Abstract
In the developing mouse retina, spontaneous and light-driven activity shapes bipolar→ganglion cell glutamatergic synapse formation, beginning around the time of eye-opening (P12–P14) and extending through the first postnatal month. During this time, glutamate release can spill outside the synaptic cleft and possibly stimulate extrasynaptic NMDA-type glutamate receptors (NMDARs) on ganglion cells. Furthermore, the role of NMDARs during development may differ between ON and OFF bipolar synapses as in mature retina, where ON synapses reportedly include extrasynaptic NMDARs with GluN2B subunits. To better understand the function of glutamatergic synapses during development, we made whole-cell recordings of NMDAR-mediated responses, in vitro, from two types of genetically identified direction-selective ganglion cells (dsGCs): TRHR (thyrotropin-releasing hormone receptor) and Drd4 (dopamine receptor 4). Both dsGC types responded to puffed NMDA between P7 and P28; and both types exhibited robust light-evoked NMDAR-mediated responses at P14 and P28 that were quantified by conductance analysis during nicotinic and GABAA receptor blockade. For a given cell type and at a given age, ON and OFF bipolar cell inputs evoked similar NMDAR-mediated responses, suggesting that ON-versus-OFF differences in mature retina do not apply to the cell types or ages studied here. At P14, puff- and light-evoked NMDAR-mediated responses in both dsGCs were partially blocked by the GluN2B antagonist ifenprodil, whereas at P28 only TRHR cells remained ifenprodil-sensitive. NMDARs contribute at both ON and OFF bipolar cell synapses during a period of robust activity-dependent synaptic development, with declining GluN2B involvement over time in specific ganglion cell types.
- activity-dependent
- bipolar cell
- circuit development
- ganglion cell
- GluN2B subunit
- NMDA receptors
Introduction
Neural circuit development depends, in part, upon activity-dependent mechanisms (Bleckert and Wong, 2011). In the retina, activity contributes to the formation of glutamatergic bipolar→ganglion cell synapses. Around the time of eye-opening in mice [postnatal day (P) 12–14], the retina becomes light-responsive as bipolar cell synaptic release transitions from spontaneous to light-driven (Fisher, 1979; Tian and Copenhagen, 2001; He et al., 2011). This release is detected by both AMPA-type receptors (AMPARs) and NMDA-type receptors (NMDARs) on postsynaptic ganglion cell dendrites (Bansal et al., 2000; Wong et al., 2000; Blankenship et al., 2009; He et al., 2011). Perturbation of bipolar cell glutamate release alters the number and strength of these synapses, and may also influence the stratification of ganglion cell dendrites under certain conditions (Kerschensteiner et al., 2009; Xu et al., 2010; Soto et al., 2012). Thus, activation of glutamate receptors clearly contributes to the development of retinal circuitry.
It is less clear whether these developing synapses incorporate NMDARs composed of specific subunits. NMDARs typically contain two GluN2 subunits (GluN2A-D), and during development, NMDARs containing GluN2B subunits can regulate the number and strength of developing synapses in the hippocampus (Gambrill and Barria, 2011; Gray et al., 2011; Tovar et al., 2013). In the mature retina, GluN2B-containing NMDARs are reportedly localized extrasynaptically and preferentially near ON bipolar synapses (Sagdullaev et al., 2006; Zhang and Diamond, 2009). During development, extrasynaptic receptors may be activated around eye-opening, when spontaneous activity evokes glutamate spillover (Blankenship et al., 2009). However, the subunit composition of the NMDARs activated by spontaneous activity has not been evaluated. Moreover, it is not known whether light-evoked glutamate release activates NMDARs in the developing retina, or whether activation and/or subunit composition of these receptors differs between ON and OFF bipolar synapses. Our study examined two types of genetically identified direction-selective ganglion cells (dsGCs) across the first month of postnatal life to determine the role of NMDARs and GluN2B subunits in encoding glutamate release during this period of robust synaptic maturation.
Materials and Methods
Mouse strains.
Mice of either sex from two strains were used: TRHR (thyrotropin-releasing hormone receptor)-GFP (Rivlin-Etzion et al., 2011) and Drd4 (dopamine receptor 4)-GFP (Huberman et al., 2009). Both mouse lines were kindly provided by Dr. Marla Feller (University of California, Berkeley, CA) and were backcrossed to C57BL/6 for >5 generations before establishing a colony.
Tissue preparation.
