Temporal Correlations between Functional and Molecular Changes in NMDA Receptors and GABA Neurotransmission in the Superior Colliculus

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Volume 17, Number 16, Issue of August 15, 1997 pp. 6264-6276
Copyright ©1997 Society for Neuroscience

Temporal Correlations between Functional and Molecular Changes in NMDA Receptors and GABA Neurotransmission in the Superior Colliculus

Jian Shi, Sandra M. Aamodt, and Martha Constantine-Paton
Department of Biology, Yale University, New Haven, Connecticut 06520

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Activation of the NMDA subtype of glutamate receptor is required for activity-dependent structural plasticity in many areasof the young brain. Previous work has shown that NMDA receptorcurrents decline approximately at the time that developmentalsynaptic plasticity ends, and in situ hybridization studies havesuggested that receptor subunit changes may be occurring duringthe same developmental interval. To establish a system in whichthe relationship between these properties of developing synapsescan be explored, we have combined patch-clamp recordings withmRNA- and protein-level biochemical analyses to study the developmentalregulation of NMDA receptors in the superficial layers of therat superior colliculus. These experiments document an abruptdecrease in the NMDA receptor contribution to synaptic currentsthat occurs before eye opening and is closely associated withchanges in NR1 protein, rapidly rising levels of the NMDA receptorsubunit NR2A, and decreasing levels of NR2B. The functional andmolecular changes also are correlated with the developmental declinein structural plasticity in these layers. In addition, both physiologicaland biochemical methods show evidence of GABA-mediated inhibitionin the superficial collicular layers beginning after eye opening.This may provide an additional heterosynaptic mechanism for controllingexcitation and plasticity in this neuropil by pattern vision.Thus our findings lend support to the idea that high levels ofNMDA receptor function are associated with the potential for structuralrearrangement in CNS neuropil and that the functional downregulationof this molecule results, at least partially, from changes inits subunit composition.
Key words: NMDA receptors; GABA; activity-dependent; superior colliculus; development; downregulation

INTRODUCTION

The NMDA glutamate receptor subtype appears early in development (LoTurco et al., 1991; Durand et al., 1996) and is believedto be critical in structurally refining connections on the basisof activity correlations (Cline et al., 1987; Cline and Constantine-Paton,1989; Bear et al., 1990; Hahm et al., 1991; Rabacchi et al., 1992;Simon et al., 1992; Schlaggar et al., 1993; Lewin et al., 1994;Schnupp et al., 1995). In many brain regions NMDA channel functiondecreases during development as synapses mature and the capacityfor synaptic rearrangement declines (Fox et al., 1991; Carmignotoand Vicini, 1992; Hestrin, 1992). This concordance suggests thathigh NMDA receptor function may be necessary for activity to modifyconnections structurally.

The roles of the NMDA receptor in synaptic development presumably require Ca²⁺ entry through its channel (Mayer and Westbrook, 1987; Cline andTsien, 1991; Fields et al., 1991; Yuste and Katz, 1991). As connectionsrefine, the amount of Ca²⁺ that NMDA receptors admit to the postsynaptic cell probably increases.Because Ca²⁺ can be toxic at high concentrations (Choi, 1988; McDonald andJohnston, 1990), neurons should require mechanisms for controllingthis increase. These findings suggest that the developmental declinein NMDA receptor function may be an activity-driven protectivemechanism that incidentally decreases potential for structuralchange (for review, see Scheetz and Constantine-Paton, 1994).A similar activity-dependent developmental exchange of nicotiniccholinergic receptor subunits that may reduce postsynaptic Ca²⁺ entry with age has been documented at the neuromuscular junction(Schuetze and Vicini, 1984; Martinou and Merlie, 1991; Dan andPoo, 1992).

Molecular studies have described changes in NMDA receptor subunit protein and transcript expression during brain development(Monyer et al., 1994; Sheng et al., 1994; Wang et al., 1995; Zhonget al., 1995; Dunah et al., 1996; Wenzel et al., 1996). Electrophysiologyhas identified different functional properties of NMDA receptorscomposed of different subunits (Monyer et al., 1992, 1994; Williamset al., 1993). In cerebellar granule cells, changes in particularsubunits have been associated with developmental changes in theproperties of the natively expressed receptors (Takahashi et al.,1996), and in neocortex, single-cell PCR has correlated increasedNR2A transcripts with decreased fall time of NMDA currents (Flintet al., 1997). However, no studies have investigated developmentalalterations in both NMDA receptor subunit transcripts and proteinsin pathways and during periods in which functional changes insynapses and structural plasticity also occur.

This study documents the developmental downregulation of NMDA receptor function and a correlated change in receptor subunittranscripts and protein. Focusing on the superficial visual layersof the rat superior colliculus, we show that this functional changein NMDA receptors is unexpectedly abrupt and occurs several daysbefore eye-opening and the onset of pattern vision. The downregulationis associated temporally with the completion of map refinementand loss of plasticity in this neuropil. We also show that increasesin GABAergic inhibition, which could downregulate NMDA receptorfunction heterosynaptically, occur relatively later, several daysafter pattern vision begins.

MATERIALS AND METHODS
Animals. Timed pregnant Sprague Dawley female rats were purchased from Camm Research Institute (Wayne, NJ), and their litterswere used for all experiments in this paper. The day of birthwas counted as postnatal day 0 (P0).

Electrophysiology. For electrophysiology, pups aged P8-P20 were anesthetized with ether and decapitated. A block of tissuecontaining the superior colliculus was dissected rapidly and placedin ice-cold artificial cerebral spinal fluid (ACSF) containing(in mM): 117 NaCl, 3 MgCl₂, 4 KCl, 3 CaCl₂, 1.2 NaHPO₄, 26 NaHCO₃,and 16 glucose, saturated with 95% O₂/5% CO₂ to a final pH of7.4. Parasagittal slices of the superior colliculus were cut ona Vibratome (Pelco, Redding, CA) at 400 µm thickness and thenplaced in a recording chamber under a piece of nylon mesh forstability during recording. The slices were maintained at roomtemperature (22-24°C) and perfused with the same bath solutionat 4 ml/min. Recording began 2 hr later, to allow slices to recoverfrom anesthesia and cutting.

