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The Journal of Neuroscience, August 15, 2000, 20(16):5899-5905
Developmental Profile of the Changing Properties of NMDA
Receptors at Cerebellar Mossy Fiber-Granule Cell Synapses
Laurence
Cathala,
Charu
Misra, and
Stuart
Cull-Candy
Department of Pharmacology, University College London, London WC1E
6BT, United Kingdom
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ABSTRACT |
During cerebellar development, granule cells display well
characterized changes in the expression of NMDA receptor (NMDAR) NR2
subunits, switching from NR2B to NR2A and NR2C in mature cells. Although various studies, including experiments on mutant mice with one
or more NR2 subunit types deleted, suggest that NR2A, NR2B, and NR2C
subunits contribute to synaptic NMDARs, changes in the properties of
the mossy fiber EPSC during development have not been fully evaluated.
In particular, information on NMDAR EPSCs in mature animals is lacking.
We have examined pharmacological and kinetic properties of NMDARs at
mossy fiber-granule cell synapses from their formation to
maturity [postnatal day 7 (P7)-P40 rats]. Significant changes were
seen in the relative amplitudes of the non-NMDAR- and NMDAR-mediated
components of the evoked EPSC and in the decay kinetics of the latter.
The NMDA/non-NMDA ratio was similar at P7, P21, and P40, but showed a
clear peak at P12. This change coincided with a speeding of the NMDAR
EPSC decay, accompanied by a decrease in sensitivity to ifenprodil
(selective NR2B-antagonist). By P21, sensitivity of the NMDAR EPSC to
Mg2+ was approximately threefold less than that at
P12 (IC50, 76 vs 28 µM), suggesting
incorporation of the NR2C subunit. However, the predicted slowing of
decay kinetics to a value more characteristic of NR2C deactivation, was
not seen until P40. Our data are consistent with the known switch from
NR2B to NR2A subunits during the first two postnatal weeks, but suggest
a gradual incorporation of the NR2C subunit that modifies
Mg2+ sensitivity and only later influences EPSC kinetics.
Key words:
cerebellum; granule cells; NMDA receptors; synaptic
transmission; patch-clamp; NMDA subunit expression; NR2C subunit
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INTRODUCTION |
The neurotransmitter
L-glutamate activates NMDA receptors (NMDARs) at many
synapses in the vertebrate CNS. These receptors are modulated by
various endogenous molecules, including
Mg2+, glycine,
Zn2+, and protons. Furthermore, they
display high Ca2+ permeability and slow
deactivation kinetics (Dingledine et al., 1999 ). These characteristic
attributes are governed by the types of NR1 and NR2 subunits forming
the receptor (Monyer et al., 1994; Feldmeyer and Cull-Candy, 1996). The
time course and pharmacology of the NMDAR-mediated component of
EPSCs (NMDAR EPSCs) can display striking changes during
development (Carmignoto and Vicini, 1992; Hestrin, 1992), primarily as
a result of changes in the type of NR2 subunit present. For example, a
switch from NR2B- to NR2A-containing receptors has been described,
resulting in acceleration of NMDAR EPSCs (Takahashi et al., 1996;
Rumbaugh and Vicini, 1999; Tovar and Westbrook, 1999) and a reduction
in synaptic plasticity (Carmignoto and Vicini, 1992; Quinlan et al.,
1999) at a number of central synapses.
In the present study we aimed to determine the effect of subunit
changes on the properties of synaptic NMDARs at the cerebellar mossy
fiber-granule cell synapse. The early expression of NR2B in granule
cells is replaced by NR2A and later by intense expression of mRNA for
NR2C. The finding that the level of NR2C mRNA is unusually high in
granule cells from adult animals, in contrast with its sparse
expression elsewhere in the CNS (Akazawa et al., 1994; Monyer et al.,
1994), has provided a further stimulus to understanding its properties
at the mossy fiber synapse. Studies of recombinant receptors indicate
that the NR2C subunit forms NMDARs with a low sensitivity to
Mg2+ block, compared with NMDARs that
contain NR2A or NR2B subunits (Kuner and Schoepfer, 1996).
NR2C-containing NMDARs (low-conductance NMDAR channels) can be readily
detected in somatic patches from granule cells in animals aged
postnatal day 19 (P19) or older, typically occurring along with the
high-conductance NR2A- or NR2B-containing NMDARs (Farrant et al.,
1994). Although studies on 1- to 3-week-old animals, including
experiments on mutant mice with one or more NR2 subunit types deleted,
suggest that NR2A, NR2B, and NR2C subunits can all contribute to
synaptic NMDARs (Ebralidze et al., 1996; Kadotani et al., 1996;
Takahashi et al., 1996), changes in the properties of the mossy fiber
EPSC over a wide developmental period have not been fully evaluated.
Furthermore, there is little information on granule cell NMDAR EPSCs in
mature animals.
We therefore, examined the properties of evoked EPSCs at the mossy
fiber-to-granule cell synapse from the time of its formation to
maturity. We show that NMDAR EPSCs are present throughout this developmental period and that mature granule cell synapses display features that differ from other synapses in the CNS. During the initial
3 weeks of postnatal development, the decay of NMDAR EPSCs was markedly
accelerated, consistent with insertion of NR2A- and gradual loss of
NR2B-containing receptors. Our experiments indicate that from the third
postnatal week NR2C-containing NMDARs make a major functional
contribution to the mossy fiber-granule cell synapse, conferring a
reduced sensitivity to Mg2+, followed by a
prolongation in time course of the NMDAR EPSC in the mature animal.