All procedures conformed to the NIH guidelines for use and care of animals in research, and were approved by the University Committee on Use and Care of Animals at University of Michigan or Yale University. Procedures were similar to those described previously (Wang et al., 2011; Borghuis et al., 2013). Briefly, retinas were harvested and dissected in gassed (95% O2 and 5% CO2) Ames medium (Sigma-Aldrich) under infrared illumination, and cut along the dorsal–ventral axis (Wei et al., 2010; Wang et al., 2011). For NMDA application experiments, both dorsal and ventral pieces were used; for light-stimulation, only ventral pieces were used.
Electrophysiology.
A piece of retina was placed in a chamber on an upright microscope and superfused (∼5 ml/min) with gassed (95% O2 and 5% CO2) Ames medium heated to 33–35°C, as described previously (Wang et al., 2011; Borghuis et al., 2013). The retina and electrode were visualized at 60× (0.9 or 1.0 NA) under IR illumination. In some experiments, green-fluorescent-protein-expressing (GFP+) ganglion cells were visualized by attenuated mercury light passed through a GFP dichroic mirror (Chroma). A GFP+ soma was localized and targeted for recording under IR illumination. In other experiments, GFP+ cells were targeted by two-photon imaging, as described previously (Borghuis et al., 2013).
Cells were recorded with borosilicate glass pipettes (4–6 MΩ) filled with intracellular solution containing the following (in mm): 110 Cs-methanesulphonate, 5 TEA-Cl, 10 HEPES, 3 NaCl, 10 BAPTA, 2 QX-314-Cl, 2–4 ATP-Mg2+, and 0.3–0.4 GTP-Na, titrated to pH 7.3. Chemicals were purchased from Sigma-Aldrich, Invitrogen, or Tocris Bioscience. Voltage-clamp recordings were performed as described previously (Manookin et al., 2010). For voltage-step protocols, initial Vhold (−100 to −75 mV) was stepped up every 8 s (10–20 mV increments) followed by a return to the initial level.
Puff-evoked NMDA response.
Responses to puffed NMDA were measured with synaptic transmission strongly attenuated by bath applying the following (in μm): the L-type Ca2+ channel blocker isradipine (30); antagonists to glycine (strychnine, 2), GABAA (gabazine, 20), and AMPA/kainate (CNQX, 100) receptors; and the NMDAR coagonist D-serine (200). A puffer pipette (3–5 MΩ) containing NMDA (10 mm) dissolved in Ames medium with D-serine (200 μm) and isradipine (30 μm) was connected to a Pico-spritzer (Parker Hannafin) and positioned near the soma. NMDA was applied via 10–30 ms puffs at 10–15 psi.
Light stimulation.
The retina was stimulated by the combined output of 12 UV LEDs (peak 365 nm, LZC-70U600, LEDEngin). Flashes were triggered by pClamp 9 software, and intensity was controlled by a pulse generator (WPI) via a custom noninverting voltage-to-current converter using an operational amplifier. In most experiments, stimuli (2 mm diameter) were 1 s flashes from a dark background at ∼104 photoisomerizations (R*)/S-cone/s (assuming a 1 μm2 cone collecting area; Wang et al., 2011) presented through a 4× objective (0.13 NA). In some experiments, intensity was attenuated (to 2–5 × 103 R*/S-cone/s) to reduce the response at Vhold = +40 mV by ∼50%. In other experiments, contrast-modulated UV spots (peak, 395 nm; mean luminance, ∼0.5 × 104 photoisomerizations/S-cone/s) were presented through the condenser, as described previously (Borghuis et al., 2013).
Assessing the impact of GFP epifluorescence on UV light responses.
Epifluorescence for identifying GFP+ dsGCs did not substantially bleach S-cone photopigment. GFP-negative ON α cells (n = 3) targeted under IR illumination were recorded in ventral retina (van Wyk et al., 2009; Estevez et al., 2012), where cones express primarily S-opsin with peak sensitivity at ∼360 nm (Jacobs et al., 1991; Wang et al., 2011). These cones should be relatively insensitive to the GFP excitation wavelength (∼488 nm). ON α cell conductance (i.e., slope of the linear current–voltage relationship) to a 365 nm UV stimulus was similar before (44 ± 10 nS) and after either one (43 ± 8 nS) or 2 min (43 ± 6 nS) of 488 nm exposure. In typical dsGC recordings, we exposed ventral tissue to <30 s of 488 nm light, which should minimally impact cone-mediated responses.