Patch electrodes were pulled from borosilicate glass (World Precision Instruments, Sarasota, FL) on a horizontal pipette puller(Model P-87, Sutter Instrument, Novato, CA) to a tip resistanceof 5-10 M $Omega$ . Electrodes were filled with a cesium-based solutionthat contained (in mM): 122.5 Cs-gluconate, 17.5 CsCl, 10 HEPES(CsOH), 0.2 Na-EGTA, 2 Mg-ATP, 0.3 Na-GTP, and 8 NaCl with 0.2%biocytin at pH 7.3. Amplifier and electrode offsets were zeroedwith the electrode in the bath solution before a patch was obtained.The liquid junction potential between the electrode solution andthe bath was measured in several experiments (Barry and Lynch,1991) and varied between 9 and 12 mV. To compensate for this,we added an estimated offset of 10 mV to all reported voltages.

Whole-cell recordings were made from neurons in the stratum griseum superficiale of the superior colliculus, using the "blind"technique of Blanton and colleagues (1989). All cells studiedin this report had seal resistances of 2-2.5 G $Omega$ . Series resistancewas <21 M $Omega$ (mean ± SD = 17 ± 2 M $Omega$ ), and recordings were terminatedif this changed during an experiment. The response signals wererecorded with an Axoclamp ID patch-clamp amplifier. They werefiltered at 5 kHz and interfaced (CED 1401 Plus, Cambridge ElectronicDesign, Cambridge, England) with a Pentium-based computer (Gateway2000, North Sioux City, SD) that stored the data and providedon-line display of responses and off-line data analysis. CED patchand voltage-clamp software was used to acquire and analyze thedata. Customized routines for averaging postsynaptic currentsusing MATLAB were written by J. Shi.

For analyses of evoked events, bipolar stimulation was applied to the deep stratum griseum superficiale (SGS) and stratumopticum with a pair of insulated tungsten microelectrodes (100K $Omega$ ; World Precision Instruments, Sarasota, FL) glued side by sideto a tip separation of 40 µm. Stimuli were 0.5 msec currents deliveredat low frequency (0.2 Hz). Stimulus intensity was set just abovethe threshold response of the neuron, between 60-100 µA (usually~80 µA). For a collection of responses to be analyzed quantitatively,the cells were held near their resting potentials ( $-$ 60 mV) whilethe slice was bathed in Mg²⁺-free ACSF. At least 13 evoked EPSCs (eEPSCs) were averaged foreach neuron, first in the bath solution and then in the solutioncontaining the NMDA receptor antagonist 2-amino-5-phosphonovalerate(AP5). Data were discarded if evoked responses obtained afterthe washout of AP5 were not within 20% of the initial baselinevalue. Stimulation, particularly in the younger slices, tendedto suppress spontaneous activity for ~5-10 min. Consequently,evoked responses usually were analyzed either in slices from whichno spontaneous data were taken or in slices that remained in goodcondition after analyses of spontaneous events were complete.Less frequently, intervals of spontaneous events were recordedafter studying evoked responses but only after the slice was allowedat least 10 min to recover.

Frequencies of spontaneous EPSCs (sEPSCs) were obtained by randomly selecting intervals of at least 70 sec from the storeddata for each neuron and counting the number of sEPSCs that occurredin that interval. Cells held in Mg²⁺-free ACSF, particularly when exposed to bicuculline, showed occasionalslower and larger currents, which appeared to be summating sEPSCsfrom a barrage of synchronized activity. If individual sEPSCscould be detected clearly in these volleys, they also were counted.However, if individual sEPSCs could not be detected, the entireinterval was eliminated from analysis, and, if necessary, longerrecording intervals were analyzed. The number of events fallingin these intervals was counted to determine the average sEPSCfrequency for that cell. For quantitative analyses of spontaneouscurrent amplitudes and kinetics, averages of the spontaneous currentsfor each neuron were obtained in Mg²⁺-free ACSF with and without AP5. Each average incorporated 30-40continuously recorded events. All single events with relativelyrapid rise times (<12 msec) were used, providing they had amplitudesat least three times the baseline. Recordings from cells thatfailed to maintain stable baselines or that failed to recoverfrom drug treatments with synaptic currents to within 20% of thecontrol recordings were discarded.

The NMDA receptor contribution to all currents was estimated as the difference current obtained by digitally subtracting theaverage obtained in the presence of AP5 from the average for thatsame neuron obtained in the absence of AP5. Kinetics of averagedevents and difference currents were examined with a double- orsingle-exponential least-squares fit. Curves fit by only a singleexponential were rare: for most neurons all averages with andwithout AP5 and the difference current could be fit with doubleexponentials, using the criterion that the amplitude of the secondcomponent was $>=$ 2% of the total amplitude. The contribution ofthe NMDA receptor current could be demonstrated by the additionof AP5 as the expected decrease in decay times and smaller relativeamplitude of the slow component (see Table 1). However, to obtaina single standard measure of decay for the purposes of comparisonacross all averages and all neurons, we measured the fall time $tau$ of total current averages and difference currents with the single-exponential $tau$ estimator as the time from peak to 0.37 peak amplitude.

Table 1. Current averages for eEPSCs

Neuron Curve fitting $tau$ ¹ (msec) R.A. (100%) $tau$ ² (msec) R.A. (100%)

P8 0 Mg 74.3 0.506 447.4 0.494

AP5 12.4 0.642 286.1 0.358

Diff. C. 95.6 0.513 516.6 0.487

P16 0 Mg 45.9 0.531 233.1 0.469

AP5 15.9 0.780 241.7 0.220

Diff. C 93.5 0.593 255.4 0.407

Current averages for eEPSCs are best fit by double exponentials, using the criterion that the amplitude of the second componentwas $>=$ 2% of the total amplitude. Averages are for the recordingsshown in Figure 1a. R.A., Relative amplitude; Diff. C., differencecurrent, eNMDA (see Materials and Methods).

