μm area dorsal to the floorplate).
Results
Spontaneously active GlyRs at E12.5 in the embryonic spinal cord
Direct evidence concerning the establishment of GABAergic and glycinergic synaptic transmission in embryonic spinal motor networks has not yet been reported. Using whole-cell patch-clamp recordings from visually identified lumbar E11.5–E14.5 spinal MNs (Fig. 1B), we first analyzed the ontogeny of isolated spontaneous postsynaptic activity. Postsynaptic currents (PSCs) were defined in a classical way, as events with a fast rising phase and a slow decay phase. At these ages, MN input resistance remained >600 MΩ, whereas their input capacitance increased from 11.8 ± 5.0 pF (n = 10) at E11.5 to 19.8 ± 1.8 pF (n = 21) at E14.5, as previously described (Delpy et al., 2008).
At E11.5, we observed no spontaneous synaptic activity on the 10 recorded MNs (data not shown). At E12.5, spontaneous isolated PSCs were either still not detected or occurred at a low frequency ranging from 0.004 to 0.03 Hz. Application of 30 mm KCl did not increase synaptic activity (data not shown). Only 13.3% of MNs (n = 30) displayed PSCs with a frequency >0.05 Hz, ranging from 0.1 to 0.45 Hz (0.21 ± 0.07 Hz; n = 4) (Fig. 1A–D1). The proportion of recorded cells displaying PSCs with a frequency >0.05 Hz increased to 90.5% (n = 24) at E13.5 and 100% (n = 21) at E14.5 (Fig. 1D1). At E13.5, the most active cells displayed PSCs with an averaged frequency of 0.22 ± 0.04 Hz (n = 21), whereas the three poorly active cells displayed PSCs with a frequency ranging from 0.005 to 0.02 Hz. At E14.5, PSC frequency significantly increased to 0.39 ± 0.08 Hz (n = 21) when compared with the most active cells recorded at E13.5 (Mann–Whitney test, p = 0.05).
At E12.5, all PSCs were blocked by the GABAAR-specific antagonist gabazine (2 μm), indicating that these synaptic currents were GABAergic postsynaptic events (Fig. 1A). At E13.5, gabazine abolished PSCs in 33.3% of the recorded MNs (Fig. 1B1), whereas other MNs expressed a proportion of gabazine-resistant PSCs that were fully blocked by strychnine, thus suggesting the presence of GABAergic or glycinergic events, or both (Fig. 1D2). At E14.5, 90.5% of the cells displayed GABAergic and glycinergic PSCs (Fig. 1C1–D2). When present, glycinergic PSCs did not appear more frequently in E14.5 compared with E13.5 MNs. There was no significant difference (Mann–Whitney test, p > 0.1) in the proportion of gabazine-resistant PSCs between E13.5 (14.6 ± 3%; n = 14) and E14.5 (21.9 ± 4.2%; n = 19).
Whole-cell recordings also revealed spontaneously occurring single-channel currents, which were more pronounced at E12.5 (Fig. 2A), and appeared well defined (4–5 pA at −60 mV) because of the high input resistance of MNs (722 ± 37 MΩ; n = 30 at E12.5). Single-channel activity was characterized by inward currents with a square time course (Fig. 2). The single-channel activity was quantified using point-per-point current amplitude histograms (see Materials and Methods). This single-channel current activity was not significantly decreased (Wilcoxon's test, p > 0.1) by 1 μm TTX (3.6 ± 6.2% decrease; n = 6) (Fig. 2A) (i.e., they did not depend on TTX-sensitive action potential firing). They were not significantly inhibited (Wilcoxon's test, p > 0.1) by 2 μm gabazine (2.9 ± 14.2% decrease; n = 5 cells) (Fig. 2B) but were significantly inhibited (Wilcoxon's test, p < 0.01) by 1–3 μm strychnine (83.8 ± 3.5% decrease; n = 9 cells) (Fig. 2C), indicating that they reflect spontaneous GlyR activation.
The strychnine-sensitive and TTX-insensitive single-channel activity suggests that GlyRs expressed by E12.5 MNs are continuously activated by the presence of endogenous agonist in the extracellular space. We therefore tested whether this tonic activity influenced the resting membrane potential of E12.5 MNs. MNs were recorded in current-clamp mode with the equilibrium chloride potential set at physiological value for this age (ECl− = −30 mV), as previously described (Delpy et al., 2008). Bath application of strychnine (5 μm) hyperpolarized the membrane potential of all tested MNs (4.4 ± 0.6 mV; n = 9), and in six of them, there was a 39.4 ± 5% decrease in the membrane noise fluctuation (Wilcoxon's matched test, p < 0.01) (supplemental Fig. 1, available at www.jneurosci.org as supplemental material) [change in the membrane noise fluctuation was estimated by calculating the coefficient of variation (CV) of the noise (CV = SD/mean)]. This indicates that spontaneous GlyR activity can sustain a significant depolarization of the MNs.