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MATERIALS AND METHODS |
Slice preparation. Parasaggital slices (200-300
µm) were cut from the cerebellum of Sprague Dawley rats between P7
and P40 as described previously (Farrant et al., 1994). Briefly,
rats were decapitated, and the brain was rapidly removed and placed in
cold "slicing" (2-4°C) solution of the following composition (mM): NaCl 125; KCl 2.5; CaCl2 1;
MgCl2 2; NaHCO3 26;
NaH2PO4 1.25; glucose 25, pH 7.4, when bubbled with 95% O2 and 5%
CO2. Slices were cut from the dissected
cerebellar vermis using a moving blade microtome (DTK-1000; Dosaka EM
Company, Kyoto, Japan); these were incubated in slicing solution at
30°C for 1 hr and subsequently were maintained at room temperature
for up to 8 hr. For electrophysiological experiments, the slices were
transferred to a chamber on a fixed-stage Axioskop microscope (Zeiss,
Welwyn Garden City, UK) and examined at room temperature (22-25°C).
Granule cells were viewed under Nomarski differential interference
optics (40× water-immersion objective; total magnification,
320-1000×), and identified from their appearance and their
characteristic electrical properties.
Solutions and drugs. Slices were perfused with external
solution, which differed from slicing solution in lacking
Mg2+. The internal (pipette) solution used
for recording contained (mM): CsF, 110; CsCl, 30;
HEPES, 10; EGTA, 5; NaCl, 4; CaCl2, 0.5; and Mg-ATP, 2, adjusted to pH 7.3 with CsOH.
Mossy fiber-evoked EPSCs were examined in isolation by blocking both
GABAergic and glycinergic receptors with 100 µM
picrotoxin. A 10 µM concentration of glycine was added to
the bathing solution to facilitate NMDAR activation. In outside-out
patch recordings, the following drugs were added to the
Mg2+-free external solution: 1 µM strychnine and 10 µM bicuculline to
block glycinergic and GABAergic receptors, respectively. Additionally, 5 µM 6-cyano-7-dinitroquinoxalinedione (CNQX) and 300 nM tetrodotoxin (TTX) were added to block AMPA receptors
and voltage-activated sodium channels. For activation of NMDARs in
patches, 10 µM NMDA was applied together with 10 µM glycine.
All salts were obtained from Sigma (Poole, UK), and BDH Chemicals
(Poole, UK). The following drugs were used: bicuculline methobromide
(Research Biochemicals, Natick, MA), CNQX,
D-2-amino-5-phosphono-pentanoic acid (AP-5),
7-chloro-kynurenate (7-CK), NMDA (Tocris Cookson, Bristol, UK),
glycine (BDH Chemicals),
N-N-N'-N'-tetrakis-(2-pyridyl-methyl)-ethylenediamine (TPEN), TTX, 6,7-dinitroquinoxaline-2,3-dione (DNQX), ifenprodil, picrotoxin, and strychnine hydrochloride (Sigma).
Recording procedures. All patch-clamp recordings were made
using an Axopatch-200A or 200B amplifier (Axon Instruments, Foster City, CA). Patch pipettes were made from thick-walled borosilicate glass tubing (GC-150F; Clark Electromedical, Pangbourne, UK). Pipettes
were coated with Sylgard resin (Dow Corning 184) and fire-polished to a
resistance of 8-10 M for whole-cell recordings or 10-12 M for
single-channel recordings. Series resistance and capacitance measures
were determined directly from the amplifier settings. Series resistance
compensation was not used. Cell capacitance was: 4.7 ± 0.4 pF
(n = 10) at P7, 3.5 ± 0.09 pF (n = 28) at P12, 3.2 ± 0.16 pF (n = 40) at P21, and
3.4 ± 0.2 pF (n = 14) at P40. Series resistance
was: 16.5 ± 0.8 M at P7, 18 ± 1 M at P12, 20 ± 0.8 M at P21, and 20 ± 1.5 M at P40. Solutions were
bath-applied via gravity feed. Afferent inputs (mossy fibers) were
stimulated via a glass pipette (~30 µm diameter) filled with
external solution. This was positioned in the white matter and a pulse
of at least 10 µsec duration was delivered at 0.1 Hz (Neurolog DS2;
Digitimer Limited). The intensity of the stimulation was set at just suprathreshold.
Data analysis. Current records were stored on digital
audiotape (DTR-1204; BioLogic, Claix, France; DC to 20 kHz). EPSCs were filtered at 2 kHz ( 3 dB, eight pole lowpass Bessel filter), and digitized at 20 kHz (digidata 1200; pClamp versions 6 and 8; Axon Instruments). Single-channel currents were filtered at 2 kHz and digitized at 10 kHz.
Evoked EPSCs were analyzed using Axograph (Axon Instruments). Average
waveforms (from at least 20 sweeps) were constructed by aligning EPSCs
on the stimulus artifact. We used two methods to analyze the NMDAR
component: (1) The amplitude of the NMDAR EPSC was measured 10 msec
after the non-NMDAR peak (average of 28 points), and (2) the charge
transfer, after subtraction of the non-NMDAR-component (charge
remaining in the presence of 50 µM AP-5 and 50 µM 7-CK), was measured by integrating the EPSC. The
decays of the non-NMDAR or NMDAR-mediated component of evoked EPSCs
were fitted separately and each were best described by the sum of two
exponential functions: A(t) = Aslow
exp(t/ slow) + Afast
exp(t/fast), where
slow and fast are the
decay time constants of the slow and fast component and
Aslow and
Afast are their respective amplitudes.
To fit the NMDAR EPSC decay, the amplitude was normalized to a value
measured 10 msec after the peak of the non-NMDAR component, and the
remaining portion of the current was fitted (see Fig. 2A). To compare the decay of EPSCs at different ages,
the weighted time constant (w) was used:
w = slow
[Aslow/(Aslow + Afast)] + fast
[Afast/(Aslow + Afast)].
For analysis of single-channel records, consecutive 100 msec epochs of
NMDAR channel activity were integrated, and the average charge transfer
in the presence and absence of drug was calculated using the program
N05 (Stephen Traynelis, Emory University, Atlanta, GA). The effect of
ifenprodil was calculated by comparing the average charge transfer
during control periods and in the presence of ifenprodil. Graphs were
constructed in Origin (version 4.1, Microcal, Northampton, MA).