Drug solutions were bath-applied, as indicated below, at the following concentrations: 1 µM GABA_A receptor antagonist bicucullinemethiodide (Sigma, St. Louis, MO), 50 µM NMDA receptor antagonistAP5 [Research Biochemicals (RBI), Natick, MA], and 10 µM non-NMDAglutamate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione(CNQX) (RBI). A complete solution change was accomplished approximatelyonce per minute. After all drug applications or changes in Mg²⁺ concentration, we allowed at least 20-30 min of washout beforenew recordings were made. However, with CNQX, even after 45 minof washout, the recording frequently had not returned to baselineconditions.

The location and morphology of recorded cells were evaluated by intracellular staining with biocytin in 16 experiments fromslices spanning the P8-P20 interval. In those experiments sliceswere fixed in 4% formalin overnight, cut at 90 µm on dry ice witha sliding microtome, post-fixed in 4% formalin, and stained withTexas Red-conjugated streptavidin (Jackson ImmunoResearch, WestGrove, PA). All cells (n = 25) were localized within the superficialcollicular layers. They represented at least four morphologicalclasses (narrow- and wide-field vertical cells, stellate cells,and piriform cells) identified in the rat SGS (Langer and Lund,1974). All cells had elaborated dendritic trees, even in the youngestslices (P8) examined. A more complete analysis of these cellswill appear as part of a subsequent report.

Molecular analyses. Pups between P0 and P27 were used in these studies. Adult tissue was obtained from the mothers. For allbiochemical experiments rats were killed by exposure to carbondioxide, followed by cervical dislocation, and the superficiallayers of the superior colliculus were dissected out rapidly.Tissue used for RNA isolation was frozen immediately in liquidnitrogen and stored at $-$ 80°C until needed. Tissue subsequentlywas homogenized directly from the freezer in 25 vol of buffer(4 M guanidinium, 17 mM N-lauroylsarcosine, 100 mM Tris, 5 mMNa citrate, and 100 mM 2-mercaptoethanol). An equal volume ofacid phenol, pH 4.5, and one-fifth vol of chloroform:isoamylalcohol(24:1) were added and mixed thoroughly. The mixture was left onice for 20 min and then centrifuged for 20 min at 16,000 × g at4°C. The aqueous layer was removed and ethanol-precipitated, washedwith 75% ethanol, dried, and redissolved in 400 µl of TE (10 mMTris and 1 mM EDTA) and 100 µl of 3 M Na-acetate. This solutionwas extracted with acid phenol a second time and ethanol-precipitatedas before. The RNA was redissolved in TE and frozen in 10 µg aliquotsat $-$ 80°C.

A ribonuclease protection assay (RPA) was used to measure RNA levels of three NMDA receptor subunits (NR1, NR2A, and NR2B)in a single sample, along with a probe for 28S transfer RNA (115base pairs; Ambion, Austin, TX) as a loading control. The NR1probe protects a 180 base pair fragment between positions 421and 600 (Moriyoshi et al., 1991). The NR2A probe protects a 369base pair fragment from 2993 to 3362 (Ishii et al., 1993). TheNR2B probe protects a 262 base pair fragment from 4019 to 4280(Monyer et al., 1992). All probes were synthesized by in vitrotranscription with [³²P]uridine 5 $'$ -triphosphate. The specific activity of the NR1 probewas 16-fold lower than that of the NR2 subunit probes to equalizeexposure times. The protection assay was run with the RPA II kit(Ambion), using 10 µg of total RNA, 20,000 cpm of each NMDA receptorsubunit probe, 1000 cpm of 28S probe, and 1 µg of cold 28S probe.All probes were determined to be in at least fourfold molar excessover the sample RNA. In each run, separate control lanes for eachprobe with 10 µg of yeast RNA gave no signal. Gels were driedand exposed to x-ray film at $-$ 80°C for 4-8 d. Each film containedlanes for each age, and densitometric values from each film werenormalized to the value for the adult lane to facilitate comparisonacross films with different exposures.

Immunoblotting. For protein extraction, tissue was homogenized immediately in 20 vol of buffer (10 mM phosphate buffer, pH7.0, 5 mM EGTA, 5 mM EDTA, 1 mM DTT, and COMPLETE protease inhibitor;Boehringer Mannheim, Indianapolis, IN) and then either fractionatedor frozen in liquid nitrogen and stored at $-$ 80°C until needed.Homogenates were fractionated by using a modification of the Yipand Kelly (1989) procedure. Rapidly thawed homogenate was centrifugedfor 10 min at 4°C at 16,000 × g, and the supernatant (crude solublefraction) was collected and placed on ice. The pellet was resuspendedin one-fourth vol of 2 mM HEPES, pH 7.2, and centrifuged for 10min at 4°C at 11,000 × g. The supernatant was discarded, and thepellet was resuspended in 0.5 mM HEPES, pH 7.3, containing 0.32M sucrose and centrifuged for 8 min at 450 × g. The supernatantfrom this spin (crude particulate fraction) and the crude solublefraction were placed in Laemmli buffer, heated to 90°C for 5 min,and then frozen in aliquots at $-$ 80°C.

Immunoblotting of proteins was performed with primary antibodies to NMDA receptor subunits (NR1, 0.5 µg/ml; NR2A 1:400; NR2B1:600; Chemicon, Temecula, CA), the 65 kDa isoform of glutamicacid decarboxylase (GAD₆₅, 1:2000; Boehringer Mannheim), and thetwo GABA transporters found exclusively in the brain (GAT-1, 1:200;GAT-3, 1:1000; Chemicon) (Ikegaki et al., 1994). Two additionalantibodies to NR1 [Tingley et al. (1993); combined N- and C-terminalantibodies @ 1:400, courtesy of Richard Huganir (Johns HopkinsMedical School, Howard Hughes Medical Institute, Baltimore, MD);Siegel et al. (1994); 54.1 @ 1:4000, courtesy of Reinhardt Jahn(Yale University School of Medicine, Howard Hughes Medical Institute,New Haven, CT)] were used to substantiate the original findingswith the Chemicon reagent. Proteins were run on 6 or 8% polyacrylamideminigels at 5 or 10 µg per lane and then transferred to nitrocelluloseby electroblotting (Idea Scientific, Minneapolis, MN). Total proteinwas visualized with Ponceau stain. Blots were blocked with 1%dried milk in 0.1% Tween/0.1 M PBS (TPBS) for 30 min and thenincubated in primary antibody in TPBS for 1 hr at room temperature.After four 10 min rinses in milk-TPBS, blots were incubated insecondary antibody (horseradish peroxidase-conjugated goat anti-rabbit,1:12,000 or goat anti-mouse, 1:2000 in milk-TPBS). Blots werewashed six times for 5 min in TPBS, reacted with chemiluminescentsubstrate (Pierce, Rockford, IL), and exposed to film (Kodak,Rochester, NY).

