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Volume 16, Number 14,
Issue of July 15, 1996
pp. 4376-4382
Copyright ©1996 Society for Neuroscience
Functional Correlation of NMDA Receptor  Subunits Expression
with the Properties of Single-Channel and Synaptic Currents in the
Developing Cerebellum
Tomoyuki Takahashi1,
Dirk Feldmeyer4,
Norimitsu Suzuki1,
Kayoko Onodera1,
Stuart G. Cull-Candy4,
Kenji Sakimura3, and
Masayoshi Mishina2
1 Department of Neurophysiology, Institute for Brain
Research and 2 Department of Pharmacology, Faculty of
Medicine, University of Tokyo, 113 Tokyo, Japan,
3 Department of Neuropharmacology, Brain Research
Institute, Niigata University, Niigata 951, Japan, and
4 Department of Pharmacology, University College London,
London WC1E 6BT, United Kingdom
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
NMDA receptor (NMDAR) subunits  1-4 are expressed
differentially with respect to brain region and ontogenic period, but
their functional roles still are unclear. We have compared an 1
subunit-ablated mutant mouse with the wild-type to characterize the
effect of subunit expression on NMDAR-mediated single-channel
currents and synaptic currents of granule cells in cerebellar slices.
Single-channel and Western blot analyses indicated that the 2
subunit disappeared gradually during the first postnatal month in both
wild-type and mutant mice. Concomitantly, the voltage-dependent
Mg2+ block of NMDAR-mediated EPSCs (NMDA-EPSCs)
was decreased. Throughout the developmental period studied, postnatal
day 7-24 (P7-P24), the decay time course of NMDA-EPSCs in 1 mutant
( /) mice was slower than in wild-type mice. We suggest that the
expression of the 3 subunit late in development is responsible for a
reduction in the sensitivity of NMDA-EPSCs to block by extracellular
Mg2+ and that receptors containing the 1
subunit determine the fast kinetics of the NMDA-EPSCs.
Key words:
NMDA receptor;
synaptic current;
single channel;
cerebellum;
gene targeting;
patch clamp
INTRODUCTION
In the cerebellum, NMDA receptors (NMDARs) are
thought to play important roles in neuronal development (Rabacchi et
al., 1992 ; Komuro and Rakic, 1993) and excitatory synaptic transmission
(Garthwaite and Brodbelt, 1989; Silver et al., 1992; D'Angelo et al.,
1993). Molecular cloning studies have revealed five NMDAR subunits
called  1 and 1-4 in mice (Ikeda et al., 1992; Kutsuwada et
al., 1992; Meguro et al., 1992; Yamazaki et al., 1992) or NR1 and
NR2A-NR2D in rats (Moriyoshi et al., 1991; Monyer et al., 1992). The
1 (NR1) subunit is indispensable for channel function (Moriyoshi et
al., 1991), and its mRNA is expressed ubiquitously, whereas the (NR2) subunit mRNAs are expressed differentially with respect to
cerebellar region and age (Watanabe et al., 1992, 1994; Akazawa et al.,
1994; Monyer et al., 1994). In cerebellar granule cells, 2 subunit
mRNA is expressed transiently during early postnatal development,
whereas 1 and 3 subunit mRNAs are expressed at a relatively late
stage (Watanabe et al., 1992; Akazawa et al., 1994; Monyer et al.,
1994). Recombinant NMDARs composed of the 1 (NR1) subunit and one of
the (NR2) subunits show distinct characteristics according to the
type of subunits involved. The subunit-dependent properties
include single-channel conductance and kinetics (Stern et al., 1992;
Tsuzuki et al., 1994), time course of current deactivation (Monyer et
al., 1992, 1994), affinity for agonists, sensitivity to antagonists
(Kutsuwada et al., 1992; Ishii et al., 1993), glycine, phorbol ester
(Kutsuwada et al., 1992), and Mg2+ (Kutsuwada et
al., 1992; Monyer et al., 1992, 1994; Ishii et al., 1993). To study
whether these subunit-dependent characteristics are reflected in
native NMDARs, we have recorded NMDAR-mediated single-channel currents
and synaptic currents from granule cells in cerebellar slices. To
enable the role of each subunit to be determined in isolation, we
have used mutant mice with their 1 subunit ablated by gene knock-out
techniques (Sakimura et al., 1995) and compared the single-channel and
synaptic currents in wild-type and mutant mice at early and late
postnatal periods. The results from these experiments indicate that
both 1- and 3-containing receptors can be present at the synapse.