Mg2+ inhibition curves were fitted with a
form of the Hill equation: I = Imax/(1 + ([A]/IC50)n + (100 Imax), where
Imax is the maximal inhibition of the
response, [A] is the concentration of
Mg2+, IC50 is the
concentration of Mg2+ required to reduce
the response to 50% of control, and n is the Hill slope
(set to 1).
Average data are expressed as mean ± SEM (n = number of cells or patches). Statistical significance between groups
was tested using the two-tailed Student's t test and were
considered significant at p < 0.05.
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RESULTS |
Age-dependent changes in EPSC amplitude in granule cells
EPSCs were examined at the mossy fiber-granule cell synapse in
cerebellar slices from rats aged between P7 and P40 (n = 68 cells). By P40, mossy fiber synapses have reached the adult level of organization (Hamori and Somogyi, 1983), and granule cells have
attained their adult pattern of NMDAR subunit mRNA expression (Akazawa
et al., 1994; Monyer et al., 1994; Watanabe et al., 1994).
Figure 1 shows typical two-component
EPSCs evoked by mossy fiber stimulation at P12 (single EPSCs; Fig.
1A) and P40 (Fig. 1B; average
EPSCs; VH = 80 mV). The initial fast
non-NMDAR component could be readily blocked by CNQX (5 µM; n = 3) or DNQX (10 µM; n = 6; data not shown),
leaving a slow NMDAR component. As shown in Figure 1, A and
B, this could be abolished in both young and mature animals
by the NMDAR antagonists AP-5 (50 µM) and 7-CK (50 µM; n = 37) (Silver et al.,
1992; Takahashi et al., 1996; Clark et al., 1997). The non-NMDAR EPSCs
showed a gradual age-dependent increase in amplitude. This component
was significantly larger at P40 (Fig. 1C, top panel)
but showed little change in its decay kinetics (weighted decay time
constant w = 2.3 ± 0.4 msec at P7,
2.1 ± 0.2 at P12, 2.4 ± 0.4 msec at P21, and 2.2 ± 0.4 msec at P40). To analyze the amplitude of NMDAR EPSCs, we measured this event 10 msec after the EPSC peak (Fig. 1B). As
is apparent in Figure 1C (bottom panel),
the NMDAR EPSCs were similar in amplitude at P7 and P40, with a
transient, but significant, increase at P12.
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Figure 1.
Age-dependent changes in the amplitude of
non-NMDAR and NMDAR EPSCs. A, A single control EPSC
recorded at P12 (80 mV) showing an initial non-NMDAR component
followed by a NMDAR component (top panel). The
NMDAR EPSC was abolished in the presence of 50 µM AP-5
and 50 µM 7-CK (bottom panel),
leaving the non-NMDAR-component. B, Average traces of
consecutive EPSCs at P40 displayed on a faster time scale, indicating a
clear separation of the NMDAR and non-NMDAR components. The amplitude
of the non-NMDAR EPSC was measured at its peak (open
circle); the NMDAR EPSC was measured 10 msec after the peak
from a 1 msec epoch (filled circle). Traces are
averaged from at least 20 evoked EPSCs and normalized to the peak.
C, Amplitudes of the non-NMDAR (top
panel) and NMDAR component (bottom
panel) for each age group (n = 7 at
P7, n = 17 at P12, n = 28 at
P21, and n = 16 at P40). D,
Amplitude ratio of NMDAR versus non-NMDAR component of the different
age groups. For each age group, the ratio is indicated for each
recorded cell (open circle); the average from each age
group is indicated by a closed square (error bars
indicate SEM). Note that at P12, the NMDAR EPSC is prominent, sometimes
exceeding that of the non-NMDAR component.
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The ratio of NMDAR- versus non-NMDAR EPSC amplitudes was similar at P7,
P21, and P40 (Fig. 1D). However, this was
significantly greater at P12 (p < 0.05).
Previous work has demonstrated that the NMDAR- versus non-NMDAR EPSC
ratio decreases between P10 and P22 (D'Angelo et al., 1993). However,
our examination of a wide range of ages has indicated that this
apparent decrease in the ratio reflects a transient increase in the
NMDAR-mediated component at P12 and that this component (and hence the
NMDAR- vs non-NMDAR EPSC ratio) was not significantly changed at the
mature synapse. The cause of the change at P12 is uncertain, although
it could reflect an increase in the open probability or density of the postsynaptic NMDARs. Furthermore, it may be a consequence of the change
in glomerular structure during this critical period of synapse
formation (P12-P15). Indeed, during this time both the synaptic
junction perimeter and the number of active sites increase (Hamori and
Somogyi, 1983), the latter being associated with an increase in
spillover of transmitter between release sites (Silver et al., 1996).
This could contribute to the transient increase in NMDAR EPSC amplitude
at P12.
Developmental changes in the decay kinetics of NMDAR EPSCs
We next examined the developmental change in NMDAR EPSC decay
kinetics. Figure 2A
shows examples of averaged EPSCs recorded at P7, P21, and P40. The
NMDAR EPSC decay times were noticeably faster at P21 than at either P7
or P40. At all ages, the decay phase of the NMDAR EPSC could be well
fitted by the sum of two exponentials (slow
and fast; Table
1). The change in the weighted mean
decay time (w) of the NMDAR EPSC is
illustrated in Figure 2B. The decay was slow at P7
(w = 147 ± 10 msec; n = 7), but accelerated significantly to 77 ± 6 msec at P12
(n = 15) and 75 ± 7 msec at P21
(n = 11). However, by P40 w
was prolonged to 147 ± 13 msec (n = 10) comparable to that observed at P7. These changes in
w were mainly because of a change in
slow. Thus, although
fast accounted for ~70% of the current, its
time course and amplitude were not significantly different at the
various ages examined (Table 1, Fig. 2C). However,
slow exhibited an approximately twofold
decrease between P7 and 12, whereas its value at P40 was similar to
that at P7. There was no significant difference between the
slow values observed at P7 and P40 or between
values at P12 and P21 (Table 1, Fig. 2C).