Radial cell fibers contain glycine
Glycine-ir neurons are sparse in the ventral part of the mouse lumbar SC at E12.5 (Allain et al., 2006), arguing against a glycine release from interneurons. At this age, glycine-ir fibers radiate to the border of the ventral horn (Allain et al., 2006) across Islet 1/2-ir motoneuronal pools (Fig. 3A). Since this morphology resembles RCs, we determined whether glycine-ir fibers are from RCs by performing double immunolabeling against glycine and nestin or against glycine and RC2. Nestin and RC2 are intermediate filament proteins expressed in RCs including neuroepithelial and radial glial cells (Hartfuss et al., 2001). We found that glycine-ir fibers were stained with anti-nestin (Fig. 3C) and anti-RC2 antibodies (Fig. 3D), indicating that they are RC fibers. Double labelings performed from E11.5 to E15.5 also revealed that RC fibers briefly express glycine immunoreactivity, the proportion of glycine-ir RCs being maximal at E13.5 (79.1 ± 3.8%; n = 18) (Fig. 3E). After E15.5, nestin immunoreactivity disappeared (data not shown), as already described in the rat SC (Barry and McDermott, 2005).
Taurine is another GlyR agonist known to be released before synaptogenesis in the neonatal rat cortex (Flint et al., 1998). Therefore, taurine could also be an endogenous GlyR agonist in the embryonic mouse SC. To determine whether taurine was also present in E12.5 lumbar SC, we performed a double immunolabeling using anti-taurine and anti-nestin antibodies. Taurine was only detected in the lateral border of the marginal zone in E12.5 lumbar SC sections (supplemental Fig. 2B, available at www.jneurosci.org as supplemental material). We did not detect taurine staining either in the ventral motor area or in the RCs (supplemental Fig. 2B3, available at www.jneurosci.org as supplemental material), which makes it unlikely that taurine could account for activation of GlyR on MNs.
Glycine is released in response to cell membrane stretch
Detecting glycine immunoreactivity within RC fibers does not necessarily imply that glycine is released by RCs. To demonstrate glycine release, we first used outside-out patches from CHO cells expressing embryonic homomeric α2 GlyRs as a “sniffer” (supplemental Fig. 3, available at www.jneurosci.org as supplemental material) to reveal the presence of glycine in the extracellular space within the MN area. Glycine EC50 is close to 200 μm for homomeric α2 GlyRs (Mangin et al., 2003). Note that homomeric α2 GlyRs are poorly sensitive to taurine with a taurine EC50 being 10 times higher than the glycine EC50 (De Saint Jan et al., 2001).
When inserting the sniffer electrode in the vicinity of MNs, we recorded outside-out currents (supplemental Fig. 3B, available at www.jneurosci.org as supplemental material). These currents were characterized by an initial peak followed by a deactivation phase (Fig. 4A1, A2) that did not result from GlyR desensitization (Fig. 4). Before E14.5, GlyR activity was still observed 15 min after inserting the sniffer electrode (Fig. 4A1). We estimated the peak concentration of glycine around MNs to be 100 μm at E11.5–E13.5 (Fig. 4B1–B3) and 30 μm at E14.5 (Fig. 4B4). We found that the glycine concentration accounting for GlyR activity 15 min after the sniffer electrode insertion was low (<10 μm) but sufficient to activate GlyR between E11.5 and E13.5 (Fig. 4C). It was maximal at E13.5 and, hence, likely to reflect basal extracellular glycine concentration accounting for the spontaneous GlyR activity recorded in motoneurons (Fig. 2). We did not detect any GlyR activity 15 min after the sniffer electrode insertion at E14.5, thus indicating that glycine concentration is below the detection threshold of the sniffer patch (Fig. 4C).
The possibility of evoking glycine release, and hence GlyR activation, by inducing a global cell membrane depolarization, was tested using bath application of 30 mm KCl. Increasing [K+]o at E12.5–E14.5 did not evoke any significant GlyR activation in the sniffer patch (Fig. 5A,E). Thus, glycine cannot be released (or is released at a concentration too low to be detected by the sniffer) in response to cell membrane depolarization.