Expression of the 1 subunits result in a relatively fast decay of
the NMDAR-mediated EPSCs (NMDA-EPSCs), whereas late expression of the
3 subunits contributes to a developmental reduction in the
voltage-dependent block of the EPSC by Mg2+.
MATERIALS AND METHODS
Preparation and solutions. Wild-type and 1
subunit-ablated mutant mice were decapitated with scissors under ether
anesthesia. After isolating the cerebellum, parasagittal slices were
cut using a tissue slicer (DTK 1000, Dosaka). Slice thickness was
150-200 µm for single-channel recordings and 250-300 µm for
recording synaptic currents. Slices were incubated at 36.5°C for 1 hr
in a submerged chamber or left at room temperature in a moist chamber
equilibrated with 95% O2/5%
CO2. For experiments, slices were transferred
into a superfusing chamber on a stage of upright microscope (Axioskop,
Zeiss, Jena, Germany), and cells were viewed under Nomarski optics.
Standard superfusate had the following composition (in
mM): NaCl 125; KCl 2.5;
NaH2PO4 1.26;
NaHCO3 26; glucose 15;
CaCl2 2; MgCl2 1.0, pH 7.4, when bubbled with 95% O2/5%
CO2. In some experiments,
MgCl2 in the superfusates was reduced to 0 mM or 0.1 mM. The
superfusate routinely contained bicuculline (10 µM) (Sigma, St. Louis, MO), strychnine
(0.5-1.0 µM) (Sigma), and glycine (10 µM) (Wako, Japan). CNQX (20 µM) (Tocris Cookson, Bristol, UK) was added to
the superfusate to isolate the NMDAR-mediated component from the AMPA
receptor-mediated component of EPSCs. Patch pipettes were pulled from
borosilicate glass (Clark GC150F-7.5), coated with Sylgard resin, and
fire-polished to a final resistance of 5-10 M for whole-cell
recording or 15-20 M for excised patch recordings. The pipette
solutions contained (in mM): Cs gluconate 110;
CsCl 30; NaCl 4; HEPES 10; EGTA 5; CaCl2 0.5, adjusted to pH 7.3 with CsOH. The pipette solution for recording
synaptic currents also contained 2 mM MgATP to
protect NMDARs from run down and 5 mM
N-(2,6-dimethylphenylcarbamoylmethyl)-triethyl-ammonium
bromide (QX314) (Research Biochemicals, Natick, MA) to suppress action
potentials.
Single-channel and whole-cell recordings from cerebellar granule
cells. Single-channel and whole-cell current recordings were made
from cells in the internal granule cell layers using an EPC-7 (List)
amplifier. The cell capacitance was measured from the amplifier, and
cells with a capacitance less than 5 pF were regarded as granule cells.
The mean input resistance of granule cells was 2.95 ± 0.24 G (± SEM, n = 11). Single-channel recordings were made from
outside-out patches excised from visually identified granule cells
(Edwards et al., 1989; Farrant et al., 1994). NMDA (50 µM) (Sigma) was bath applied to a patch by
switching the superfusion line. Whole-cell recordings of EPSCs were
made primarily using the blind techniques (Blanton et al., 1989). The
mean access resistance with this method was 67.5 ± 4.9 M
(n = 11) corresponding to 2.3% of granule cell access
resistance. Given the relatively slow time course of NMDA-EPSCs,
kinetic distortion by the access resistance was negligible. EPSCs were
evoked by stimulating mossy fibers at 0.1 Hz at the white matter with a
patch pipette (tip diameter, 3-5 µm) filled with 1 M NaCl. In earlier experiments on
Mg2+ block, NMDA-EPSCs also were recorded from
visually identified granule cells. Results obtained by the two methods
were essentially the same; therefore, the data were pooled. All
experiments were performed at room temperature (23-26°C).
Single-channel and whole-cell current analyses.
Single-channel currents were stored using a tape recorder
(BioLogic DTR-1204) (bandwidth DC to 5.0 kHz) and analyzed off line.
