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The Journal of Neuroscience, March 15, 1998, 18(6):1935-1943
Developmental Changes in NMDA Receptor Glycine Affinity and
Ifenprodil Sensitivity Reveal Three Distinct Populations of NMDA
Receptors in Individual Rat Cortical Neurons
James N. C.
Kew,
J. Grayson
Richards,
Vincent
Mutel, and
John A.
Kemp
Pharma Division, Preclinical CNS Research, F. Hoffmann-La Roche
Ltd., CH-4070 Basel, Switzerland
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ABSTRACT |
Previous work with recombinant receptors has shown that the
identity of the NMDA NR2 subunit influences receptor affinity for both
glutamate and glycine. We have investigated the developmental change in
NMDA receptor affinity for both glutamate and glycine in acutely
dissociated parietal cortex neurons of the rat, together with the
expression during ontogeny of NR2A and NR2B mRNA and protein. Whereas
there is little change in NMDA receptor glutamate affinity with age, a
population of NMDA receptors emerges in 14- and 28-d-old animals with a
markedly reduced affinity for glycine (mKD = ~800 nM) and a reduced sensitivity to the NR2B
subunit-selective NMDA antagonist ifenprodil. These changes are
paralleled by a developmental increase in the expression of NR2A. Thus,
in mature animals a population of NMDA receptors appears with a lower
affinity for glycine that might not be saturated under normal
physiological conditions. Ifenprodil (10 µM) inhibits
virtually all of the NMDA receptor-evoked current in very young neurons
that contain a single population of receptors exhibiting a high
affinity for glycine (mKD = ~20
nM). In older neurons, which contain NMDA receptors with
both high and low affinities for glycine, ifenprodil (10 µM) inhibits both the high-affinity population and a
significant proportion of the low-affinity component, thus revealing
three pharmacologically distinct populations of NMDA receptors in
single neurons. Moreover, these observations suggest that ifenprodil might bind with high affinity to NMDA receptors containing both NR2A
and NR2B subunits as well as those containing only NR2B.
Key words:
NMDA receptor; glycine; ifenprodil; NMDA receptor
subtype; glutamate receptor; NR2A; NR2B
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INTRODUCTION |
The NMDA receptor is unique among
ligand-gated ion channels in its requirement for two co-agonists,
acting at the glutamate and glycine recognition sites, for receptor
activation (Johnson and Ascher, 1987 ; Kleckner and Dingledine, 1988).
The physiological role of the glycine site in the regulation of NMDA
receptor activity remains unclear. Whereas both co-agonists are
required for receptor activation, it is glutamate that appears to play
the neurotransmitter role, being released from presynaptic terminals in
an activity-dependent manner, whereas glycine is apparently present at
a more constant level, indicating a more modulatory function (for
review, see Kemp and Leeson, 1993). Measurements of glycine
concentration in the extracellular and cerebrospinal fluids suggest
that it is present at low micromolar levels (Westergren et al., 1994), concentrations that have been considered saturating for NMDA
receptors.
A number of groups have investigated the effects of application of
exogenous glycine on NMDA-mediated responses both in vivo and in brain slices in vitro. Several studies failed to
observe any potentiation of NMDA responses (Fletcher and Lodge, 1988; Kemp et al., 1988; Llano et al., 1988; Obrenovitch et al., 1997), suggesting that the levels of glycine were indeed saturating. However,
others have observed positive modulation of NMDA-evoked responses,
indicating that the glycine site may not be fully saturated (Danysz et
al., 1989; Thomson et al., 1989; Wood et al., 1989; Singh et al., 1990;
Wilcox et al., 1996). Notably, the glycine transporter GLYT-1 is
expressed in forebrain regions where no inhibitory glycinergic neurons
have been detected (Smith et al., 1992, Borowsky et al., 1993, Zafra et
al., 1995), indicating a possible role in the regulation of NMDA
receptor-mediated neurotransmission.
Receptor cloning studies have identified several NMDA receptor
subunits, NMDA receptor 1 (NMDAR1), of which eight splice variants have
been described, and four NR2 subunits, A-D, which are believed to
assemble in various combinations to generate heteromeric complexes predicted to contain four (Laube et al., 1997) or five subunits (for
review, see McBain and Mayer, 1994). NMDAR1 is believed to be an
obligate component of functional receptors, because NR2 subunits are
unable to form functional NMDA receptors when expressed alone. However,
co-expression of NMDAR1 with one or more of the NR2 subunits readily
generates receptors with distinct functional and pharmacological
properties that appear to best resemble native receptors (Kutsuwada et
al., 1992; Monyer et al., 1992). The NR2 subunits are expressed
differentially in a spatiotemporal manner (for review, see McBain and
Mayer, 1994), which together with the differential expression of the
NMDAR1 isoforms suggests the existence of a variety of native NMDA
receptors. In the forebrain, the predominant NR2 subunits are NR2A and
NR2B, and thus, the most abundant heteromeric receptor combinations are
likely to be NMDAR1-NR2A, NMDAR1-NR2B, and, possibly,
three-subunit-containing NMDAR1-NR2A-NR2B receptors (Sheng et al.,
1994, Luo et al., 1997). Notably, recombinant NMDAR1-NR2A receptors
exhibit ~10-fold lower affinity for glycine and ~400-fold lower
affinity for the noncompetitive antagonist ifenprodil, relative to
NMDAR1-NR2B receptors (Kutsuwada et al., 1992; Williams, 1993;
Priestley et al., 1995); however, the pharmacological properties of
NMDAR1-NR2A-NR2B receptors are unknown.
Using whole-cell patch-clamp recordings, we have examined NMDA receptor
affinity for both glutamate and glycine in acutely dissociated rat
cortical neurones from 2- to 3-, 14- to 15-, and 27- to 29-d-old
animals. We have also examined the expression of NR2A and NR2B mRNA and
protein at these time points by in situ hybridization
histochemistry and Western blot analysis and investigated the
sensitivity of the receptors to the NR2B subunit-selective NMDA
receptor antagonist ifenprodil.