Because nonsynaptic release of neurotransmitters can also be evoked by cell membrane stretches (Chavas et al., 2004), we tested the effect of applying a hypotonic solution to our preparation. Lowering the external osmotic pressure is known to evoke swelling, which in turn increases the mechanical tension of cell membranes. A medium osmolarity of 200 mosmol/kg H2O was chosen according to what is known for mechanical release of ATP by astrocytes (Liu et al., 2008). As shown in Figure 5B, a large inward current, reflecting a release of glycine, was reproducibly induced when reducing extracellular osmotic pressure from 325 to 200 mosmol/kg H2O (i.e., 40% reduction). This glycine release was observed at all stages tested (E11.5–E14.5) and was reversed when the osmotic pressure was restored to control value (325 mosmol/kg H2O) (Fig. 5B). Since reducing the osmolarity also decreases [Na+]o and [Cl−]o, we determined whether a GlyR activation in the sniffer patch could still be observed when the osmotic pressure is restored using glycerol. Glycerol had no noticeable effect on GlyR intrinsic activation properties (data not shown). Restoring the osmotic pressure with a glycerol solution suppressed outside-out current, whereas an additional hypotonic challenge reactivated GlyRs in the sniffer patch (n = 4) (Fig. 5C), indicating that glycine release is selectively evoked by decreasing the osmotic pressure. To test whether glycine release could be evoked by mechanical stimuli alone, we touched a fired polished electrode on the surface of the SC (club-ending with a 5–10 μm tip) to stimulate the radial cell end feet, as previously described for mechanical stimulation of astrocytic end feet in the hippocampus (Kozlov et al., 2006). The club-ending of the electrode was first approached to the surface of the SC under visual control and then was pushed by 5–10 μm. We observed that such a stimulus can indeed evoke sniffer GlyR activity and, hence, glycine release (Fig. 5D) (n = 3).
Glycine is released from RC fibers
To determine whether the glycine release evoked by a hypotonic solution can originate from RC fibers, we first compared, at E12.5, the percentage of glycine-ir RC fibers, located in the marginal zone of lumbar SC sections in control conditions (325 mosmol/kg H2O ACSF) or exposed to hypotonic ACSF (200 mosmol/kg H2O) with or without GlyT blockers (1 μm ALX-5407, a GlyT1 specific blocker, and 0.5 μm ALX-1393, a blocker of both GlyT1 and GlyT2). A combined treatment with GlyT blockers and a hypotonic shock led to a complete loss of glycine immunoreactivity in RC fibers (Fig. 6A,B). Treatment with either GlyT blockers alone or hypotonic ACSF alone significantly reduced glycine immunoreactivity in RC fibers, but to a lesser extent than the combined treatment (Fig. 6C). Hypotonic solutions did not change taurine immunoreactivity detected in the marginal zone of the SC (data not shown), which confirms that taurine release is unlikely to be involved in the sniffer response.
Because RCs express GlyT1 only (Jursky and Nelson, 1996) and since GlyT blockers reduced the proportion of glycine-ir RC fibers, these results also indicate that glycine efflux could occur even in control conditions and that GlyT1 mediates glycine uptake rather than efflux even in the presence of a hypotonic solution. When penetrating the SC with the sniffer electrode, we observed an initial peak of activation followed by a slow decay (Fig. 4). It is likely that this initial peak reflects glycine release evoked when the electrode penetrates the SC (Fig. 5D). As shown in Figure 7, the decay rate of the sniffer current becomes faster at E14.5 than at E12.5 (Fig. 7A1–B1). The decay rate was estimated by measuring the duration of the sniffer current at 20% of the peak amplitude. The decay rate of the sniffer response was in the second time range at all age tested (Fig. 7) and did not change significantly between E11.5 and E13.5 (Kruskal–Wallis rank sum test, p > 0.1) (Fig. 7C). At E11.5, the 20% peak amplitude duration was 62.4 ± 9.8 s (n = 7). The 20% peak amplitude duration was 84.4 ± 12 s (n = 21) at E12.5 and 54.8 ± 11.6 s (n = 12) at E13.5. It became significantly shorter at E14.5 (20.6 ± 3.4 s; n = 21) (Kruskal–Wallis rank sum test, p < 0.01) (Fig. 7C). The decay rate of the sniffer response might then reflect some clearance mechanisms attributable to GlyT activity, which becomes more efficient at E14.5. This was confirmed by incubating SCs with the GlyT1 blocker ALX-5407, which resulted in a significant increase (Mann–Whitney test, p < 0.01) in the decay rate of the sniffer current at E14.5 (Fig. 7D) and in the occurrence of a basal GlyR activation (Fig. 7B2), as observed in control conditions at E12.5 (Figs. 4A1, 7A1). These results suggest that GlyT1 transporter activity lowers the basal level of extracellular glycine concentration below the GlyR activation threshold at E14.5. It has also to be noted that ALX-5407 significantly increased (Mann–Whitney test, p < 0.01) the decay rate of the sniffer current at E12.5 (Fig. 7C), indicating that some GlyT1 are already active at this age.
Together, our data, obtained using a multiple approach, clearly show that the spontaneous activation of GlyRs that was detected on motoneurons results from the release of glycine from RCs.