Band density on the autoradiographs was measured by densitometry with National Institutes of Health Image 1.57 and its gel-plottingmacros. Pixel intensities were calibrated to optical densitieswith a density wedge. Measurements were confirmed to be withinthe linear range of the film by analysis of a dilution seriesprocessed with the samples. All data are reported as mean ± SEof band optical densities.

RESULTS

NMDA receptor changes
Electrophysiology All cells analyzed for this study had resting potentials between $-$ 60 and $-$ 50 mV and input resistances between 331 and 904M $Omega$ (mean = 617 ± 208 M $Omega$ ). There was no consistent change in eitherof these properties across the P8-P20 age range examined. In initialstudies EPSCs were examined after a wide range of stimulus intensitiesand frequencies. In most young neurons (younger than ~P14) high-stimulationintensities produced a response that clearly was not limited tomonosynaptic inputs and that decremented even after interstimulusintervals of several minutes. Consequently, most analyses andall quantification used low-frequency stimulation at the lowestintensity that evoked a reproducible response. This focus on minimalexcitatory potentials evoked at low frequencies (minimal eEPSCs)reduced but did not always eliminate a slight amplitude decrementwith time.

In accord with previous findings (Hestrin, 1992), EPSCs recorded in response to stimulation of the stratum opticum appearedto be glutamatergic: CNQX significantly reduced peak amplitudeand rise time of the eEPSC but had relatively little effect ondecay, whereas AP5 applied to neurons at relatively polarizedpotentials (20-40 mV) consistently decreased fall times. The reversalpotentials for these currents were ~0 mV.

In initial quantitative studies neurons were clamped at 40 mV, and CNQX was applied to study the remaining slow componentattributable to NMDA receptor activation. In many cases, particularlyin younger slices studied at these potentials, it was impossibleto maintain responses within 20% of initial amplitude during prolongedrecording. Consequently, to obtain a relatively large, minimallybiased sampling of the levels of activity and of the NMDA receptorcurrents present under normal physiological conditions in thisneuropil, we adopted an alternative approach. After levels ofspontaneous activity were assayed in normal ACSF, most data weretaken near resting potential ( $-$ 60 mV) in 0 Mg²⁺ ACSF. Under these conditions, as expected, all cells were sensitiveto both CNQX and AP5 at all holding potentials, and combined applicationof CNQX and AP5 abolished the events.

Effects of AP5 application on these minimal eEPSCs were studied quantitatively in 35 neurons taken from slices spanning theP8-P20 interval. AP5 reduced the peak amplitudes of the averagesby varied amounts and produced prominent decrements in the decaytime, particularly evident in neurons from younger slices. Examplesof the minimal eEPSC averages and difference (or NMDA receptor)currents (average eEPSC_{w/o AP5} $-$ average eEPSC_{w AP5} = eNMDA) obtainedin these recordings are shown in Figure 1a. Table 1 shows therelative amplitudes and $tau$ values for the same average currentsobtained from the double-exponential least-squares fit. However,for the comparisons that follow (see Materials and Methods), risetime (R.T.) for the total and NMDA currents was measured as thetime from baseline to 90% peak amplitude, and decay ( $tau$ ) was estimatedas time to 0.37 of peak amplitude. Peak amplitudes of total currentaverages varied between $-$ 456 and $-$ 28 pA (mean = $-$ 112 ± 94 pA)but showed no consistent change with age. Peak amplitudes of thedifference currents representing the eNMDA current varied from $-$ 166 pA to $-$ 12 pA and also revealed no consistent change withage. In contrast, $tau$ for eNMDA showed a pronounced drop over thisinterval (Fig. 1b). Rise times, which should be more sensitivethan the slower decays to changes in capacitance (Spruston etal., 1993) do not show this effect, indicating that the decaychange is not an artifact of alterations in dendritic filteringwith age.
Fig. 1. Analyses of evoked currents. a, Averaged evoked currents and difference currents from a P8 and a P16 neuron. Currents wereevoked by minimal stimulation of the stratum opticum with theslice maintained in 0 Mg²⁺ ACSF and the cells held at $-$ 60 mV. Each average incorporatesat least 13 evoked currents. The difference current (Diff. C)was obtained by digitally subtracting the current average in 0Mg²⁺ ACSF with AP5 from the current average in 0 Mg²⁺ ACSF. It represents the current attributable to NMDA receptoractivation or eNMDA. R.T., Rise time as measured from the baselineto 90% of peak amplitude. $tau$ values (Tau) are for the single-exponentialleast-squares fit (see Materials and Methods and Table 1). b,Scatterplot of $tau$ ( $bullet$ ) and rise times ( $open circle$ ) of eNMDA obtained as describedin a and in Materials and Methods. The regression line for risetime against age is shown, but the correlation coefficient forthis line is low (r² = 0.15); n = 34 neurons.
[View Larger Version of this Image (13K GIF file)]

Evoked responses provide information about changes in synapses derived mainly from the collicular inputs (optic tract andcortex; Langer and Lund, 1974), but they do not sample other synapsesin the neuropil effectively. In addition, inferences from thekinetics of these responses are complicated because of possiblecontributions from polysynaptic inputs and because, particularlyin poorly myelinated young axons, a volley in the afferent pathwaydoes not necessarily arrive at all synapses synchronously. Consequently,to obtain a more representative estimate of changes in neurotransmitterfunction at synapses in the superficial layers of the superiorcolliculus, we focused the rest of this analysis on the fast sEPSCsthat are numerous and of relatively large amplitude in the youngcollicular neurons. Based on the following criteria, these eventsappear to be glutamatergic. In pilot studies CNQX applicationto all cells held at 20 or 40 mV reduced the peak amplitude butnot the duration of these events. In all cells studied, thesecurrents were decreased in duration by AP5. Their frequency wasnot reduced on application of bicuculline to the ACSF (see Fig.8). As with the eEPSC analysis, all recordings analyzed quantitativelywere from neurons clamped at $-$ 60 mV.
Fig. 8. Spontaneous excitatory current (sEPSC) frequencies plotted against the age of the slice. a, sEPSC frequencies recorded in2 mM Mg²⁺ with neurons clamped at $-$ 60 mV. b, The effect of bicucullinemethiodide on sEPSC frequency in cells held at $-$ 60 mV in 0 Mg²⁺ ACSF.
[View Larger Version of this Image (14K GIF file)]