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MATERIALS AND METHODS |
Acute cortical neuronal dissociation
Brain slices (450 µm) from 2- to 3-, 14- to 15-, or 27- to
29-d-old rats (Roro specific pathogen-free (spf) 120) were cut with a vibratome in an ice-cold solution that contained (in
mM): NaCl 125, KCl 2.5, CaCl2 2, MgCl2 1, NaH2PO4 1.25, NaHCO3 26, and D-glucose 25, pH adjusted to 7.4 with oxycarbon (95% O2 and 5% CO2),
and were subsequently incubated at 20°C in the same solution. All
reagents were obtained from Sigma (St. Louis, MO) unless stated otherwise. When neurons were needed for electrophysiological
experiments, the parietal cortex was dissected out of each slice and
treated for 10 min at 37°C with a solution containing (in
mM): Na2SO4 82, K2SO4 30, MgCl2 3, and HEPES 2, and
1 mg/ml papain, pH adjusted to 7.4 with NaOH. The cortex was then
dissected into small (1-2 mm2) pieces and washed in
an identical solution without papain, and neurons were isolated by
gentle trituration with a Pasteur pipette with a narrow flame-polished
tip in an identical solution. Neurons were then plated on
poly-L-ornithine (1 mg/ml in H20)-coated glass coverslips.
Whole-cell voltage-clamp recordings
Whole-cell voltage-clamp recordings were performed as described
previously (Kew et al., 1996). Neurons were continuously perfused with
a simple salt solution (in mM: NaCl 149, KCl 3.25, CaCl2 2, MgCl2 2, HEPES 10, and
D-glucose 11, pH adjusted to 7.35 with NaOH and osmolarity
adjusted to 350 mOsm using sucrose). Patch pipettes were pulled from
thin-walled borosilicate glass (GC150TF; Clark Electromedical
Instruments, Pangbourne, UK) using a DMZ universal electrode puller.
Pipettes had resistances of ~2-4 M when filled with patch pipette
solution (in mM: CsF 120, CsCl 10, EGTA 11, CaCl2 0.5, and HEPES 10, pH adjusted to 7.25 with CsOH and
osmolarity adjusted to 330 mOsm with sucrose). Whole-cell current
recordings were made from neurons at a holding potential of  60 mV
using an Axopatch 200A amplifier (Axon Instruments, Foster City, CA).
Pipette seal resistances were typically >10 G, and pipette
capacitance transients were minimized both before and after membrane
breakthrough. No series resistance compensation was applied. Drugs were
diluted from concentrated stock solutions into a modified version of
the salt solution used to perfuse the culture that lacked
MgCl2. Drugs were applied to cells by fast perfusion from a
double- or triple-barreled capillary assembly composed of large-tipped
(~350 µm) capillaries with an internal diameter of 320 µm.
Solution equilibration times were determined by stepping from a
solution of kainate (100 µM) in 10 mM NaCl to
one containing 149 mM NaCl. The mean ± SE time
constant of the exponential increase in membrane current after such a
step was 29.2 ± 1.5 msec (Kew et al., 1996). Ifenprodil was
obtained from Synthelabo Recherche (Bagneux, France).
Equilibrium concentration-response curves
Best fit lines were computed for equilibrium
concentration-response data using a two-equivalent binding site model
for monophasic fits:
![I=I<SUB><UP>max</UP></SUB>/(1+(mK<SUB><UP><SC>d</SC></UP></SUB>/[A]))<SUP>2</SUP>](/content/vol18/issue6/fulltext/1935/img001.gif)
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(1)
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where mKD is the microscopic dissociation
constant, and [A] is the agonist concentration. Data were
fitted with a 2 × 2 equivalent binding site model for biphasic
fits:
![I=I<SUB><UP>max</UP>(<UP><SC>h</SC></UP>)</SUB>/(1+(mK<SUB><UP><SC>d</SC></UP>(<UP><SC>h</SC></UP>)</SUB>/[A]))<SUP>2</SUP>+I<SUB><UP>max</UP>(<UP><SC>l</SC></UP>)</SUB>/(1+(mK<SUB><UP><SC>d</SC></UP>(<UP><SC>l</SC></UP>)</SUB>/[A]))<SUP>2</SUP>](/content/vol18/issue6/fulltext/1935/img002.gif)
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(2)
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where Imax(H) and
Imax(L) are the current amplitudes of the high-
and low-affinity components of the concentration-response curve, and
mKD(H) and mKD(L) are the
microscopic dissociation constants for the high- and low-affinity
components of the curve.
A baseline contamination of glycine was present in all solutions,
illustrated by a consistent, small response evoked by the application
of NMDA in the absence of added glycine. To correct for this glycine
contamination, glycine concentration-response data for each neuron
were initially fitted with a modified version of either the
two-equivalent binding site model:
![I=I<SUB><UP>max</UP></SUB>/(1+(mK<SUB><UP><SC>d</SC></UP></SUB>/[A+g]))<SUP>2</SUP>](/content/vol18/issue6/fulltext/1935/img003.gif)
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(3)
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or the 2 × 2 equivalent binding site model:
![I=I<SUB><UP>max<SC>h</SC></UP></SUB>/(1+(mK<SUB><UP><SC>d</SC></UP>(<UP><SC>h</SC></UP>)</SUB>/[A+g]))<SUP>2</SUP>+I<SUB><UP>max<SC>l</SC></UP></SUB>/(1+(mK<SUB><UP><SC>d</SC></UP>(<UP><SC>l</SC></UP>)</SUB>/[A]))<SUP>2</SUP>](/content/vol18/issue6/fulltext/1935/img004.gif)
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(4)
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incorporating a variable, g, representing the basal
contaminating glycine concentration. For the 2 × 2 equivalent
binding site model, the variable g is only included in the
term defining the high-affinity interaction, in which the effects of
the contaminating glycine are most pronounced.