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Figure 2.
Age-dependent changes in decay kinetics of NMDAR
EPSCs. A, Representative normalized averaged NMDAR EPSCs
at P7, P21, and P40. In all cases, the decay was best fitted by a
double exponential function. The fitted functions are superimposed
(black line) with their fast and
slow values indicated. B, Plot of
weighted ( ) versus age. Note that values of
at P7 and P40 are significantly different from those
at P12 and P21. For each age group, individual cells are indicated by
an open circle, and the average from each age group is
indicated by a closed symbol (error bars indicate SEM).
C, Relative amplitude (in percentage) of fast and slow
components versus time constant of decay. For each age group the mean
fast and the mean slow are plotted versus
their relative contribution to the total NMDAR EPSC.
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In situ hybridization studies have indicated that NR2B mRNA
is present in granule cells only in the first and second postnatal weeks (Akazawa et al., 1994; Monyer et al., 1994; Watanabe et al.,
1994). Furthermore the NR2B protein in cerebellar tissue is reduced
with age (Takahashi et al., 1996; Wenzel et al., 1997), being replaced
by NR2A and NR2C subunits (Wenzel et al., 1997). To determine whether
the change in NMDAR EPSC decay kinetics could be directly ascribed to
changes in the subunit composition of synaptic NMDARs, we examined the
effect of subunit-selective drugs and Mg2+
ions on NMDAR EPSCs.
Effect of NR1/NR2B selective blocker ifenprodil on EPSCs
Ifenprodil acts as an atypical noncompetitive NMDAR antagonist
that selectively interacts with NR2B-containing NMDARs (Williams, 1993,
1995; Gallagher et al., 1996) and has been extensively used to assess
the presence of the NR2B subunit at central synapses (Cull-Candy et
al., 1998; Stocca and Vicini, 1998; Quinlan et al., 1999; Tovar and
Westbrook, 1999; Misra et al., 2000a).
Figure 3 compares EPSCs in the presence
and absence of ifenprodil (10 µM) at P7, P12, and P21.
Whereas ifenprodil reduced the amplitude of the NMDAR EPSC at all ages,
the strong inhibition apparent at P7 decreased progressively with age.
The percentage inhibition was significantly less at P21 versus P7
(p < 0.05; Fig. 3D). Indeed, in some
cells ifenprodil produced a barely detectable reduction by P21 (Fig.
3C). These observations suggest that in young animals NMDAR
EPSCs are mediated largely by NR2B-containing NMDARs, but by P21 these
make a relatively small contribution. This is in keeping with our
previous experiments on P21 knock-out mice lacking the NR2A subunit, in
which the NR2B protein had declined to ~20% of its maximum level and
the high-conductance (NR2B-containing) channels represented only
~15% of openings at this age (Takahashi et al., 1996). Similarly,
recent experiments by Rumbaugh and Vicini (1999) have shown that NMDAR
EPSCs are inhibited in an age-dependent manner by the NR2B-selective
antagonist CP 101,606.
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Figure 3.
Ifenprodil block of the NMDAR EPSC decreases with
age. A-C, Average evoked EPSCs before and during bath
application of 10 µM ifenprodil at P7
(A), P12 (B), and P21
(C). Note that only the NMDAR EPSC was reduced by
ifenprodil. D, Mean percentage inhibition of the NMDAR
EPSC induced by ifenprodil in the different age groups. The percentage
inhibition was estimated by comparing the amplitude of the
NMDAR EPSC 10 msec after the non-NMDAR peak in control conditions and 2 min after the onset of drug application. The percentage inhibition
decreased significantly with age from 55 ± 4% at P7
(n = 6; p < 0.05) to 38 ± 8% at P12 (n = 6; p < 0.05) and 18 ± 6% at P21 (n = 6;
p > 0.05).
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Expression of mRNA for the NR2A subunit begins during the second
postnatal week (Akazawa et al., 1994; Monyer et al., 1994). Because
recombinant NR1/NR2A receptors are insensitive to ifenprodil, it seemed
likely that NMDAR EPSCs observed in the presence of ifenprodil in older
animals reflected an increased expression of NR2A-containing NMDARs. To
confirm this, we examined the effect of the
Zn2+ chelator TPEN on whole-cell NMDA
responses. TPEN has previously been shown to potentiate, by up to
threefold, the response of recombinant NR2A-containing NMDARs, whereas
having little effect on other NR2-containing NMDARs (Paoletti et al.,
1997). TPEN (1 µM) potentiated NMDA (10 µM)-evoked currents at P6 by 38 ± 1% (n = 15; p < 0.05), suggesting an
early contribution of the NR2A subunit to granule cell NMDARs (data not shown).
These pharmacological properties, together with the NMDAR EPSC decay
kinetics, support the idea that both NR2B and NR2A subunits are present
at immature mossy fiber synapses. This conclusion is also consistent
with our earlier observation that high-conductance (50 pS) NMDAR
channels underlie the NMDAR EPSC at ~P12 (Clark et al., 1997). Our
slow value for NMDAR EPSCs at P7 approximates to the deactivation time of ~400 msec reported for recombinant NR2B-containing NMDARs, consistent with the strong ifenprodil block at
this stage. Our slow values at P12-P21 were
close to the fast deactivation value ( ~120 msec) reported for
recombinant NR2A-containing NMDARs (Monyer et al., 1994; Vicini et al.,
1998). Moreover, the relative amplitude we obtained for the
fast-decaying component of the NMDAR EPSC (~70-75%) is within the
range described for recombinant NR1/NR2A receptors (~60-90%; Vicini
et al., 1998; Wyllie et al., 1998) and approaches the value of
~80% reported by Ebralidze et al., (1996) at this synapse in
P14-P18 mice lacking the NR2C subunit. However, it seems unlikely that
the NMDAR EPSC in P12-P21 rats arose from pure NR1/NR2A receptors,
given the fact that they were still markedly reduced by ifenprodil at
P12 and exhibited a low sensitivity to
Mg2+ at P21 (see below). It is also of
note that our value for slow at P40 matches
the deactivation kinetics (, ~380 msec) reported for recombinant
NR2C-containing NMDARs (Monyer et al., 1994).