Analysis.
Responses were analyzed using custom MATLAB routines (version 7.10). A conductance analysis was performed on leak-subtracted responses, as described previously (Manookin et al., 2010). Input resistance for representative samples was 207 ± 17 MΩ (TRHR; n = 39) and 226 ± 16 MΩ (Drd4; n = 28), and the uncompensated series resistance was 16 ± 1 MΩ. Current–voltage (I–V) relationships were modeled as the weighted sum of three ligand-gated currents (Iligand) mediated by AMPA, NMDA, and GABA/glycine receptors (least-squares fit; Manookin et al., 2010): The weights estimate the ligand-gated conductances that combine to generate the measured I–V relationship. The NMDA weights, which are strongly voltage-dependent, represent the conductance at −60 mV (i.e., around the resting potential).
For the data in Figure 3 (ON or OFF responses at P14 or P28), the AMPAR- and NMDAR-mediated conductances measured were each similar between the two cell types, and there was no evidence for bimodality between cell types (p > 0.1; Hartigan's dip test); data from the two types were therefore combined. Statistical comparisons were performed using one-sample, two-tailed Student's t tests. Results are reported as mean ± SEM.
Results
NMDA receptor subunit composition changes during early postnatal development
Puffing NMDA evoked responses in GFP+ dsGCs in both TRHR and Drd4 mice at four ages (P7, P14, P21, P28). These responses reflected opening of NMDA channels, because synaptic transmission and multiple receptors (AMPA/kainate, GABAA, and glycine) were blocked (see Materials and Methods); and the I–V relationship showed the characteristic J-shape of an NMDAR-mediated response (Traynelis et al., 2010). In both cell types, the GluN2B antagonist ifenprodil (10 μm; Fig. 1A) suppressed ∼50% of the response at P7, as quantified by the ifenprodil:control response ratio measured at Vhold near +40 mV (INMDA +40 mV) where NMDAR conductance is maximal (Fig. 1B). During development, ifenprodil's effect diminished, and differences between the cell types emerged. In Drd4 cells, the ifenprodil:control response ratio was significantly <1 at P7 (0.55 ± 0.06; p < 0.001) and P14 (0.71 ± 0.07; p < 0.01), but not at P21 (0.83 ± 0.10; p > 0.2) or P28 (1.03 ± 0.08; p > 0.2). In TRHR cells, the ratio was <1 at all four ages: P7 (0.47 ± 0.03; p < 0.001), P14 (0.58 ± 0.08; p < 0.005), P21 (0.63 ± 0.09; p < 0.01), and P28 (0.72 ± 0.05; p < 0.005). Ifenprodil's effect could be reversed upon washout (Fig. 1C1,C2). These results suggest that Drd4 and TRHR dsGCs differ in GluN2B subunit expression by P28.
Glutamatergic inputs onto dsGCs could be isolated pharmacologically
Puff-evoked NMDA activates all membrane-bound receptors, including nonsynaptic receptors distant from release sites; whereas light-evoked glutamate release specifically activates synaptic, and possibly, extrasynaptic receptors near release sites (Zhang and Diamond, 2009). UV light responses were studied in targeted GFP+ dsGCs in the ventral retina (see Materials and Methods). We tested whether NMDARs were activated by light-evoked glutamate release at P14 and P28, which spans much of the period of bipolar→ganglion cell synapse formation.
In a P14 Drd4 cell, a UV flash (1 s; 2 mm diameter) evoked robust responses at light-onset and light-offset that were dominated by inhibition, resulting in linear I–V relationships that reversed near the chloride equilibrium potential (ECl; −67 mV; Fig. 2A). Data from the two cell types were qualitatively similar and were combined to generate averaged I–V plots at P14 and P28 (Fig. 2A). The large inhibitory input obscured the relatively small excitatory input (Poleg-Polsky and Diamond, 2011).
Glutamatergic excitatory responses were subsequently isolated by applying antagonists to nictotinic acetylcholine (hexamethonium, 100 μm) and GABAA (gabazine, 20 μm) receptors. Transient responses at light-onset and light-offset (Fig. 2B) showed J-shaped I–V relationships reversing near Ecation (0 mV; Fig. 2B). Data from the two cell types were qualitatively similar and were combined to generate averaged I–V plots at P14 and P28; a J-shaped I–V relationship was apparent at both ages (Fig. 2B). The J-shape was blocked by the NMDAR antagonist D-AP5 (100 μm; Fig. 2C; Manookin et al., 2010), and the ON response was blocked by the group III mGluR agonist L-AP4 (50 μm; Fig. 2D), which suppresses ON bipolar cells. Thus, ON and OFF bipolar release onto NMDARs could be individually evaluated by light-ON and light-OFF responses in the presence of nicotinic and GABAA receptor antagonists.