The derived contaminating glycine concentration was then added to each
glycine concentration used in the concentration-response curve to give
the true glycine concentrations. The concentration-response curve was
then replotted using the true glycine concentrations and fitted with
the appropriate equation excluding the term for the contaminating
glycine (g) (i.e., Eq. 1 or 2). Plotting the current evoked by NMDA in the absence of added glycine against the
predicted contaminating glycine concentration provided a control for
the accuracy of this correction procedure. The mean calculated contaminating glycine concentration was 20 ± 2 nM
(mean ± SE; n = 24). Affinity estimates are
quoted either as the apparent microscopic dissociation constant
(mKD) or as the corresponding negative
logarithm (pmKD) to enable statistical
analysis of the data.
Inhibition curves
Inhibition curves were fitted according to a modified version of
the Hill equation with baseline, which describes a two-binding site
isotherm:
![I=I<SUB><UP>max</UP>(<UP><SC>h</SC></UP>)</SUB>/(1+([A]/<UP>IC</UP><SUB><UP>50</UP>(<UP><SC>h</SC></UP>)</SUB>)<SUP>s(<UP><SC>h</SC></UP>)</SUP>)+I<SUB><UP>max</UP>(<UP><SC>l</SC></UP>)</SUB>/(1+([A]/<UP>IC</UP><SUB><UP>50</UP>(<UP><SC>l</SC></UP>)</SUB>)<SUP>s(<UP><SC>l</SC></UP>)</SUP>)+(100−I<SUB><UP>max</UP>(<UP><SC>h</SC></UP>)</SUB>−I<SUB><UP>max</UP>(<UP><SC>l</SC></UP>)</SUB>)](/content/vol18/issue6/fulltext/1935/img005.gif)
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(5)
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where Imax(H) and
Imax(L) are the relative percentages of the
high- and low-affinity components of the antagonism, [A]
is the antagonist concentration, IC50(H) and
IC50(L) are the concentrations of antagonist required to
reduce the agonist response to 50% of the control value for each
component of the curve, and s(H) and s(L) are the
slopes of the fitted lines for the high- and low-affinity components,
respectively.
Exponential curve fitting
Neuronal currents were filtered (cutoff frequency, 5 kHz),
digitized using a Digidata 1200 (Axon Instruments), and captured on-line to the hard disk of a Gateway 2000 P4D-66 computer using Axoscope software (Axon Instruments). Jumps into and out of 1 mM 7-chlorokynurenic acid (Research Biochemicals, Natick,
MA) were performed three times for each cell and averaged using
Axoscope software. All curves were fitted using GraphPad Prism software (GraphPad Software, San Diego, CA). The recovery of the steady-state current after the rapid removal of 7-chlorokynurenic acid was best
fitted by a curve-fitting model assuming that channel gating requires
the binding of two agonist molecules to two equivalent sites according
to the equation:
where B0 is the current baseline before
the start, A is the current response amplitude, t
is time, and  is the time constant for agonist occupation
of each independent site.
In situ hybridization analysis
Tissue preparation. Rat brains were rapidly dissected
from halothane-anesthetized 3-, 14-, or 28-d-old Roro spf 120 rats and immediately frozen in dry ice. Parasagittal cryostat sections (~12
µm thick) of brain were mounted on Superfrost Plus slides (Menzel-Gläser) and fixed in 4% paraformaldehyde (in PBS, pH 7.4) for 20 min, followed by three 5 min washes in PBS.
Probe labeling. Oligodeoxyribonucleotide probes, prepared on
a DNA synthesizer (Genosys Biotechnologies) complementary to the rat
NR2A and NR2B subunit cDNAs (bp 69  10 and 86 27, respectively (Monyer et al., 1992)), were used. The oligomers were
labeled at the 3' end with terminal deoxynucleotidyl-transferase (Life
Technologies, Basel, Switzerland) and [35S]dATP
(New England Nuclear, Boston, MA). The reaction mixture (50 µl total)
contained 5.5 µl of [35S]dATP, 10 µl of
tailing buffer (Life Technologies; in mM: potassium cacodylate 500, pH 7.2, CoCl2 10, and dithiothreitol 1), 1 µl of oligomer (100 ng/ml), 1 µl of bovine serum albumin (2 mg/ml, RNase- and DNase-free), 6.5 µl of terminal deoxynucleotidyl
transferase (Life Technologies; 15 U/µl) and 26 µl of
H2O. The mixture was transferred to 37°C for 5 min, and
then the reaction was stopped by adding 5 µl of EDTA (0.5 M) and transferring the mixture to 75°C for 10 min. The
labeled probes were separated from unincorporated nucleotides with a
Biogel P30 spun column (Bio-Rad, Glattbrugg, Switzerland; 2 × 4 min at 1600 × g).
In situ hybridization histochemistry
Sections were hybridized with 50 µl of a solution with the
following constituents: 4× SSC, 20% dextran sulfate, 0.25 mg/ml tRNA
(Boehringer Mannheim, Mannheim, Germany), 0.25 mg/ml salmon testes
DNA, 50% deionized formamide (Bethesda Research Laboratories, Bethesda, MD), 0.1 M dithiothreitol (Fluka, Buchs,
Switzerland), 0.5× Denhard's solution, and 35S-labeled
probe (3 × 105 cpm). Sections covered with
strips of Fujifilm were incubated in a humid chamber at 43°C for
20-24 hr. After removal of the strips, the sections were washed twice
in a solution containing 1× SSC and 10 mM dithiothreitol
for 15 min each at 55°C, then twice in 0.5× SSC and 10 mM dithiothreitol for 15 min each at 55°C, and then
finally once in 0.5× SSC and 10 mM dithiothreitol for 15 min at room temperature. After a dip in double-distilled water,
sections were dehydrated in ethanol and exposed for up to 4 weeks at
4°C to sheet film (Hyperfilm,  -Max; Amersham, Zürich, Switzerland) to reveal the regional localization of the mRNA. The film
was developed in Kodak PL12 then transferred to Kodak Rapid Fix. The
films were used as negatives to produce reverse images, i.e., white
areas revealing high levels of hybridization signal on a black
background. Densitometric analysis of hybridization signal in the
parietal cortex (four readings per cortex from four sections per
parameter) was performed using a computer-assisted image analyzer
(MCID-M2; Imaging Research Inc., St. Catherine's, Ontario,
Canada).