Ifenprodil block of extrasynaptic NMDARs decreased with age
For comparison with synaptic data, we also examined the effect of
ifenprodil on somatic patches at P7, P12, and P21. Bath application of
10 µM NMDA (with 10 µM glycine) resulted in
clear single-channel activity in all outside-out patches analyzed
(Farrant et al., 1994). As illustrated in Figure
4A, the single-channel activity at P7 was significantly reduced (although not completely blocked) by 10 µM ifenprodil. Residual channel
openings were clearly briefer in duration (Fig. 4B),
as previously described for recombinant NR1/NR2B receptors (Williams,
1993; Priestley et al., 1995) and for native NMDARs (Legendre and
Westbrook, 1991). By P21, the effect of ifenprodil on patches was
markedly reduced (Fig. 4B). We examined the effect in
more detail by comparing mean charge transfer through single NMDAR
channels, in control conditions and in 10 µM
ifenprodil. Figure 4C shows examples of measurements obtained by integrating consecutive 100 msec epochs of channel activity
at P7 and P21. The effect of ifenprodil on charge transfer was
significantly reduced by P21. As shown in Figure 4D,
there was a significant difference in the percentage of inhibition at P7 versus P21 (p < 0.05).
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Figure 4.
Effect of ifenprodil on single-channel
currents in outside-out patches from granule cells of different ages.
A, B, Recordings at P7 and P21 in
response to 10 µM NMDA (and 10 µM glycine).
The bottom trace of each pair illustrates channel
openings from the same cell in the presence of 10 µM
ifenprodil. C, Plots of mean current integral of
single-channel activity, in the absence and presence of ifenprodil.
Each dot represents charge transfer during a 100 msec
epoch (filled circles). At P7, ifenprodil
markedly reduced charge transfer (open circles). At P21
charge transfer was largely unaffected by ifenprodil. D,
Plot summarizing percentage inhibition of channel activity by
ifenprodil in patches from granule cells of various ages. The
percentage of inhibition decreased significantly with age, from 73 ± 4% at P7 (n = 6; p < 0.05), to 48 ± 10% at P12 (n = 7;
p < 0.05), and 25 ± 14% at P21
(n = 6; p > 0.05).
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The presence of residual NMDAR-channel activity at P7 in
ifenprodil-treated patches does not necessarily imply that the
remaining events arose from other NMDAR subtypes, because ifenprodil
produces only ~80% block in a pure population of recombinant
NR1/NR2B receptors (Williams, 1993; Priestley et al., 1995; Tovar and
Westbrook, 1999). The gradual age-dependent reduction in ifenprodil
sensitivity of extrasynaptic NMDAR channels was comparable to that of
synaptic NMDARs activated during the EPSC (compare Figs. 3D
and 4D; but see Rumbaugh and Vicini, 1999).
Age-dependent shift in IC50 for Mg2+
block of synaptic NMDARs
Voltage-dependent block of the NMDAR pore by extracellular
Mg2+ ions (Mayer et al., 1984; Nowak et
al., 1984) is critical in allowing synaptic NMDARs to act as
coincidence detectors (for review, see Malenka and Nicoll, 1999). The
degree of block produced by Mg2+ is much
less for NR2C- than for NR2A- or NR2B-containing recombinant receptors
(Monyer et al., 1994; Kuner and Schoepfer, 1996). From the second
postnatal week granule cells express mRNA for the NR2C subunit, and we
have previously shown that NR2C-containing NMDARs can be detected in
the soma of these cells (Farrant et al., 1994). Earlier studies on
mutant mice, by ourselves and others (Ebralidze et al., 1996; Takahashi
et al., 1996), have indicated that both NR2A and NR2C subunits may
contribute to EPSCs by the end of the third postnatal week. In the
present study, the slowing of the NMDAR EPSC at P40 suggests a
relatively late appearance of NR2C-containing receptors at the synapse.
To examine this question further we tested the effect of
Mg2+ on NMDAR EPSCs at P12, P21, and P40.
Figure 5A shows evoked EPSCs
at P12 and P21, normalized to the peak of the non-NMDAR component and
superimposed to allow comparison of the NMDAR components.
Mg2+ produced a concentration-dependent
block of the NMDAR EPSC. The degree of block produced by 0.03 and 0.1 mM Mg2+ was greater
at P12 than at P21. We estimated the mean charge transfer carried by
synaptic NMDARs by integrating NMDAR EPSCs (see Materials and Methods).
Charge transfer was determined over a range of
Mg2+ concentrations (0.01-2
mM); the inhibition curves obtained from this
analysis are depicted in Figure 5B. These were fitted by the
Hill equation and had a single component. At P21, there was an
approximately threefold shift in the IC50
toward higher Mg2+ concentrations. The
mean IC50 values were 28 ± 2 µM at P12, and 76 ± 8 µM at P21: these were significantly different
(p < 0.05).
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|
Figure 5.