Records were filtered with an eight-pole Bessel filter at a cut-off
frequency of 2 kHz (3 dB) and digitized at 20 kHz (PC-AT personal
computer equipped with a CED 1401+ interface). Patches with high noise
levels were excluded from analysis to avoid ambiguities in channel
identification. Amplitudes of single-channel events were determined by
the method of time course fitting (Colquhoun and Sigworth, 1995). Mean
single-channel currents were obtained from maximum likelihood fits of
the sum of 2-4 Gaussian distributions to the cursor fitted amplitudes
(Colquhoun and Sigworth, 1995). Only events longer than two filter rise
times (332 µsec) were included in the amplitude distributions, i.e.,
openings that had reached at least 99% of their full amplitude to
avoid the problem of assigning openings to wrong conductance levels.
Single-channel chord conductances were calculated on assuming a
reversal potential of 0 mV (Farrant et al., 1994). NMDA-EPSCs were
low-pass filtered at 0.5 kHz, digitized at 2.5 kHz (Dagan LM-12S
interface), and analyzed on a personal computer (Dell 466/LV). Holding
potentials were not corrected for the liquid junction potential between
pipette solution and superfusate (+7 mV). All values are expressed as
mean ± SEM.
Measurement of the 1 and 2 subunit proteins. Rabbit
anti-1 and anti-2 antibodies were raised against fusion proteins
containing a carboxyl-terminal portion of the 1 and 2 subunits.
DNA fragments that encode the amino acid residues 1335-1414 of the
1 subunit (Meguro et al., 1992) or the amino acid residues
1353-1432 of the 2 subunit (Kutsuwada et al., 1992) were amplified
by PCR using appropriate synthetic oligonucleotides and were cloned
into the expression vector pGEX-2T (Smith and Johnson, 1988) for
production of the fusion proteins with glutathione S-transferase. The
expression plasmids were transformed into Escherichia coli
BL21. Induction and purification of the fusion proteins were performed
as described (Araki et al., 1993). The fusion proteins were purified
further by SDS-PAGE and were used for immunizing New Zealand white
rabbits.
The 1 mutant (/) and wild-type (+/+) mice of various postnatal
ages were decapitated under anesthesia, and cerebella were removed
rapidly. Each cerebellum was homogenized in 10 vol of buffer H (10 mM Tris-Cl, pH7.2, 5 mM
EDTA, 0.32 M sucrose, 1 mM
phenylmethylsulfonyl fluoride, and 10 mg/l leupeptin) within 3 min of
decapitation, and centrifuged at 700 × g for 10 min to
obtain a postnuclear fraction. Protein determinations were made by the
method of Lowry et al. (1951). Various amounts of the protein prepared
at different postnatal ages were fractionated by SDS-PAGE to ensure
that densitometoric measurements were within the linear range. The
proteins in the gel were electroblotted onto a nitrocellulose membrane
(Schleicher and Schuell, Dassel, Germany). The blots were immunoreacted
with anti-1 and anti-2 sera at a dilution of 1:800 and 1:1600,
respectively, and were visualized by chemiluminescence (ECL detection
system, Amersham, Tokyo, Japan). For quantitative analysis, the
immunoreactive bands were scanned using a computing densitometer
(Shimazu CS-9300PC).
RESULTS
Developmental changes in NMDAR single-channel currents and 2
subunit protein
Single-channel currents were induced by NMDA applied to
outside-out patches excised from granule cells in cerebellar slices
(Fig. 1). In wild-type (+/+) mice at postnatal day 9 (P9), the channel openings were predominantly of the high-conductance
class (Stern et al., 1992; Farrant et al., 1994; Cull-Candy et al.,
1995) with a main conductance of 49.2 ± 1.1 pS and a subconductance of
40.2 ± 1.1 pS in the presence of 1 mM
Ca2+ (n = 5 patches). Transitions
between the two levels were observed frequently (Fig.
1A). As animals matured, another class of NMDAR
channels with lower conductance levels appeared in addition to the
high-conductance channels (Fig. 1B). At P21, 27% of all
channel openings observed were of this low-conductance type (Fig.
2A, open circle) with
main and subconductance levels of 36.4 ± 0.64 pS and 19.5 ± 1.7 pS,
respectively (n = 4). Within each conductance class,
direct transitions were observed clearly between the main level and
sublevel. However, no transitions were observed between high- and
low-conductance events, suggesting that the two distinct classes of
channel openings arise from two different receptor types, which can
coexist in a patch. These results in wild-type mice are in good
agreement with those obtained in normal rat cerebellar granule cells
(Farrant et al., 1994).
Fig. 1.