Western blot analysis
Membrane preparation. Parietal cortices were
dissected from 3-, 14-, or 28-d-old Roro spf 120 rats and were
homogenized with a Polytron (14,000 rpm; Kinematica AG, Littau,
Switzerland) at 4°C in 100 volumes (w/v) of Tris-HCl, 10 mM; and sucrose, 0.32 M, pH 7.4. The homogenate
was then centrifuged at 700 × g for 10 min at 4°C.
The resulting pellet was rehomogenized, as above, and the homogenate
was spun down. The supernatants from the two centrifugations were
combined and centrifuged at 37,000 × g for 40 min at
4°C. The pellet was then resuspended in the same volume of Tris-HCl,
10 mM, pH 7.4, and the preparation was frozen at 80°C.
Membrane solubilization. After thawing, the membranes were
centrifuged at 20,000 × g for 10 min at 4°C, and the
pellets were solubilized in a buffer containing HEPES, 20 mM; NaCl, 150 mM; MgCl2, 1.5 mM; EGTA, 1 mM; glycerol, 10%; Triton X-100,
1%; SDS, 0.1%; leupeptin, 10 µg/ml; PMSF, 1 mM; and
aprotinin, 10 µg/ml, pH 7.5. The lysates were sonicated and incubated
for 1 hr at 4°C. After centrifugation at 26,000 × g
for 20 min at 4°C, the protein concentration was determined in an
aliquot of each preparation using the BCA method (Pierce, Socochim,
Lausanne, Switzerland) with bovine serum albumin as standard.
Western blot. The individual lysates were diluted in a
Laemmli buffer (Tris-HCl, 250 mM; SDS, 4%; glycerol, 20%;
bromophenol blue, 0.06 mg/ml; and dithiothreitol, 0.1 M, pH
6.8) to the same final protein concentration and heated for 5 min at
95°C. Ten micrograms of membrane protein were separated by gel
electrophoresis using a 7.5% acrylamide gel and blotted overnight onto
a nitrocellulose filter (0.2 µm, Bio-Rad). Prestained broad-range
SDS-PAGE standards (Bio-Rad) were run on each gel. The filters were
blocked in PBS containing 5% skimmed milk powder and incubated with a
solution containing 1 mg/ml of an antibody to NR2A (AB 1555P; Chemicon, Luzern, Switzerland) or 1 mg/ml of an antibody to NR2B (AB 1557P, Chemicon). After washing, the filter was incubated in horseradish peroxidase-conjugated goat anti-rabbit Ig (1:3000), washed, and developed to reveal bound antibody using an ECL kit (Amersham). A
standard curve, made with a gradient of protein from cortices of
28-d-old rat brains, was run in parallel to calibrate the samples. Films were scanned with a Hewlett Packard ScanJet 4C scanner and subsequently analyzed by measuring optical densities of the
immunostained bands on the film using one-dimensional image analysis
software (Kodak Digital Science). Densitometric values for the
experimental rat brain samples were always within the range of values
encompassed by the standard curve.
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RESULTS |
Developmental change in NMDA receptor glycine affinity
Glycine and glutamate concentration-response curves were performed
using whole-cell voltage-clamp recordings from acutely dissociated rat
cortical neurons prepared from 2- to 3-, 14- to 15-, and 27- to
29-d-old rats. Glycine concentration-response curves were constructed
by jumping rapidly from a control solution to one containing 100 µM NMDA in the presence of increasing concentrations of
glycine in both the control and NMDA solutions. Neurons from 2- to
3-d-old animals consistently exhibited monophasic glycine concentration-response curves (Fig.
1A,B) with a mean
pmKD of 7.75 ± 0.06 (mean ± SE;
n = 8 neurons) and a maximum response at ~1
µM glycine. A plot of data from all neurons normalized to their respective individual 1 µM glycine response fitted
with the two-equivalent binding site model (Eq. 1) yielded an
mKD of 18 nM (Fig.
1C).
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Figure 1.
Glycine concentration-response curves from 2- to
3-d-old cortical neurons. A, Representative glycine
concentration-response data from a typical neuron. Inward currents
were elicited in response to 2 sec fast applications of 100 µM NMDA at 29 sec intervals (intervening sections of the
trace have been omitted for clarity) in the presence of increasing
concentrations of glycine. Applied glycine concentrations are shown.
The baseline glycine contamination was calculated as 23 nM.
Therefore, the true glycine concentration was calculated as the applied
glycine concentration plus 23 nM. B, Plot of
the glycine concentration-peak current response data from
A. Shown is a monophasic curve fitted with the
two-equivalent binding site model that yielded an
mKD of 31 nM. C,
Plot of the glycine concentration-response data from eight neurons.
Data from each neuron have been normalized to their respective
individual 1 µM glycine peak response. Shown is a curve
fitted with the two-equivalent binding site model that yielded an
mKD of 18 nM.
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Neurons from 27- to 29-d-old rats generated biphasic glycine
concentration-response curves (Fig.
2A-C). The mean
pmKD values of the high- and low-affinity
components were 7.40 ± 0.07 and 6.08 ± 0.08, respectively
(n = 8 cells), with the mean amplitudes of the high-
and low-affinity components of 53 ± 5 and 47 ± 5%, respectively. The proportion of the high-affinity component in individual neurons ranged from a minimum of 30 to a maximum of 75%.
Data from all neurons were normalized to their respective individual 30 µM glycine responses, plotted together, and fitted with
the 2 × 2 equivalent binding site model (Eq. 2), yielding high-
and low-affinity mKD values of 41 and 774 nM, respectively (Fig. 2C). Notably, the maximum
response was achieved with ~30 µM glycine, and 1 µM glycine elicited an ~60% maximal response (Fig.