NMDARs on ON and OFF dsGC dendrites can be activated by light-evoked glutamate release in dsGCs
Light responses were modeled as the weighted sum of three basis functions (Fig. 3A; see Materials and Methods) where the weights describe each receptor's conductance (Manookin et al., 2010). The AMPAR basis function was assumed to be linear and reverse at 0 mV. The NMDAR basis function was derived from puff-evoked NMDA responses (Fig. 1), and the inhibitory (GABA/glycine) receptor basis function was derived from the light-ON response under control conditions, which was dominated by inhibition (Fig. 2). Population analysis was performed on normalized conductances, and fits were converted to I–V basis functions (Fig. 3B) as described previously (Manookin et al., 2010).
At P14, TRHR cell responses showed J-shaped I–V relationships that were well fit by the basis functions (Fig. 3C). Data from the two cell types showed similar patterns of excitatory conductance and were combined (see Materials and Methods; data from individual cell types are shown in Fig. 4). Both cell types showed significant AMPAR- and NMDAR-mediated conductances at light-onset and light-offset (p < 0.001 in each case; Fig. 3E). A low-intensity flash that reduced responses by approximately twofold (see Materials and Methods) also generated significant AMPAR- and NMDAR-mediated conductances (p < 0.001 in each case; Fig. 3E). Here, and in all subsequent experiments using hexamethonium and gabazine, the inhibitory conductance was not significantly greater than zero for either response in either cell type (data not shown; p > 0.1 in all cases). To determine whether spatially restricted stimuli also elicited NMDAR-mediated conductances, GFP+ cells were targeted by two-photon microscopy, and a smaller stimulus (0.17 mm diameter; 100% contrast) was presented against a uniform background at mean luminance (see Materials and Methods). In some cases, the nicotinic antagonist curare (50 μm) replaced hexamethonium. This stimulus generated smaller responses overall, but still showed significant AMPAR- and NMDAR-mediated conductances at both light-onset and light-offset in both cell types (p < 0.001 in each case; Fig. 3D,E). Thus, at P14, light-evoked glutamate release activates NMDARs at ON and OFF bipolar terminals in Drd4 and TRHR cells.
Recordings at P28 showed similar results. The UV flash generated significant AMPAR- and NMDAR-mediated components at light-onset and light-offset in both cell types at both stimulus intensities (p < 0.05 in each case; Fig. 3F,H), as did the contrast-reversing spot (p < 0.001 in each case; Fig. 3G,H). Thus, at P14 and P28, light-ON and light-OFF responses reliably activate NMDARs.
NMDARs activated by light-evoked glutamate release contain GluN2B subunits at P14 but show cell-type-specific composition at P28
At P14, the UV flash response showed sensitivity to ifenprodil, demonstrating a GluN2B subunit contribution (Fig. 4A). We quantified ifenprodil's effect by the ratio of the fitted conductances in ifenprodil relative to control conditions (i.e., hexamethonium and gabazine only). For Drd4 and TRHR cells, ifenprodil significantly reduced NMDAR ratios below one (p < 0.005 in each case), whereas the AMPAR ratios were not affected (p > 0.1; Fig. 4B,C). Thus, GluN2B-containing NMDARs were activated by light-evoked glutamate release at ON and OFF synapses onto Drd4 and TRHR dsGCs.
The same experiment at P28 showed differences between the cell types. For Drd4 cells, AMPAR and NMDAR ratios were unaffected by ifenprodil (p > 0.1 in all cases; Fig. 4E). In TRHR cells, ifenprodil significantly reduced the NMDAR ratios (p < 0.05 in each case), but not the AMPAR ratios (p > 0.2; Fig. 4D,F). To test whether the TRHR cells were simply delayed in their loss of ifenprodil sensitivity, we performed experiments at P35. Ifenprodil continued to reduce the NMDAR ratios (p < 0.005 in each case), but not the AMPAR ratios (p > 0.9; Fig. 4F) at P35. Thus, by P28, NMDARs on TRHR cells continue to incorporate GluN2B subunits at ON and OFF bipolar synapses, whereas those of Drd4 cells do not.