NMDA-gated single-channel currents in outside-out
patches excised from cerebellar granule cells of wild-type and 1
subunit-ablated mutant mice. Single-channel currents were activated by
50 µM NMDA in patches excised from cerebellar
granule cells at 70 mV holding potential in nominally
Mg2+-free solution containing 1 mM Ca2+, 10 µM glycine, 0.3 µM
tetrodotoxin, and 1.0 µM strychnine. Channel
openings in a patch from P9 (A) and P21 (B)
wild-type (+/+) mice and P9 (C) and P21 (D) 1
mutant (/) mice are shown. In D, the currents recorded
from the patch with only low-conductance channels are illustrated.
Dashed lines in sample records (upper panel)
indicate the mean current amplitudes derived from the corresponding
single-channel amplitude distribution (histograms in lower
panels). Main levels and sublevels of high-conductance channels
were 49.2 ± 1.1 pS and 40.2 ± 1.1 pS (n = 5) at P9
wild-type, 51.8 ± 1.4 pS and 42.3 ± 2.1 pS (n = 6) at
P21 wild-type, and 50.0 ± 0.60 pS and 40.3 ± 0.59 pS
(n = 7) at P9 1 mutant (/). Main levels and
sublevels of low-conductance channels were 36.4 ± 0.64 and 19.5 ± 1.7 pS (n = 4) at P21 wild-type and 33.7 ± 1.4 pS and 18.2 ± 0.52 pS (n = 6) at P21 1 mutant (/). For
illustration, records were filtered at 1 kHz (3 dB).
[View Larger Version of this Image (25K GIF file)]
Fig. 2.
Developmental declines in high-conductance
channels in 1 mutant (/) mice and 2 subunit protein in mutant
and wild-type mice. A, The proportion of high-conductance
(~50/40 pS) NMDAR channels in cerebellar granule cells plotted
against postnatal age. Filled circles are data from 1
mutant (/) mice. Open circles are those from wild-type
mice. The fraction of high-conductance channel events of all openings
in a patch was measured from an event histogram (Fig. 1), and the mean
value of four to eight patches (symbols) and SEM
(bars) were indicated at each period. B, Relative
amount of immunoreactive 2 subunit in whole cerebella of 1 mutant
(filled symbols) and wild-type (open symbols)
mice at various postnatal days. Individual values were determined by
densitometric measurements of immunoreactive bands shown in the
inset and were normalized to the value at P6. There was no
difference in the amount of 2 subunit protein between wild-type and
mutant mice at P6. Each data point derived from five to nine mice
cerebella. Inset, 50 µg each of postnuclear proteins of
cerebella of 1 mutant mice (/, upper panel)
and wild-type (+/+, lower panel) mice was
loaded on each lane of SDS-PAGE (7% gel). After electrophoresis, the
protein was electrotransferred onto a nitrocellulose membrane. The blot
then was probed with antiserum (1:1600) against 2, and protein bands
were visualized by a chemiluminescence detection system (Amersham).
Molecular mass markers are indicated on the left, and age of
animals are indicated on top. Western blot analyses of
proteins from 1 mutant (/) mice using anti-1 antibodies
revealed no detectable immunoreactive bands, whereas the levels of the
1 subunit protein increased during the postnatal development in
wild-type mice (data not shown).
[View Larger Version of this Image (14K GIF file)]
Next, we recorded the NMDAR single-channel currents from cerebellar
granule cells of mutant mice with their 1 subunit ablated by gene
knock-out techniques (Sakimura et al., 1995). In homozygous
1-ablated (/) mice at the early postnatal period (P9), the NMDAR
channel conductance profile was indistinguishable from that of
wild-type (+/+) mice, with a main conductance of 50.0 ± 0.60 pS and a
subconductance of 40.3 ± 0.59 pS (n = 7) (Fig.
1C). However, at P21, this high-conductance class became
less frequent (15%) (Fig. 2A), and the
low-conductance channels with a main conductance of 33.7 ± 1.4 pS and
a subconductance of 18.2 ± 0.52 pS (n = 6) became
dominant (Fig. 1D). At P30, high-conductance channels were
virtually absent (<1%), leaving only low-conductance channels (Fig.
2A). These results suggest a progressive change
during development from the expression of high-conductance channels to
the expression of low-conductance channels.
The decline in expression of high-conductance channels during
development of 1 mutant (/) mice contrasts with their continuous
presence in wild-type mice. This suggests that the 1 subunit
normally forms high-conductance channels, presumably with the 1
subunit as it does for recombinant NMDARs (Stern et al., 1992).