2A-C). Thus, in 27- to 29-d-old animals a population
of NMDA receptors appears with a lower affinity for glycine (Fig. 2D).
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Figure 2.
Glycine concentration-response curves from 27- to
29-d-old cortical neurons reveal a low-affinity glycine component.
A, Representative glycine concentration-response data
from a typical neuron. Inward currents were elicited in response to 2 sec fast applications of 100 µM NMDA at 29 sec intervals
(intervening sections of the trace have been omitted for clarity) in
the presence of increasing concentrations of glycine. Applied glycine
concentrations are shown. The baseline glycine contamination was
calculated as 6 nM. Therefore, the true glycine
concentration was calculated as the applied glycine concentration plus
6 nM. B, Plot of the glycine concentration-peak current response data from A. Shown
is a biphasic curve fitted with the 2 × 2 equivalent binding site
model (solid line) that yielded
mKD values and relative amplitudes of 16 nM (30%) and 520 nM (70%) for the high- and
low-affinity components, respectively. A monophasic curve fitted with
the two-equivalent site model (broken line) is shown for
comparative purposes. C, Plot of the glycine
concentration-response data from eight neurons. Data from each neuron
have been normalized to their respective individual 30 µM
glycine peak response. Shown is a biphasic curve fitted with the 2 × 2 equivalent binding site model (solid line) that
yielded mKD values and relative amplitudes
of 41 nM (52%) and 774 nM (48%) for the high-
and low-affinity components, respectively. The biphasic fit was
significantly better than a monophasic fit using the two-equivalent
biding site model (broken line)
(p < 0.001, F test).
D, Comparison of glycine concentration-response data
from 2- to 3-d-old rats (open circles) and 27- to 29-d
old rats (closed circles). Data from each neuron have
been normalized to their respective individual 1 µM
glycine peak response.
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Fourteen- to 15-d-old animals yielded a mixed population of neurons,
most of which exhibited monophasic glycine concentration-response curves, with a minority exhibiting biphasic curves. Of nine neurons tested, seven exhibited monophasic curves with a maximum response at
~1 µM glycine and a mean pmKD of
7.65 ± 0.06. Two neurons exhibited biphasic curves with a maximum
response at ~30 µM glycine and with
mKD values of 20 and 44 nM for the
high-affinity component and 1100 and 860 nM for the
low-affinity component. Amplitudes of the high-affinity component were
46 and 84% and for the low-affinity component were 54 and 16%,
respectively.
Glutamate concentration-response curves were constructed by jumping
rapidly from a control solution to one containing increasing concentrations of glutamate in the continuous presence of 30 µM glycine and 10 µM NBQX (to prevent
activation of AMPA and kainate receptors) in both the control and
glutamate-containing solutions. Glutamate concentration-response
curves from all three age groups were monophasic. Fits of the mean data
with the two-equivalent binding site model yielded
mKD values of 1.4, 2.3, and 2.4 µM for 2- to 3-, 14- to 15-, and 27- to 29-d-old animals, respectively, and maximum responses for all three age groups at ~300
µM glutamate (Fig. 3).
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Figure 3.
Glutamate concentration-response curves from 2- to 3-d-old cortical neurons (open circles), 14- to
15-d-old cortical neurons (open squares), and 27- to
29-d-old cortical neurons (closed circles). Mean ± SE peak currents for each age group have been normalized to their
respective 300 µM glutamate peak response. Peak inward currents were elicited in response to 2 sec fast applications of
increasing concentrations of glutamate in the continuous presence of 30 µM glycine and 10 µM NBQX. Shown are
monophasic curves fitted with the two-equivalent binding site model
that yielded mKD values of 1.4, 2.3, and 2.4 µM for 2- to 3-, 14- to 15-, and 27- to 29-d-old animals,
respectively.
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On completion of concentration-response curves with both glutamate and
glycine, we assessed the inhibition of currents evoked by a maximal
concentration of the appropriate agonist, together with the appropriate
co-agonist, by 10 µM ifenprodil. Ifenprodil (10 µM) was applied continuously, and agonist applications
were made until stable steady-state current levels were attained. In neurons from 2- to 3-, 14- to 15-, and 27- to 29-d-old animals, 10 µM ifenprodil inhibited 90 ± 2, 68 ± 3, and
65 ± 4% of the steady-state current, respectively
(n = 7, 15, and 9, respectively). Thus, ifenprodil
sensitivity is reduced in an age-dependent manner. Notably, in 28-d-old
animals the mean amplitude of the high-affinity component of
the glycine concentration-response curves was 53 ± 5%, whereas
ifenprodil inhibited significantly more of the steady-state current
(65 ± 4%; one-tailed t-test, p < 0.05), suggesting that ifenprodil might inhibit a proportion of NMDA
receptors exhibiting low affinity for glycine together with those
exhibiting high affinity. We obtained ifenprodil inhibition curves
against 100 µM NMDA-evoked steady-state currents in the
continuous presence of 30 µM glycine using 27- to
29-d-old neurons (Fig. 4). As
demonstrated previously with cultured neurons (Priestley et al., 1994),
inhibition curves to ifenprodil were biphasic, with IC50
values of 0.21 and 58 µM for the high- and low-affinity
components, respectively. The relative amplitudes of the high- and
low-affinity components were 70 and 30%, respectively. Importantly, 10 µM ifenprodil inhibited the high-affinity component
completely but left the low-affinity component almost unaffected.
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Figure 4.