Discussion
Here, we evaluated functional NMDAR-mediated responses in two types of genetically identified dsGCs during the first postnatal month (Huberman et al., 2009; Rivlin-Etzion et al., 2011). Our main findings are as follows: (1) GluN2B-containing NMDARs are activated by light-evoked glutamate release at synaptic and possibly extrasynaptic locations on ON and OFF layer dendrites during a period of bipolar→ganglion cell synapse formation (Figs. 2⇑–4), and (2) GluN2B subunits are developmentally downregulated from functional NMDARs in a cell-type-specific fashion; through P14, both cell types express GluN2B-containing NMDARs, whereas at P28, only TRHR cells continued to express GluN2B subunits (Figs. 1, 4).
The functional downregulation of GluN2B subunits supports anatomical studies in rodent suggesting that ganglion cell GluN2B expression peaks before P21 (Hartveit et al., 1994; Watanabe et al., 1994; but see Guenther et al., 2004). Further, spontaneous glutamate release activates NMDARs around eye-opening (Bansal et al., 2000; Wong et al., 2000; Blankenship et al., 2009). However, it was not known whether GluN2B subunits incorporate into functional NMDARs that are activated by spontaneous activity. Our data show, by P7, functional GluN2B-containing NMDARs on ganglion cells that could be activated by spontaneous release before eye opening.
NMDARs would apparently contribute to light-evoked responses in vivo. Direction selectivity is present by P11 (Chen et al., 2009), and preferred-direction motion depolarizes the membrane potential by ∼10–20 mV to drive spiking (Chen et al., 2009; Dhande et al., 2013). We found some NMDAR-mediated conductance at rest (∼−65 to −60 mV), which should grow larger with depolarization toward spike threshold (Fig. 1). Thus, it is likely that dsGCs commonly experience light-evoked glutamate release that generates sufficient depolarization to activate NMDARs on their dendrites.
Our data suggest that light stimulation evokes release onto synaptic NMDARs and possibly onto extrasynaptic NMDARs as well. Bright UV flashes evoked a strong inhibitory conductance that coincided with excitation (Fig. 2), and prevented quantification of the excitatory conductance. Glutamate conductance was instead measured under nicotinic/GABAA receptor blockade (Fig. 3), which may have caused or augmented glutamate spillover. Two findings suggested that spillover is not essential to activate NMDARs. First, NMDARs contributed to weak responses to dim or small stimuli (Fig. 3), which likely limited spillover. Second, ifenprodil-insensitive, presumed GluN2A subunit contributions to the light-evoked responses suggested that some NMDARs reside at both ON and OFF bipolar synapses (Zhang and Diamond, 2009). The additional contribution of extrasynaptic NMDARs to light-evoked responses during development deserves further study.
In the retina, bipolar cell→ganglion cell synapse formation peaks between P14 and P28 (Morgan et al., 2008, 2011; Kerschensteiner et al., 2009; Soto et al., 2011). GluN2B subunits could play a role in controlling synapse number during this period, although the duration of this role would apparently vary by cell type (Fig. 4). Further, we found no evidence for differential localization of GluN2B subunits at ON and OFF synapses, as suggested in mature retina (Zhang and Diamond, 2009). Thus, GluN2B subunits may regulate the development of glutamate receptor density, according to models proposed in other systems (Gambrill and Barria, 2011; Gray et al., 2011), but their precise role in retinal synaptic development requires further investigation.
Drd4 and TRHR dsGCs both respond preferentially to the same (posterior) direction of motion, and therefore, appeared to be the same dsGC type. However, their axonal projection patterns, and directional tuning properties differ, suggesting that they are, in fact, distinct types (Rivlin-Etzion et al., 2011). This interpretation is supported by our data showing different GluN2B subunit expression at P28.
Footnotes
- Received October 18, 2013.
- Revision received December 6, 2013.
- Accepted December 28, 2013.
This work was supported by NIH Grants EY014454, F32-EY021063, and Core Grant EY07003 to the University of Michigan, a Midwest Eye Banks research grant, and an unrestricted grant from Research to Prevent Blindness to Yale University.
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. Jonathan B. Demb, 300 George Street, Suite 8100, New Haven, CT 06511. jonathan.demb{at}yale.edu
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