Recombinant NMDARs composed of NR2B (2) and NR1 (1) likewise form
high-conductance channels (~50/40 pS), whereas those of NR2C (3)
and NR1 (1) form low-conductance channels (~36/19 pS) (Stern et
al., 1992). In situ hybridization studies in cerebellar
granule cells indicate that the 2 subunit mRNA is present only in
the first and second postnatal weeks and disappears thereafter, whereas
mRNAs encoding the 1 or 3 subunit appear relatively late and
persist in the adult (Watanabe et al., 1992, 1994; Akazawa et al.,
1994; Monyer et al., 1994). Our results with native NMDARs, taken
together with these reports on recombinant NMDARs, suggest that an
2-to-3 subunit switch underlies the developmental shift of the
NMDAR channel population from the high-conductance class to the
low-conductance class in 1-ablated mutant mice.
The age-dependent reduction in the 2 subunit protein level was
determined using Western blot analysis of whole cerebellar tissue.
Because NMDARs appear to be expressed exclusively in neurons (Wyllie et
al., 1991) and the granule cell is the most abundant neuron in the
cerebellum, these measurements should reflect subunit expression by
granule cells. As illustrated in the inset of Figure 2B, the
density of the 2 subunit protein decreased with postnatal
development in both wild-type (+/+, lower panel) and 1
mutant (/, upper panel) mice. The relative amount of the
2 subunit protein was quantified densitometrically at different
postnatal periods (Fig. 2B). In developing 1 mutant
(/) mice, the time course of decline in cerebellar 2 subunit
protein (Fig. 2B, filled circles) was strikingly
similar to that of the loss of high-conductance channels in granule
cell patches (Fig. 2A). The decline of the 2 subunit
protein in wild-type cerebellum (+/+, open circles in Fig.
2B) was essentially the same as that in the 1 mutant
(/, filled circles), suggesting that the disruption of
the 1 subunit gene had no effect on the expression of the 2
subunit. The 2 subunit protein persisted until 1 postnatal month,
although its mRNA was no longer detectable after 2 postnatal weeks
(Watanabe et al., 1992, 1994).
Developmental changes in the NMDA receptor-mediated EPSCs
Next, we examined which subunits contribute to excitatory
synaptic transmission at cerebellar mossy fiber-granule cell synapses.
Stimulation of mossy fibers in the white matter evoked EPSCs in granule
cells in both wild-type and 1 mutant (/) mice. Application of
CNQX (20 µM) blocked a fast
AMPA-receptor-mediated component of the EPSC, leaving a slow
NMDAR-mediated component (NMDA-EPSC) that was blocked by the NMDAR
antagonists D-2-amino-5-phosphonopentanoic acid (100 µM) and 7-chlorokynurenic acid (40 µM). NMDA-EPSCs were first observed at ~P5
and could be consistently evoked after P7 (Fig.
3A). As animals matured, NMDA-EPSCs appeared
to become smaller. In Mg2+-free solution at 70
mV, the mean amplitude of the NMDA-EPSCs evoked by a supramaximal
stimulus intensity was 77.6 ± 12 pA (n = 20) at
P7-P9, whereas it was 21.2 ± 1.6 pA at P21-P24 (n = 30) in wild-type mice. Similarly in 1 mutant (/) mice, the
amplitude of NMDA-EPSCs was 73.9 ± 9.7 pA (n = 22) at
P7-P9, but only 18.5 ± 2.3 pA (n = 20) at P21-P24
(Fig. 3A).
Fig. 3.
NMDA-EPSCs evoked in cerebellar granule cells by
stimulating mossy fiber inputs. A, Averaged NMDA-EPSCs
recorded from cerebellar granule cells of wild-type (+/+, upper
row) and 1 mutant mice (/, lower row) at early
(P8, left column) and late (P21-P22,
right column) postnatal stages. In
Mg2+-free solution containing CNQX (20 µM), bicuculline (10 µM), and strychnine (0.5 µM). EPSCs (20-25) were averaged for each
trace. Holding potential was 70 mV. B, A kinetic
comparison of NMDA-EPSCs. Rise time (10-90%, abscissa) and
decay time (from peak to 37%, ordinate) were compared
between wild-type (open circles) and 1 mutant (/)
mice (filled triangles) at P21-P24.