The NMDA receptor contribution to the sEPSCs was measured quantitatively by maintaining slices in Mg²⁺-free ACSF and applying the averaging procedure (described inMaterials and Methods) to determine average sEPSC current withand without AP5 and average sNMDA (sEPSC_{w/o AP5} $-$ average sEPSC_w
AP5= sNMDA). In P10 or younger colliculi, the sEPSCs recorded inthe presence of AP5 showed a marked reduction in duration, ascompared with the sEPSCs of the same neurons in the absence ofAP5. As shown by the representative traces in Figure 2, this qualitativelyobvious difference in spontaneous events recorded in the presenceand absence of AP5 was absent in neurons from older slices, indicatinga decreased contribution of NMDA receptors to these currents withage.
Fig. 2. Examples of sEPSCs recorded in 0 Mg²⁺ with and without AP5 from a P8 neuron and a P15 neuron. AP5 application has a more pronouncedeffect on the fall time of the events in the younger slice.
[View Larger Version of this Image (21K GIF file)]

The NMDA receptor component of sEPSCs was studied in 75 neurons. Figure 3 illustrates representative average sEPSCs recordedfrom four neurons in slices from P8-P20 pups. As in the eEPSCanalysis, for purposes of comparison the fall time $tau$ is estimatedas the time to 0.37 of peak amplitude. For the sEPSC currents,however, current onset was measured as the time from baselineto current peak (T_p).
Fig. 3. Averaged spontaneous currents and difference currents (sNMDA) from P8, P12, P19, and P20 neurons. Each average incorporates30-60 spontaneous events selected according to strict criteriaand averaged by custom-written software that aligned onsets (seeMaterials and Methods). Difference currents (Diff. C.) were obtainedas in Figure 1. T_p, Time to peak, measured as the timefrom baseline to the peak current. $tau$ values (Tau) are for thesingle-exponential least-squares fit.
[View Larger Version of this Image (28K GIF file)]

The peak amplitudes of the sNMDA current did not change significantly with age (Fig. 4a; range from $-$ 69 to $-$ 2 pA; mean = 15± 13 pA), although there was a tendency to obtain large peak amplitudesfor the average sEPSC_w/oAP5 (Fig. 4b; range from $-$ 113 to $-$ 8 pA;mean = $-$ 41 ± 26 pA) in older slices (Fig. 4c).
Fig. 4. Peak amplitude of sNMDA (sEPSCs_{w/o AP5} $-$ sEPSCs_{w AP5}) does not change across the P8-P12 interval. The peak amplitude of thetotal current shows a slight increase with age. a, Peak amplitudeof average sNMDA against the age of the slice. b, Peak amplitudeof total average current (total sEPSC; sEPSCs_{w/o AP5}) againstthe age of the slice. c, The ratio of sNMDA peak amplitude relativeto total sEPSC plotted against the age of the slice. The regressionline for sNMDA/sEPSCs_{w/o AP5} against age is shown. The correlationis poor (r² = 0.12); n = 75 neurons.
[View Larger Version of this Image (13K GIF file)]

Developmental changes in the kinetics of the sNMDA current are shown in the scatterplot of Figure 5a. In contrast to the relativelyconstant amplitude of sNMDA over the P8-P20 interval, the decayof sNMDA drops abruptly between P10 and P11. Figure 5b shows thischange plotted as the mean and SD of $tau$ sNMDA in neurons recordedfrom slices of the same age. Figure 5c shows the mean and SD ofthe time to peak for sNMDA of the same averages. Values of $tau$ fromneurons between P8 and P10 and from neurons between P11 and P20were found to be significantly different (p < 0.01, Student'st test for different sizes of populations). No significant differencewas found for the times to peak in the same two populations. Thus,as in the eEPSC analyses, there is no evidence that the pronounceddifferences in decay are attributable to changes in the dendriticfiltering properties of the neurons.
Fig. 5. Analyses of sNMDA kinetics. a, Scatterplot of $tau$ and time to peak of sNMDA. The regression line for time to peak versus ageis shown, but the correlation coefficient is low (r² = 0.10). b, The mean and SD of $tau$ sNMDA for data shown in a whenneurons are grouped by the postnatal day of recording. Fall timesof sNMDA drop significantly at P11. The neurons in the P8-P10group have $tau$ values that are significantly different from theneurons in the P11-P20 group at the p < 0.01 level. c, Mean andSD of the time to peak of the same neurons. There is no differencein time to peak between the P8-P10 group and the P11-P20 groupof neurons; n = 75 neurons.
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NMDA receptor transcript and protein analysis
RNase protection assays were used to assay quantitatively the changes in the levels of NMDA receptor subunit transcripts NR1,NR2B, and NR2A. Quantitative Western blotting of protein fromcolliculi of the same age that used antibodies specific for NR1,NR2B, and NR2A were used to measure levels of the correspondingproteins. Time points were chosen for ease of comparison withprevious anatomical (Simon et al., 1992), molecular (Hofer etal., 1994), and biochemical (Scheetz et al., 1996) results inthis same neuropil. To assure accurate comparisons with the previousstudies and the current physiological assays of synaptic function,we took great care to dissect out only the superficial visuallayers of the superior colliculus for these analyses.