Age-dependent change in sensitivity of the NMDAR
EPSC to Mg2+. A, Evoked EPSCs at P12
(top panel) and P21 (bottom
panel), recorded in control medium (no added
Mg2+) and in the presence of Mg2+
(0.03 and 0.1 mM), and in 0 Mg2+ plus
AP-5 and 7-CK (holding potential, 80 mV). Average traces, obtained at
different Mg2+ concentrations were normalized to the
peak and superimposed to allow a direct comparison of the
dose-dependent inhibition of NMDAR EPSCs induced by
Mg2+. For clarity only two Mg2+
concentrations are depicted at each age (0.03 mM, 0.1 mM). At the end of each experiment 50 µM AP-5
and 50 µM 7-CK were applied to abolish any residual
NMDAR-component. The remaining EPSC (the non-NMDAR-component) was
subtracted from the traces to allow a direct estimate of charge
transfer carried by the NMDAR-component. B,
Mg2+ inhibition curve for NMDAR EPSCs. The mean
charge transfer was estimated for each Mg2+
concentration: 0.01 mM (n = 6 at P12;
n = 4 at P21), 0.03 mM
(n = 5 at p12; n = 10 at P21),
0.1 mM (n = 5 at P12;
n = 10 at P21; n = 4 at P40),
0.3 mM (n = 11 at P12,
n = 11 at P21), and 2 mM
(n = 6 at P12; n = 6 at P21).
The NMDAR EPSC, expressed as a percentage of control, was plotted
versus Mg2+ concentration. Both curves were best
fitted by the Hill equation (black curve). The
IC50 values derived from the fit were 28 ± 2 µM at P12 and 76 ± 8 µM at P21
(p < 0.05).
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|
We also examined granule cells at P40. Because of the difficulty in
recording from P40 cells for the time required to construct a full
inhibition curve we examined the effect of a single
Mg2+ concentration, chosen to fall
approximately on the midpoint of the curve. A concentration of 0.1 mM Mg2+ produced 37 ± 7% inhibition of NMDAR EPSCs (n = 4; Fig.
5B). This degree of inhibition was not significantly
different from that observed at P21 for the same
Mg2+ concentration, indicating that the
Mg2+ sensitivity of NMDAR EPSCs exhibited
little further change with age. The reduced
Mg2+ sensitivity, observed from P21
onward, together with the increased duration of the NMDAR EPSC at P40,
suggests that NR2C subunits make a major contribution to the properties
of the NMDAR EPSCs at the mature mossy fiber-granule cell synapse.
| |
DISCUSSION |
Our experiments have identified distinct changes in the functional
and pharmacological properties of NMDAR EPSCs at the mossy fiber-granule cell synapse. These observations have several broad implications for the role of NMDARs in granule cells, particularly with
respect to the influence of the NR2C subunit at the mature synapse.
First, we find functional evidence for the early loss of NR2B and
insertion of NR2A subunits. Second, our observations demonstrate a
pronounced slowing in time course of the NMDAR EPSC in the mature cells
consistent with incorporation of the NR2C subunit. Third, our results
suggest that the influence of the NR2C subunit on the
Mg2+ sensitivity of synaptic NMDARs
precedes its effects on NMDAR decay kinetics. These various aspects are
considered below.
Our experiments indicate that during the first postnatal week the
properties of NMDAR EPSCs in granule cells are governed by the NR2B
subunit. By the second postnatal week, the speeding up of the NMDAR
EPSC, together with the increased TPEN sensitivity and decreased
ifenprodil sensitivity, suggests an increasing contribution from the
NR2A subunit. These changes in kinetic and pharmacological properties
correlate well with the known changes in mRNA expression pattern within
the cerebellum (Akazawa et al., 1994; Monyer et al., 1994; Watanabe et
al., 1994). Furthermore, they resemble the developmental switch from
NR2B to NR2A that occurs at a number of central synapses in early CNS
development, resulting in shortening of the NMDAR EPSC (Quinlan et al.,
1999; Roberts and Ramoa, 1999; Rumbaugh and Vicini, 1999; Tovar
and Westbrook, 1999).
Our data indicate that the NR2A subunit, along with the NR2B subunit,
contribute to synaptic NMDARs soon after synapse formation (from P7).
Indeed, we found that, whereas ifenprodil markedly reduced NMDAR EPSC
amplitude at the end of the first postnatal week, the magnitude of
block was less than expected if NR2B was the only NR2 subunit present
(Tovar and Westbrook, 1999). The progressive reduction in ifenprodil
sensitivity, to low levels by the end of the third postnatal week,
indicate a gradual switch from NR2B to NR2A at the immature granule
cell synapse. It is not clear whether this pharmacological change and
acceleration of the NMDAR EPSC reflects an increase in the relative
proportion of NR1/NR2A receptors (with concomitant decrease in NR1/NR2B
receptors), or the formation of triheteromeric NR1/NR2A/NR2B receptors
(Vicini et al., 1998), or a mixture of both diheteromeric and
triheteromeric assemblies. Interestingly, the presence of highly
ifenprodil-sensitive (NR1/NR2B receptors) extrasynaptic NMDARs together
with a population of less ifenprodil-sensitive synaptic receptors in
hippocampal cells, had led to the suggestion that diheteromeric and
triheteromeric (NR1/NR2A/NR2B) can coexist within cells (Tovar and
Westbrook, 1999). The age-dependent reduction in ifenprodil sensitivity
that we observed for extrasynaptic receptors was comparable to that seen at the synapse. This contrasts with the results of Rumbaugh and
Vicini (1999), obtained using another NR2B-selective antagonist (CP
101,606), who have suggested that the loss of NR2B-containing NMDARs
occurs more rapidly at the synapse. The reason for this difference is
not clear.
Cerebellar granule cells express high levels of mRNA for the NR2C
subunit in rats older than ~P11 (Akazawa et al., 1994; Watanabe et
al., 1994). Furthermore, somatic patches from >P19 granule cells give
rise to channel openings with the characteristically low single-channel
conductance typical of NR2C-containing receptors (~18 and 35 pS;
Farrant et al., 1994). Experiments on knock-out mice (Ebralidze et al.,
1996; Kadotani et al., 1996; Takahashi et al., 1996) have suggested
that the NR2A and NR2C subunits are present at the mossy fiber synapse
at the end of the third postnatal week. Paradoxically, however,
previous studies have suggested that the decay time of the NMDAR EPSC
is fast regardless of the presence of the NR2C subunit. We now find
that at the mature synapse (P40), when the level of NR2C is likely to
be high (Monyer et al., 1994) the decay kinetics of the NMDAR
EPSC has become slow. As the decay kinetics matched well to the
deactivation time of recombinant NR1/NR2C receptors, it seems likely
that these receptors predominate at the mature synapse.