Glycine release from RCs and Ca2+
The sniffer currents evoked by hypotonic solutions cannot result from glycine release attributable to action potential firing since they were still observed in the presence of TTX (Fig. 8A). Neurotransmitter release from RCs is related to Ca2+ influx, at least in the developing cortex (Weissman et al., 2004). We also found that glycine release evoked by hypotonic solutions partially requires Ca2+ influx (Fig. 8B). The reversible decrease in the sniffer response amplitude in the absence of external calcium (Fig. 8B) cannot result from a direct effect on GlyR activation. Indeed, the responses evoked by 100 μm glycine application were not significantly (Wilcoxon's test, p > 0.1) modified in the absence of external Ca2+ (95 ± 5.9% of control; n = 4) (supplemental Fig. 5A, available at www.jneurosci.org as supplemental material). Since the application of a high [K+]o solution failed to evoke a sniffer response, it is unlikely that voltage-gated Ca2+ channels are involved in glycine release from RCs. Hence we analyzed the effect of nonselective Ca2+ channel blockers Gd3+ (100 μm), SKF-96365 (100 μm), and flufenamic acid (100 μm). Gd3+ at 100 μm had no significant effect (Wilcoxon's test, p > 0.1) on outside-out currents evoked by 100 μm glycine application (93 ± 7% of control; n = 4) (supplemental Fig. 5B, available at www.jneurosci.org as supplemental material). Gd3+, SKF-96365, or flufenamic acid partially inhibited the sniffer response to a hypotonic shock. Gd3+ had a smaller effect than flufenamic acid (Fig. 8C,D). The effects of SKF-96365 or flufenamic acid were irreversible (Fig. 8D,E) and were not attributable to a direct inhibition of GlyRs only (supplemental Fig. 5C,D, available at www.jneurosci.org as supplemental material). Effectively, although the coapplication of SKF-96365 and 100 μm glycine or of flufenamic acid and 100 μm glycine decreased outside-out current amplitudes by 86.3 ± 8% (n = 6) and 93.1 ± 1% (n = 3), respectively, these inhibitory effects of SKF-96365 and flufenamic acid were reversible (supplemental Fig. 5C,D, available at www.jneurosci.org as supplemental material). When glycine was applied 2 min after the coapplication of SKF-96365 and glycine or after the coapplication of flufenamic acid and glycine, the amplitude of the evoked outside-out currents was 96.5 ± 6.5% (n = 6) and 81 ± 8% of control (n = 3), respectively.
We then used immunohistochemistry to test whether glycine release from RCs induced by a hypotonic challenge in the presence of GlyT blockers may be prevented by Gd3+, SKF-96365, and flufenamic acid. We quantified the proportion of RC fibers containing glycine in E12.5 lumbar SC exposed to the following: hypotonic shock, GlyT blockers, hypotonic shock/GlyT blockers with Gd3+ or SKF-96365/flufenamic acid (Fig. 6C). We found that, in the presence of Gd3+ (100 μm), there was a moderate but not significant increase in the percentage of RC fibers still containing glycine after hypotonic challenge with GlyT blockers (1.9 ± 1.0%, n = 7, vs 0.9 ± 0.6%, n = 25; p = 0.08). The addition of SKF-96365 (100 μm) and flufenamic acid (100 μm) had a stronger effect than Gd3+. These blockers increased >10 times (p < 0.01) the proportion of glycine-ir RC fibers after hypotonic challenge in the presence of GlyT blockers (24.4 ± 3.7%; n = 10) (Fig. 6C).
Nonvesicular release of glycine from RCs
Because glycine release, evoked in response to hypotonic shock, was reduced in the absence of external Ca2+, we supposed that it could reflect vesicular release of glycine. To test whether glycine release is vesicular, we analyzed the effect of preincubation (during 1–3 h at 35°C) with 4 μm bafilomycin A1, an inhibitor of the V (vacuolar)-ATPase that prevents the entrance of neurotransmitters into synaptic vesicles (Cousin and Nicholls, 1997). Glycine release evoked by hypotonic shock was analyzed using sniffer patches in E14.5 SCs because many synapses are functional at this embryonic age. We first analyzed the effect of this toxin on the spontaneous and evoked synaptic activity (elevated [K+]o) recorded on spinal MNs (Fig. 9A1, A2). The application of 30 mm KCl dramatically increased the frequency of postsynaptic events (Fig. 9A1) and preincubation with bafilomycin was able to completely eliminate spontaneous and evoked PSCs (n = 6), indicating that synaptic vesicular release was impaired (Fig. 9A2). In these preparations, the hypotonic solution was still able to evoke a sniffer current (Fig. 9A3), suggesting that glycine released by this method is unlikely to be vesicular.
In addition, we could not detect immunoreactivity for the vesicular inhibitory amino acid transporters (VIAATs) for glycine inside glycine-ir RCs (supplemental Fig. 6, available at www.jneurosci.org as supplemental material), reinforcing the hypothesis of a nonvesicular release of glycine from RCs.