[View Larger Version of this Image (12K GIF file)]
Kinetic properties
In both wild-type and mutant mice, the decay time course of
NMDA-EPSCs could be well described by a double exponential function. In
the wild-type mice, the time constants for the fast and slow components
were 51.8 ± 4.8 msec (57.3 ± 3.0%) and 377 ± 37 msec at P7-P9
(n = 20), and 35.7 ± 1.6 msec (76.8 ± 1.5%) and 254 ± 24 msec at P21-P24 (n = 30). Thus during
development, there was a clear acceleration in the EPSC decay, with a
significant decrease of both fast and slow time constants as well
as an increase in the relative amplitude of the fast
component (p < 0.01, Student's t
test). A similar developmental change also was seen in the mutant mice,
for which the corresponding values were 87.8 ± 6.0 msec (48.2 ± 3.2%) and 471 ± 65 msec at P7-P9 (n = 22), and 44.2 ± 3.4 msec (59.0 ± 2.5%) and 227 ± 15 msec at P21-P24
(n = 20). However, deletion of the 1 subunit from
synaptic NMDARs clearly resulted in a slowing of the fast component
decay and a decrease in its relative amplitude in both P7-P9 and
P21-P24 mutant mice (p < 0.02). This is illustrated
in Figure 3B as a plot of NMDA-EPSC rise time (10-90%)
against decay time (from peak to 37%) at P21-P24. Between wild-type
and 1 mutant (/) mice, a clear difference was observed in decay
time, with the former (47.0 ± 2.1 msec, n = 30) being
significantly shorter than the latter (74.2 ± 2.5 msec,
n = 20, p < 0.0001), whereas no
difference was observed in NMDA-EPSC rise time between the groups at
P21-P24 (wild-type 7.91 ± 0.45 msec; mutant 7.72 ± 0.38 msec).
Similarly at P7-P9, the NMDA-EPSC decay time of wild-type mice (102 ± 5.5 msec, n = 20) was significantly faster than that of
mutant mice (169 ± 8.5 msec, n = 22, p < 0.0001).
Voltage-dependent Mg2+ block
One important feature of NMDAR channels is their sensitivity to
voltage-dependent block by Mg2+ (Nowak et al.,
1984). Current-voltage relationships were obtained for the NMDA-EPSCs
at early (P7-P9) and late (P21-P24) postnatal periods in wild-type
(+/+) and 1 mutant (/) mice (Fig. 4). At P7-P9,
NMDA-EPSCs in both wild-type and 1 mutant (/) mice showed a
typical voltage-dependent block by 0.1 mM
Mg2+ (left panels in Fig.
4A,B; filled circles in
B), with the amplitude being smaller at more negative
potentials. As expected, the block was more pronounced in 1 mM Mg2+ (open
circles in Fig. 4B). At P21-P24, the degree of
Mg2+ block was reduced in both wild-type and 1
mutant (/) mice (right panels in Fig.
4A,B). At a holding potential of 70
mV, the peak amplitude of NMDA-EPSCs remaining in 0.1 mM Mg2+ (Fig.
5A) in wild-type mice (open
column) at P7-P9 was 26 ± 3.9% of that in
Mg2+-free solution (n = 6),
whereas it was 65 ± 4.4% at P21-P24 (n = 6)
(significant difference at p < 0.0001). Similarly in
1 mutant (/) (filled columns), the remaining
proportion of NMDA-EPSCs in 0.1 mM
Mg2+ was significantly smaller at the early
period than at the late period (19 ± 3.4%, n = 6 vs
61 ± 7.1%, n = 5) (p < 0.001). Also in 1 mM Mg2+
(Fig. 5B) in both wild-type and mutant, the proportion of
NMDA-EPSCs remaining unblocked at P21-P24 (wild-type, 15 ± 2.6%,
n = 5; mutant, 21 ± 2.0%, n = 5) was
larger than that at P7-P9 (wild-type, 5.3 ± 0.99%, n = 5; mutant, 4.1 ± 0.68%, n = 7) (these values are
significantly different: p < 0.01 in the wild-type and
p < 0.0001 in the mutant). Thus, the extent of
Mg2+ block of NMDA-EPSCs decreased in
an age-dependent manner but was independent of the presence of the 1
subunit.
Fig. 4.
Voltage-dependent Mg2+ block
of NMDA-EPSCs. A, NMDA-EPSCs recorded in the presence of 0.1 mM Mg2+ at different
holding potentials are superimposed. Records are from cerebellar
granule cells of wild-type mice at P8 (top left) and P21
(top right), and 1 mutant (/) mice at P9
(bottom left) and P22 (bottom right) periods.