Biphasic ifenprodil inhibition curves from 27- to
29-d-old cortical neurons. The antagonism of 100 µM NMDA
steady-state currents by increasing concentrations of ifenprodil is
expressed as a function of control response (i.e., pre-ifenprodil
response amplitude). NMDA (100 µM) was applied for 5 sec
at 25 sec intervals in the continuous presence of 30 µM
glycine. Increasing concentrations of ifenprodil were applied in both
agonist-containing and wash solutions. NMDA applications were made
until stable steady-state current levels were attained in the presence
of each concentration of ifenprodil. Shown is a curve fitted through
the mean data ± SE obtained from four neurons, using a biphasic
model, from which IC50 values and slopes of 0.21 µM (slope = 1) and 58 µM (slope = 2) were obtained for the high- and low-affinity components, respectively. The relative amplitudes of the high- and low-affinity components were 70 and 30%, respectively. Notably, 10 µM
ifenprodil produced a maximal inhibition of the high-affinity component
but left the low-affinity component almost unaffected.
|
|
Ifenprodil inhibits NMDA receptors with both high and low
glycine affinities
To further investigate the ability of 10 µM
ifenprodil to inhibit the high- and low-affinity glycine components of
the NMDA current, a kinetic approach was used. The high- and
low-affinity glycine components were revealed by rapid application of a
high concentration of the glycine site antagonist 7-chlorokynurenic acid during a steady-state current evoked by 100 µM
glutamate in the continuous presence of 30 µM glycine and
10 µM NBQX. The decay of NMDA currents after rapid
application of 7-chlorokynurenic acid in the presence of glycine has
been demonstrated previously to reflect the rate of dissociation of
glycine from the NMDA receptor, which is the rate-limiting step
(Benveniste et al., 1990). The rate of dissociation of glycine varies
significantly depending on the receptor affinity (Priestley and Kemp,
1993). In 2- to 3-d-old animals, the current decay after rapid
application of 1 mM 7-chlorokynurenic acid was well fitted
by a single exponential with a mean on-rate time constant of 1327 ± 57 msec (n = 10 cells) (Fig.
5A). The recovery of the
steady-state current after a rapid jump back into 100 µM
glutamate in the absence of 7-chlorokynurenic acid, which is likely to
represent the rate of 7-chlorokynurenic acid unbinding, was, as would
be predicted, best fitted by a two-equivalent binding site model (see
Materials and Methods) that yielded a mean value of 77 ± 4 msec. Notably, the speed of solution exchange using our perfusion
system ( = ~30 msec) renders the absolute accuracy of the fast
measured time constants somewhat uncertain. Nevertheless, the measured
7-chlorokynurenic acid off rates were very similar to those reported
previously by Benveniste et al. (1990). After recovery from the jumps
into 7-chlorokynurenic acid, a rapid jump was made into 100 µM glutamate and 10 µM ifenprodil. Ifenprodil inhibited 93 ± 1% of the steady-state current. In
neurons from 27- to 29-d-old animals the current decay after rapid
application of 1 mM 7-chlorokynurenic acid was well fitted
by two exponentials, with mean on-rate time constants (and relative
amplitudes) of 94 ± 10 msec (64 ± 2%) and 1644 ± 223 msec (36 ± 2%) (Fig. 5B) (n = 8 cells). The time course of the slow component was not significantly different from the on rate in the 2- to 3-d-old neurons (two-tailed t-test, p > 0.15). The recovery of the
steady-state current after a rapid jump back from the 7-chlorokynurenic
acid-containing solution was again best fitted by a two-equivalent
binding site model that yielded a mean value of 75 ± 6 msec,
which was not significantly different from the value obtained from the
younger neurons (two tailed t-test, p > 0.76). Ifenprodil (10 µM) inhibited 68 ± 3% of the
steady-state current, significantly less than in the 3-d-old neurons
(two tailed t-test, p < 0.001). The decay
of the current after rapid application of ifenprodil to neurons of both
ages was best fitted with a single exponential (Fig. 5), and after removal of ifenprodil the current recovery was slow ( = ~50 sec; data not shown), in agreement with our previous observations (Kew et
al., 1998) and consistent with ifenprodil binding with high affinity to
a single receptor population. A two-phase onset and recovery from block
by ifenprodil of steady-state NMDA currents evoked in the presence of
high ( 30 µM) but not low concentrations of ifenprodil
has been reported previously (Legendre and Westbrook, 1991). The fast
rates of onset and recovery from block at high concentrations of
ifenprodil only were attributed to a low-affinity interaction. We have
observed a similar two-phase onset and recovery from block of
steady-state NMDA currents (100 µM NMDA and 30 µM glycine) from 27- to 29-d-old neurons by 300 µM ifenprodil, which inhibits virtually all of the
NMDA-evoked current (Fig. 4), but not 10 µM ifenprodil
(data not shown), confirming that the low-affinity ifenprodil
interaction is readily distinguishable kinetically, and that it is
clearly not apparent with 10 µM ifenprodil.
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Figure 5.
Fast application of 7chlorokynurenic acid during a 100 µM glutamate- plus 30 µM glycine-evoked steady-state current reveals high- and
low-affinity glycine components. Steady-state currents were evoked in
2- to 3-d-old cortical neurons (A) and 27- to
29-d-old cortical neurons (B) in the continual
presence of 10 µM NBQX. Steady-state current amplitudes
were 70 and 435 pA in A and B, respectively. Once a stable steady-state current was attained, a rapid
jump was made into an identical solution containing 1 mM
7-chlorokynurenic acid (7Cl-Kyn) until a stable
steady-state current was again achieved, after which a rapid
jump was made back into a 7-chlorokynurenic acid-free solution. The
jump into and out of 7-chlorokynurenic acid was repeated three times on each neuron. An averaged current inhibition and recovery from a
representative neuron in each age group is shown. The decay of the
currents after rapid application of 7-chlorokynurenic acid was fitted
with single (2- to 3-d-old neurons) and double (27- to
29-d-old neurons) exponential curves, respectively. The current recoveries after removal of 7-chlorokynurenic acid were fitted with
the two-equivalent binding site model. After the jumps into 7-chlorokynurenic acid, a rapid jump was made into 100 µM
glutamate and 10 µM ifenprodil. The decay of the current
was well fitted by single exponentials ( = 720 and 1000 msec for 2- to 3- and 27- to 29-d-old neurons, respectively). Note the different
time scales of the three current traces shown for each age group.