Despite the relatively late change in the time course of the NMDAR
EPSC, a shift in IC50 for
Mg2+ was apparent by the end of the third
postnatal week. This is consistent with the reduced voltage dependence
of block that we previously observed in 3-week-old mice (Takahashi et
al., 1996). However, the change in Mg2+
sensitivity obtained in the present study is less than that described for recombinant NR1/NR2C receptors. In heterologous expression systems
the IC50 for Mg 2+
block of NR1/NR2C receptors was approximately six times greater than
for NR1/NR2A or NR1/NR2B assemblies
(VH = 80 mV; Kuner and Schoepfer,
1996), compared with our threefold shift. It is of note that when NR2A
and NR2C subunits are coexpressed (together with NR1) they exhibit a
sensitivity to Mg2+ that is appreciably
less than for the NR1/NR2A assemblies (Chazot et al., 1994). Indeed,
biochemical studies have suggested that coexpression of NR2A and NR2C
subunits gives rise to receptors that display a
Mg2+ sensitivity comparable to that of
native cerebellar NMDARs from adult mice (Chazot et al., 1994). It is
therefore an attractive possibility that the intermediate
IC50 that we observe may reflect the presence of
triheteromeric NR1/NR2A/NR2C assemblies at the mossy fiber synapse.
However, it would be difficult to distinguish between this and the
presence of a mixed population of NR2A- and NR2C-containing receptors,
especially as it is unclear whether such native receptors would behave
in a manner identical to their recombinant counterparts.
The reason why the reduction in Mg2+
sensitivity preceded the change in decay kinetics is unclear. One
possibility is that a low level of NR2C subunits is sufficient to
produce triheteromeric assemblies that may have a reduced
Mg2+ sensitivity but still exhibit rapid
decay kinetics. On the other hand a higher proportion of NR2C may
generate sufficient diheteromeric NR1/NR2C assemblies for these to
dictate the overall decay time of the NMDAR EPSC. Indeed, there is
evidence that the NR2A protein level in granule cells decreases between
the third postnatal week and adulthood, whereas the NR2C protein level
remains high (Wenzel et al., 1997). This would be consistent with such
an interpretation and with the idea that an increased proportion of
NR1/NR2C receptors is the primary cause of the slow decay of the mature
NMDAR EPSC.
What are the functional consequences of the change in subunit
composition of NMDARs at the mossy fiber synapse? NMDARs are critical
in triggering activity-dependent synaptic modification (for review, see
Gustafsson and Wigstrom, 1988; Malenka and Nicoll, 1999). Developmental
changes in receptor expression are therefore likely to have a marked
influence on the properties of synaptic plasticity. Many of the
cellular functions performed by NMDARs depend on the fact that the open
NMDAR channel generates a substantial inward
Ca2+ current, activating second messengers
and intracellular enzymes (MacDermott et al., 1986; Ascher and Nowak,
1988; Jahr and Stevens, 1993; Dingledine et al., 1999). Although
NMDAR-dependent long-term potentiation has been identified at the mossy
fiber input (D'Angelo et al., 1999), it remains to be seen how the
changes in channel kinetics and Mg2+
sensitivity influence the coincidence detection behavior of the synaptic NMDARs at the mature synapse. In the visual cortex, the experience-dependent acceleration of the NMDAR EPSC, which occurs during development, results from a switch between NR2B- and
NR2A-containing NMDARs (Quinlan et al., 1999) and correlates with a
modification in the long-term depression/long-term potentiation
threshold, making long-term depression more likely (Kirkwood et al.,
1996). It will be of interest to see whether a developmental
modification of long-term changes also occurs at granule cell synapses.
Recent studies have indicated that both native NR1/NR2C- and NR1/NR2D
receptors (like their recombinant counterparts) give rise to channels
with unique properties. These include a low conductance and a low
sensitivity to block by Mg2+ ions, when
compared with "conventional" NMDARs (Momiyama et al., 1996;
Cull-Candy et al., 1998). If present at synapses, these receptors could
therefore operate as "low-threshold" NMDAR channels, because their
weak Mg2+ block would be more readily
alleviated by membrane depolarization. Despite the widespread
occurrence of functional NR2D-containing NMDARs in the extrasynaptic
membrane of neurons, there is little direct evidence that NR1/NR2D
receptors are targeted to synaptic sites (Bardoni et al., 1998; Misra
et al., 2000a). Indeed, there are no reports of synaptic responses with
decay times comparable to the deactivation rate for native NR1/NR2D
receptors (Misra et al., 2000b). It is therefore of particular interest
that the other type of NR2 subunit giving rise to low-conductance
channels appears to determine key properties of the NMDAR EPSCs in
mature granule cells.
| |
FOOTNOTES |
Received March 8, 2000; revised May 10, 2000; accepted May 19, 2000.
This work was supported by the Wellcome Trust. L.C. gratefully
acknowledges receipt of a Wellcome Travelling Fellowship, and C.M.
gratefully acknowledges receipt of a Wellcome Prize Fellowship. We
thank Stephen Brickley, Beverley Clark, and Mark Farrant for valuable
discussions and comments on this manuscript.