Glycine release could alternatively result from the opening of large channels in response to membrane stretch such as hemichannels formed by connexins or pannexins, P2X7 receptors, and/or the TRPV1 (Suadicani et al., 2006; Chung et al., 2008; Iovine et al., 2008). Unopposed hemichannels are present on RCs in the cortex of fetal rats (Elias et al., 2007). Other proteins such as the noncanonical connexin C23 (Iovine et al., 2008) or the TRPV1 (Chung et al., 2008) can also allow the permeation of small molecules. In that context, it is important to notice that flufenamic acid can block connexins (Weissman et al., 2004), P2X7 receptors (Suadicani et al., 2006), and transient receptor potential (TRP) channels (for review, see Pedersen and Nilius, 2007).
We therefore determined whether functional hemichannels and P2X7 receptors are present on SC RCs by using a classical procedure to reveal the presence of connexin or pannexin hemichannels on RCs in the SC of fetal mice at E12.5–E13.5. Radial cell bodies are located in the median zone of the ventromedian part of the lumbar SC. Hemichannels are permeable to the small anionic fluorescent dye LY [molecular weight (MW) 457] or to the cationic Neurobiotin (MW 322). LY can pass through connexons or pannexons (Shestopalov and Panchin, 2008) as well as through P2X7 receptors (Colomar and Amédée, 2001), and Neurobiotin can pass through hemichannels formed by connexin C23 (Iovine et al., 2008). In control conditions (325 mosmol/kg H2O), some cells (22.5 ± 2.5 cells; n = 12 slices; 4 lumbar slices per SC; 3 SCs) displayed a low LY staining. Applying a hypotonic solution (200 mosmol/kg H2O) did not significantly change (Mann–Whitney test, p > 0.05) LY uptake by cells located in the ventromedian part of the lumbar SC (15.3 ± 3.1 cells; n = 12 slices; 4 lumbar slices per SC; 3 SCs) (supplemental Fig. 7A, available at www.jneurosci.org as supplemental material). In control conditions (325 mosmol/kg H2O), very few cells displayed Neurobiotin staining in the ventromedian part of the lumbar SC (1.7 ± 0.4 cells; n = 12 slices; 4 lumbar slices per SC; 3 SCs). Applying a hypotonic solution (200 mosmol/kg H2O) did not significantly change (Mann–Whitney test, p > 0.05) the number of cells displaying Neurobiotin staining (0.8 ± 0.2 cells; n = 12 slices; 4 lumbar slices per SC; 3 SCs) (supplemental Fig. 7B, available at www.jneurosci.org as supplemental material). Moreover, 20 μm ATP application (P2X receptor agonist) did not evoke any GlyR sniffer activation (n = 4), and neither did 10 μm capsaicin, a TRPV1 agonist (n = 4) (supplemental Fig. 7C, available at www.jneurosci.org as supplemental material). Accordingly, these findings do not support the implication of hemiconnexins, P2X or TRPV1 receptors in glycine release.
We have shown that flufenamic acid and SKF-96365 partially inhibit the sniffer response to a hypotonic shock (Fig. 8D,E). Flufenamic acid is also known to block chloride channels (Do et al., 2006; Greenwood and Leblanc, 2007). Hence, it seems possible that volume-sensitive chloride channels may also be involved in glycine release. For example, VSOR anion channels have been suggested to release small molecules after mechanical stimuli (Liu et al., 2008). We looked for a possible involvement of VSOR in glycine release from RCs, by quantifying the proportion of RC fibers containing glycine in E12.5 lumbar SC in control condition or having been exposed to hypotonic shock/GlyT blockers in the absence or in the presence of DCPIB, a specific blocker of VSOR channels (Liu et al., 2008).