Intervening sections of the trace have been omitted for clarity.
|
|
Developmental changes in cortical expression of NR2A and NR2B mRNA
and protein
NR2A and NR2B are the predominant NR2 subunits in the cortex both
during development and in the adult (Monyer et al., 1992, 1994;
Watanabe et al., 1992; Zhong et al., 1995; Wenzel et al., 1997).
Therefore, we examined the expression of NR2A and NR2B mRNA and protein
in 3-, 14-, and 28-d-old rats. In situ hybridization analysis (Fig. 6) revealed that NR2A mRNA
is already expressed at moderate levels in the parietal cortex of
3-d-old rats (40%) and that its expression is maximal (100%) at
14 d and is maintained at 28 d (from optical density
measurements). In contrast, NR2B mRNA is already expressed at its
maximum level in 3-d-old animals. This expression level is maintained
at 14 d and then declines to 50% at 28 d.
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Figure 6.
Expression of NR2A and NR2B transcripts in rat
brain during ontogeny, revealed by in situ hybridization
histochemistry. Note the relatively low level of NR2A hybridization
signal (white areas) in postnatal d 3 (PN3) parietal cortex and the reduction in the NR2B
hybridization signal from PN14 to PN28.
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|
Quantitative Western blot analysis of parietal cortex membranes
prepared from animals at each time point revealed that the level of
NR2B protein was highest in 14-d-old rat cortex (100%), with 70 and
85% of the 14 d level present at 3 and 28 d, respectively (Fig. 7). NR2A protein was highest in
28-d-old rat cortex with 83% of this maximum level present at 14 d and undetectable levels in 3-d-old animals (Fig. 7).
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Figure 7.
Expression of NR2A and NR2B protein in rat
parietal cortex during ontogeny, revealed by Western blot analysis.
Note that the absolute optical densities for NR2A and NR2B are not
comparable because of the different affinities of the antibodies.
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| |
DISCUSSION |
In this study we have demonstrated a developmental change in rat
cortical neuronal NMDA receptor glycine affinity such that with age a
population of NMDA receptors appears that exhibits a markedly lower
affinity for glycine. Whereas it has long been accepted that activation
of the NMDA receptor requires occupation of both the glutamate and
glycine recognition sites (Johnson and Ascher, 1987; Kleckner and
Dingledine, 1988), the physiological role of glycine in the regulation
of NMDA receptor activity has remained unclear. The glycine
concentration in the extracellular and cerebrospinal fluids has been
estimated to be in the low micromolar range (Westergren et al., 1994);
however, glycine transporters (Zafra et al., 1995) might reduce the
glycine concentration to well below 1 µM in the local
microenvironment of NMDA receptors (Supplisson and Bergman, 1997). The
appearance of a population of NMDA receptors with a relatively low
affinity for glycine (mKD = ~800
nM; maximum response at ~30 µM glycine) as
revealed in this study, suggests that the extracellular glycine
concentration might not be saturating at a proportion of the cortical
NMDA receptors in adult rats. Modulation of extracellular glycine
concentration, perhaps by activity-dependent glycine release, or
perhaps by modulation of NMDA receptor affinity for glycine by receptor
phosphorylation and dephosphorylation (Wang et al., 1994), might
regulate the activity of this receptor subpopulation. Notably,
glutamate concentration-response analysis of neurons from all three
age groups tested revealed very little developmental change in receptor
affinity.
Studies on recombinant NMDA receptors have revealed that in heteromeric
receptors composed of NMDAR1 and NR2 subunits, the identity of the NR2
subunit exerts a major influence on receptor glycine affinity (Ikeda et
al., 1992; Kutsuwada et al., 1992; Priestley et al., 1995), whereas all
NMDAR1 splice variants exhibit similar affinities for glycine
(Nakanishi et al., 1992; Durand et al., 1993; Hollmann et al., 1993).
Receptors containing NR2D appear to exhibit the highest affinity for
both glutamate and glycine (Ikeda et al., 1992), whereas receptors
containing NR2A exhibit a markedly lower affinity for glycine relative
to the other NR2 subunits (Kutsuwada et al., 1992). In the adult rodent the predominant NR2 subunits in the forebrain are NR2A and NR2B, with
NR2C expressed largely in the cerebellum and various select nuclei and
NR2D expression confined to the diencephalon and midbrain (Kutsuwada et
al., 1992; Monyer et al., 1992, 1994, Ishii et al., 1993; Dunah et al.,
1996). Thus, in the adult forebrain the most abundant heteromeric
combinations are likely to be NMDAR1-NR2A, NMDAR1-NR2B, and
three-subunit-containing NMDAR1-NR2A-NR2B receptors (Sheng et al.,
1994; Luo et al., 1997). In the embryonic and early neonatal forebrain,
NR2B is expressed at relatively high levels, with expression of NR2A
increasing from birth through the second postnatal week, after which
time an adult expression pattern is reached (Watanabe et al., 1992;
Monyer et al., 1994; Sheng et al., 1994; Zhong et al., 1995; Wenzel et
al., 1997). In this study we have confirmed these observations. Despite
the expression of NR2A mRNA in the cortex of 3-d-old rats, we were
unable to detect any NR2A protein by Western blot analysis. The absence
of NR2A protein in these neurons is also supported by our
pharmacological analysis (discussed below). Interestingly, Wood et al.
(1996) have described a 5'-untranslated region of the NR2A mRNA that severely restricts its translation and that may form part of a mechanism controlling translational efficiency. The appearance of NMDA
receptors with a low affinity for glycine appears to correlate well
with the increased expression of NR2A mRNA and protein at 14 and
particularly 28 d, at which time it is accompanied by a decrease
in NR2B mRNA and protein. Thus, of the time points examined, the ratio
of NR2A/NR2B protein is at its highest at 28 d.