The time course for NR1 protein levels differed from the levels of expression of the corresponding transcript. The NR1 mRNAis low at P0 and P6, increases from P6 to P19, and then declinesslightly into adulthood (Fig. 6a,b). This time course is similarto that seen previously with quantitative Northern blotting (Hoferet al., 1994). Nevertheless, NR1 protein levels are highest inthe first postnatal week and decline thereafter to a low adultlevel (Fig. 6e,f). This discrepancy is not attributable to a peculiarityof the antibody used in the Western blot analysis or simply tochanging splice variants (Zukin and Bennett, 1995); multiple anti-NR1antibodies recognizing different epitopes showed a decrease inNR1 protein during the interval when the transcript analysis wouldpredict a rise in protein levels (Fig. 7).
Fig. 6. Time course of NMDA receptor subunit mRNA and protein development in the superficial layers of the superior colliculus. Theleft side of the figure shows a typical RNase protection assaygel (a) and averaged optical density measurements for the NMDAreceptor subunit mRNAs NR1 (b), NR2A (c), and NR2B (d). Each transcripthas been normalized to the adult level to facilitate comparisonbetween films (n = 5). The right side of the figure shows a typicalimmunoblotting protein time course (e) and averaged optical densitymeasurements for the NMDA receptor subunit proteins NR1 (f), NR2A(g), and NR2B (h) (n = 8 blots for each). In e, the Western blotsfor NR1 and NR2A were run on the same blot after it was cut betweenthe two bands, suggesting that the developmental changes are notan artifact of protein loading. Note that the absolute opticaldensities for different subunits are not comparable because ofthe different affinities of the antibodies and film exposure times.
[View Larger Version of this Image (37K GIF file)]

Fig. 7. Immunoblotting time course with three different antibodies against NR1 protein: Chemicon (top; n = 8), Jahn (middle; n = 8),and Huganir (bottom, n = 2). The decline of protein levels withage is not an artifact associated with a particular epitope. Inall cases the adult protein levels are significantly lower thanthan protein levels in the first week of life.
[View Larger Version of this Image (15K GIF file)]

Protein and transcript levels were matched more closely for the NR2 subunits examined. The NR2A subunit showed developmentalchanges that were more abrupt than those seen for either NR1 orNR2B, particularly at the protein level (Fig. 6e,g). Transcriptlevels for NR2A were barely discernible at P6 and P0, rose almostfourfold between P6 and P12, and continued to rise steeply toP19 and then showed a second large increase between P27 and adulthood.Protein levels followed the early rises quite closely but showeda slight decrease between P27 and the adult (Fig. 6e,g). The NR2Bsubunit mRNA (Fig. 6a,d) and protein (Fig. 6e,h) both declinedwith age, with a similar time course. Absolute levels of NR1 transcriptat their peak (P19) were 35 times higher than peak NR2B subunittranscript levels at their peak (P0), and absolute levels of transcriptfor NR2A at its peak (adulthood) were approximately fourfold lowerthan peak levels of NR2B. The considerably lower level of NR2Acould explain the relatively larger SE in the NR2A mRNA measurements.

In situ hybridization studies indicate that the most recently cloned NR2 subunit, NR2D, also is expressed in the superiorcolliculus. Pilot studies with a probe for NR2D indicated thatthis subunit was present at levels at least an order of magnitudelower than the other two NR2 subunits in the superficial collicularlayers, even from P6-P12 when previous studies suggest it mightbe maximal (Wenzel et al., 1996). This made accurate quantificationof its transcript difficult. Protein levels for NR2D could notbe quantified because an appropriate antibody was not yet available.

Thus our data indicate that the NMDA receptors in the visual layers of the superior colliculus are composed predominantlyof NR1 and NR2B subunits during the first postnatal week and ofNR1 and NR2A subunits after P19. Most significantly, however,between P8 and P12 when the most dramatic functional changes inNMDA receptor current are taking place, the molecular compositionof the receptor is changing also.

Development of GABAergic neurotransmission
Analysis of the frequency of sEPSCs in Mg²⁺-containing ACSF across the P8-P12 interval revealed a drop in frequency at P18 (Fig.8a). This observation suggested that inhibition became significantlymore pronounced in this neuropil in the third postnatal week.To explore this possibility, we added bicuculline methiodide afterthe last washout of AP5 for a final interval of spontaneous recordingin 0 Mg²⁺. Under these conditions neurons from older slices showed a markedincrease in the frequency of spontaneous events, whereas the frequencyof single spontaneous events in younger neurons was unchanged.These data are plotted in Figure 8b as the ratio of the frequencyof spontaneous events with bicuculline to the frequency in thesame neuron without bicuculline. The data suggest an abrupt increasein bicuculline-sensitive inhibition at P18.

Inhibition can play a powerful role in clamping dendritic membrane at potentials that will maintain the Mg²⁺ block on the NMDA receptor channel. Consequently, to better comprehendthe regulation of this receptor, we believed it was importantto document the time course of the changes in the GABA systemat the same time points used to assay levels of NMDA receptorsubunit expression. We concentrated these analyses on indicescharacteristic of GABA neurotransmission by using quantitativeWestern blotting for the 65 kDa isoform of GAD, which is the formfound in synapses (Kaufman et al., 1991), and for two transporterproteins (GAT-1 and GAT-3) responsible for the high-affinity uptakeof GABA.

As shown in Figure 9, none of the GABAergic proteins examined could be detected at P0. GAD was seen first at P12 and increaseduntil P27 (Fig. 9a). Of the GABA transporter proteins, GAT-1 appearedat P6, increased rapidly at P19, and then declined slightly intoadulthood (Fig. 9b), whereas GAT-3 appeared at P19 and reachedadult levels at P27 (Fig. 9c).
Fig. 9. Immunoblotting time course of protein isolated from the superficial layers of the superior colliculus for proteins involvedin GABAergic neurotransmission: the synthetic enzyme GAD (top;n = 11) and the GABA transporters GAT-1 (middle; n = 6) and GAT-3(bottom; n = 6).
[View Larger Version of this Image (13K GIF file)]

DISCUSSION

Functional and molecular synaptic changes
This study documents a pronounced developmental downregulation of the NMDA receptor contribution to synaptic currents in thesuperficial layers of the superior colliculus because of an abruptdecrease in the fall time of NMDA receptor currents (Figs. 2,5). These changes, occurring between P10 and P11, coincide withretinocollicular projection refinement, which is complete by P11-P12(Simon and O'Leary, 1992) and requires functional NMDA receptors(Simon et al., 1992).