In the presence of DCPIB (10 μm), there was a significant increase in the percentage of RC fibers containing glycine after hypotonic challenge with GlyT blockers when compared with data obtained after hypotonic challenge with GlyT blockers in the absence of DCPIB (49.3 ± 3.8%, n = 14, vs 1.1 ± 0.6%, n = 28; p < 0.01, Dunnett's multiple comparison after one-way ANOVA) (Fig. 9B). Interestingly, this percentage in DCPIB-treated preparations was not significantly different from control (57.8 ± 3.4%; n = 23). Similar results were obtained with 10 μm phloretin, another blocker of VSOR channels (Liu et al., 2008): phloretin significantly increased the percentage of glycine-ir RC fibers detected after a hypotonic shock with GlyT blockers (32.5 ± 4.3%, n = 4, vs 1.1 ± 0.6%, n = 28; p < 0.01, Dunnett's multiple comparison) (Fig. 9B4). The percentage of RC fibers in phloretin-treated preparations was also not significantly different from control. Hence, we analyzed the effect of DCPIB (10 μm) and phloretin (10 μm) on the sniffer response to a hypotonic shock (supplemental Fig. 7D,E, available at www.jneurosci.org as supplemental material). Both DCPIB and phloretin inhibited the sniffer response to a hypotonic shock (86.7 ± 5.9% block for DCPIB, n = 5, and 78.3 ± 11.8% block for phloretin, n = 3). This was not attributable to direct inhibition of glycine-evoked responses (supplemental Fig. 5, available at www.jneurosci.org as supplemental material) at least for DCPIB. Indeed, the sniffer responses induced by hypotonic solution were still decreased 10 min after the end of the application of DCPIB (80.5 ± 8% block; n = 5). This was significantly different (Mann–Whitney test, p < 0.01) from the decrease in GlyR activation observed 10 min after the end of DCPIB application (23.1 ± 5.6%; n = 9). The inhibition of the sniffer response evoked by phloretin was also poorly reversible. We observed a 76.7 ± 11.1% inhibition (n = 3) 10 min after the end of the application of this drug (supplemental Fig. 7E, available at www.jneurosci.org as supplemental material). However, phloretin-evoked inhibition of GlyR activation was also poorly reversible (64.1 ± 7.1%; n = 6) (supplemental Fig. 5F, available at www.jneurosci.org as supplemental material), which precluded making any conclusion on the effect of phloretin on glycine release using the sniffer recording technique.
Functional relevance of early glycine release from RCs
Glycine has been described as the transmitter system required, with ACh, for the propagation of the spontaneous rhythmic activity in E12.5 embryonic mouse spinal cord (Hanson and Landmesser, 2003). We performed multiple extracellular recordings from E12.5 spinal cords to assess the implication of glycine released from RCs in rhythmic spontaneous activity expressed by motor networks. Because blocking the glycine transporters GlyT1 decreased glycine radial cell content (Fig. 6) and increased extracellular glycine concentration (Fig. 7), we first compared the effect of the GlyR antagonist strychnine (5 μm) with the effect of ALX-5407 (1 μm). We did not test the effect of the VSOR blocker DCPIB and phloretin since these compounds partially inhibited GlyR activation (see above) (supplemental Fig. 5, available at www.jneurosci.org as supplemental material). As shown in Figure 10, strychnine and ALX-5407 (n = 6 experiments) had opposite effects on the spontaneous bursting activity of the spinal cord. Strychnine decreased the burst duration from 3.26 ± 0.20 to 2.88 ± 1.13 s, whereas ALX-5407 significantly increased it from 3.30 ± 0.33 to 4.12 ± 0.70 s. Strychnine also decreased the burst area from 666.7 ± 96.2 (arbitrary units) to 544.6 ± 89.8, whereas ALX-5407 increased it from 604.0 ± 104.5 to 730.5 ± 145.1. Finally, strychnine increased the period of recurring bursts of activity from 173.9 ± 19.3 to 311.0 ± 50.8 s, whereas ALX-5407 significantly reduced the period from 167.5 ± 10.3 to 111.7 ± 2.6 s (*p < 0.05, Wilcoxon's matched pairs tests). Strychnine application also slowed down the propagation of spontaneous activity along the cord. The delay between cervical and lumbar recording sites was 1.23 ± 0.18 s in control condition versus 2.56 ± 0.43 s in the presence of strychnine (n = 6 experiments; p < 0.05, Wilcoxon's matched pairs test) (only bursts propagating rostrocaudally were quantified, these latter being the most common).
We then tested, at E12.5, whether strychnine affects the propagation of evoked activity (electrical stimulation at the cervical level). Although strychnine affected the propagation of the electrical activity across the spinal cord, it did not prevent it. As illustrated in Figure 10A2, spontaneous bursts still traveled across the spinal cord in strychnine condition, but with a much longer delay between cervical and lumbar recording levels. The strychnine treatment also considerably slowed down the propagation of evoked bursts (Fig. 10, compare A1 and A2, bottom traces). In two experiments, in the presence of strychnine, the burst evoked by a threshold electrical stimulation (0.04 V) vanished before reaching the thoracic and lumbar recording electrodes (Fig. 10C2). However, a slight increase of the stimulation intensity (0.05 V) (Fig. 10C3) restored a rostrocaudally propagating activity, indicating that glycine release is not essential for the propagation of the activity along the spinal cord. The delay between cervical and lumbar level was 1.40 ± 0.11 s in control condition and 2.81 ± 0.14 s in the presence of strychnine and when the stimulation intensity was raised (n = 8 from four experiments; p < 0.05, Wilcoxon's matched pairs test).