Ifenprodil is a subtype-selective NMDA antagonist that exhibits
~400-fold higher affinity for NMDAR1-1a-NR2B than for
NMDAR1-1a-NR2A heteromeric receptors (Williams, 1993). In this study
we have assayed the inhibition of steady-state currents by 10 µM ifenprodil, a concentration that maximally inhibits
currents elicited in Xenopus oocytes expressing NR2B but
leaves currents in oocytes expressing NR2A almost unaffected (Williams,
1993). We have demonstrated, both with inhibition curves and
kinetically, that 10 µM ifenprodil exhibits only a
high-affinity interaction with NMDA receptors expressed in 27- to
29-d-old neurons, and that it produces a maximal inhibition of the
high-affinity ifenprodil component of the current. Furthermore, the
proportion of NMDA steady-state current inhibited by ifenprodil (10 µM) decreased with age, in agreement with previous studies (Williams et al., 1993), again apparently correlating well with
the increased expression of the ifenprodil-insensitive NR2A subunit at
14 and 28 d.
Ifenprodil (10 µM) inhibited currents elicited in neurons
from 2- to 3-d-old animals almost completely, as would be predicted from the presence of NR2B and absence of NR2A protein. From studies with recombinant receptors it can be predicted that native NMDA receptors containing only NR2B would exhibit a relatively high affinity
for glycine (Kutsuwada et al., 1992; Priestley et al., 1995). This
prediction is supported by our observations that glycine concentration-response curves on cortical neurons from 2- to 3-d-old animals were monophasic and of high affinity, and that the decay of 100 µM glutamate/30 µM glycine-evoked
steady-state currents after rapid application of 7-chlorokynurenic acid
were well fitted by a single exponential with slow kinetics. Thus, it
appears likely that the large majority of NMDA receptors in cortical
neurons from these very young animals contain NR2B as the sole NR2
subunit. We have not assessed the expression of NR2D, which has been
shown to be expressed at relatively low levels in the rat cortex (Dunah et al., 1996; Wenzel et al., 1996), in neurochemically identified interneurons (Standaert et al., 1996). Recombinant receptors containing NR2D exhibit the highest affinity for glycine (Ikeda et al., 1992) but
also display a significantly higher affinity for glutamate (Ikeda et
al., 1992) and NMDA (Buller and Monaghan, 1997) as well as an extremely
slow current deactivation after removal of glutamate (Monyer et al.,
1994). Furthermore, they are insensitive to blockade by 10 µM ifenprodil (Williams, 1995). We have not observed a
similar pharmacological profile in this study, suggesting that NR2D was not expressed or was expressed at very low levels in the neurons we
recorded from.
Cortical neurons from 27- to 29-d-old animals are likely to contain
both NR2A and NR2B protein and, accordingly, to contain NMDA receptors
with high and low glycine affinity and high and low sensitivity to
ifenprodil. The fast and slow components of the decay of the glutamate
steady-state currents after rapid application of 7-chlorokynurenic acid
represent the low- and high-affinity glycine components, respectively
(Benveniste et al., 1990; Priestley and Kemp, 1993). Whereas 10 µM ifenprodil inhibited almost all of the 100 µM glutamate-evoked steady-state current in 3-d-old neurons, in which only the high-affinity glycine component is evident,
it inhibited 68 ± 3% in 28-d-old neurons, significantly more
than the proportion of the high-affinity (slow) glycine component (36 ± 2%; two tailed t-test, p < 0.0001). Thus, in 28-d-old neurons ifenprodil inhibits both the
high-affinity glycine component of the current and a considerable
portion (by subtraction of the above values, ~50%) of the
low-affinity glycine component.
NMDA receptor activation requires occupation of two independent glycine
sites (Benveniste and Mayer, 1991; Clements and Westbrook, 1991), and
thus, the current relaxation after removal of glycine (or addition of
7-chlorokynurenic acid) reflects the rate of glycine dissociation from
the lower-affinity site (i.e., the site with the fastest rate of
dissociation). Accordingly, if an NMDA receptor contained both NR2A and
NR2B, which conferred distinct affinities on each of the two glycine
sites, it would be the lower-affinity site that determined the
functional glycine affinity of the receptor. Furthermore, if the
inhibitory effect of ifenprodil was mediated by occupation of only a
single high-affinity binding site, as suggested by the slope of
monophasic, high-affinity ifenprodil inhibition curves (Kew et al.,
1996) and the slope of the high-affinity component of the biphasic
inhibition curve from 27- to 29-d-old neurons, the presence of a single
NR2B subunit, which contains amino acids critical for high-affinity
ifenprodil binding (Gallagher et al., 1996), would be sufficient to
confer high-affinity ifenprodil sensitivity. Thus, ifenprodil would
bind with high affinity to NMDA receptors exhibiting low glycine
affinity that contain both NR2A and NR2B subunits, in accord with our
findings.
Thus, our results suggest that individual cortical neurones of 27- to
29-d-old rats contain at least three populations of NMDA receptors: (1)
receptors exhibiting high affinity for glycine, slow glycine
dissociation kinetics, and high-affinity block by ifenprodil, which
contain NR2B as the sole NR2 subunit, (2) receptors exhibiting low
affinity for glycine, fast glycine dissociation kinetics, and
insensitivity to ifenprodil, which contain NR2A as the sole NR2
subunit, and (3) receptors exhibiting low affinity for glycine, fast
glycine dissociation kinetics, and high-affinity block by ifenprodil,
which are likely to contain both NR2A and NR2B.
| |
FOOTNOTES |
Received Oct. 23, 1997; revised Dec. 11, 1997; accepted Dec. 23, 1997.
We thank Jürg Messer, Zaiga Bleuel, and Danièle Buchy for
expert technical assistance.
Correspondence should be addressed to John A. Kemp, Pharma Division,
Preclinical CNS Research, F. Hoffmann-La Roche Ltd., Building 69/412,
CH-4070 Basel, Switzerland.
| |
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Abstract
Introduction
Compound via MeSH