Pronounced changes in NMDA receptor subunit expression also occur approximately at this time. Consistent with our previousNorthern analysis (Hofer et al., 1994), the current protectionanalysis documents a rapid rise in NR1 subunit transcripts betweenP6 and P12. NR1 is the subunit common to all NMDA receptors, sothis increase could reflect requirements for more NMDA receptors,as might be expected during intense neuropil expansion (Wartonand McCart, 1989). Nevertheless, NR1 protein levels begin to decreaseduring the same interval, suggesting that more than simple receptoraddition is occurring. NR1 translation rates may slow at thistime. However, considering that the effects of slowing translationprobably would be masked by rising transcript levels, a more likelypossibility is that NMDA receptors are more stable in the fetusand neonate than during map refinement in the juvenile animal.Elimination of receptors, both extrajunctional (Burden, 1977)and junctional (Balice-Gordon et al., 1993), occurs in muscleduring synaptic competition. Although superficial superior colliculussynapse density does not show a net decrease until the secondpostnatal month (Warton and McCart, 1989), NR1 protein decreasesduring map refinement could be comparable to cholinergic receptordecreases during synapse elimination at the neuromuscular junction,specifically removal of many receptors at nonsynaptic sites whilereceptors are inserted at effective synapses.

Simultaneous with NR1 protein changes is a shift in the prominence of NR2A subunits relative to NR2B subunits. Native NMDAreceptors require both NR1 and NR2 subunits to produce the largeconductances characteristically measured in neurons (Kutsuwadaet al., 1992; Meguro et al., 1992; Sheng et al., 1994; Luo etal., 1997). Transfection of heterologous cells demonstrates thatreceptors composed of NR1 and NR2B subunits have longer open timesthan NR1/NR2A receptors (Monyer et al., 1992, 1994). Recently,single-cell PCR in somatosensory cortex has indicated that decreasesin receptor fall time are associated tightly with increases inmRNA for NR2A (Flint et al., 1997). Our study provides evidencefor a similar correlation between NR2A transcript increase andfall time decrease in the superior colliculus. We add the findingsthat NMDA receptor proteins also are changing significantly atthis time and confirm, in a large population of cells, that thefunctional and molecular changes occur in close correlation. However,there are some caveats to the idea that the NR2A subunit is solelyresponsible for observed functional changes. Our earlier Northernblot analysis (Hofer et al., 1994) showed that the expressionof NR1 splice variants shifts at this time toward a predominanceof shorter species lacking C-terminal sequences that, in heteromericNR1/NR2 receptors, facilitate current potentiation by PKC activators(Zukin and Bennett, 1995). Also, we do not yet know what is happeningto NR2D. Although likely to be present at lower levels than eitherNR2A or NR2B, the NR2D subunit has its greatest expression inperinatal tissue and greatly increases channel open time whenexpressed with NR1 in heterologous cells (Monyer et al., 1994).Moreover, NR2D protein is higher in the superior colliculus thanin cortex, and its levels have been reported to peak at P10 andthen decline (Dunah et al., 1996).

The vast majority of GABAergic inhibition in the superficial superior colliculus is intrinsic (Mize, 1992), and the presentanalyses suggest that inhibition might develop relatively late.Earlier EM studies reported presumed inhibitory synapses withinrat retinocollicular neuropil at the end of the first postnatalweek (Lund and Lund, 1972). However, our immunoblotting analysisof GAD and GAT protein levels supports a later onset. GAD₆₅ firstbecomes reliably detectable in these superficial collicular layersat P12. It shows a pronounced increase by P19, as do both GABAtransporters. In this neuropil sEPSC rates are high from P8 toP17. At P18, 4 d after eye opening and approximately at the timewhen the optics clear, these rates drop to nearly one-half oftheir previous values. The timing of this change corresponds tothat when applied bicuculline first increases the sEPSC rate.The timing of this change suggests that inhibition onset may betriggered by high levels of activity from pattern vision and isconsistent with the finding that GAD₆₅, which predominates insynaptic terminals, has been shown to be modulated by activity(Kaufman et al., 1991).

Several paradoxical observations are present in the physiological data on inhibition, however. For example, our recordingsreveal little evidence of Cl-mediated IPSCs in these cells. E_Cl in these recordings is approximately $-$ 40 mV, so we initially assumed that depolarizing IPSCs were lostin the noise in cells held at $-$ 60 mV. However, traces recordedat more positive holding potentials also failed to reveal a distinctpopulation of spontaneous currents reversing at negative potentials.In the one previous study of inhibition in the early rat colliculus,Warton and colleagues (1990), using sharp electrodes, reportedthat inhibition became more pronounced after eye opening. Nevertheless,between P9 and P12, 16 of 21 neurons responded to intracollicularstimulation with Cl-dependent IPSCs in that study, indicating that such currentsexist even in young colliculi. Perhaps the inhibitory interactionswe detected as increases in sEPSC frequency in response to bicucullineoccur predominantly on neurons we did not sample or exceptionallylocally in the serial dendrodendritic synapses characteristicof the superficial superior colliculus (Lund and Lund, 1972; Mizeet al., 1991). In the latter location they may shunt excitatorycurrent without producing discernible current at the soma. Clearly,additional work focused specifically on inhibition is necessaryto resolve these ambiguities.

The superficial layers of the developing rat superior colliculus were examined in one of the first studies to evaluate NMDAreceptor downregulation in development and to suggest that changingsubunit composition of the receptor might be involved (Hestrin,1992). Isolating NMDA currents in evoked responses with positiveholding potentials and bath-applied CNQX, Hestrin documented slowlydeclining NMDA receptor current decay occurring between P11 andP33. Glutamate and CNQX applied to patches excised from a subsetof collicular neurons showed that the NMDA receptor decay declinedbecause of changing open time of the NMDA channel itself. Ourinvestigation confirms and extends these results, because ourevoked recordings also suggest this slow change in NMDA receptorcurrent decay (see Fig. 1b) in addition to the abrupt declinebetween P10 and P11. The two studies differ because Hestrin didnot sample spontaneous events extensively and, perhaps more significantly,did not perform many recordings early in the second postnatalweek when the NMDA receptor contribution abruptly decreases.