Discussion
Although a nonsynaptic release of classical neurotransmitters such as GABA and glutamate was previously described in the developing CNS (for review, see Ben-Ari, 2001; Spitzer, 2006), the cellular origin and the mechanisms of this first neurotransmitter release at early developmental stages was never clearly addressed in vivo. In this paper, we provide the first evidence of the release of the classical neurotransmitter glycine by RCs at early stages of the SC development. Radial cells are involved in cell migration and are potent neuronal and glial progenitors (Pinto and Götz, 2007). Here, we also give evidences that this release of glycine at E12.5 modulates the propagation of the spontaneous activity in the isolated embryonic spinal cord.
Taurine was initially proposed as the main GlyR agonist in the developing CNS (Flint et al., 1998), but we found no evidence for taurine release in the embryonic SC. Indeed, taurine immunoreactivity was restricted to the marginal zone and was not expressed by RCs. Also, taurine immunoreactivity did not disappear in the presence of a hypotonic solution, which makes it unlikely that taurine is released by osmotic changes. Therefore, we propose that glycine is the main endogenous GlyR agonist at early developmental stages of the SC neuronal networks, and this is reinforced by the fact that the extracellular endogenous GlyR agonist concentration is enhanced in the presence of GlyT blockers.
Radial cells are the main source of glycine before E13.5
Both neuroepithelial cells and glial cell progenitors share similar, radial, morphology. They also share expression of the intermediate filament nestin and the antigen for RC2 (Pinto and Götz, 2007). In the mouse spinal cord, neuroepithelial cells appear at the onset of the neurogenesis (E10), whereas radial glial cells occur at E12/E13 when neurogenesis comes to an end (Barry and McDermott, 2005). Since the proportion of glycine-ir radial cells increases from E11.5 to E13.5 and since almost all radial cells contain glycine at E13.5 (>80%), we assume that they are radial glial cells. At E12.5, RCs appear to be the exclusive source of glycine, glycinergic neurons being detected at E13.5 at more caudal spinal levels only (Allain et al., 2006). After E13.5, the proportion of RCs expressing glycine declines. This temporary expression of glycine in RCs may rely on several mechanisms that are not mutually exclusive. The first possibility is a developmental change in the efficacy of radial cells in glycine (re)uptake. The expression of GlyT1 by spinal radial cells in fetal mice increases from E11.5 to E13.5 and then declines at later stages (Jursky and Nelson, 1996), which could suggest that radial cell glycine content originates from glycine uptake. The second possibility is a developmentally regulated synthesis of glycine by differentiating radial cells. Glycine is mainly formed via a complex metabolic pathway in astroglia (Furuya et al., 2000) to provide a microenvironment for optimal neuronal network development and operation (de Koning et al., 2003).
Release of glycine and mechanical stimuli
Nonvesicular release was described for GABA and glutamate in the developing cortex (Liu et al., 2005) and hippocampus (Demarque et al., 2002; Le Meur et al., 2007). We show here that the glycine release by RCs after a hypotonic shock is also nonvesicular. Because of its transport stoichiometry (2 Na+/1 Cl−/1 glycine) (Aragón et al., 1987), GlyT1 can take up or release glycine depending on the concentration of Na+ or glycine and on the membrane potential (Roux and Supplisson, 2000; Huang et al., 2004). Although we cannot completely rule out the possibly that GlyT1 also participates in glycine release from RCs in the embryonic SC, it is unlikely to be the major mechanism. Indeed, blocking GlyT1 decreases the proportion of glycine-ir RCs, indicating that the main function of the glycine transporters is more likely to be (re)uptake of glycine into RC fibers.
Glycine release could be induced by mechanical stimuli and by hypotonic shocks. Neurotransmitter release in response to mechanical stimuli in the embryo is still poorly understood, and the corresponding physiological stimulus is unclear. However, there is evidence suggesting that, at least in the developing cortex, blood circulation through blood vessels could result in RC fiber deformation (RCs extend intermediate branches around blood vessels) and, hence, evoke neurotransmitter release (Weissman et al., 2004). Cellular membrane deformation was also proposed to explain mechanical-dependent release of GABA by astrocytes in the olfactory bulbs of young rats (Kozlov et al., 2006). Accordingly, because RCs include astroglial progenitors (Pinto and Götz, 2007), one may suppose that astrocytes maintain during development a release mechanism already present in their precursor cells.
Another possible mechanical stimulus, although slow, could be RC fiber local deformation during the migration of the newborn neurons. Newly formed interneurons migrate from E10.5 to E13.5 in the ventral horn (Goulding and Pfaff, 2005) and neuronal migration could evoke mechanical stimuli and deformation of radial cell fibers (Kriegstein and Noctor, 2004). Finally, a last potential physiological stimulus could be the flow of the CSF (Vígh et al., 2004) since radial cell fiber endings are located close to the pial surface of the SC. Additional experiments will be necessary to address this issue.