Correspondence should be addressed to Stuart Cull-Candy, University
College London, Gower Street, London WC1E 6BT, UK. E-mail: s.cull-candy{at}ucl.ac.uk.
| |
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P. B. Sargent, C. Saviane, T. A. Nielsen, D. A. DiGregorio, and R. A. Silver
Rapid Vesicular Release, Quantal Variability, and Spillover Contribute to the Precision and Reliability of Transmission at a Glomerular Synapse
J. Neurosci.,
September 7, 2005;
25(36):
8173 - 8187.
[Abstract]
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H.-H. Chen, C.-T. Wei, Y.-R. Lin, T.-H. Chien, and M.-H. Chan
Neonatal Toluene Exposure Alters Agonist and Antagonist Sensitivity and NR2B Subunit Expression of NMDA Receptors in Cultured Cerebellar Granule Neurons
Toxicol. Sci.,
May 1, 2005;
85(1):
666 - 674.
[Abstract]
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Q. Liu and M. T. T. Wong-Riley
Postnatal developmental expressions of neurotransmitters and receptors in various brain stem nuclei of rats
J Appl Physiol,
April 1, 2005;
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[Abstract]
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Z. Fu, S. M Logan, and S. Vicini
Deletion of the NR2A subunit prevents developmental changes of NMDA-mEPSCs in cultured mouse cerebellar granule neurones
J. Physiol.,
March 15, 2005;
563(3):
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[Abstract]
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S. G. Cull-Candy and D. N. Leszkiewicz
Role of Distinct NMDA Receptor Subtypes at Central Synapses
Sci. Signal.,
October 19, 2004;
2004(255):
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[Abstract]
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K. J. Todd, C. A. B. Slatter, and D. W. Ali
Activation of Ionotropic Glutamate Receptors on Peripheral Axons of Primary Motoneurons Mediates Transmitter Release at the Zebrafish NMJ
J Neurophysiol,
February 1, 2004;
91(2):
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[Abstract]
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L. Cathala, S. Brickley, S. Cull-Candy, and M. Farrant
Maturation of EPSCs and Intrinsic Membrane Properties Enhances Precision at a Cerebellar Synapse
J. Neurosci.,
July 9, 2003;
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[Abstract]
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S. G. Brickley, C. Misra, M. H. S. Mok, M. Mishina, and S. G. Cull-Candy
NR2B and NR2D Subunits Coassemble in Cerebellar Golgi Cells to Form a Distinct NMDA Receptor Subtype Restricted to Extrasynaptic Sites
J. Neurosci.,
June 15, 2003;
23(12):
4958 - 4966.
[Abstract]
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C. Szinyei, O. Stork, and H.-C. Pape
Contribution of NR2B Subunits to Synaptic Transmission in Amygdaloid Interneurons
J. Neurosci.,
April 1, 2003;
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[Abstract]
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G. Losi, K. Prybylowski, Z. Fu, J. Luo, R. J Wenthold, and S. Vicini
PSD-95 regulates NMDA receptors in developing cerebellar granule neurons of the rat
J. Physiol.,
April 1, 2003;
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[Abstract]
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D. E. Chapman, K. A. Keefe, and K. S. Wilcox
Evidence for Functionally Distinct Synaptic NMDA Receptors in Ventromedial Versus Dorsolateral Striatum
J Neurophysiol,
January 1, 2003;
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[Abstract]
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P. Rossi, E. Sola, V. Taglietti, T. Borchardt, F. Steigerwald, J. K. Utvik, O. P. Ottersen, G. Kohr, and E. D'Angelo
NMDA Receptor 2 (NR2) C-Terminal Control of NR Open Probability Regulates Synaptic Transmission and Plasticity at a Cerebellar Synapse
J. Neurosci.,
November 15, 2002;
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I. Joshi and L.-Y. Wang
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J. Physiol.,
May 1, 2002;
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[Abstract]
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D. Billups, Y.-B. Liu, S. Birnstiel, and N. T. Slater
NMDA Receptor-Mediated Currents in Rat Cerebellar Granule and Unipolar Brush Cells
J Neurophysiol,
April 1, 2002;
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[Abstract]
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J. Nabekura, T. Ueno, S. Katsurabayashi, A. Furuta, N. Akaike, and M. Okada
Reduced NR2A expression and prolonged decay of NMDA receptor-mediated synaptic current in rat vagal motoneurons following axotomy
J. Physiol.,
March 15, 2002;
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[Abstract]
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G. Losi, K. Prybylowski, Z. Fu, J. H. Luo, and S. Vicini
Silent Synapses in Developing Cerebellar Granule Neurons
J Neurophysiol,
March 1, 2002;
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[Abstract]
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G. Abdrachmanova, J. Teisinger, and L. Vyklicky Jr
Axotomy-induced changes in the properties of NMDA receptor channels in rat spinal cord motoneurons
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January 1, 2002;
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K. Futai, M. Okada, K. Matsuyama, and T. Takahashi
High-Fidelity Transmission Acquired via a Developmental Decrease in NMDA Receptor Expression at an Auditory Synapse
J. Neurosci.,
May 15, 2001;
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[Abstract]
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G. Abdrachmanova, J. Teisinger, and L. Vyklicky Jr
Axotomy-induced changes in the properties of NMDA receptor channels in rat spinal cord motoneurons
J. Physiol.,
January 1, 2002;
538(1):
53 - 63.
[Abstract]
[Full Text]
[PDF]
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J. Nabekura, T. Ueno, S. Katsurabayashi, A. Furuta, N. Akaike, and M. Okada
Reduced NR2A expression and prolonged decay of NMDA receptor-mediated synaptic current in rat vagal motoneurons following axotomy
J. Physiol.,
March 15, 2002;
539(3):
735 - 741.
[Abstract]
[Full Text]
[PDF]
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I. Joshi and L.-Y. Wang
Developmental profiles of glutamate receptors and synaptic transmission at a single synapse in the mouse auditory brainstem
J. Physiol.,
May 1, 2002;
540(3):
861 - 873.
[Abstract]
[Full Text]
[PDF]
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TOP
ABSTRACT
INTRODUCTION