NMDA receptor-mediated activity and structural plasticity
In mammals, structural plasticity is studied more in the geniculocortical pathway than in the retinocollicular pathway. Plasticityin the afferent layers of mammalian visual cortex has been correlatedwith the normal developmental downregulation of NMDA receptorfunction in those layers (Fox et al., 1989). Dark rearing (Foxet al., 1991; Carmignoto and Vicini, 1992) and tetrodotoxin (TTX)application to cortex (Carmignoto and Vicini, 1992) delay thedecrease in receptor function. In addition, Carmignoto and Vicini(1992) suggested that developmental changes in NMDA receptor channelgating properties in rat layer IV could account for the changesin synaptic receptor function. However, the complexity of corticalcircuitry and differences in developmental maturity across layershave caused difficulty in identifying and isolating the specifictarget cell populations that demonstrate functional changes tobe able to study them quantitatively at the molecular level. Inthe superficial layers of the mammalian superior colliculus, integratedfunctional and molecular studies are facilitated because the cellsare developmentally more homogeneous and they are separated physicallyfrom the neurons in deeper layers.

Structural plasticity in the superior colliculus appears to terminate during the period when we have documented significantchanges in NMDA receptors. In rats, retinocollicular axons canfill in an induced scotoma until P10 (Lund and Lund, 1976), andcorticocollicular inputs can fill retinal scotomas until P15 (Mustariand Lund, 1976). Spontaneous activity and NMDA receptor functionhave been implicated in collicular synaptogenesis before patternvision by evidence that TTX disrupts the elimination of the ipsilateralretinocollicular projection (Thompson and Holt, 1989), that earlytemporally patterned spontaneous activity occurs in the fetusof many species (Maffei and Galli-Resta, 1990; Meister, 1996),and that both retinocollicular map refinement (Simon et al., 1992)and several indices of normal synaptic differentiation (Hoferet al., 1994; Scheetz et al., 1996) in the rat can be stalledby chronic NMDA receptor antagonism begun at P0. The differentiationof inhibitory transmission after eye opening that we have observedmay represent an additional mechanism for controlling both excitationand the potential for structural change in this neuropil.

FOOTNOTES

Received March 26, 1997; revised May 16, 1997; accepted May 23, 1997.

This work was supported by National Institutes of Health Grants NS32290 to M.C.P. and NS09569 to S.M.A. from the NationalInstitute of Neurological Disorders and Stroke and the NationalInstitute of Mental Health. We thank Dr. Nigel Daw for his criticalreading of this manuscript and Dr. Richard Huganir for his generousdonation of antibodies against the NR1 subunit.

Correspondence should be addressed to Dr. Martha Constantine-Paton, Department of Biology, P.O. Box 108203, Yale University,New Haven, CT 06520.

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M. T. Colonnese, J.-P. Zhao, and M. Constantine-Paton
NMDA Receptor Currents Suppress Synapse Formation on Sprouting Axons In Vivo
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M. Townsend, Y. Liu, and M. Constantine-Paton
Retina-Driven Dephosphorylation of the NR2A Subunit Correlates with Faster NMDA Receptor Kinetics at Developing Retinocollicular Synapses
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S. G. Cull-Candy and D. N. Leszkiewicz
Role of Distinct NMDA Receptor Subtypes at Central Synapses
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Y.-X. Tao, G. Rumbaugh, G.-D. Wang, R. S. Petralia, C. Zhao, F. W. Kauer, F. Tao, M. Zhuo, R. J. Wenthold, S. N. Raja, et al.
Impaired NMDA Receptor-Mediated Postsynaptic Function and Blunted NMDA Receptor-Dependent Persistent Pain in Mice Lacking Postsynaptic Density-93 Protein
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A. Yoshii, M. H. Sheng, and M. Constantine-Paton
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M. Townsend, A. Yoshii, M. Mishina, and M. Constantine-Paton
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M. T. Colonnese, J. Shi, and M. Constantine-Paton
Chronic NMDA Receptor Blockade From Birth Delays the Maturation of NMDA Currents, but Does Not Affect AMPA/Kainate Currents
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C. Henneberger, R. Juttner, T. Rothe, and R. Grantyn
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J. Shi, S. M. Aamodt, M. Townsend, and M. Constantine-Paton
Developmental Depression of Glutamate Neurotransmission by Chronic Low-Level Activation of NMDA Receptors
J. Neurosci., August 15, 2001; 21(16): 6233 - 6244.
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M. T. Colonnese and M. Constantine-Paton
Chronic NMDA Receptor Blockade from Birth Increases the Sprouting Capacity of Ipsilateral Retinocollicular Axons without Disrupting Their Early Segregation
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Fine-Tuning an Auditory Synapse for Speed and Fidelity: Developmental Changes in Presynaptic Waveform, EPSC Kinetics, and Synaptic Plasticity
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S. M. Aamodt, J. Shi, M. T. Colonnese, W. Veras, and M. Constantine-Paton
Chronic NMDA Exposure Accelerates Development of GABAergic Inhibition in the Superior Colliculus
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Two-Stage, Input-Specific Synaptic Maturation in a Nucleus Essential for Vocal Production in the Zebra Finch
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F.-S. Lo and R. R. Mize
Retinal Input Induces Three Firing Patterns in Neurons of the Superficial Superior Colliculus of Neonatal Rats
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C. D. Hohnke and M. Sur
Stable Properties of Spontaneous EPSCs and Miniature Retinal EPSCs during the Development of ON/OFF Sublamination in the Ferret Lateral Geniculate Nucleus
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A. J. King, J. W.�H. Schnupp, and I. D. Thompson
Signals from the Superficial Layers of the Superior Colliculus Enable the Development of the Auditory Space Map in the Deeper Layers
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M. C Bellingham, R. Lim, and B. Walmsley
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S. Strack and R. J. Colbran
Autophosphorylation-dependent Targeting of Calcium/ Calmodulin-dependent Protein Kinase II by the NR2B Subunit of the N-Methyl- D-aspartate Receptor
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F.-S. Lo and R. R. Mize
Synaptic Regulation of L-Type Ca2+ Channel Activity and Long-Term Depression during Refinement of the Retinocollicular Pathway in Developing Rodent Superior Colliculus
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