Glycine release mechanism(s)
Neurotransmitter release by mechanical stimuli was previously described in the adult and in the developing CNS in slices (Flint et al., 1998; Kozlov et al., 2006), but the release pathway remained to be determined. One of the major problems to characterize the release pathway involved in nonvesicular release of neurotransmitter is the lack of strong specificity of the channel blockers generally used to analyze the implication of TRPs, hemichannels, P2XRs, and volume-sensitive chloride channels. For example, flufenamic acid has been described as a TRP channel blocker (Inoue et al., 2001; Lee et al., 2003), although it also interferes with connexin/pannexin hemichannels, with P2X receptors (Lee et al., 2001; Weissman et al., 2004) and with GlyRs (supplemental Fig. 5, available at www.jneurosci.org as supplemental material). To overcome this problem, we used a multiple approach, which allowed us to exclude P2X receptors, TRPV1 receptors, and hemichannels as potential release pathways for glycine. Moreover, Gd3+, also known to be a potent TRP blocker (Hamill and McBride, 1996; Cho et al., 2002), did not prevent loss of glycine content from RCs, which makes unlikely that TRP activation is involved in glycine release by RCs.
Accordingly, the last known candidate allowing glycine release could be the VSOR anion channels (Liu et al., 2008) or the maxi anion channels (Liu et al., 2006). Release of small molecules such as ATP or glutamate, evoked by mechanical stimuli, can also involve VSOR anion channels or maxi anion channels at least in vitro (Liu et al., 2006, 2008). Since we were able to prevent the decrease in RC glycine content evoked by hypotonic solution using DCPIB and phloretin, two blockers of VSOR channels, and since VSOR channels are poorly blocked by Gd3+ (Decher et al., 2001), we propose that glycine release involves mainly the opening of VSOR channels. VSOR channels have a small pore radius (≈0.63 nm) allowing efflux of small amino acids only (Ternovsky et al., 2004), such as glycine. Accordingly, the opening of VSOR channels cannot be detected during uptake experiments using bigger molecules such as LY or Neurobiotin.
We also showed that glycine release is partly dependent on Ca2+ influx, but, since glycine release cannot be evoked by high [K+]o solutions, it is unlikely to involve voltage-gated Ca2+ channels. We therefore cannot entirely exclude that glycine release is also modulated by voltage-independent Ca2+ channels (Christensen and Corey, 2007), but it is interesting to mention that VSOR channel openings are also evoked by increasing [Ca2+]i and by activation of PLC1 (Varela et al., 2007).
Glycine release and functional early developing neuronal network
Glycine synaptic release in the early mouse embryonic SC (E12.5) has been proposed to be involved in the genesis of recurrent episodes of spontaneous activity and their propagation along the SC (Branchereau et al., 2002; Hanson and Landmesser, 2003). This proposal was based on extracellular recordings and on pharmacological studies using GlyR antagonists in vitro. However, we show that glycinergic synaptic activity does not occur at E12.5 ruling out the possibility that a glycine synaptic network can be involved in the intersegmental propagation of the spontaneous electrical activity in the embryonic SC at this early stage. The first functional synapses occur at E13.5 in the embryonic mouse lumbar SC and are GABAergic, being consistent with what is known in other areas of the CNS (Ben-Ari, 2001). The lack of glycinergic synaptic events is also consistent with the very low proportion of glycinergic neurons detected at E12.5 (Allain et al., 2006). We demonstrated that blocking GlyRs by strychnine depressed the spontaneous activity, whereas increasing the glycine concentration by ALX-5407 boosted it. We therefore propose that fluctuations of basal glycine concentrations, likely to be released from RCs, influence the excitability of developing neural networks, thereby modulating the propagation speed and the likelihood of spontaneous activity propagating along the SC (Hanson and Landmesser, 2003; Ren and Greer, 2003; Yvert et al., 2004).
Footnotes
-
This work was supported by Association Française contre les Myopathies (France), Fondation pour la Recherche sur le Cerveau (France), and Conseil Régional d'Aquitaine Grant 20040301202A. A.-L.S. was supported by Fondation pour la Recherche Médicale (France). We thank Drs. Joseph O'Neill and Alain Marty for critical reading of this manuscript.
- Correspondence should be addressed to either of the following: Dr. Pascal Legendre, Inserm Unité 952/Centre National de la Recherche Scientifique, Unité Mixte de Recherche 7224, Université Pierre et Marie Curie, Bâtiment B, étage 6, boite postale 37, 7 quai Saint Bernard, F-75005 Paris, France, pascal.legendre{at}snv.jussieu.fr; or Dr. Pascal Branchereau, Centre de Neurosciences Intégratives et Cognitives, Université de Bordeaux et Centre National de la Recherche Scientifique, Unité Mixte de Recherche 5228, Bâtiment B2 Est, étage 4, F-33405 Talence Cedex, France, p.branchereau{at}cnic.u-bordeaux1.fr