Each trace is averaged from 12 to 20 EPSCs. B,
Current-voltage (I-V) relationships of
NMDA-EPSCs from wild-type mice (top panels) and 1 mutant
(/) mice (bottom panels) at the early (left
panels) and late (right panels) postnatal periods. Data
points are obtained in the presence of 0.1 mM
Mg2+ (filled circles) or 1 mM Mg2+ (open
circles), or in the nominal absence of external
Mg2+ (open triangles at 70 mV). The
EPSC amplitudes were normalized to the mean value at + 50 mV in each
experimental condition. Each data point and error bar indicates mean
and SEM of NMDA-EPSCs derived from 5 to 11 cells.
[View Larger Version of this Image (21K GIF file)]
Fig. 5.
Mg2+ block of NMDA-EPSCs at
70 mV. Amplitude of NMDA-EPSCs remaining after
Mg2+ block relative to those in
Mg2+ -free solution in wild-type (open
column) and 1 mutant (/) (filled column) mice.
Extracellular Mg2+ concentration was 0.1 mM (A) and 1 mM
(B), respectively. Significant difference was found for the
remaining EPSCs between P7-P9 and P21-P24 in wild-type mice
(between filled columns in A) (p < 0.0001) and mutant mice (between open columns in
A) (p < 0.001) in 0.1 mM Mg2+, as well as in 1 mM Mg2+ (B)
(p < 0.01 and p < 0.0001 for
wild-type and mutant mice, respectively). The difference in the
remaining EPSCs was not significant between wild-type and mutant in 0.1 mM Mg2+ or in 1 mM Mg2+. The mean amplitude
of NMDA-EPSCs remaining in 1 mM
Mg2+ at 70 mV was 4.2 and 6.6 pA for wild-type
and mutant mice granule cells, respectively, at P21-P24, whereas the
corresponding values at P7-P9 were 2.7 and 2.0 pA, respectively.
[View Larger Version of this Image (29K GIF file)]
DISCUSSION
Comparison of native and recombinant NMDAR channel properties
We observed a clear change in the NMDA receptor channel properties
in developing cerebellar granule cells. In wild-type mice,
high-conductance channel openings (~50/40 pS) were observed at high
frequency over the entire postnatal period examined (P7-P29), whereas
in 1 mutant (/) mice, these were observed only at an early
postnatal stage. Low-conductance channel openings (~35/20 pS)
appeared in both wild-type and 1 mutant (/) mice only at a late
stage. In situ hybridization studies indicate that mRNAs
encoding the 1 or 3 subunit are expressed relatively late
postnatally, whereas the 2 subunit mRNAs appear transiently during
early postnatal development (Watanabe et al., 1992; 1994; Akazawa et
al., 1994; Monyer et al., 1994). The 2 subunit protein in cerebellar
tissue examined by Western blot analysis displayed an age-dependent
decline that was similar in time course to the decline in the
proportion of high-conductance channels in cerebellar granule cells of
1 mutant (/) mice. Thus, the channel conductances observed in
native cerebellar tissue correspond well with those reported for
recombinant NMDARs containing the 1 subunit in combination with one
of the subunits; high-conductance channels are formed by the 1
(NR1) subunit in combination with either 1 (NR2A) or 2 (NR2B)
subunit, whereas low-conductance channels are composed of the 1
(NR1) subunit together with the 3 (NR2C) subunit (Stern et al.,
1992; Cull-Candy et al., 1995). Our present results support the
hypothesis that different subunits in combination with the 1
subunit form distinct NMDARs in cerebellar granule cells, although we
cannot exclude the possibilities that multiple subunits including
those undiscovered may contribute to individual NMDARs in
situ (Sheng et al., 1994).
Synaptic currents mediated by NMDARs
NMDA-EPSCs were recorded from cerebellar granule cells of 1
mutant (/) mice at early or late postnatal stages when the 2 or
3 subunit, respectively, is predominantly expressed. Comparison of
wild-type and mutant NMDA-EPSCs indicated that expression of the 1
subunit resulted in a faster decay time of NMDA-EPSCs. Therefore,
distinct subunits appear to be expressed subsynaptically and
contribute to excitatory synaptic transmission at different stages of
development.
The decay time of the NMDA-EPSCs is known to be much longer than the
mean open time or burst length of NMDAR channels (Edmonds and
Colquhoun, 1992; Lester and Jahr, 1992), but it is comparable to the
deactivation time of NMDAR current responses in patches (Lester et al.,
1990; Lester and Jahr, 1992), possibly because of a prolonged latency
to first opening (Edmonds and Colquhoun, 1992). The deactivation time
of NMDAR current responses is faster for agonists of low affinity
(Lester and Jahr, 1992). Recombinant 1-1 (NR2A-NR1) NMDARs have
the lowest affinity for L-glutamate (Kutsuwada et
al., 1992; Ishii et al., 1993) and the fastest current deactivation
time (Monyer et al., 1994). Consistent with this observation, our
present results indicate that 1 subunit ablation slows the decay
time of NMDA-EPSCs. In contrast to the 2 subunit, expression of the
1 subunit increases with postnatal development (Watanabe et al.,
1992, 1994). Therefore, the 2-to-1 subunit switch may underlie
developmental acceleration in the kinetics of NMDA-EPSCs at the mossy
fiber-granule cell synapse. This mechanism also may underlie the
kinetic changes during development reported in the superior colliculus
(Hestrin, 1992) and the visual cortex (Car- mignoto and Vicini,
1992) of rats, although additional factors such as developmental
changes in the subunit splice variants (Della Vedova et al., 1994)
also could contribute. In this regard, the developmental switch from
2 to 1 subunit of NMDARs at the cerebellar synapses appears
analogous to the  -to- subunit switch of nicotinic acetylcholine
receptors at the neuromuscular junction (Mishina et al., 1986) and the
 2-to-1 subunit switch of glycine receptors at spinal inhibitory
synapses (Takahashi et al., 1992).
The voltage-dependent Mg2+ block of NMDAR is
thought to play a crucial role in synaptic plasticity, because it can
prevent Ca2+ entry through the receptor into
cells at the resting potential. It has been reported that NMDARs in
visual cortical neurons are relatively insensitive to
Mg2+ at the early developmental period (Kato and
Yoshimura, 1993). In contrast, our results demonstrate that NMDA-EPSCs
in cerebellar granule cells were less sensitive to
Mg2+ block at the later postnatal period. Because
this phenomenon was observed in both wild-type and 1 mutant (/)
mice, it is most likely that the 3 subunit rather than the 1
subunit is responsible for this change. In fact, the recombinant NMDAR
3-1 (NR2C-NR1) is relatively resistant to
Mg2+ compared with 1-1 (NR2A-NR1) or
2-1 (NR2B-NR1) receptors (Kutsuwada et al., 1992; Monyer et
al., 1992). Our results from native NMDARs together with these reports
on recombinant NMDARs suggest that the developmental reduction in the
sensitivity of NMDARs to Mg2+ block is a result
of the 3 subunit expressed at the relatively late stage of
development.
During postnatal development, NMDA-EPSCs became faster in decay time,
smaller in peak amplitude, and more resistant to the voltage-dependent
block by Mg2+. Reductions in time course and
amplitude of NMDA-EPSCs would contribute to reduced
Ca2+ entry through NMDARs during synaptic
transmission, whereas a decrease in Mg2+ block
would increase the Ca2+ entry particularly at the
resting membrane potential. NMDARs also are present on premigratory and
migrating granule cells before synapse formation (Farrant et al.,
1994), and Ca2+ entry through these receptors
appears to contribute to cell migration (Komuro and Rakic, 1993). The
precise role of synaptic NMDAR-mediated Ca2+
entry into postmigratory granule cells remains to be elucidated.
FOOTNOTES
Received Feb. 26, 1996; revised April 26, 1996; accepted May 1, 1996.
This work was supported by the Monbusho International Scientific
Research Program of Japan (T.T.) and by the Wellcome Trust and the
Howard Hughes Medical Institute (S.G.C.C.). We are grateful to Drs.
Mark Farrant, Toshiya Manabe, and Yasunori Hayashi for critical reading
of this manuscript, and Drs. David Colquhoun and Stephen Traynelis for
generously providing software.
Correspondence should be addressed to Tomoyuki Takahashi, Department of
Neurophysiology, Institute for Brain Research, Faculty of Medicine,
University of Tokyo, Tokyo 113, Japan.
Dr. Feldmeyer's present address: Abteilung für Zellphysiologie,
Max-Planck-Institute für Medizinische Forschung, D-69120
Heidelberg, Germany.
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